TY - JOUR
T1 - Destabilized bacterial and fungal network weakens soil multifunctionality under increasing grazing stress
AU - Li, Shaoyu
AU - Zhang, Bin
AU - Li, Yanan
AU - Zhao, Tianqi
AU - Zheng, Jiahua
AU - Qiao, Jirong
AU - Zhang, Feng
AU - Han, Guodong
AU - Bisseling, Ton
AU - Zhao, Mengli
PY - 2025/2
Y1 - 2025/2
N2 - Although it is universally acknowledged that grazing weakens most grassland ecosystem functions, the effect of varying grazing stress on soil multifunctionality (SMF) and the associated microbially-mediated mechanisms have not been fully elucidated. Here, we used a 20-year field experiment to evaluate the influence of different grazing intensities (no grazing [CK], light grazing [LG], moderate grazing [MG], and heavy grazing [HG]) on SMF and explored the regulating effect of bacterial and fungal community structure, network attributes. We evaluated 18 soil functions including soil hydrological parameters, enzymatic activities, and nutrients to characterize four individual functions (water regulation and C-, N-, P- cycling) and SMF. Our results showed that except for water regulation, SMF and other individual functions gradually decreased with increasing grazing stress. In addition, high grazing stress also reduced microbial diversity and network complexity destabilized bacterial network stability. Structural equation modeling revealed that SMF was mainly regulated by bacterial network complexity and fungal network stability. These results provide strong empirical evidence that bacterial and fungal communities have different roles in shaping SMF along grazing stresses gradient. Therefore, assessing soil multifunctionality should account not only microbial diversity but also their interactions within microbial networks. This approach is crucial for informing strategies in the degraded land restoration and sustainable utilization of grassland in arid and semi-arid ecosystems.
AB - Although it is universally acknowledged that grazing weakens most grassland ecosystem functions, the effect of varying grazing stress on soil multifunctionality (SMF) and the associated microbially-mediated mechanisms have not been fully elucidated. Here, we used a 20-year field experiment to evaluate the influence of different grazing intensities (no grazing [CK], light grazing [LG], moderate grazing [MG], and heavy grazing [HG]) on SMF and explored the regulating effect of bacterial and fungal community structure, network attributes. We evaluated 18 soil functions including soil hydrological parameters, enzymatic activities, and nutrients to characterize four individual functions (water regulation and C-, N-, P- cycling) and SMF. Our results showed that except for water regulation, SMF and other individual functions gradually decreased with increasing grazing stress. In addition, high grazing stress also reduced microbial diversity and network complexity destabilized bacterial network stability. Structural equation modeling revealed that SMF was mainly regulated by bacterial network complexity and fungal network stability. These results provide strong empirical evidence that bacterial and fungal communities have different roles in shaping SMF along grazing stresses gradient. Therefore, assessing soil multifunctionality should account not only microbial diversity but also their interactions within microbial networks. This approach is crucial for informing strategies in the degraded land restoration and sustainable utilization of grassland in arid and semi-arid ecosystems.
KW - Desert grassland
KW - Long-term grazing
KW - Microbial network complexity
KW - Microbial network stability
KW - Soil multifunctionality
U2 - 10.1016/j.apsoil.2024.105827
DO - 10.1016/j.apsoil.2024.105827
M3 - Article
AN - SCOPUS:85212541696
SN - 0929-1393
VL - 206
JO - Applied Soil Ecology
JF - Applied Soil Ecology
M1 - 105827
ER -