Linking main ecological clusters of soil bacterial–fungal networks and nitrogen cycling genes to crop yields under diverse cropping systems in the North China Plain

IF 5.2 2区农林科学 Q1 AGRICULTURE, MULTIDISCIPLINARY

Chemical and Biological Technologies in Agriculture Pub Date : 2024-07-30 DOI:10.1186/s40538-024-00617-6

Shuting Yu, Xinguo Chen, Tianshu Wang, Shuihong Yao, Xinhua Peng

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引用次数: 0

Abstract

Background

Crop rotation changes crop species and the associated management strategies, significantly influencing soil fertility and soil microbial communities. Interactions among the species in microbial communities are important for soil nutrient cycling. Yet, the contribution of soil microbial interactions to crop yield and soil nitrogen-cycle function under wheat–maize and wheat–soybean rotation conversion remains unclear. An 8-year field experiment was conducted to investigate the impact of simple [8-year wheat–maize rotation (8WM) and 8-year wheat–soybean rotation (8WS)] and diverse cropping systems [4-year wheat–soybean followed by 4-year wheat–maize rotation (4WS4WM) and 4-year wheat–maize followed by 4-year wheat–soybean rotation (4WM4WS)] on crop yield, soil properties, bacterial–fungal co-occurrence networks and nitrogen functional potentials. The abundances of genes with nitrogen fixation (nifH), nitrification (AOB and nxrA) and denitrification (narG, nirK, norB and nosZ) potentials were quantified and bacterial and fungal communities were characterized.

Results

4WS4WM led to higher succeeding maize yields and lower bacterial–fungal network complexity, nitrogen fixation potentials and denitrifying potentials than 8WM. Meanwhile, 4WM4WS exhibited higher succeeding wheat and soybean yields, network complexity and lower nitrifying potentials than 8WS. The ecological cluster with the most nitrifying and denitrifying bacterial species (Module#5) and that with the least species (Module#3) dominated the potentials of nitrogen fixation, nitrification and denitrification and succeeding maize yields in 4WS4WM and 8WM. Module#4 with the highest abundances of nitrifying bacteria (Nitrosomonadaceae) and Module#2 with the most species dominated the nitrifying potentials and succeeding wheat and soybean yields in 4WM4WS and 8WS. Soil water content, organic carbon, dissolved organic carbon, NO₃⁻ and pH were key drivers influencing Module#3 and Module#5, while only NH₄⁺ significantly affected Module#2 and Module#4.

Conclusions

These findings demonstrate the importance of ecological clusters within soil microbial network in regulating crop yield and soil nitrogen cycling, and identify specific ecological clusters dominating nitrogen functional potentials in wheat–maize and wheat–soybean rotations, offering science-based recommendations for sustainable crop rotation practices.

Graphical Abstract

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将华北平原不同耕作制度下土壤细菌-真菌网络和氮循环基因的主要生态群与作物产量联系起来

轮作会改变作物种类和相关的管理策略，从而对土壤肥力和土壤微生物群落产生重大影响。微生物群落中物种之间的相互作用对土壤养分循环非常重要。然而，在小麦-玉米和小麦-大豆轮作转换下，土壤微生物相互作用对作物产量和土壤氮循环功能的贡献仍不清楚。我们进行了一项为期 8 年的田间试验，研究简单种植系统[8 年小麦-玉米轮作（8WM）和 8 年小麦-大豆轮作（8WS）]和多样化种植系统[4 年小麦-大豆后 4 年小麦-玉米轮作（4WS4WM）和 4 年小麦-玉米后 4 年小麦-大豆轮作（4WM4WS）]对作物产量、土壤性质、细菌-真菌共生网络和氮功能潜力的影响。对具有固氮（nifH）、硝化（AOB 和 nxrA）和反硝化（narG、nirK、norB 和 nosZ）潜力的基因丰度进行了量化，并对细菌和真菌群落进行了特征描述。与 8WM 相比，4WS4WM 玉米产量更高，而细菌-真菌网络复杂性、固氮潜力和反硝化潜力较低。同时，与 8WS 相比，4WM4WS 表现出更高的小麦和大豆后继产量、网络复杂性和更低的硝化潜力。在 4WS4WM 和 8WM 中，硝化和反硝化细菌种类最多的生态群组（模块 #5）和种类最少的生态群组（模块 #3）在固氮、硝化和反硝化潜力以及玉米后继产量方面占主导地位。在 4WM4WS 和 8WS 中，硝化细菌（亚硝化单胞菌科）数量最多的模块 #4 和物种最多的模块 #2 主导了硝化潜力以及后续的小麦和大豆产量。土壤含水量、有机碳、溶解有机碳、NO3- 和 pH 是影响模块 #3 和模块 #5 的主要驱动因素，而只有 NH4+ 对模块 #2 和模块 #4 有显著影响。这些发现证明了土壤微生物网络中的生态群在调节作物产量和土壤氮循环中的重要性，并确定了在小麦-玉米和小麦-大豆轮作中主导氮功能潜力的特定生态群，为可持续轮作实践提供了科学建议。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Chemical and Biological Technologies in Agriculture Biochemistry, Genetics and Molecular Biology-Biotechnology

CiteScore

6.80

自引率

3.00%

发文量

审稿时长

15 weeks

期刊介绍： Chemical and Biological Technologies in Agriculture is an international, interdisciplinary, peer-reviewed forum for the advancement and application to all fields of agriculture of modern chemical, biochemical and molecular technologies. The scope of this journal includes chemical and biochemical processes aimed to increase sustainable agricultural and food production, the evaluation of quality and origin of raw primary products and their transformation into foods and chemicals, as well as environmental monitoring and remediation. Of special interest are the effects of chemical and biochemical technologies, also at the nano and supramolecular scale, on the relationships between soil, plants, microorganisms and their environment, with the help of modern bioinformatics. Another special focus is the use of modern bioorganic and biological chemistry to develop new technologies for plant nutrition and bio-stimulation, advancement of biorefineries from biomasses, safe and traceable food products, carbon storage in soil and plants and restoration of contaminated soils to agriculture. This journal presents the first opportunity to bring together researchers from a wide number of disciplines within the agricultural chemical and biological sciences, from both industry and academia. The principle aim of Chemical and Biological Technologies in Agriculture is to allow the exchange of the most advanced chemical and biochemical knowledge to develop technologies which address one of the most pressing challenges of our times - sustaining a growing world population. Chemical and Biological Technologies in Agriculture publishes original research articles, short letters and invited reviews. Articles from scientists in industry, academia as well as private research institutes, non-governmental and environmental organizations are encouraged.