Abstract

The survival of insects that inhabit Canadian arctic regions depends on a number of factors which have important ecological, behavioral, physiological, and biochemical components. The ability to withstand low winter temperatures is one of the most conspicuous adaptations of northern insects and the one most closely studied in the laboratory. Most species studied so far conform to one or other of the two major overwintering strategies, namely, frost susceptibility, the ability to avoid freezing by supercooling to a considerable degree, or frost tolerance, the survival of actual ice formation within the body. The Arctic beetle, Pytho americanus Kirby, is frost tolerant in both larval and adult stages, a situation which would be congruous with its northern distribution and allow it to spread its life cycle over a number of growing seasons. The main biochemical correlates during the cold-hardening process in this species are increasing glycerol and decreasing glycogen concentrations. In addition to its normally assumed roles in cryoprotection there is evidence to suggest that glycerol may further serve to minimize dehydration in the overwintering insect by increasing the level of bound water. P. americanus larvae and adults have narrow supercooling ranges and maintain their supercooling points in the region of −4 to −8 °C. It is hypothesized that these elevated supercooling points are a result of the presence in the hemolymph of nucleating agents which ensure ice formation at high subzero temperatures. Low temperature tolerance strategies of some other arctic and alpine species have been examined and compared with those of relatives from more southerly latitudes. P. americanus has been collected in the Canadian Rockies at elevations of over 6000′, and its frost-tolerant attributes are identical to those of the population collected in the Arctic. A closely related species, P. deplanatus, from the Rockies, however, although it too exhibits frost tolerance in the larval stage, differs markedly from P. americanus in its ability to depress its supercooling range to −54 °C. It appears that P. deplanatus does not have the ability to synthesize ice-nucleating agents and, therefore, can overwinter in a supercooled condition. Two congeneric species of willow leaf gall sawflies ( Pontania spp.), one from Tuktoyaktuk, N.W.T., and the other from southern Vancouver Island have also been compared and contrasted. Pontania sp. on Salix glauca (Tuk., ca. 70 °N) is frost tolerant in its larval stage, has relatively high supercooling points (ca. −9.0 °C), but does not accumulate glycerol. Pontania sp. from Salix lasiandra (Victoria, ca. 48 °N) has almost identical overwintering properties, indicating the close phylogenetic affinities of cold tolerance in this genus rather than independent adaptation to widely different climatic conditions. Some of the lowest supercooling points ever recorded are from willow stem gall forming insects. Rhabdophaga sp. (Cecidomyiidae) forms potato galls on the stems of Salix lanata in the Inuvik area, N.W.T. After low temperature acclimation, supercooling points down to −66 °C have been recorded from individual larvae. This is a record, and it indicates that we may be dealing with a system in which most water is in a metabolically bound state. Glycerol levels reach 20% of the fresh body weight during this period. Diastrophus kincaidii Cynipidae) forms stem galls on Thimble Berry ( Rubus parviflorus) on southern Vancouver Island. Both of the forementioned species overwinter as larvae in their galls and are, therefore, exposed to ambient air temperatures. A more benign winter climate on Vancouver Island is reflected in the fact that D. kincaidii has supercooling points only in the −30 to −33 °C range at the peak of low temperature acclimation, and glycerol levels just below 4% of fresh body weight. Both species are frost susceptible and depend on their supercooling abilities to survive low winter temperatures.

Talk to us

Join us for a 30 min session where you can share your feedback and ask us any queries you have

Schedule a call

Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.