Tree diversity, tree growth, and microclimate independently structure Lepidoptera herbivore community stability
Publikation: Beiträge in Zeitschriften › Zeitschriftenaufsätze › Forschung › begutachtet
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in: Ecological Monographs, Jahrgang 95, Nr. 3, e70026, 08.2025.
Publikation: Beiträge in Zeitschriften › Zeitschriftenaufsätze › Forschung › begutachtet
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T1 - Tree diversity, tree growth, and microclimate independently structure Lepidoptera herbivore community stability
AU - Wang, Ming Qiang
AU - Albert, Georg
AU - Chesters, Douglas
AU - Bruelheide, Helge
AU - Li, Yi
AU - Chen, Jing Ting
AU - Haider, Sylvia
AU - Li, Shan
AU - von Oheimb, Goddert
AU - Proß, Tobias
AU - Schnabel, Florian
AU - Yang, Bo
AU - Zhou, Qing Song
AU - Ma, Keping
AU - Liu, Xiaojuan
AU - Zhu, Chao Dong
AU - Luo, Arong
AU - Schuldt, Andreas
N1 - Publisher Copyright: © 2025 The Ecological Society of America.
PY - 2025/8
Y1 - 2025/8
N2 - Insect herbivores are integral to the functioning of forest ecosystems. However, increasing herbivore outbreaks highlight the need to understand the factors driving the spatial and temporal stability of herbivore communities. While the longer term consequences of climatic fluctuations are well established in this context, the role of local-scale interactions between herbivores, their host communities, and local microclimates in influencing herbivore stability remains unclear. In this study, we investigated the relative importance of host tree species richness, functional diversity, trait composition, tree growth dynamics, and climate in driving herbivore spatiotemporal stability and the resulting patterns in abundance and diversity. We focused on Lepidoptera caterpillars as very diverse and functionally highly relevant herbivores in forest ecosystems. Tree species richness promoted mean caterpillar abundance, species richness, and phylogenetic diversity by positively affecting their temporal and spatial stability. These effects were mostly direct but counteracted by largely independent and overall negative effects of tree functional diversity, tree growth stability, and microclimate temperature stability. The strength and direction of these effects varied across seasons, reflecting shifts in environmental conditions and herbivore species turnover. The effects of tree diversity on caterpillar communities were related to compositional changes through distinct pathways by reducing taxonomic beta diversity and thus enhancing species richness stability and by increasing phylogenetic beta diversity which may promote asynchrony among distantly related species. Crucially, our findings suggest that tree diversity buffers herbivore communities against climate fluctuations by enhancing their spatiotemporal stability. In consequence, ongoing biodiversity loss may lead to greater fluctuations in herbivore populations and an increased risk of outbreaks. Our study provides novel insights into the mechanisms underlying bottom-up regulation of herbivores, emphasizing the critical role of tree diversity in maintaining stable herbivore communities in a changing climate.
AB - Insect herbivores are integral to the functioning of forest ecosystems. However, increasing herbivore outbreaks highlight the need to understand the factors driving the spatial and temporal stability of herbivore communities. While the longer term consequences of climatic fluctuations are well established in this context, the role of local-scale interactions between herbivores, their host communities, and local microclimates in influencing herbivore stability remains unclear. In this study, we investigated the relative importance of host tree species richness, functional diversity, trait composition, tree growth dynamics, and climate in driving herbivore spatiotemporal stability and the resulting patterns in abundance and diversity. We focused on Lepidoptera caterpillars as very diverse and functionally highly relevant herbivores in forest ecosystems. Tree species richness promoted mean caterpillar abundance, species richness, and phylogenetic diversity by positively affecting their temporal and spatial stability. These effects were mostly direct but counteracted by largely independent and overall negative effects of tree functional diversity, tree growth stability, and microclimate temperature stability. The strength and direction of these effects varied across seasons, reflecting shifts in environmental conditions and herbivore species turnover. The effects of tree diversity on caterpillar communities were related to compositional changes through distinct pathways by reducing taxonomic beta diversity and thus enhancing species richness stability and by increasing phylogenetic beta diversity which may promote asynchrony among distantly related species. Crucially, our findings suggest that tree diversity buffers herbivore communities against climate fluctuations by enhancing their spatiotemporal stability. In consequence, ongoing biodiversity loss may lead to greater fluctuations in herbivore populations and an increased risk of outbreaks. Our study provides novel insights into the mechanisms underlying bottom-up regulation of herbivores, emphasizing the critical role of tree diversity in maintaining stable herbivore communities in a changing climate.
KW - BEF-China
KW - biodiversity loss
KW - climate change
KW - functional diversity
KW - herbivore community dynamics
KW - spatiotemporal assembly
KW - tree diversity
KW - Biology
KW - Ecosystems Research
UR - http://www.scopus.com/inward/record.url?scp=105013646748&partnerID=8YFLogxK
U2 - 10.1002/ecm.70026
DO - 10.1002/ecm.70026
M3 - Journal articles
AN - SCOPUS:105013646748
VL - 95
JO - Ecological Monographs
JF - Ecological Monographs
SN - 0012-9615
IS - 3
M1 - e70026
ER -