环境科学
保护性农业
矿化(土壤科学)
农学
农业
硝化作用
可持续农业
氮气循环
全球变暖
农林复合经营
水土保持
气候变化
硝酸盐
生态学
覆盖作物
氮气
农业生产力
反硝化
作物轮作
精耕细作
微生物种群生物学
粮食安全
持续性
作者
Cunkang Hao,Jennifer A. J. Dungait,Wen‐Hui Shang,Ruixing Hou,Huarui Gong,Yunfeng Yang,Hans Lambers,Peng Yu,Manuel Delgado‐Baquerizo,Xingliang Xu,Amit Kumar,Ye Deng,Xi Peng,Zhenling Cui,Yakov Kuzyakov,Jizhong Zhou,Fusuo Zhang,Jing Tian
标识
DOI:10.1038/s41467-025-65999-z
摘要
N-labeling, root metabolomics and microbial metagenomics. We find that warming amplifies the positive effects on wheat nitrate uptake by 25% in conservation agriculture compared to conventional agriculture, while alleviating microbial competition for N. Additionally, warming increases soil gross N mineralization and nitrification rates by 191% and 159%, but decreases microbial immobilization by 24% in conservation agriculture. Concurrently, microbial genes for mineralization and nitrification are enriched, while those for N immobilization and nitrate reduction are reduced under conservation agriculture with warming. These shifts are driven by alterations in root primary and secondary metabolites, which reshape N-cycling microbial functional niches and optimize multiple microbial N processes beyond mere organic N mining. This reconfiguration increases carbon-nitrogen exchange efficiency, enabling wheat to outcompete soil microorganisms for N. Collectively, our findings suggest that conservation agriculture enhances plant N acquisition by strengthening plant-soil-microbe interactions under climate change, providing a sustainable strategy for future food security.
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