Mechanistic constraints and optimality models: thermoregulatory strategies in colias butterflies

To explore mechanistic constraints on the evolution of optimal phenotypes, we develop an optimality model for thermoregulation in Colias butterflies. The model identifies the thermoregulatory characteristics of butterflies that maximize time available for flight activity subject to an overheating co...

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Bibliographic Details
Published in:Ecology (Durham) 1984-12, Vol.65 (6), p.1835-1839
Main Authors: Kingsolver, Joel G., Watt, Ward B.
Format: Article
Language:English
Subjects:
Biochemistry. Physiology. Immunology
Biological and medical sciences
Body temperature
Butterflies
Colias
Ecological modeling
evolution
Flight mechanics
Fundamental and applied biological sciences. Psychology
Insect flight
Insecta
Invertebrates
Mesas
Meteorology
Modeling
phenotypic selection
Physiology. Development
Pieridae
selection pressure
Thermoregulation
Wind velocity
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Summary:To explore mechanistic constraints on the evolution of optimal phenotypes, we develop an optimality model for thermoregulation in Colias butterflies. The model identifies the thermoregulatory characteristics of butterflies that maximize time available for flight activity subject to an overheating constraint, and was tested in three Colias populations along an elevational gradient. Model simulations and field results showed that environmental variation limits available flight time in higher elevation populations, even for optimally designed butterflies. Optimal predicted thermoregulatory characteristics were within two standard deviations of the observed characteristics in each population. Model simulations and field transplant experiments showed that large departures from optimality would have deleterious consequences for flight and overheating. This represents the first test of a strategy model for optimal thermoregulatory characteristics in animals. Our results illustrate how the constraints imposed by environmental variation and the mechanisms of adaptation affect the evolution of locally optimal phenotypes. We argue that, used in this mechanistic context, optimality modeling remains a powerful tool in studying adaptation.
ISSN:0012-9658
1939-9170
DOI:10.2307/1937780