Abstract
Flight is a central determinant of fitness in butterflies and other insects, but it is restricted to a limited range of body temperatures. To achieve these body temperatures, butterflies use a combination of morphological, behavioural and physiological mechanisms. Here, we used common garden (without direct solar radiation) and reciprocal transplant (full solar radiation) experiments in the field to determine the thermal sensitivity of flight initiation for two species of Colias butterflies along an elevation gradient in the southwestern Rocky Mountains. The mean body temperature for flight initiation in the field was lower (24-26°C) than indicated by previous studies (28-30°C) in these species. There were small but significant differences in thermal sensitivity of flight initiation between species; high-elevation Colias meadii initiated flight at a lower mean body temperature than lower-elevation Colias eriphyle. Morphological differences (in wing melanin and thoracic setae) drive body temperature differences between species and contributed strongly to differences in the time and probability of flight and air temperatures at flight initiation. Our results suggest that differences both in thermal sensitivity (15% contribution) and in morphology (85% contribution) contribute to the differences in flight initiation between the two species in the field. Understanding these differences, which influence flight performance and fitness, aids in forecasting responses to climate change.
Highlights
Most ectotherms have a restricted range of body temperatures over which they can achieve high rates of resource acquisition, growth and other aspects of performance (Andrewartha and Birch, 1954; Magnuson et al, 1979; Huey and Hertz, 1984)
Our results suggest that differences both in thermal sensitivity (15% contribution) and in morphology (85% contribution) contribute to the differences in flight initiation between the two species in the field
Previous work along an elevation gradient showed that C. eriphyle from higher elevations are able to initiate flight earlier than those from lower elevations, owing to differences in wing melanin among populations (Ellers and Boggs, 2004)
Summary
Most ectotherms have a restricted range of body temperatures over which they can achieve high rates of resource acquisition, growth and other aspects of performance (Andrewartha and Birch, 1954; Magnuson et al, 1979; Huey and Hertz, 1984). Locomotion is a key aspect of performance in many ectotherms, and thermal constraints on locomotion can be important determinants of activity patterns, reproductive success and fitness (Adolph and Porter, 1993; Kearney et al, 2009a; Sinervo et al, 2010; Buckley and Kingsolver, 2012). Performance at lower temperatures may be important for organisms at higher elevations or latitudes, where the time available for activity or development can be strongly limited (Kingsolver, 1983b; Adolph and Porter, 1993; Sinervo and Adolph, 1994)
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