Behavioural thermoregulation and the relative roles of convection and radiation in a basking butterfly.

Poikilothermic animals are often reliant on behavioural thermoregulation to elevate core-body temperature above the temperature of their surroundings. Butterflies are able to do this by altering body posture and location while basking, however the specific mechanisms that achieve such regulation vary among species. The role of the wings has been particularly difficult to describe, with uncertainty surrounding whether they are positioned to reduce convective heat loss or to maximise heat gained through radiation. Characterisation of the extent to which these processes affect core-body temperature will provide insights into the way in which a species׳ thermal sensitivity and morphological traits have evolved. We conducted field and laboratory measurements to assess how basking posture affects the core-body temperature of an Australian butterfly, the common brown (Heteronympha merope). We show that, with wings held open, heat lost through convection is reduced while heat gained through radiation is simultaneously maximised. These responses have been incorporated into a biophysical model that accurately predicts the core-body temperature of basking specimens in the field, providing a powerful tool to explore how climate constrains the distribution and abundance of basking butterflies.

[1]  Raymond B Huey,et al.  Behavioral Drive versus Behavioral Inertia in Evolution: A Null Model Approach , 2003, The American Naturalist.

[2]  J. Kingsolver,et al.  Thermoregulation and the determinants of heat transfer in Colias butterflies , 1982, Oecologia.

[3]  P. Brakefield,et al.  PLASTICITY IN BUTTERFLY EGG SIZE: WHY LARGER OFFSPRING AT LOWER TEMPERATURES? , 2003 .

[4]  J. Kingsolver EVOLUTION AND COADAPTATION OF THERMOREGULATORY BEHAVIOR AND WING PIGMENTATION PATTERN IN PIERID BUTTERFLIES , 1987, Evolution; international journal of organic evolution.

[5]  P. S. Digby Factors Affecting the Temperature Excess of Insects in Sunshine , 1955 .

[6]  J. Kingsolver,et al.  Thermal physiological ecology of Colias butterflies in flight , 1986, Oecologia.

[7]  W. Porter Solar Radiation through the Living Body Walls of Vertebrates with Emphasis on Desert Reptiles , 1967 .

[8]  T. Casey Biophysical Ecology and Heat Exchange in Insects , 1992 .

[9]  J. Kingsolver Thermoregulatory significance of wing melanization in Pieris butterflies (Lepidoptera: Pieridae): physics, posture, and pattern , 1985, Oecologia.

[10]  Robert D. Stevenson,et al.  The Relative Importance of Behavioral and Physiological Adjustments Controlling Body Temperature in Terrestrial Ectotherms , 1985, The American Naturalist.

[11]  J. McNeil,et al.  Sexual Differences in the Thermoregulation of Thymelicus Lineola Adults (Lepidoptera: Hesperiidae) , 1986 .

[12]  Theoretical and experimental studies of energy exchange from jackrabbit ears and cylindrically shaped appendages. , 1971, Biophysical journal.

[13]  Robert Dudley,et al.  Biomechanics of Flight in Neotropical Butterflies: Morphometrics and Kinematics , 1990 .

[14]  J. Kingsolver Thermal ecology of Pieris butterflies (Lepidoptera: Pieridae): a new mechanism of behavioral thermoregulation , 1985, Oecologia.

[15]  M. Kearney,et al.  Modelling species distributions without using species distributions: the cane toad in Australia under current and future climates , 2008 .

[16]  J. Kingsolver Ecological Significance of Flight Activity in Colias Butterflies: Implications for Reproductive Strategy and Population Structure , 1983 .

[17]  M. Chappell,et al.  Analysis of Heat Transfer in Vanessa Butterflies: Effects of Wing Position and Orientation to Wind and Light , 1986, Physiological Zoology.

[18]  Michael Kearney,et al.  The potential for behavioral thermoregulation to buffer “cold-blooded” animals against climate warming , 2009, Proceedings of the National Academy of Sciences.

[19]  Joel G. Kingsolver,et al.  Thermoregulation and Flight in Colias Butterflies: Elevational Patterns and Mechanistic Limitations , 1983 .

[20]  D. Kemp,et al.  Behavioural thermoregulation in butterflies: the interacting effects of body size and basking posture in Hypolimnas bolina (L.) (Lepidoptera:Nymphalidae) , 2004 .

[21]  P. Brakefield,et al.  Fitness consequences of temperature‐mediated egg size plasticity in a butterfly , 2003 .

[22]  L. T. Wasserthal The rôle of butterfly wings in regulation of body temperature , 1975 .

[23]  J. E. Rawlins THERMOREGULATION BY THE BLACK SWALLOWTAIL BUTTERFLY, PAPILIO POLYXENES (LEPIDOPTERA: PAPILIONIDAE)' , 1980 .

[24]  T. Sisk,et al.  Butterfly Response to Microclimatic Conditions Following Ponderosa Pine Restoration , 2001 .

[25]  R. Rutowski,et al.  Behavioural thermoregulation at mate encounter sites by male butterflies (Asterocampa leilia, Nymphalidae) , 1994, Animal Behaviour.

[26]  J. Mitchell,et al.  Heat transfer from spheres and other animal forms. , 1976, Biophysical journal.

[27]  D. M. Gates,et al.  THERMODYNAMIC EQUILIBRIA OF ANIMALS WITH ENVIRONMENT , 1969 .

[28]  W. B. Watt ADAPTIVE SIGNIFICANCE OF PIGMENT POLYMORPHISMS IN COLIAS BUTTERFLIES. III. PROGRESS IN THE STUDY OF THE “ALBA” VARIANT , 1973, Evolution; international journal of organic evolution.

[29]  K. S. Norris Color adaptation in desert reptiles and its thermal relationships , 1967 .

[30]  N. Church Heat Loss and the Body Temperatures of Flying Insects , 1960 .

[31]  D. Kemp,et al.  A novel method of behavioural thermoregulation in butterflies , 2002 .

[32]  B. Heinrich Is ‘Reflectance’ Basking Real? , 1990 .

[33]  Harry K. Clench,et al.  Behavioral Thermoregulation in Butterflies , 1966 .

[34]  D. J. Lactin,et al.  CONVECTIVE HEAT LOSS AND CHANGE IN BODY TEMPERATURE OF GRASSHOPPER AND LOCUST NYMPHS: RELATIVE IMPORTANCE OF WIND SPEED, INSECT SIZE AND INSECT ORIENTATION , 1998 .

[35]  C M BOGERT,et al.  THERMOREGULATION IN REPTILES, A FACTOR IN EVOLUTION , 1949, Evolution; international journal of organic evolution.

[36]  J. Kingsolver,et al.  Thermoregulatory Strategies in Colias Butterflies: Thermal Stress and the Limits to Adaptation in Temporally Varying Environments , 1983, The American Naturalist.