Herbivore species and patch heterogeneity modulate grazing-induced shifts in soil nematode trophic structure and energy flux

Quanhui Ma; Yao Wang; G. F. Veen; Ting Liu; Xue Qing; Yonghuan Yue; Haoran Yu; Deli Wang; Wenjia Wu; Jingjing Yang; Dima Chen; Yu Zhu; Ling Wang

doi:10.1111/1365-2435.70204

Herbivore species and patch heterogeneity modulate grazing-induced shifts in soil nematode trophic structure and energy flux

Quanhui Ma
, Yao Wang
, G. F. Veen
, Ting Liu
, Xue Qing
, Yonghuan Yue
, Haoran Yu
, Deli Wang
, Wenjia Wu
, Jingjing Yang
, Dima Chen
, Yu Zhu^* (Corresponding author)
, Ling Wang^* (Corresponding author)

^*Corresponding author for this work

NIOO - Terrestrial Ecology (TE)

Research output: Contribution to journal/periodical › Article › Scientific › peer-review

Abstract

Grazing by large herbivores is a critical factor shaping grassland biodiversity and ecosystem functioning worldwide, yet its consequences for soil communities remain poorly understood. This gap is important because soil food webs underpin ecosystem processes and may respond differently to grazing depending on herbivore identity and local heterogeneity (i.e. patchiness). Here, a four-year field experiment was conducted to investigate the influences of cattle and sheep grazing on soil nematode communities in a grassland that features a mosaic of degraded high-salinity and undegraded low-salinity patches. We focus on nematode communities because nematode-based indices offer key insights into the structure of the soil food web and overall soil health. In the absence of grazing, degraded patches exhibited a more simplified soil food web structure, indicated by reduced nematode diversity, maturity index and structure index, but higher nematode biomass and energy flux compared to undegraded patches. However, sheep grazing reduced total nematode biomass and energy flux in degraded patches, while cattle grazing decreased the biomass of higher trophic levels (i.e. omnivores and predators), the energy flux from lower to higher trophic levels and flow uniformity in undegraded patches. These effects resulted from declines in the abundance of large-bodied nematodes, primarily limited by soil pore space and soil microbial biomass. Collectively, our findings demonstrate that livestock grazing can exacerbate soil degradation by inhibiting soil fauna communities, but the outcomes are patch- and herbivore-specific. By combining nematode structural and functional indices, our study advances understanding of how herbivore identity interacts with fine-scale grassland heterogeneity to regulate soil food webs. This framework provides a new pathway for linking grazing management to soil health, offering a scientific basis for adaptive policies that balance production goals with sustainable grassland restoration under environmental change. Read the free Plain Language Summary for this article on the Journal blog.

Original language	English
Journal	Functional Ecology
DOIs	https://doi.org/10.1111/1365-2435.70204
Publication status	Accepted/In press - 2025

Keywords

biomass
large herbivores
soil fauna
soil food web
spatial heterogeneity

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10.1111/1365-2435.70204Licence: CC BY

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@article{b1c78715ba3044e288099a6c9dba64e8,

title = "Herbivore species and patch heterogeneity modulate grazing-induced shifts in soil nematode trophic structure and energy flux",

abstract = "Grazing by large herbivores is a critical factor shaping grassland biodiversity and ecosystem functioning worldwide, yet its consequences for soil communities remain poorly understood. This gap is important because soil food webs underpin ecosystem processes and may respond differently to grazing depending on herbivore identity and local heterogeneity (i.e. patchiness). Here, a four-year field experiment was conducted to investigate the influences of cattle and sheep grazing on soil nematode communities in a grassland that features a mosaic of degraded high-salinity and undegraded low-salinity patches. We focus on nematode communities because nematode-based indices offer key insights into the structure of the soil food web and overall soil health. In the absence of grazing, degraded patches exhibited a more simplified soil food web structure, indicated by reduced nematode diversity, maturity index and structure index, but higher nematode biomass and energy flux compared to undegraded patches. However, sheep grazing reduced total nematode biomass and energy flux in degraded patches, while cattle grazing decreased the biomass of higher trophic levels (i.e. omnivores and predators), the energy flux from lower to higher trophic levels and flow uniformity in undegraded patches. These effects resulted from declines in the abundance of large-bodied nematodes, primarily limited by soil pore space and soil microbial biomass. Collectively, our findings demonstrate that livestock grazing can exacerbate soil degradation by inhibiting soil fauna communities, but the outcomes are patch- and herbivore-specific. By combining nematode structural and functional indices, our study advances understanding of how herbivore identity interacts with fine-scale grassland heterogeneity to regulate soil food webs. This framework provides a new pathway for linking grazing management to soil health, offering a scientific basis for adaptive policies that balance production goals with sustainable grassland restoration under environmental change. Read the free Plain Language Summary for this article on the Journal blog.",

keywords = "biomass, large herbivores, soil fauna, soil food web, spatial heterogeneity",

author = "Quanhui Ma and Yao Wang and Veen, \{G. F.\} and Ting Liu and Xue Qing and Yonghuan Yue and Haoran Yu and Deli Wang and Wenjia Wu and Jingjing Yang and Dima Chen and Yu Zhu and Ling Wang",

note = "Publisher Copyright: {\textcopyright} 2025 The Author(s). Functional Ecology published by John Wiley \& Sons Ltd on behalf of British Ecological Society.",

year = "2025",

doi = "10.1111/1365-2435.70204",

language = "English",

journal = "Functional Ecology",

issn = "0269-8463",

publisher = "Wiley-Blackwell",

}

TY - JOUR

T1 - Herbivore species and patch heterogeneity modulate grazing-induced shifts in soil nematode trophic structure and energy flux

AU - Ma, Quanhui

AU - Wang, Yao

AU - Veen, G. F.

AU - Liu, Ting

AU - Qing, Xue

AU - Yue, Yonghuan

AU - Yu, Haoran

AU - Wang, Deli

AU - Wu, Wenjia

AU - Yang, Jingjing

AU - Chen, Dima

AU - Zhu, Yu

AU - Wang, Ling

PY - 2025

Y1 - 2025

N2 - Grazing by large herbivores is a critical factor shaping grassland biodiversity and ecosystem functioning worldwide, yet its consequences for soil communities remain poorly understood. This gap is important because soil food webs underpin ecosystem processes and may respond differently to grazing depending on herbivore identity and local heterogeneity (i.e. patchiness). Here, a four-year field experiment was conducted to investigate the influences of cattle and sheep grazing on soil nematode communities in a grassland that features a mosaic of degraded high-salinity and undegraded low-salinity patches. We focus on nematode communities because nematode-based indices offer key insights into the structure of the soil food web and overall soil health. In the absence of grazing, degraded patches exhibited a more simplified soil food web structure, indicated by reduced nematode diversity, maturity index and structure index, but higher nematode biomass and energy flux compared to undegraded patches. However, sheep grazing reduced total nematode biomass and energy flux in degraded patches, while cattle grazing decreased the biomass of higher trophic levels (i.e. omnivores and predators), the energy flux from lower to higher trophic levels and flow uniformity in undegraded patches. These effects resulted from declines in the abundance of large-bodied nematodes, primarily limited by soil pore space and soil microbial biomass. Collectively, our findings demonstrate that livestock grazing can exacerbate soil degradation by inhibiting soil fauna communities, but the outcomes are patch- and herbivore-specific. By combining nematode structural and functional indices, our study advances understanding of how herbivore identity interacts with fine-scale grassland heterogeneity to regulate soil food webs. This framework provides a new pathway for linking grazing management to soil health, offering a scientific basis for adaptive policies that balance production goals with sustainable grassland restoration under environmental change. Read the free Plain Language Summary for this article on the Journal blog.

AB - Grazing by large herbivores is a critical factor shaping grassland biodiversity and ecosystem functioning worldwide, yet its consequences for soil communities remain poorly understood. This gap is important because soil food webs underpin ecosystem processes and may respond differently to grazing depending on herbivore identity and local heterogeneity (i.e. patchiness). Here, a four-year field experiment was conducted to investigate the influences of cattle and sheep grazing on soil nematode communities in a grassland that features a mosaic of degraded high-salinity and undegraded low-salinity patches. We focus on nematode communities because nematode-based indices offer key insights into the structure of the soil food web and overall soil health. In the absence of grazing, degraded patches exhibited a more simplified soil food web structure, indicated by reduced nematode diversity, maturity index and structure index, but higher nematode biomass and energy flux compared to undegraded patches. However, sheep grazing reduced total nematode biomass and energy flux in degraded patches, while cattle grazing decreased the biomass of higher trophic levels (i.e. omnivores and predators), the energy flux from lower to higher trophic levels and flow uniformity in undegraded patches. These effects resulted from declines in the abundance of large-bodied nematodes, primarily limited by soil pore space and soil microbial biomass. Collectively, our findings demonstrate that livestock grazing can exacerbate soil degradation by inhibiting soil fauna communities, but the outcomes are patch- and herbivore-specific. By combining nematode structural and functional indices, our study advances understanding of how herbivore identity interacts with fine-scale grassland heterogeneity to regulate soil food webs. This framework provides a new pathway for linking grazing management to soil health, offering a scientific basis for adaptive policies that balance production goals with sustainable grassland restoration under environmental change. Read the free Plain Language Summary for this article on the Journal blog.

KW - biomass

KW - large herbivores

KW - soil fauna

KW - soil food web

KW - spatial heterogeneity

U2 - 10.1111/1365-2435.70204

DO - 10.1111/1365-2435.70204

M3 - Article

AN - SCOPUS:105022626860

SN - 0269-8463

JO - Functional Ecology

JF - Functional Ecology

ER -

Herbivore species and patch heterogeneity modulate grazing-induced shifts in soil nematode trophic structure and energy flux

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Keywords

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