Soil properties drive nitrous oxide accumulation patterns by shaping denitrifying bacteriomes.

IF 6.2 2区 环境科学与生态学 Q1 GENETICS & HEREDITY
Saira Bano, Qiaoyu Wu, Siyu Yu, Xinhui Wang, Xiaojun Zhang
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Abstract

In agroecosystems, nitrous oxide (N₂O) emissions are influenced by both microbiome composition and soil properties, yet the relative importance of these factors in determining differential N₂O emissions remains unclear. This study investigates the impacts of these factors on N₂O emissions using two primary agricultural soils from northern China: fluvo-aquic soil (FS) from the North China Plain and black soil (BS) from Northeast China, which exhibit significant differences in physicochemical properties. In non-sterilized controls (NSC), we observed distinct denitrifying bacterial phenotypes between FS and BS, with BS exhibiting significantly higher N₂O emissions. Cross-inoculation experiments were conducted by introducing extracted microbiomes into sterile recipient soils of both types to disentangle the relative contributions of soil properties and microbiomes on N₂O emission potential. The results showed recipient-soil-dependent gas kinetics, with significantly higher N₂O/(N₂O + N₂) ratios in BS compared to FS, regardless of the inoculum type. Metagenomic analysis further revealed significant shifts in denitrification genes and microbial diversity of the inoculated bacteriomes influenced by the recipient soil. The higher ratios of nirS/nosZ in FS and nirK/nosZ in BS indicated that the recipient soil dictates the formation of different denitrifying guilds. Specifically, the BS environment fosters nirK-based denitrifiers like Rhodanobacter, contributing to higher N₂O accumulation, while FS supports a diverse array of denitrifiers, including Pseudomonas and Stutzerimonas, associated with complete denitrification and lower N₂O emissions. This study underscores the critical role of soil properties in shaping microbial community dynamics and greenhouse gas emissions. These findings highlight the importance of considering soil physicochemical properties in managing agricultural practices to mitigate N₂O emissions.

土壤特性通过塑造反硝化细菌群来驱动一氧化二氮的积累模式。
在农业生态系统中,一氧化二氮(N₂O)的排放受微生物群组成和土壤性质的影响,但这些因素在决定不同的 N₂O 排放中的相对重要性仍不清楚。本研究利用华北平原的氟钾土壤(FS)和东北黑土(BS)这两种初级农用土壤,研究了这些因素对 N₂O 排放的影响。在非灭菌对照(NSC)中,我们观察到FS和BS的反硝化细菌表型截然不同,BS的N₂O排放量明显更高。我们将提取的微生物组引入两种类型的无菌受体土壤中,进行了交叉接种实验,以区分土壤特性和微生物组对 N₂O 排放潜力的相对贡献。结果表明,无论接种物类型如何,受体土壤依赖于气体动力学,与 FS 相比,BS 的 N₂O/(N₂O + N₂)比率明显更高。元基因组分析进一步揭示了受体土壤对接种菌群的反硝化基因和微生物多样性的显著影响。FS中nirS/nosZ和BS中nirK/nosZ的比例较高,这表明受体土壤决定了不同反硝化行会的形成。具体地说,BS 环境促进了以 nirK 为基础的反硝化菌(如 Rhodanobacter)的发展,导致更高的 N₂O 积累,而 FS 则支持包括假单胞菌和 Stutzerimonas 在内的多种反硝化菌,与完全反硝化和较低的 N₂O 排放有关。这项研究强调了土壤特性在影响微生物群落动态和温室气体排放方面的关键作用。这些发现强调了在管理农业实践以减少氮氧化物排放时考虑土壤理化性质的重要性。
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来源期刊
Environmental Microbiome
Environmental Microbiome Immunology and Microbiology-Microbiology
CiteScore
7.40
自引率
2.50%
发文量
55
审稿时长
13 weeks
期刊介绍: Microorganisms, omnipresent across Earth's diverse environments, play a crucial role in adapting to external changes, influencing Earth's systems and cycles, and contributing significantly to agricultural practices. Through applied microbiology, they offer solutions to various everyday needs. Environmental Microbiome recognizes the universal presence and significance of microorganisms, inviting submissions that explore the diverse facets of environmental and applied microbiological research.
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