期刊
SCIENCE OF THE TOTAL ENVIRONMENT
卷 880, 期 -, 页码 -出版社
ELSEVIER
DOI: 10.1016/j.scitotenv.2023.163147
关键词
Soil aggregate; Glomalin-related soil protein; Denitrifier; PotentialN2O flux; GeoChip 5; 0
Agricultural ecosystems contribute significantly to atmospheric emissions of soil nitrous oxide (N2O), which exacerbate environmental pollution and contribute to global warming. Glomalin-related soil protein (GRSP) stabilizes soil aggregates and enhances soil carbon and nitrogen storage in agricultural ecosystems. Our findings showed that GRSP content increased with the increase in soil aggregate size, and potential N2O fluxes were highest in microaggregates (250-53 mu m), followed by macroaggregates (2000-250 mu m), and lowest in silt + clay (<53 mu m) fractions. The study also revealed a significant correlation between denitrifying microbial community, soil aggregate GRSP fractions, and potential N2O fluxes.
Agricultural ecosystems contribute significantly to atmospheric emissions of soil nitrous oxide (N2O), which exacer-bate environmental pollution and contribute to global warming. Glomalin-related soil protein (GRSP) stabilizes soil ag-gregates and enhances soil carbon and nitrogen storage in agricultural ecosystems. However, the underlying mechanisms and relative importance of GRSP on N2O fluxes within soil aggregate fraction remain largely unclear. We examined the GRSP content, denitrifying bacterial community composition, and potential N2O fluxes across three aggregate-size fractions (2000-250 mu m, 250-53 mu m, and <53 mu m) under a long-term fertilization agricultural ecosystem, subjected to mineral fertilizer or manure and their combination. Our findings indicated that various fertil-ization treatments have no discernible impact on the size distribution of soil aggregates, paving the way to further re-search into the impact of soil aggregates on GRSP content, the denitrifying bacterial community composition, and potential N2O fluxes. GRSP content increased with the increase in soil aggregate size. Potential N2O fluxes (including gross N2O production and N2O reduction and net N2O production) among aggregates were highest in microaggregates (250-53 mu m), followed by macroaggregates (2000-250 mu m) and lowest in silt + clay (<53 mu m) fractions. Potential N2O fluxes had a positive response to soil aggregate GRSP fractions. The non-metric multidimensional scaling analysis revealed that soil aggregate size could drive the denitrifying functional microbial community composition, and deter-ministic processes play more critical roles than stochasticity processes in driving denitrifying functional composition under soil aggregate fractions. Procrustes analysis revealed a significant correlation between denitrifying microbial community, soil aggregate GRSP fractions, and potential N2O fluxes. Our study suggests that soil aggregate GRSP fractions influence potential nitrous oxide fluxes by affecting denitrifying microbial functional composition within soil aggregate.
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