Soil carbon storage and accessibility drive microbial carbon use efficiency by regulating microbial diversity and key taxa in intercropping ecosystems

IF 5.1 1区 农林科学 Q1 SOIL SCIENCE Biology and Fertility of Soils Pub Date : 2024-03-15 DOI:10.1007/s00374-024-01804-1
Ziyu Yang, Qirui Zhu, Yuping Zhang, Pan Jiang, Yizhe Wang, Jiangchi Fei, Xiangmin Rong, Jianwei Peng, Xiaomeng Wei, Gongwen Luo
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Abstract

Intercropping is a powerful practice to alter the allocation of photosynthetic carbon (C) to belowground ecosystems via promotion of diversified plant communities. The feedback of soil C stability to intercropping is controlled by microbial C use efficiency (CUE). Despite its significance, there is currently insufficient evidence to decipher how soil microbial CUE reacts to intercropping. By combining a 10-year-long intercropping experiment with a substrate-independent 18O-H2O labelling approach and high-throughput sequencing, we elucidated the performance of intercropping on soil C pool and microbial metabolic traits as well as their relationships with soil microbial communities. Compared with monoculture, maize intercropping with peanut and soybean significantly increased soil C storage, soil mineral-associated organic C (MAOC), soil dissolved organic (DOC), and soil microbial biomass (MBC) contents at maize four growth stages. Soil microbial CUE increased significantly, especially at maize flowering and mature stages, as a consequence of enhanced microbial growth and biomass turnover rate after maize intercropping with peanut and soybean. Soil C storage and accessibility indicators (e.g., MAOC, DOC, and MBC contents) could significantly predict the changes of soil microbial diversity and core taxa. Meanwhile, the beta-diversity (community composition) of soil bacteria, fungi, saprotroph and protists, as well as rare fungal taxa were positively correlated with soil microbial CUE, and these indicators showed a high prediction of the microbial CUE. Soil C storage and accessibility indicators directly and indirectly influenced soil microbial CUE by regulating microbial diversity and key taxa. Soil microbial diversity and core taxa directly and indirectly influenced microbial CUE by mediating microbial respiration, growth, biomass, and enzyme activity, which mediated by soil C storage and accessibility. These findings provide an evidence for the associations between microbial diversity, CUE, and soil C stability, highlighting the importance of intercropping-driven soil microbiome to enhance soil microbial CUE.

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通过调节间作生态系统中的微生物多样性和关键类群,土壤碳储量和可获取性推动微生物碳利用效率的提高
间作是通过促进多样化植物群落来改变光合碳(C)向地下生态系统分配的一种有效方法。土壤碳稳定性对间作的反馈受微生物碳利用效率(CUE)的控制。尽管其意义重大,但目前还没有足够的证据来解释土壤微生物 CUE 如何对间作产生反应。通过将长达 10 年的间作实验与基质无关的 18O-H2O 标记方法和高通量测序相结合,我们阐明了间作对土壤碳库和微生物代谢特征的影响,以及它们与土壤微生物群落的关系。与单作相比,玉米与花生和大豆间作显著增加了玉米四个生长阶段的土壤碳储量、土壤矿质相关有机碳(MAOC)、土壤溶解有机物(DOC)和土壤微生物生物量(MBC)含量。由于玉米与花生和大豆间作后微生物生长和生物量周转率提高,土壤微生物 CUE 显著增加,尤其是在玉米开花期和成熟期。土壤碳储量和可利用性指标(如 MAOC、DOC 和 MBC 含量)可显著预测土壤微生物多样性和核心类群的变化。同时,土壤细菌、真菌、噬菌体和原生动物的β-多样性(群落组成)以及稀有真菌类群与土壤微生物CUE呈正相关,这些指标对微生物CUE有较高的预测作用。土壤碳储量和可利用性指标通过调控微生物多样性和关键类群直接或间接影响土壤微生物CUE。土壤微生物多样性和核心类群通过调节微生物的呼吸、生长、生物量和酶活性直接和间接影响微生物的CUE,而微生物的呼吸、生长、生物量和酶活性又受土壤碳储量和可及性的影响。这些发现为微生物多样性、CUE 和土壤碳稳定性之间的联系提供了证据,突出了间作驱动的土壤微生物组对提高土壤微生物 CUE 的重要性。
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来源期刊
Biology and Fertility of Soils
Biology and Fertility of Soils 农林科学-土壤科学
CiteScore
11.80
自引率
10.80%
发文量
62
审稿时长
2.2 months
期刊介绍: Biology and Fertility of Soils publishes in English original papers, reviews and short communications on all fundamental and applied aspects of biology – microflora and microfauna - and fertility of soils. It offers a forum for research aimed at broadening the understanding of biological functions, processes and interactions in soils, particularly concerning the increasing demands of agriculture, deforestation and industrialization. The journal includes articles on techniques and methods that evaluate processes, biogeochemical interactions and ecological stresses, and sometimes presents special issues on relevant topics.
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