Temporal variation of thermal sensitivity to global warming: Acclimatization in the guitarist beetle, Megelenophorus americanus (Coleoptera: Tenebrionidae) from the Monte Desert.

Global warming is a major threat to biodiversity, the increase in mean temperature plus the higher rate and intensity of heat waves can severely affect organisms by exposing them to temperatures beyond their tolerance limits. Desert ectotherms are particularly vulnerable due to their dependence on environmental temperatures in an extreme habitat. Thermal tolerance changes depending on environmental conditions, studying these fluctuations provides a better understanding of species susceptibility to global warming. Tenebrionids are successful desert-inhabiting ectotherm taxa because of a series of adaptations for heat tolerance and water loss. We studied the seasonal variation (acclimatization) of thermal tolerance in Megelenophorus americanus, a widely distributed species in the Monte Desert (Argentina). To do this, we measured environmental and operative temperatures: body temperature (T), soil temperature (T), air temperature (T), environmental temperature (T) and maximum temperature (T), and tolerance proxies volunteer thermal maximum (VT) Fluid release (FR) and critical thermal maximum (CT) in a population of M. americanus from San Juan province, Argentina from October to March (full activity season). We found that T and T are accurate predictors of T, suggesting thermoconformism. All tolerance proxies showed differences among months, suggesting a natural acclimatization process in situ. Insects were found operating beyond VT (thermal stress) but they were far from reaching CT under natural conditions. Organisms present different degrees of tolerance plasticity that should be considered when predicting potential impacts of climate change.