Comparative overwintering physiology of Alaska and Indiana populations of the beetle Cucujus clavipes (Fabricius): roles of antifreeze proteins, polyols, dehydration and diapause

Comparative overwintering physiology of Alaska and Indiana populations of the beetle Cucujus clavipes (Fabricius): roles of antifreeze proteins, polyols, dehydration and diapause

The beetle Cucujus clavipes is found in North America over a broad latitudinal range from North Carolina (latitude approximately 35 degrees N) to near tree line in the Brooks Range in Alaska (latitude, approximately 67 degrees 30' N). The cold adaptations of populations from northern Indiana (a...

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Bibliographic Details
Published in:Journal of experimental biology Vol. 208; no. Pt 23; pp. 4467 - 4477
Main Authors: Bennett, Valerie A, Sformo, Todd, Walters, Kent, Tøien, Øivind, Jeannet, Kennan, Hochstrasser, Ronald, Pan, Qingfeng, Serianni, Anthony S, Barnes, Brian M, Duman, John G
Format: Journal Article
Language:English
Published: England 01-12-2005
Subjects:
Adaptation, Physiological - physiology
Alaska
Animals
Antifreeze Proteins - metabolism
Carbon Dioxide - metabolism
Cold Temperature
Coleoptera - metabolism
Coleoptera - physiology
Cucujidae
Cucujus clavipes
Dehydration - physiopathology
Glycerol - metabolism
Indiana
Polymers - metabolism
USA, Alaska
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Summary:The beetle Cucujus clavipes is found in North America over a broad latitudinal range from North Carolina (latitude approximately 35 degrees N) to near tree line in the Brooks Range in Alaska (latitude, approximately 67 degrees 30' N). The cold adaptations of populations from northern Indiana (approximately 41 degrees 45' N) and Alaska were compared and, as expected, the supercooling points (the temperatures at which they froze) of these freeze-avoiding insects were significantly lower in Alaska insects. Both populations produce glycerol, but the concentrations in Alaska larvae were much higher than in Indiana insects (approximately 2.2 and 0.5 mol l(-1), respectively). In addition, both populations produce antifreeze proteins. Interestingly, in the autumn both populations have the same approximate level of hemolymph thermal hysteresis, indicative of antifreeze protein activity, suggesting that they synthesize similar amounts of antifreeze protein. A major difference is that the Alaska larvae undergo extreme dehydration in winter wherein water content decreases from 63-65% body water (1.70-1.85 g H2O g(-1) dry mass) in summer to 28-40% body water (0.40-0.68 g H2O g(-1) dry mass) in winter. These 2.5-4.6-fold reductions in body water greatly increase the concentrations of antifreeze in the Alaska insects. Glycerol concentrations would increase to 7-10 mol l(-1) while thermal hysteresis increased to nearly 13 degrees C (the highest ever measured in any organism) in concentrated hemolymph. By contrast, Indiana larvae do not desiccate in winter. The Alaska population also undergoes a diapause while insects from Indiana do not. The result of these, and likely additional, adaptations is that while the mean winter supercooling points of Indiana larvae were approximately -23 degrees C, those of Alaska larvae were -35 to -42 degrees C, and at certain times Alaska C. clavipes did not freeze when cooled to -80 degrees C.
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ISSN:0022-0949
1477-9145
DOI:10.1242/jeb.01892