物种个体水平响应比物种重排和周转更能驱动氮磷添加后生产力的变化

doi:10.1093/jpe/rtag097

物种个体水平响应比物种重排和周转更能驱动氮磷添加后生产力的变化

收稿日期:2025-09-15 接受日期:2026-04-15

Individual species responses, rather than species reordering and turnover, drive ANPP changes following N and P addition

Zhenzhen Pan^1,2, Wei Zhao³, Shaohao Bang³, Ruibing Wang^1,2, Huan Chen^1,2, Xiaomei Sun⁴, Xiaolong Zhou^1,2,* and Zhengwei Ren^3,*

¹ College of Ecology and Environment, Xinjiang University, Urumqi 830017, China
² Key Laboratory of Oasis Ecology of Education Ministry, Xinjiang University, Urumqi 830017, China
³ College of Ecology, Lanzhou University, Lanzhou 730000, China
⁴ College of Resource and Environmental Science, Gansu Agricultural University, Lanzhou 730070, China
^*Correspondence: Xiaolong Zhou:Email: zhouxiaolong@xju.edu.cn; Zhengwei Ren Email: renzhw@lzu.edu.cn

Received:2025-09-15 Accepted:2026-04-15
Supported by:
This study was supported by the National Natural Science Foundation of China (32460268), and the Xinjiang University's Excellent Graduate Innovation Project in 2025 (XJDX2025YJS231).

摘要/Abstract

摘要： 养分富集通过植物功能性状介导的过程影响草地生态系统生产力。然而，从种内响应到物种重排与周转等层级响应过程如何通过功能性状相互作用并共同影响地上净初级生产力(生产力)，目前尚不清楚。本研究旨在量化这些相互关系及其对生产力变化的相对贡献。基于为期五年的氮和磷添加实验，通过调查植物群落和测定功能性状，量化了驱动生产力变化的层级群落响应。结果表明，物种个体水平响应是生产力变化的主要驱动力(路径系数为0.91)，而物种重排与周转的贡献均不显著(路径系数分别为–0.29和–0.27)。植物盖度是连接群落过程与生产力的关键性状。氮添加促进了植物生长，并通过增加莎草科和禾本科的盖度、减少豆科和杂类草的盖度，对功能群进行了重新排序；由于丧失物种和新增物种的生产力均较低，物种周转对生产力的影响较弱。这些结果表明，氮添加和氮磷混合添加通过增加持久性物种的盖度显著增加了生产力。相反，磷添加虽未显著增加生产力，但通过植物氮磷比介导的个体水平响应与生产力相联系。上述结果从功能性状-生态系统功能关系的角度，为理解草地植物生产力对养分富集的响应提供了新视角。

关键词: 高寒草甸, 生产力, 个体水平响应, 植物盖度, 物种重排, 物种周转

Abstract: Nutrient enrichment influences grassland ecosystem productivity through plant functional trait-mediated processes. However, how responses across hierarchical levels-ranging from intraspecific responses to species reordering and turnover-interact to jointly shape aboveground net primary productivity (ANPP) via functional traits is not well understood. Our study aimed to quantify these interrelationships and their relative contributions to predicting ANPP changes. We conducted a five-year experiment involving nitrogen (N) and phosphorus (P) addition and quantified the hierarchical community responses driving ANPP by systematically investigating plant communities and measuring functional traits. Our findings indicated that individual species response was the main driving force for ANPP changes (path coefficient: 0.91), whereas species reordering and turnover contributions were not significant (-0.29 and -0.27). Plant coverage was the key trait linking community processes to ANPP. N addition promoted the growth of plants and reordered the functional groups by increasing the coverage of sedges and grasses and reducing the coverage of legumes and forbs. Species turnover had a weak influence on ANPP due to the low ANPP of both the lost and gained species. These results indicated that N and NP addition significantly increased ANPP by enhancing the coverage of persistent species. Conversely, P addition did not significantly increase ANPP, but was linked to it through plant N:P ratios-mediated individual species responses. This offers a new perspective on ANPP responses to nutrient enrichment through functional traits-ecosystem function relationships.

Key words: alpine meadow, ANPP, individual species response, plant coverage, species reordering, species turnover

. 物种个体水平响应比物种重排和周转更能驱动氮磷添加后生产力的变化[J]. Journal of Plant Ecology, DOI: 10.1093/jpe/rtag097.

Zhenzhen Pan, Wei Zhao, Shaohao Bang, Ruibing Wang, Huan Chen, Xiaomei Sun, Xiaolong Zhou, Zhengwei Ren. Individual species responses, rather than species reordering and turnover, drive ANPP changes following N and P addition[J]. J Plant Ecol, DOI: 10.1093/jpe/rtag097.

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