干旱引起的真菌多样性与群落稳定性下降驱动了温带湖滨湿地生态系统的多功能性

doi:10.1093/jpe/rtag124

干旱引起的真菌多样性与群落稳定性下降驱动了温带湖滨湿地生态系统的多功能性

收稿日期:2026-01-22 接受日期:2026-05-11

Aridity induced declines in fungal diversity and community stability drive ecosystem multifunctionality in temperate lakeshore wetlands

Zhichao Xu¹, Huamin Liu¹, Shan Jiang¹, Rui Zhang¹, Yunhao Wen¹, Xiao-Ai Cao², Yabo Shi³, Lu Wen¹, Yang Bai¹, Jiangtao Peng¹, Cunzhu Liang¹, Lixin Wang^1,†

¹ Ministry of Education Key Laboratory of Ecology and Resource Use of the Mongolian Plateau, Inner Mongolia Key Laboratory of River and Lake Ecology, Collaborative Innovation Center for Grassland Ecological Security (Jointly Supported by the Ministry of Education of China and Inner Mongolia Autonomous Region), School of Ecology and Environment, Inner Mongolia University, Hohhot 010021, China
² School of Environment and Energy, Peking University Shenzhen Graduate School, Shenzhen, 518055, China
³ College of Ecology and Environment, Baotou Teacher’s College, Baotou 014030, China
^†Corresponding author. E-mail address: lxwang@imu.edu.cn (Lixin Wang)

Received:2026-01-22 Accepted:2026-05-11
Supported by:
This work was funded by the National Natural Science Fund, P.R. China (32571847, 32460288), the Natural Science Foundation of Inner Mongolia the Science (2025QN03046, 2023QN03016), and Technology Major Project of Inner Mongolia (2025YFHH0185, 2023YFHH0053 and 2024ZY0128).

摘要/Abstract

摘要： 湖滨湿地是受气候干旱影响最脆弱的生态系统之一，其中土壤微生物及其相互作用在维持生态系统功能方面发挥着核心作用。然而，在这些隐域性生态系统中，气候干旱如何改变微生物网络结构的复杂性与稳定性，并进而影响生态系统多功能性（EMF），目前尚不明确。本研究调查了横跨蒙古高原约2400公里干旱梯度（涵盖干旱和半干旱地区）的54个湖滨湿地样点，分析了土壤微生物共现网络及其与EMF之间的关系。结果表明：在干旱区湖滨湿地中，气候干旱显著增强了网络复杂性；而在半干旱区，群落稳定性则随干旱程度的增加而显著下降。值得注意的是，干旱显著降低了真菌多样性和群落稳定性。总体而言，微生物群落稳定性和网络复杂性受生物多样性的调节，并共同维持湖滨湿地的EMF。具体而言，半干旱区的EMF受网络复杂性介导的群落稳定性所调节；而在干旱区，研究结果强调了土壤真菌多样性和稳定性在维持EMF中的主导作用。综上所述，本研究证明了湖滨湿地微生物网络的复杂性与稳定性受气候干旱塑造，并在维持生态系统多功能性中发挥着至关重要的作用。这些发现为隐域性湿地中生物网络维持功能稳定性的独特机制提供了新见解，并为退化湿地的生态功能恢复提供了理论指导。

关键词: 生态系统多功能性, 网络复杂性, 群落稳定性, 生物多样性, 湖滨湿地

Abstract: Lakeshore wetlands are among the ecosystems most vulnerable to climatic aridity, where soil microorganisms and their interactions play a pivotal role in maintaining ecosystem functions. However, it remains unclear how climatic aridity alters the complexity and stability of microbial co-occurrence networks in these intrazonal habitats, thereby impacting ecosystem multifunctionality (EMF). Here, we investigated soil microbial co-occurrence networks at 54 lakeshore wetland sites spanning a ~2,400 km climatic aridity gradient (covering both arid and semiarid regions) across the Mongolian Plateau and evaluated their relationships with EMF. Our results showed that climatic aridity significantly enhanced network complexity in arid lakeshore wetlands, whereas community stability significantly declined with increasing aridity in semiarid regions. Notably, aridity markedly reduced fungal diversity and community stability. Overall, microbial community stability and network complexity were regulated by biodiversity and jointly sustained the EMF in lakeshore wetlands. Specifically, EMF in semiarid regions was regulated by community stability mediated through network complexity; conversely, in arid regions, our findings underscore the predominant role of soil fungal diversity and stability in maintaining EMF. Collectively, this study demonstrates that the complexity and stability of microbial networks in lakeshore wetlands are shaped by climatic aridity and play a crucial role in maintaining EMF. These findings provide novel insights into the unique mechanisms by which biotic networks sustain ecosystem multifunctionality in intrazonal wetlands and offer theoretical guidance for the restoration of ecosystem functions in degraded wetlands. SCRIPT

Key words: ecosystem multifunctionality, network complexity, community stability, biodiversity, lakeshore wetland

. 干旱引起的真菌多样性与群落稳定性下降驱动了温带湖滨湿地生态系统的多功能性[J]. Journal of Plant Ecology, DOI: 10.1093/jpe/rtag124.

Zhichao Xu, Huamin Liu, Shan Jiang, Rui Zhang, Yunhao Wen, Xiao-Ai Cao, Yabo Shi, Lu Wen, Yang Bai, Jiangtao Peng, Cunzhu Liang, Lixin Wang. Aridity induced declines in fungal diversity and community stability drive ecosystem multifunctionality in temperate lakeshore wetlands[J]. J Plant Ecol, DOI: 10.1093/jpe/rtag124.

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