1. Bacterial Community Structure Modulates Soil Phosphorus Turnover at Early Stages of Primary Succession.
- Author
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Wang, Yuhan, Bing, Haijian, Moorhead, Daryl L., Hou, Enqing, Wu, Yanhong, Wang, Jipeng, Duan, Chengjiao, Cui, Qingliang, Zhang, Zhiqin, Zhu, He, Qiu, Tianyi, Dai, Zhongmin, Tan, Wenfeng, Huang, Min, Lambers, Hans, Reich, Peter B., and Fang, Linchuan
- Subjects
MOUNTAIN soils ,BIOGEOCHEMICAL cycles ,SOIL microbiology ,BACTERIAL diversity ,BACTERIAL communities ,FUNGAL communities ,PLATEAUS - Abstract
Microbes are the drivers of soil phosphorus (P) cycling in terrestrial ecosystems; however, the role of soil microbes in mediating P cycling in P‐rich soils during primary succession remains uncertain. This study examined the impacts of bacterial community structure (diversity and composition) and its functional potential (absolute abundances of P‐cycling functional genes) on soil P cycling along a 130‐year glacial chronosequence on the eastern Tibetan Plateau. Bacterial community structure was a better predictor of soil P fractions than P‐cycling genes along the chronosequence. After glacier retreat, the solubilization of inorganic P and the mineralization of organic P were significantly enhanced by increased bacterial diversity, changed interspecific interactions, and abundant species involved in soil P mineralization, thereby increasing P availability. Although 84% of P‐cycling genes were associated with organic P mineralization, these genes were more closely associated with soil organic carbon than with organic P. Bacterial carbon demand probably determined soil P turnover, indicating the dominant role of organic matter decomposition processes in P‐rich alpine soils. Moreover, the significant decrease in the complexity of the bacterial co‐occurrence network and the taxa‐gene‐P network at the later stage indicates a declining dominance of the bacterial community in driving soil P cycling with succession. Our results reveal that bacteria with a complex community structure have a prominent potential for biogeochemical P cycling in P‐rich soils during the early stages of primary succession. Plain Language Summary: Microbial P turnover regulates soil P biogeochemical cycling during primary succession. Here, we revealed that the changes in bacterial community diversity, taxa abundance, and interspecific interaction were better predictors of soil P fraction variation than P‐cycling gene abundances along a 130‐year glacial chronosequence. The close link of organic P mineralization genes to SOC shows that bacterial carbon demand actuated soil P turnover through organic matter mineralization. Furthermore, we found that bacterial functioning on soil P cycling predominated during early succession stages, which attenuated with the dominance of higher plants and plant‐fungal symbionts. Key Points: Changes in bacterial community diversity, taxa abundance and interspecific interaction contributed the most to soil P fraction variationBacterial C demand facilitated soil P turnover by mediating their organic P mineralization potentialBacterial functioning on P cycling predominated during early succession stages but attenuated when higher plant‐fungal symbionts emerged [ABSTRACT FROM AUTHOR]
- Published
- 2024
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