| 作 者:Peng Y, Luo J, Guo LL, Chen HY, Gao YX, Peng ZY, Liu LL* |
| 影响因子:20.6 |
| 刊物名称:Nature Geoscience |
| 出版年份:2026 |
| 卷: 期: 页码:DOI: 10.1038/s41561-026-01992-5 |
Ecosystem nitrogen retention results from complex, long-term plant–soil–microbe interactions, yet integrating these processes across climatic gradient remains challenging. As a time-integrated tracer, the natural abundance of the stable nitrogen isotope (δ15N) in soil captures the cumulative balance of nitrogen inputs, transformationslosses, offering a robust proxy for ecosystem nitrogen retention. Although spatial patterns in δ15N have been widely documented, the driverstheir shifts across climatic thresholds remain unclear. Using data from 31 sites across the National Ecological Observatory Network in the United States, here we revealed that soil δ15N varies nonlinearly with mean annual precipitation, with a threshold (~700 mm) marking a shift in dominant controls. Below this threshold, soil δ15N decreased with precipitationwas shaped by plant community structure, microbial compositionsoil nitrate concentration. Above the threshold, soil δ15N increased with precipitation, with soil physicochemical properties, particularly soil carbon/nitrogen ratio, nitrate concentrationclay content, exerting stronger influence. Precipitation thus regulates the ‘leakiness’ of the nitrogen cycle, shifting from rainfall-enhanced retention driven by plant–microbe competition in drier regions to rainfall-induced losses mediated by coupled hydrologicalmicrobial transformations in wetter regions. These findings advance understanding of spatial variation in natural nitrogen cyclingprovide a framework for predicting nitrogen dynamics under changing precipitation regimes.
