文献类型： 外文期刊

作者： Ma, Long ¹ ; Wu, Dongming ¹ ; Li, Ruonan ³ ; Luan, Haoan ⁴ ; Tang, Jiwei ¹ ; Wang, Liying ³ ; Guo, Tengfei ⁵ ; Ai, Chao ¹ ; Huang, Shaowen ¹ ;

作者机构： 1.Chinese Acad Agr Sci, Inst Agr Resources & Reg Planning, State Key Lab Efficient Utilizat Arid & Semiarid A, Beijing 100081, Peoples R China

2.Chinese Acad Trop Agr Sci, Environm & Plant Protect Inst, Key Lab Low carbon Green Agr Trop reg China, Minist Agr & Rural Affairs, Haikou 571101, Peoples R China

3.Hebei Acad Agr & Forestry Sci, Inst Agr Resources & Environm, Shijiazhuang 050051, Peoples R China

4.Hebei Agr Univ, Coll Forestry, Baoding 071000, Peoples R China

5.Henan Acad Agr Sci, Inst Plant Nutr & Environm Resources, Zhengzhou 450002, Peoples R China

关键词： DNA-SIP; Different nitrogen forms; Fertilization legacy effects; Temperatures response; Carbohydrate-active enzyme gene; Soil nutrient stoichiometry

期刊名称：APPLIED SOIL ECOLOGY （ 影响因子：5.0； 五年影响因子：5.4 ）

ISSN： 0929-1393

年卷期： 2025 年 210 卷

页码：

收录情况： SCI

摘要： Straw returned into field is a crucial practice for improving soil carbon sequestration and crop productivity. However, it remains unknow how fertilization legacy effects with different nitrogen (N) forms regulate the microbial communities and genes of straw decomposition under global warming. This study analyzed soils with 12 years of four fertilization regimes, including chemical-fertilizer-N (CF), 2/4 chemical-fertilizer-N + 2/4 manure-N (CM), 2/4 chemical-fertilizer-N + 2/4 maize-straw-N (CS), and 2/4 chemical-fertilizer-N + 1/4 manure-N + 1/4 maize-straw-N (CMS). Soils with 13C-labeled maize straw were incubated at 15, 25, and 35 degrees C, and microbial function involved in straw decomposition and nutrient stoichiometric mechanisms were explored using DNA-SIP combined with metagenomics analysis. Results showed that organic-materials N treatments, especially straw-amended N treatments (CMS and CS), improved cellulose decomposition by increasing beta-glucosidase genes whereas decreasing endoglucanase and cellobiohydrolase genes. Organic-materials N treatments promoted hemicellulose degradation by increasing xylanase gene expression. Straw-amended N treatments facilitated lignin degradation by upregulating oxidase genes. These positive legacy effects were amplified with elevated temperatures and could be attributed to heterogeneity in straw-decomposing communities. Specifically, the abundance of Gemmatimonadetes and Betaproteobacteria increased with incubation temperature increased, whereas Alphaproteobacteria and Actinomycetia decreased. Organic-materials N treatments, especially straw-amended N treatments, increased the relative abundance of Actinomycetia, Gammaproteobacteria, and Gemmatimonadetes by 2.8 %, 2.7 %, and 39.7 % on average, respectively. Mantel's test further indicated that soil TOC, DOC, MBC, and C/N at different temperatures significantly promoted straw decomposition, with TN and C/P ratio being particularly influential at low and high temperatures, respectively. In conclusion, N fertilization modifies microbial communities and genes involved in straw decomposition through nutrient stoichiometry regulation. The rise in temperature decouples these relationships, highlighting the significance of applying organic-fertilizer-N to improve straw decomposition under global warming.