Using the response–effect trait framework to disentangle the effects of environmental change on the ecosystem services

doi:10.1093/jpe/rtae024

J Plant Ecol ›› 2024, Vol. 17 ›› Issue (5): rtae024.DOI: 10.1093/jpe/rtae024

• Research Articles •

Using the response–effect trait framework to disentangle the effects of environmental change on the ecosystem services

Cheng Zheng¹, Fei Zhang¹, Ziqi Lin¹, Liuhuan Yuan¹, Hongbin Yao¹, Gaohui Duan¹, Yandan Liu¹, Yangyang Liu¹, Haijing Shi^2,3,* and Zhongming Wen^1,2,*

¹College of Grassland Agriculture, Northwest A&F University, Yangling 712100, China, ²Institute of Soil and Water Conservation, Chinese Academy of Sciences and Ministry of Water Resources, Yangling 712100, China, ³Institute of Soil and Water Conservation, Northwest A&F University, Yangling 712100, China
^*Corresponding author. E-mail: zmwen@ms.iswc.ac.cn (W.Z.); shihaijingcn@nwafu.edu.cn (S.H.)

Received:2023-12-27 Accepted:2024-03-21 Online:2024-04-05 Published:2024-10-01
Supported by:
This study was fnancially supported by the CAS ‘light of West China’ program (XAB2020YN04) and the Natural Science Foundation of China (41977077 and 41671289).

利用响应-效应性状框架揭示气候变化和人类活动对生态系统服务的影响

Abstract

Abstract: Functional traits play a vital role in mediating the responses of ecosystem services to environmental changes and in predicting the functioning of the ecosystem. However, the connection between functional traits and ecosystem services has become increasingly intricate due to climate change and human activities for degraded ecosystems. To investigate this relationship, we selected 27 sampling sites in the Yanhe River Basin of the Chinese Loess Plateau, each containing two types of vegetation ecosystems: natural vegetation and artificial vegetation ecosystems. At each sampling site, we measured ecosystem services and calculated the composition index of community traits. We established a response–effect trait framework that included environmental factors such as climate, elevation and human activities. Our results showed that leaf tissue density (LTD) was the overlapping response and effect trait when responding to climate change. LTD is positively correlated with mean annual temperature and negatively correlated with supporting services. Under the influence of human activities, leaf nitrogen content and leaf dry matter content were carriers of environmental change. Comparing the two vegetation ecosystems, the relationship between functional traits and ecosystem services showed divergent patterns, indicating that human activities increased the uncertainty of the relationship between functional traits and ecosystem services. Trait-based ecology holds promise for enhancing predictions of ecosystem services responses to environmental changes. However, the predictive ability is influenced by the complexity of environmental changes. In conclusion, our study highlights the importance of understanding the complex connection between functional traits and ecosystem services in response to climate changes and human activities.

Key words: Robinia pseudoacacia plantation, BEF, degraded ecosystem, climate change, functional diversity, linear mixed-effect models

摘要：
功能性状在调节生态系统服务响应环境变化方面发挥着重要作用。然而，由于气候变化和人类活动，功能性状与生态系统服务之间的联系变得更复杂。本研究在延河流域选取了27个采样点，每个采样点包含两种类型的植被生态系统：无人类活动的生态系统(自然植被)和存在人类活动的生态系统(刺槐(Robinia pseudoacacia)人工林)。在每个采样点，我们测量了生态系统服务并计算了植物群落性状的组成指数。研究结果表明，叶片组织密度(LTD)是响应气候变化时的重叠性状。LTD与年平均气温呈正相关，与支持服务呈负相关。比较两种植被生态系统，功能性状与生态系统服务之间的关系呈现出不同的模式，表明人类活动增加了功能性状与生态系统服务之间关系的不确定性。基于性状的研究有望增强生态系统服务对环境变化响应的预测。然而，预测能力受到环境变化复杂性的影响，特别是人类活动对生态系统的干扰。总之，该研究强调了理解功能性状和生态系统服务之间复杂联系以应对气候变化和人类活动的重要性。

关键词: 刺槐(Robinia pseudoacacia)人工林, 生物多样性生态系统功能(BEF), 退化生态系统, 气候变化, 功能多样性, 线性混合效应模型

Cheng Zheng, Fei Zhang, Ziqi Lin, Liuhuan Yuan, Hongbin Yao, Gaohui Duan, Yandan Liu, Yangyang Liu, Haijing Shi, Zhongming Wen. Using the response–effect trait framework to disentangle the effects of environmental change on the ecosystem services[J]. J Plant Ecol, 2024, 17(5): 1-13.

[1]	Bingqian Su, Wenlong Xu, Zhuoxia Su, Zhouping Shangguan. Machine learning applications to reveal the difference in Robinia pseudoacacia growth and its drivers on China’s Loess Plateau [J]. J Plant Ecol, 2025, 18(1): 1-16.
[2]	Nan Jiang, Miaogen Shen and Zhiyong Yang. Differential phenological responses to temperature among various stages of spring vegetation green-up [J]. J Plant Ecol, 2024, 17(6): 1-rtae063.
[3]	Lu Bai, Lei Tian, Zhiguo Ren, Xiaohui Song, Kailiang Yu, Lin Meng, Zhanfeng Hou, Haiyan Ren. Climate warming advances plant reproductive phenology in China’s northern grasslands [J]. J Plant Ecol, 2024, 17(6): 1-.
[4]	Shunqiu Li, Lisha Lyu, Tong Lyu, Dimitar Dimitrov, Yunyun Wang. Spatial pattern and ecological adaptation of heterostylous and homostylous species of Primula in China [J]. J Plant Ecol, 2024, 17(6): 1-13.
[5]	Xiaohong Li, Jinxia Huang, Zuncheng Bai, Hang Zou, Wanyu Wang, Wanyu Qi, Maohua Ma. Riparian plant community structure and assembly processes differed by variations in riverbank curvatures: implications for restoring habitats along the Three Gorges Reservoir [J]. J Plant Ecol, 2024, 17(5): 1-16.
[6]	Yanhua Zhu, Ji Zheng, Hongzhang Kang, Nan Hui1, Shan Yin, Zhicheng Chen, Baoming Du, Chunjiang Liu. Spatial variations in leaf trichomes and their coordination with stomata in Quercus variabilis across Eastern Asia [J]. J Plant Ecol, 2024, 17(3): 0-rtae023.
[7]	Ji Suonan, Wangwang Lü, Aimée T. Classen, Wenying Wang, Ben La, Xuwei Lu, Cuo Songzha, Chenghao Chen, Qi Miao, Fanghui Sun, Lhamo Tsering, Shiping Wang. Alpine plants exhibited deep supercooling upon exposed to episodic frost events during the growing season on the Qinghai-Tibet Plateau [J]. J Plant Ecol, 2024, 17(3): 0-rtae034.
[8]	Kohei Suzuki, Ikutaro Tsuyama, Radnaakhand Tungalag, Amartuvshin Narantsetseg, Tsagaanbandi Tsendeekhuu, Masato Shinoda, Norikazu Yamanaka, Takashi Kamijo. Projected distributions of Mongolian rangeland vegetation under future climate conditions [J]. J Plant Ecol, 2024, 17(3): 0-rtae028.
[9]	Xu-Yan Liu, Yu-Kun Hu. Changes in plant multidimensional chemical diversity along a local soil chemical gradient in temperate forest swamps [J]. J Plant Ecol, 2023, 16(2): 1-rtac031.
[10]	Brian Njoroge, Yuelin Li, Dennis Otieno, Shizhong Liu, Simin Wei, Ze Meng, Qianmei Zhang, Deqiang Zhang, Juxiu Liu, Guowei Chu, Fasih Ullah Haider and John Tenhunen. Seasonal droughts drive up carbon gain in a subtropical forest [J]. J Plant Ecol, 2023, 16(1): 0-.
[11]	Zhongmin Hu, Minqi Liang, Alan Knapp, Jianyang Xia, and Wenping Yuan. Are regional precipitation–productivity relationships robust to decadal-scale dry period? [J]. J Plant Ecol, 2022, 15(4): 711-720.
[12]	Lian Liu, Xiaoting Xu, Lei Zhang, Yaoqi Li, Nawal Shrestha, Danilo M. Neves, Qinggang Wang, Hong Chang, Xiangyan Su, Yunpeng Liu, Jianyong Wu, Dimitar Dimitrov, Zhiheng Wang and Jianquan Liu. Global patterns of species richness of the holarctic alpine herb Saxifraga: the role of temperature and habitat heterogeneity [J]. J Plant Ecol, 2022, 15(2): 237-252.
[13]	Yuan-Qi Pan, Xiu Zeng, Wen-De Chen, Xin-Ran Tang, Kui Dai, Yan-Jun Du and Xi-Qiang Song. Chilling rather than photoperiod controls budburst for gymnosperm species in subtropical China [J]. J Plant Ecol, 2022, 15(1): 100-110.
[14]	Hai Liu, Feng Liu, Hongmeng Yuan, Liang Zheng, and Yuan Zhang. Assessing the relative role of climate and human activities on vegetation cover changes in the up–down stream of Danjiangkou, China [J]. J Plant Ecol, 2022, 15(1): 180-195.
[15]	Feng-Hui Guo, Xi-Liang Li, Jing-Jing Yin, Saheed Olaide Jimoh and Xiang-Yang Hou. Grazing-induced legacy effects enhance plant adaption to drought by larger root allocation plasticity [J]. J Plant Ecol, 2021, 14(6): 1024-1029.

Using the response–effect trait framework to disentangle the effects of environmental change on the ecosystem services

利用响应-效应性状框架揭示气候变化和人类活动对生态系统服务的影响

HTML

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments