Your search keyword '"L.Keith Miller"' showing total 3 results

1. Freezing tolerance in relation to cooling rate in an adult insect

Author

L.Keith Miller

Subjects

biology, Temperature, Adult insect, Thermodynamics, Slight change, General Medicine, Cooling rates, Upis ceramboides, biology.organism_classification, General Biochemistry, Genetics and Molecular Biology, Coleoptera, Cooling rate, Animal science, Freezing, Animals, Mortality, General Agricultural and Biological Sciences, Freezing tolerance

Abstract

In the adult tenebrionid beetle Upis ceramboides unusually low cooling rates are required to demonstrate maximum freezing tolerance, and a very slight change in rate can reduce survival from 100 to 0%. Freezing to −50 °C results in 100% mortality at rates above 0.35 °C/min, but no injury is apparent if the cooling rate is 0.28 °C/min. The lower lethal temperature, determined with a cooling rate of 0.17 °C/min, is about −60 °C. The maximum cooling rate which allows full survival is nearly identical to optimal cooling rates previously found for mouse embryos and some lymphocytes, but the striking sensitivity to very slight changes in rate is unique to Upis . Most studies dealing with insect freezing tolerance have utilized rates of 1 °C/min or faster, and the failure of some of these laboratory studies to observe freezing survival may be due to the use of lethal cooling rates.

Published

1978

2. Physical and chemical changes associated with seasonal alterations in freezing tolerance in the adult northern tenebrionid, Upis ceramboides

Author

L.Keith Miller

Subjects

Physiology, Taiga, Biology, Upis ceramboides, Seasonality, biology.organism_classification, medicine.disease, Hibernaculum, Lower limit, chemistry.chemical_compound, Horticulture, chemistry, Insect Science, Botany, medicine, Threitol, Supercooling, Freezing tolerance

Abstract

The adult tenebrionid beetle Upis ceramboides overwinters in the northern taiga forests of North America in a hibernaculum typically just beneath loose tree bark above the snowline. The beetles may be exposed to temperatures as low as −55°C, which is approximately the lower limit of cold tolerance found in specimens collected in mid-winter. Supercooling points average −6.3°C throughout the year and, contrary to expectation, show no seasonal variation in spite of major alterations in haemolymph composition and freezing tolerance. Summer beetles are incapable of withstanding temperatures below the supercooling point but freezing tolerance increases during the fall (September–November) and the lower lethal temperature (LLT) is maintained at ca. −55°C until March, after which it gradually rises to the summer level of −6°C. Changes in freezing tolerance are closely associated with seasonal alterations in the polyhydric alcohols sorbitol and threitol. Neither polyol is present in measureable amount during summer; sorbitol accumulates to an average haemolymph concentration of 0.44 M/l in winter and threitol reaches 0.25 M/l. Summer beetles contain about 14% more water than beetles collected during the other seasons. Upis ceramboides thus undergoes unique seasonal changes in physical and chemical characteristics that enable it to tolerate severe, prolonged subfreezing temperatures.

Published

1978

3. Freezing tolerance in an adult insect

Author

L.Keith Miller

Subjects

Coleoptera, Horticulture, Multidisciplinary, Ecology, Pterostichus brevicornis, Freezing, Adult insect, Temperature, Cooling rates, Seasons, Biology, Adaptation, Physiological, Freezing tolerance

Abstract

The adult carabid beetle Pterostichus brevicornis tolerates freezing under natural conditions. Laboratory tests confirm that winter beetles tolerate temperatures below -35 degrees C, whereas summer beetles die if frozen at -6.6 degrees C. Winter beetles can be cooled to about -10 degrees C before freezing, and they thaw near -3.5 degrees C. Summer beetles thaw at -0.7 degrees C. To avoid freezing damage even in winter beetles, cooling rates must be near 20 degrees C per hour or less.

Published

1969