Dynamics of nitrogen mineralization and nitrogen cycling functional genes in response to soil pore size distribution

IF 3.7 2区 农林科学 Q1 ECOLOGY
Danni Li , Yi Li , Shuihong Yao , Hu Zhou , Shan Huang , Xianlong Peng , Yili Meng
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引用次数: 0

Abstract

Soil pore distribution influences the permeability of gas, water, and solutes, affecting microbial activities such as nitrogen (N) mineralization. Understanding its impact on N mineralization and the subsequent N transformations is essential for managing compacted paddy soils. This study conducted incubation experiments on two paddy soils from typical Chinese rice regions, Northeastern meadow chernozemic Mollisols, and Southern umbric Ferralsols, under three bulk densities (1.0 g cm−3, 1.2 g cm−3, and 1.4 g cm−3) to investigate the effects of soil porosity on N mineralization and N cycling functional genes. Although the cumulative mineralized N showed no significant difference, with increased macropores (>100 μm) and mesopores (30–100 μm), Ferralsols exhibited a significantly higher net N mineralization rate from day 0 to day 7, while Mollisols extended the mineralization after day 21. Soil dissolved organic carbon (DOC) had a similar temporal trend to the net N mineralization rate, suggesting DOC was the product of mineralization. Soil microbial biomass carbon (MBC) showed an opposite temporal trend to the net N mineralization rate in Mollisols, suggesting microbial biomass as a key N source for mineralization. Soil pores distribution did not affect nitrification under waterlogged conditions, but it affected nirK, nirS and nosZ genes by altering redox potential and substrates availability in the pore micro-environment. Overall, soil pores over 30 μm were the key pore size ranges affecting the intensity and duration of N mineralization, with different effects on DOC, MBC, and N cycling functional genes in Mollisols and Ferralsols. These findings emphasized the role of pore size in regulating N transformation in waterlogged conditions, contributing to the understanding of the N availability in compacted paddy soils from typical geographic rice-growing regions.
氮矿化和氮循环功能基因对土壤孔径分布的动态响应
土壤孔隙分布会影响气体、水和溶质的渗透性,从而影响氮(N)矿化等微生物活动。了解土壤孔隙分布对氮矿化及后续氮转化的影响对于治理板结水稻土至关重要。本研究对中国典型水稻区的两种水稻土--东北草甸钙质软土和南方钙质软土--在三种容重(1.0 g cm-3、1.2 g cm-3 和 1.4 g cm-3)下进行了培养实验,以研究土壤孔隙度对氮矿化和氮循环功能基因的影响。虽然累积矿化氮没有显著差异,但随着大孔(100 μm)和中孔(30-100 μm)的增加,Ferralsols 在第 0 天到第 7 天的净氮矿化率明显更高,而 Mollisols 在第 21 天后矿化率延长。土壤溶解有机碳(DOC)与净氮矿化率的时间趋势相似,表明 DOC 是矿化的产物。土壤微生物生物量碳(MBC)与 Mollisols 中净氮矿化率的时间趋势相反,表明微生物生物量是矿化的关键氮源。土壤孔隙分布并不影响积水条件下的硝化作用,但会通过改变孔隙微环境中的氧化还原电位和基质可用性而影响 nirK、nirS 和 nosZ 基因。总体而言,30 μm 以上的土壤孔隙是影响氮矿化强度和持续时间的关键孔隙大小范围,对软质土和铁质土中的 DOC、MBC 和氮循环功能基因具有不同的影响。这些发现强调了孔隙大小在调节涝渍条件下氮转化中的作用,有助于了解典型水稻种植区压实水稻土中氮的可用性。
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来源期刊
European Journal of Soil Biology
European Journal of Soil Biology 环境科学-生态学
CiteScore
6.90
自引率
0.00%
发文量
51
审稿时长
27 days
期刊介绍: The European Journal of Soil Biology covers all aspects of soil biology which deal with microbial and faunal ecology and activity in soils, as well as natural ecosystems or biomes connected to ecological interests: biodiversity, biological conservation, adaptation, impact of global changes on soil biodiversity and ecosystem functioning and effects and fate of pollutants as influenced by soil organisms. Different levels in ecosystem structure are taken into account: individuals, populations, communities and ecosystems themselves. At each level, different disciplinary approaches are welcomed: molecular biology, genetics, ecophysiology, ecology, biogeography and landscape ecology.
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