Bacterial Community Structure Modulates Soil Phosphorus Turnover at Early Stages of Primary Succession

IF 5.4 2区 地球科学 Q1 ENVIRONMENTAL SCIENCES Global Biogeochemical Cycles Pub Date : 2024-10-07 DOI:10.1029/2024GB008174
Yuhan Wang, Haijian Bing, Daryl L. Moorhead, Enqing Hou, Yanhong Wu, Jipeng Wang, Chengjiao Duan, Qingliang Cui, Zhiqin Zhang, He Zhu, Tianyi Qiu, Zhongmin Dai, Wenfeng Tan, Min Huang, Hans Lambers, Peter B. Reich, Linchuan Fang
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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.

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细菌群落结构调节初级演替早期阶段的土壤磷周转
微生物是陆地生态系统中土壤磷(P)循环的驱动力;然而,在原生演替过程中,土壤微生物在富含 P 的土壤中介导 P 循环的作用仍不确定。本研究考察了青藏高原东部130年冰川时序上细菌群落结构(多样性和组成)及其功能潜力(P循环功能基因的绝对丰度)对土壤P循环的影响。与P循环基因相比,细菌群落结构能更好地预测土壤中P的含量。冰川退缩后,由于细菌多样性增加、种间相互作用改变以及参与土壤钾矿化的物种丰富,无机钾的溶解和有机钾的矿化显著增强,从而提高了钾的可用性。虽然 84% 的 P 循环基因与有机 P 矿化有关,但这些基因与土壤有机碳的关系比与有机 P 的关系更为密切。细菌对碳的需求可能决定了土壤中 P 的周转,这表明有机质分解过程在富含 P 的高寒土壤中起着主导作用。此外,细菌共生网络和类群-基因-P 网络的复杂性在后期明显下降,这表明随着演替的进行,细菌群落在推动土壤 P 循环方面的主导作用在下降。我们的研究结果表明,在原生演替的早期阶段,具有复杂群落结构的细菌在富含 P 的土壤中具有显著的 P 生物地球化学循环潜力。
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来源期刊
Global Biogeochemical Cycles
Global Biogeochemical Cycles 环境科学-地球科学综合
CiteScore
8.90
自引率
7.70%
发文量
141
审稿时长
8-16 weeks
期刊介绍: Global Biogeochemical Cycles (GBC) features research on regional to global biogeochemical interactions, as well as more local studies that demonstrate fundamental implications for biogeochemical processing at regional or global scales. Published papers draw on a wide array of methods and knowledge and extend in time from the deep geologic past to recent historical and potential future interactions. This broad scope includes studies that elucidate human activities as interactive components of biogeochemical cycles and physical Earth Systems including climate. Authors are required to make their work accessible to a broad interdisciplinary range of scientists.
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