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Natural history predicts patterns of thermal vulnerability in amphibians from the Atlantic Rainforest of Brazil

AutorInnen: 
Carilo Filho, L. M., de Carvalho, B. T., Azevedo, B. K., Gutiérrez-Pesquera, L. M., Mira-Mendes, C. V., Solé, M., Orrico, V. G. D.
Erscheinungsjahr: 
2021
Vollständiger Titel: 
Natural history predicts patterns of thermal vulnerability in amphibians from the Atlantic Rainforest of Brazil
ZFMK-Autorinnen / ZFMK-Autoren: 
Org. Einordnung: 
Publiziert in: 
Ecology and Evolution
Publikationstyp: 
Zeitschriftenaufsatz
DOI Name: 
10.1002/ece3.796
Keywords: 
climate changes, CTMax, deforestation, future vulnerability, tropical amphibians, warming tolerance
Bibliographische Angaben: 
Carilo Filho, L. M., de Carvalho, B. T., Azevedo, B. K., Gutiérrez-Pesquera, L. M., Mira-Mendes, C. V., Solé, M., Orrico, V. G. D. (2021): Natural history predicts patterns of thermal vulnerability in amphibians from the Atlantic Rainforest of Brazil. - Ecology and Evolution 2021 (11):16462–16472; DOI: 10.1002/ece3.796
Abstract: 

In the Brazilian Atlantic Rainforest (AF), amphibians (625 species) face habitat deg-radation leading to stressful thermal conditions that constrain animal activity (e.g., foraging and reproduction). Data on thermal ecology for these species are still scarce. We tested the hypothesis that environmental occupation affects the thermal tolerance of amphibian species more than their phylogenetic relationships. We evaluated patterns of thermal tolerance of 47 amphibian species by assessing critical thermal maxima and warming tolerances, relating these variables with ecological covariates (e.g., adult macro- and microhabitat and site of larval development). We used mean and maximum environmental temperature, ecological covariates, and morphological measurements in the phylogenetic generalized least squares model selection to eval-uate which traits better predict thermal tolerance. We did not recover phylogenetic signal under a Brownian model; our results point to a strong association between critical thermal maxima and habitat and development site. Forest species were less tolerant to warm temperatures than open area or generalist species. Species with larvae that develop in lentic environment were more tolerant than those in lotic ones. Thus, species inhabiting forest microclimates are more vulnerable to the synergistic effect of habitat loss and climate change. We use radar charts as a quick evaluation tool for thermal risk diagnoses using aspects of natural history as axes.