Nitrogen addition regulates community biomass resistance and recovery to drought by altering species asynchrony rather than the diversity response

doi:10.1093/jpe/rtaf158

J Plant Ecol ›› 2026, Vol. 19 ›› Issue (2): rtaf158.DOI: 10.1093/jpe/rtaf158

• Research Article • Previous Articles

Nitrogen addition regulates community biomass resistance and recovery to drought by altering species asynchrony rather than the diversity response

Yimin Zhao¹, Zhen Zhang¹, Li Zhang², Miaojun Ma³, Guorui Hu³, Shurong Zhou^1*

¹School of Ecology, Hainan University, Haikou 570228, China, ²Co-Innovation Center for Sustainable Forestry in Southern China, Bamboo Research Institute, Nanjing Forestry University, Nanjing 210000, China, ³State Key Laboratory of Herbage Improvement and Grassland Agro-ecosystems, College of Ecology, Lanzhou University, Lanzhou 730000, China

*Corresponding author. E-mail: zhshrong@hainanu.edu.cn

Online:2025-09-30 Published:2026-04-01
Supported by:
This study was supported by the National Natural Science Foundation of China (Grants No. U22A20449 and 31830009), Collaborative Innovation Center of Ecological Civilization, Hainan University (XTCX2022STC25), and the Fundamental Research Funds in Hainan University (KYQD (ZR) -20081).

氮添加影响群落生物量对干旱的抵抗力和恢复力：物种异步性与多样性的相对贡献

Abstract

Abstract: Extreme climatic events often co-occur with persistent environmental disturbances, such as nitrogen enrichment, which may influence the resistance and recovery of plant communities to extreme climatic conditions. However, most studies have focused on the resistance and recovery of community functions (e.g. biomass) to climatic events while neglecting the corresponding responses of diversity. Here, we performed a soil nitrogen addition experiment in an alpine meadow from 2011 to 2020, with 2015 characterized by extreme drought. We explored the effects of nitrogen addition on the resistance and recovery of plant community biomass and diversity in response to extreme drought using measures including community biomass, taxonomic diversity (TD), phylogenetic diversity (PD) and functional diversity (FD). We found that nitrogen addition decreased biomass resistance, mainly due to species asynchrony rather than the diversity resistance, even though PD and FD resistance also declined. Meanwhile, nitrogen addition enhanced the recovery of biomass to drought. This was mainly attributable to the direct, positive impact of nitrogen on biomass recovery, coupled with an indirect influence of species asynchrony, without any diversity (TD, PD, FD) recovery effects. Our results indicate that soil nitrogen enrichment mainly influences plant biomass responses to extreme drought, with a relatively small effect on plant diversity. Additionally, the mechanisms driving diversity and biomass responses may operate independently, as changes in diversity response did not scale up to changes in biomass. We anticipate that maintenance of plant community biomass during extreme drought would be more challenging in conditions of high nitrogen deposition.

Nitrogen enrichment is known to modify ecosystem functional responses to drought, yet its effects on biodiversity responses and their coupling with ecosystem functioning remain unresolved. We show that nitrogen addition markedly altered the resistance and recovery of plant biomass to drought, while these responses were decoupled from changes in biodiversity resistance and recovery, suggesting that ecosystem functioning and biodiversity respond to drought largely independently across different dimensions.

Key words: alpine meadow, diversity resistance, drought, function stability, nitrogen, species asynchrony, Tibetan plateau

摘要：
环境扰动(如氮富集)会影响植物群落对极端气候的抵抗力与恢复力。然而，以往研究主要关注生态系统功能(如生物量)对极端气候的响应，而对多样性的响应研究相对匮乏。本研究于2011–2020年在高寒草甸开展氮添加野外控制实验(2015年为极端干旱年份)，通过测定群落生物量、分类多样性(taxonomic diversity, TD)、系统发育多样性(phylogenetic diversity, PD)和功能多样性(functional diversity, FD)等指标，探究了极端干旱前后氮添加对生物量/多样性抵抗力与恢复力的影响。结果发现，氮添加降低了群落生物量对极端干旱的抵抗力，这主要与物种异步性而非多样性的下降有关。然而，氮添加增强了群落生物量的恢复力，这主要是由于氮添加直接促进生物量的恢复，以及间接通过物种异步性增强生物量的恢复力，而多样性(TD、PD、FD)在干旱后恢复对生物量的作用较弱。本研究表明，氮富集背景下植物生物量对极端干旱的响应比多样性更加敏感并且多样性变化并未影响生物量对干旱的响应，表明二者对极端干旱的响应机制并不相同。在未来极端干旱频发背景下，活性氮的输入会导致高寒草地植物群落生物量稳定性的维持将面临更大威胁。

关键词: 高寒草甸, 多样性抵抗力, 干旱, 功能稳定性, 氮添加, 物种异步性, 青藏高原

Yimin Zhao, Zhen Zhang, Li Zhang, Miaojun Ma, Guorui Hu, Shurong Zhou. Nitrogen addition regulates community biomass resistance and recovery to drought by altering species asynchrony rather than the diversity response[J]. J Plant Ecol, 2026, 19(2): 1-43.

[1]	Jiatao Zhang, Lan Du, Yonghong Luo, Yann Hautier, Ru Tian, Yan Shen, Mohsin Mahmood, Zhuwen Xu. Distinct effects of drought and nitrogen enrichment on the compositional and productivity stability of temperate grasslands [J]. J Plant Ecol, 2026, 19(2): 1-.
[2]	Hui Jiang, Yuan-Yuan Zeng, Xu-Dong Liu, Francisco J Corpas, Md Mahadi Hasan, Feng-Ping Li, Xue-Qian Tian, Yu-Hang Zhang, Rui-Yun He, Xiang-Wen Fang. Rooting for survival: ABA-mediated hormonal integration driving primary root elongation under drought stress [J]. J Plant Ecol, 2026, 19(2): 1-.
[3]	Qian Liu, Xiaolin Zhu, Nan Jiang, Lihao Zhang, Shiyuan Wu, Ge Meng, Yunze Zang, Miaogen Shen. Improving estimation of aboveground carbon, nitrogen and phosphorus stock in forest ecosystems by integrating radar and optical remote sensing [J]. J Plant Ecol, 2026, 19(2): 1-.
[4]	Tiancai Zhou, Gusang Qunzong, Jian Sun. Leaf nitrogen and phosphorus are more coupled in legumes than in non-legumes, globally [J]. J Plant Ecol, 2026, 19(2): 1-.
[5]	Ying Guo, Lin Zhang, Wei Shen, Guangshuai Cui, Yanhong Tang, Tianxiang Luo. Nitrogen and carbon supply controls tree radial growth at an alpine treeline [J]. J Plant Ecol, 2026, 19(2): 1-.
[6]	Yaping Lin, Qiufang Zhang, Hao Sun, Jiaohong Lu, Zehong Yao, Quanxin Zeng, Chenxing Lian, Huizhi Pi, Xiaochun Yuan, Yuehmin Chen. Parallel patterns of microbial carbon and nitrogen use efficiency in response to nitrogen addition across soil depths in a Castanopsis faberi forest [J]. J Plant Ecol, 2026, 19(2): 1-.
[7]	Ruibing Duan, Zhongjie Shi, Rui Zhang, Lele Wang, Hui Jin, Zhenghu Zhou, Ying Jin. Leaf hydraulic and stomatal traits coordinated with rooting depth in desert species [J]. J Plant Ecol, 2026, 19(2): 1-.
[8]	Qiuhua Li, Yakun Liu, Xinyue Jin, Xiaotian Fan, Jiaqiang Wang, Wanbing Liu, Chunbo Li, Jishuai Su, Osbert Jianxin Sun, Xingguo Han, Yong Jiang, Heyong Liu. Changes in nutrient resorption efficiency with nitrogen and zinc addition and mowing in a meadow steppe [J]. J Plant Ecol, 2026, 19(2): 0-.
[9]	Jiahui Chen, Nan Jia, Youcun Suo, Nan Hu, Guofu Zhao, Haiyang Gong, Zhiqiang Wang. Long-term yak-grazing alters plant fine-root C:N:P stoichiometry in a Tibetan alpine meadow [J]. J Plant Ecol, 2026, 19(1): 1-.
[10]	Peipei Liu, Cai-E Wang, Mei Huang, A. Allan Degen, Wenyin Wang, Lingyan Qi, Binyu Luo, Tianyun Qi, Jianxin Jiao, Zhanhuan Shang. The shift from dominant Kobresia species to toxic plants is associated with bare patch encroachment on alpine meadow hillslopes [J]. J Plant Ecol, 2026, 19(1): 1-.
[11]	Jiaoneng Yu, Fei Ren, Li Ma, Huakun Zhou, Xiaotao Huang, Yongsheng Yang, Songbo Qu, Yuxuan Cui, Ribu Shama, Yuxia Zhang, Xu-Ri, Almaz Borjigidai. Community dynamics of alpine meadows under fencing durations: based on diversity, niches, and interspecific associations [J]. J Plant Ecol, 2026, 19(1): 1-.
[12]	Deyi Wang, Hans Jacquemyn, Guangru Wang, Yongping Kou, Junxiang Ding, Peipei Zhang, Huajun Yin. Evolutionary history and environmental filtering jointly structure ectomycorrhizal fungal communities across Pinaceae forests on the Qinghai-Tibetan Plateau [J]. J Plant Ecol, 2026, 19(1): 1-30.
[13]	Huiyuan Cheng, Kaling Huang, Mengdi Luan, Zifan Zhang, Xuebin Yan, Hui Guo. Latitudinal pattern of plant invasion driven by species diversity over phylogenetic distance [J]. J Plant Ecol, 2025, 18(6): 1-30.
[14]	Zengzeng Yang, Chunping Zhang, Quan Cao, Yang Yu, Zhengshe Zhang, Yongshang Tong, Xiaofang Zhang, Xue Zhang, Lian Huo, Kongtao Wei, Yulong He, Quanmin Dong. Response of growth and reproductive traits to mowing tolerance mechanism in Elymus species [J]. J Plant Ecol, 2025, 18(6): 1-30.
[15]	Fangling Ma, Yao Zheng, La Wei, Lin Xiang, Lifei Ren, Wenming Bai, Qiuying Tian, Wen-Hao Zhang. Soil chemistry exerts a more significant influence on bacterial responses to nitrogen disturbances than root exudates [J]. J Plant Ecol, 2025, 18(6): 1-37.

Nitrogen addition regulates community biomass resistance and recovery to drought by altering species asynchrony rather than the diversity response

氮添加影响群落生物量对干旱的抵抗力和恢复力：物种异步性与多样性的相对贡献

HTML

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments