Abstract
All physiological processes of ectotherms depend on environmental temperature. Thus, adaptation of physiological mechanisms to the thermal environments is important for achieving optimal performance and fitness. The European Common Frog, Rana temporaria, is widely distributed across different thermal habitats. This makes it an exceptional model for studying the adaptations to different thermal conditions. We raised tadpoles from Germany and Croatia at two constant temperature treatments (15°C, 20°C), and under natural temperature fluctuations (in outdoor treatments), and tested how different developmental temperatures affected developmental traits, that is, length of larval development, morphometrics, and body condition, as well as jumping performance of metamorphs. Our results revealed population‐specific differences in developmental time, body condition, and jumping performance. Croatian frogs developed faster in all treatments, were heavier, in better body condition, and had longer hind limbs and better jumping abilities than German metamorphs. The populations further differed in thermal sensitivity of jumping performance. While metamorphs from Croatia increased their jumping performance with higher temperatures, German metamorphs reached their performance maximum at lower temperatures. These population‐specific differences in common environments indicate local genetic adaptation, with southern populations being better adapted to higher temperatures than those from north of the Alps.
Highlights
Ectotherms are unable to generate a significant amount of metabolic body heat (Hillman et al 2009)
All physiological processes and the performance of ectotherms strongly depended on environmental temperatures (Angilletta 2009)
Tadpoles from or at all (OT)-CRO developed at higher temperatures and metamorphosed significantly faster than OT-GER
Summary
Ectotherms are unable to generate a significant amount of metabolic body heat (Hillman et al 2009). All physiological processes and the performance of ectotherms strongly depended on environmental temperatures (Angilletta 2009). Adaptation to local thermal conditions is of great importance to achieve optimal performance and fitness (Kingsolver and Huey 2003; Angilletta 2009; Keller and Seehausen 2012). Such adaptations may be genetically fixed or phenotypically plastic. Phenotypic plasticity, in contrast, enables single genotypes to produce multiple phenotypes in different environments, allowing the expression of a broader range of morphological, behavioral, or physiological characters and, survival under a wide set of environmental conditions (West-Eberhard 2003)
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