Climatic stability, not average habitat temperature, determines thermal tolerance of subterranean beetles

dc.contributor.author Colado, Raquel ca
dc.contributor.author Pallarés, Susana ca
dc.contributor.author Fresneda, Javier ca
dc.contributor.author Mammola, Stefano ca
dc.contributor.author Rizzo, Valeria ca
dc.contributor.author Sánchez-Fernández, David ca
dc.contributor.other Consorci del Museu de Ciències Naturals de Barcelona ca
dc.date.accessioned 2023-02-09T10:46:56Z
dc.date.available 2023-02-09T10:46:56Z
dc.date.issued 2022-01-11
dc.description.abstract The climatic variability hypothesis predicts the evolution of species with wide thermal tolerance ranges in environments with variable temperatures, and the evolution of thermal specialists in thermally stable environments. In caves, the extent of spatial and temporal thermal variability experienced by taxa decreases with their degree of specialization to deep subterranean habitats. We use phylogenetic generalized least squares to model the relationship among thermal tolerance (upper lethal limits), subterranean specialization (estimated using ecomorphological traits), and habitat temperature in 16 beetle species of the tribe Leptodirini (Leiodidae). We found a significant, negative relationship between thermal tolerance and the degree of subterranean specialization. Conversely, habitat temperature had only a marginal effect on lethal limits. In agreement with the climatic variability hypothesis and under a climate change context, we show that the specialization process to live in deep subterranean habitats involves a reduction of upper lethal limits, but not an adjustment to habitat temperature. Thermal variability seems to exert a higher evolutionary pressure than mean habitat temperature to configure the thermal niche of subterranean species. Our results provide novel insights on thermal physiology of species with poor dispersal capabilities and on the evolutionary process of adaptation to subterranean environments. We further emphasize that the pathways determining vulnerability of subterranean species to climate change greatly depend on the degree of specialization to deep subterranean environments. ca
dc.description.abstract The climatic variability hypothesis predicts the evolution of species with wide thermal tolerance ranges in environments with variable temperatures, and the evolution of thermal specialists in thermally stable environments. In caves, the extent of spatial and temporal thermal variability experienced by taxa decreases with their degree of specialization to deep subterranean habitats. We use phylogenetic generalized least squares to model the relationship among thermal tolerance (upper lethal limits), subterranean specialization (estimated using ecomorphological traits), and habitat temperature in 16 beetle species of the tribe Leptodirini (Leiodidae). We found a significant, negative relationship between thermal tolerance and the degree of subterranean specialization. Conversely, habitat temperature had only a marginal effect on lethal limits. In agreement with the climatic variability hypothesis and under a climate change context, we show that the specialization process to live in deep subterranean habitats involves a reduction of upper lethal limits, but not an adjustment to habitat temperature. Thermal variability seems to exert a higher evolutionary pressure than mean habitat temperature to configure the thermal niche of subterranean species. Our results provide novel insights on thermal physiology of species with poor dispersal capabilities and on the evolutionary process of adaptation to subterranean environments. We further emphasize that the pathways determining vulnerability of subterranean species to climate change greatly depend on the degree of specialization to deep subterranean environments. en
dc.description.abstract The climatic variability hypothesis predicts the evolution of species with wide thermal tolerance ranges in environments with variable temperatures, and the evolution of thermal specialists in thermally stable environments. In caves, the extent of spatial and temporal thermal variability experienced by taxa decreases with their degree of specialization to deep subterranean habitats. We use phylogenetic generalized least squares to model the relationship among thermal tolerance (upper lethal limits), subterranean specialization (estimated using ecomorphological traits), and habitat temperature in 16 beetle species of the tribe Leptodirini (Leiodidae). We found a significant, negative relationship between thermal tolerance and the degree of subterranean specialization. Conversely, habitat temperature had only a marginal effect on lethal limits. In agreement with the climatic variability hypothesis and under a climate change context, we show that the specialization process to live in deep subterranean habitats involves a reduction of upper lethal limits, but not an adjustment to habitat temperature. Thermal variability seems to exert a higher evolutionary pressure than mean habitat temperature to configure the thermal niche of subterranean species. Our results provide novel insights on thermal physiology of species with poor dispersal capabilities and on the evolutionary process of adaptation to subterranean environments. We further emphasize that the pathways determining vulnerability of subterranean species to climate change greatly depend on the degree of specialization to deep subterranean environments. es
dc.format application/pdf ca
dc.format.extent 11 p. ca
dc.format.mimetype application/pdf ca
dc.identifier.citation Ecology, vol. 103, issue 4 (Apr. 2022), e3629 ca
dc.identifier.entitat consorcis ca
dc.identifier.uri http://hdl.handle.net/11703/129021
dc.language eng ca
dc.provenance Ajuntament de Barcelona. Museu de Ciències Naturals de Barcelona ca
dc.publisher Ecological Society of America ca
dc.rights Tots els drets reservats ca
dc.rights.accessrights info:eu-repo/semantics/restrictedAccess ca
dc.rights.holder Copyright by the Ecological Society of America. Colado, Raquel, Susana Pallarés, Javier Fresneda, Stefano Mammola, Valeria Rizzo, David S anchez-Fern andez. 2022. “Climatic Stability, Not Average Habitat Temperature, Determines Thermal Tolerance of Subterranean Beetles.” Ecology e3629. https://doi.org/10.1002/ecy.3629 ca
dc.rights.notes L'Ajuntament de Barcelona no pot donar autorització sobre l'ús d'aquest document ni facilitar-ne còpies. La utilització i/o reproducció d'aquest document fora de l’àmbit municipal representa l'incompliment de la legislació vigent sobre propietat intel·lectual ca
dc.subject Fauna cavernícola ca
dc.subject Canvis climàtics ca
dc.subject Coleòpters ca
dc.subject Liòdids ca
dc.subject Cave animals en
dc.subject Climatic changes en
dc.subject Beetles en
dc.subject Round fungus beetles en
dc.subject Fauna de cuevas es
dc.subject Cambios climáticos es
dc.subject Coleópteros es
dc.subject Leiódidos es
dc.subject.category Ciència i tecnologia ca
dc.subject.forma articles ca
dc.title Climatic stability, not average habitat temperature, determines thermal tolerance of subterranean beetles ca
dc.type text ca
dc.type.driver info:eu-repo/semantics/article ca
dc.type.driver info:eu-repo/semantics/publishedVersion ca
metadadalocal.dependencia 8008920

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