Differences of key processes in soil nitrogen cycling and their driving factors under different land-use types

doi:10.13287/j.1001-9332.202505.036

Abstract

Abstract: To investigate the responses and drivers of soil microbial nitrogen (N)-cycling functional genes under different land-use types, we analyzed five representative ecosystems in the Yellow River alluvial plain: Tamarix chinensis forests, Fraxinus chinensis forests, grasslands, wetlands, and farmlands. With metagenomic sequencing, we quantified the relative abundances of 22 functional genes associated with six critical N-cycling processes. Soil physicochemical properties were characterized. There were significant variations in soil nitrogen (N)-cycling functional gene abundances across land-use types. Wetlands exhibited the highest relative abundances of nitrogen fixation (1.28×10^-5), nitrification (4.91×10^-4), and denitrification (7.03×10^-4) genes, but the lowest assimilatory nitrate reduction potential (1.84×10^-4). Farmlands showed maximal assimilatory nitrate reduction gene abundance (3.31×10^-4), while grasslands dominated in ammonification gene expression (2.35×10^-4), significantly higher than other ecosystems. T. chinensis forests maintained the most constrained N-cycling profile, with minimal nitrification (2.77×10^-4) and denitrification (5.25×10^-4) relative gene abundances. Redundancy analysis identified soil total nitrogen, organic carbon, total potassium, and electrical conductivity as the key environmental drivers of these variations. Our findings demonstrated that land-use types could shape microbial N-cycling functional gene abundances by altering soil nutrient conditions, with consequence on fundamental processes of soil nitrogen transformation.

Key words: land use type, nitrogen-transforming microorganism, Yellow River alluvial plain, metagenomics

WEN Ming, LIU Yu, FENG Chaoyang, JI Wei, LI Zhuoqing. Differences of key processes in soil nitrogen cycling and their driving factors under different land-use types[J]. Chinese Journal of Applied Ecology, 2025, 36(5): 1387-1397.

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