Abstract
With the prominent role augmented rates of thermogenesis play in the regulation of body temperature by most birds in winter cold, it is of interest to examine the extent to which this process is affected by metabolic acclimatization. Such adjustment affects not only the cold resistance of these animals, but also their energy requirements in a season when food supplies are declining and the time to locate them minimal. We shall emphasize naturally occurring forms of metabolic acclimatization in wild birds, but some consideration also will be given to that associated with exposure to cold in the laboratory. Smaller birds are of primary concern because of their limited capacities for insulative acclimatization, though indications of metabolic acclimatization in larger forms also will be considered. Particular attention will be devoted to indications of acclimatization involving metabolic level, thermogenic capacity, endurance in the cold, extent of energy reserves, and the biochemical correlates of cold resistance. Our goal is to characterize metabolic acclimatization by birds to cold and season to an extent commensurate with current knowledge of this form of compensation.
Research of W. R. Dawson and associates supported by grants from the National Science Foundation, currently BSR 84-07952.
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References
Ambrose, S. J., and Bradshaw, S. D., 1988, Seasonal changes in standard metabolic rates in the white-browed scrubwren Sericornis frontalis (Acanthizidae) from arid, semi-arid, and mesic environments. Comp. Biochem. Physiol., 89A: 79.
Arieli, A., Berman, A., and Meltzer, A., 1979, Cold thermogenesis in the summer-acclimatized and winter-acclimated domestic fowl, Comp. Biochem. Physiol., 63C: 7.
Barré, H., 1986, Metabolic and insulative changes in winter-and summeracclimatized king penguin chicks, J. Comp. Physiol., B154: 317.
Barré, H., Cohen-Adad, F., and Rouanet, J., 1987, Two daily glucagon injections induce nonshivering thermogenesis in Muscovy ducklings. Am. J. Physiol., 252: E616.
Barré, H., and Roussel, B., 1986, Thermal and metabolic adaptation to first cold-water immersion in juvenile penguins, Am. J. physiol., 251: R456.
Bech, C., 1980, Body temperature, metabolic rate, and insulation in winter and summer acclimatized mute swans (Cygnus olor), J. Comp. Physiol., B136: 61.
Blem, C. R., 1973, Geographic variation in the bioenergetics of the house sparrow, Qrnithol. Monogr., 14: 96.
Blem, C. R., 1976, Patterns of lipid storage and utilization in birds, Am. Zool., 16: 671.
Blem, C. R., and Pagels, J. F., 1984, Mid-winter lipid reserves of the golden-crowned kinglet, Condor, 86: 491.
Brackenbury, J., 1984, Physiological responses of birds to flight and running, Biol. Rev., 59: 559.
Brody, S., 1945, “Bioenergetics and Growth,” Reinhold Publishing Corp., New York.
Calder, W. A., 1984, “Size, Function, and Life History,” Harvard Univ. Press, Cambridge, MA.
Callow, M., Morten, A., and Guppy, M., 1986, Marathon fatigue: the role of plasma free fatty acids, Eur. J. Appl. Physiol., 55: 654.
Cannon, B., and Nedergaard, J., 1988, Shivering and non-shivering thermogenesis in birds, this volume.
Carey, C., Dawson, W. R., Maxwell, L. C., and Faulkner, J. A., 1978, Seasonal acclimatization to temperature in cardueline finches. II. Changes in body composition and mass in relation to season and acute cold stress, J. Comp. Physiol., B125: 101.
Carey, C., Marsh, R. L., Bekoff, A. C., and Olin, A., 1988, Enzyme activities and muscular patterns of shivering in house finches, this volume.
Clark, J. H., and Conlee, R. K., 1979, Muscle and liver glycogen content: diurnal variation and endurance, J. Appl. Physiol., 47: 425.
Dawson, W. R., 1958, Relation of oxygen consumption ancf evaporative water loss to temperature in the cardinal, Physiol. Zool., 31: 37.
Dawson, W. R., Buttemer, W. A., and Carey, C., 1985, A reexaminat ion of the metabolic response of house finches to temperature, Condor, 87: 424.
Dawson, W. R., and Carey, C., 1976, Seasonal acclimatization to temperature in cardueline finches. I. Insulative and metabolic adjustments, J. Comp. Physiol., 112: 317.
Dawson, W. R., and Marsh, R. L., 1986, Winter fattening in the American goldfinch and the possible role of temperature in its regulation, Physiol. Zool., 59: 357.
Dawson, W. R., Marsh, R. L., Buttemer, W. A., and Carey, C., 1983a, Seasonal and geographic variation of cold resistance in house finches Carpodacus mexicanus, Physiol. Zool., 56: 353.
Dawson, W. R., Marsh, R. L., and Yacoe, M. E., 1983b, Metabolic adjustments of small passerine birds for migration and cold, Am. J. Physiol., 245: R755.
Dawson, W. R., and Smith, B. K., 1986, Seasonal acclimatization in the American goldfinch (Carduelis trirstis), In: “Living in the Cold,” H. C. Heller, X. J. Musacchia, and L. C. H. Wang, eds., Elsevier Science Publishing Co., New York.
Dawson, W. R., and Tordoff, H. B., 1959, Relation of oxygen consumption to temperature in the evening grosbeak, Condor, 61: 388.
Depocas, F., 1962, Body glucose as fuel in white rats exposed to cold: results with fasted rats, Am. J. Physiol., 202: 1015.
Dontcheff, L., and Kayser, C., 1934, Le rythme saisonnier du métabolisme de base chez le pigeon en fonction de la température moyenne du milieu, Ann. Physiol Physiocohim. Biol., 10: 285.
Evans, P. R., 1969, Winter fat deposition and overnight survival of yellow buntings (Emberiza citrinella L.), J. Anim.Ecol., 38: 415.
Gelineo, S., 1934, Influence du milieu thermique sur la courbe de la thermorégulation, Compt. Rend.Soc. Biol., 117: 40.
Gelineo, S., 1955, Température d’adaptation et production de chaleur chez oiseaux de petite taille, Arch. Sci. Physiol., 9: 225.
Gelineo, S., 1964, Organ systems in adaptation: the temperature regulating system, In: “Handbook of Physiology, Section 4, Adaptation to Environment,” D. B. Dill, ed., American Physiological Society, Washington, D. C.
Gelineo, S., 1969, Heat production in birds in summer and winter, Srpska Akad. Nauka I Umetnosti Belgrad, Bull Classe Sci Math. Natur., XXVI, Sci. Natur. (n. s.), no. 12: 99
George, J. C., and John, T. M., 1986, Physiological responses to cold exposure in pigeons. In: “Living in the Cold,” H. C. Heller, X. J. Musacchia, and L. C. H. Wang, eds., Elsevier Science Publishing Co., New York.
Giaja, J., 1925, Le métabolisme de sommet et le quotient métabolique, Ann. Physiol. Physcicochim. Biol., 1: 596.
Giaja, J., 1931, Contribution à l’étude de la thermorégulation des oiseaux, Ann. Physiol. Physicochim. Biol., 7: 13.
Hart, J. S., 1962, Seasonal acclimatization in four species of small wild birds, Physiol. Zool., 35: 224.
Hart, J. S., 1964, Insulative and metabolic adaptations to cold in vertebrates, Soc. Exp. Biol. Symp., 35: 31.
Hartman, F. A., 1961, Locomotor mechanisms in birds, Smithsonian Misc. Coll., 143: 1.
Harvey, S., Klandorf, H., Foltzer, C., Strosser, M. T., and Phillips, J. G., 1985, Endocrine responses of ducks (Anas platyrhynchos) to treadmill exercise, Gen. Comp. Endocr., 48: 415.
Hissa, R., and Palokangas, R., 1970, Thermoregulation in the titmouse (Parus major L.), Comp. Biochem. Physiol., 33: 942.
Hohtola, E., 1982, Thermal and electromyographic correlates of shivering thermogenesis in the pigeon, Comp. Biochem. Physiol., 73A: 159.
Hohtola, E., and Stevens, E. D., 1986, The relationship of muscle electrical activity, tremor and heat production to shivering thermogenesis in Japanese quail, J. Exp. Biol., 125: 119.
Irving, L., Krog, J., and Monson, M., 1955, The metabolism of some Alaskan animals in winter and summer, Physiol. Zool., 28: 173.
Johnson, S. R., and McTaggart Cowan, I., 1975, The energy cycle and thermal tolerance of the starlings (Aves, Sturnidae) in North America, Can. J. Zool., 53: 55.
Karlsson, J., Nordesjo, L.-O., and Saltin, B., 1974, Muscle glycogen utilization during exercise after physical training, Acta Physiol. Scand., 90: 210.
King, J. R., 1972, Adaptive periodic fat storage by birds, Proc. XVth Internat. Ornith. Congr., p. 201.
King, J. R., and Farner, D. S., 1961, Energy metabolism, thermoregulation and body temperature, In: “Biology and Comparative Physiology of Birds,” Vol. II, A. J. Marshall, ed., Academic Press, New York.
Kendeigh, S. C., 1944, Effect of air temperature on the rate of energy metabolism of the English sparrow, J. Exp. Zool., 96: 1.
Koteja, P, 1986, Maximum cold-induced oxygen consumption in the house sparrow Passer domesticus L., Physiol. Zool., 59: 43.
LeClerq, B., 1984, Adipose tissue metabolism and its control in birds, Poultry Sci., 63: 2044.
McCumbee, W. D., and Hazelwood, R. L., 1978, Sensitivity of chicken and rat adipocytes and hepatocytes to isologous and heterologous pancreatic hormones, Gen. Comp. Endocr., 34: 421.
Marsh, R. L., Carey, C., and Dawson, W. R., 1984, Substrate concentrations and turnover of plasma glucose during cold exposure in seasonally acclimatized house finches, Carpodacus mexicanus, J. Comp. Physiol., B154: 469.
Marsh, R. L., and Dawson, W. R., 1982, Substrate metabolism in seasonally acclimatized American goldfinches, Am. J. Physiol., 242: R563.
Marsh, R. L., and Dawson, W. R., 1988a, Avian adjustments to cold, In: “Animal Adaptation to Cold,” L. Wang, ed., Springer-Verlag, Berlin. (In press)
Marsh, R. L., Dawson, W. R., 1988b, Metabolism of energy substrates and seasonal acclimatization, this volume.
Marsh, R. L., Dawson, W. R., Camilliere, J., and Olson, J. M., 1989, Regulation of glycolysis in the pectoralis muscles of seasonally acclimatized American goldfinches exposed to cold, Am. J. Physiol., submitted.
Miller, D. S., 1939, A study of the physiology of the sparrow thyroid, J. Exp. Zool., 80: 259.
Minaire, Y., Vincent-Falquet, J.-C., Pernod, A., and Chatonnet, J., 1973, Energy supply in acute cold-exposed dogs, J. Appl. Physiol., 35: 51.
Pearce, J., 1977, Some differences between avian and mammalian biochemistry, Internat. J. Biochem., 8: 269.
Randle, P. J., Tubbs, P. K., 1979, Carbohydrate and fatty acid metabolism, In: “Handbook of Physiology, Section 2, The Cardiovascular System, Vol. 1, The Heart,” R. M. Berne, N. Sperelakis, and S. R. Geiger, eds., American Physiological Society, New York.
Rennie, M. J., Winder. W. W., and Holloszy, J. O., 1976, A sparing effect of plasma fatty acids on muscle and liver glycogen content of the exercising rat, Biochem. J., 156: 649.
Riesenfeld, G., Berman, A., and Hurwitz, S., 1979, Glucose kinetics and heat production in normotherraic, hypothermic, and hyperthermic fasted chickens, Comp. Biochem. Physiol., 67A: 199.
Rogers, C. M., Ketterson, E. D., and Nolan, Jr., V., 1988, Regulation of winter fattening in dark-eyed juncos Junco hyemalis hyemalis: a geographical perspective, unpublished ms.
Rosenmann, M., and Morrison, P., 1974, Maximum oxygen consumption and heat loss facilitation in small homeotherms by He-O2, Am. J. Physio1., 226: 490.
Saarela, S., 1988, Thermogenic capacity of greenfinches and siskins in winter and summer, this volume.
Scholander, P. F., Hock, R., Walters, V., Johnson, F., and Irving, L., 1950, Heat regulation in some arctic and tropical mammals and birds, Biol. Bull., 99: 237.
Steube, M. M., and Ketterson, E. D., 1982, A study of fasting in tree sparrows (Spizella arborea) and dark-eyed juncos (Junco hyemalis): ecological implications, Auk, 99: 299.
Thomas, V. G., and George, J. C., 1975, Changes in plasma, liver, and muscle metabolite levels in Japanese quail exposed to cold, J. Comp. Physiol., 100: 297.
Wallgren, H., 1954, Energy metabolism of two species of the genus Emberiza as correlated with distribution and migration, Acta Zool. Fennica, 84: 1.
West, G. C., 1965, Shivering and heat production in wild birds, Physiol. Zool., 38: 111.
Withers, P. C., 1977, Respiration, metabolism, and heat exchange of euthermic and torpid poorwills and hummingbirds, Physiol. Zool., 50: 43.
Yacoe, M. E., and Dawson, W. R., 1983, Seasonal acclimatization in American goldfinches: the role of the pectoralis muscle, Am. J. Physiol., 242: R265.
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Dawson, W.R., Marsh, R.L. (1989). Metabolic Acclimatization to Cold and Season in Birds. In: Bech, C., Reinertsen, R.E. (eds) Physiology of Cold Adaptation in Birds. NATO ASI Series, vol 173. Springer, Boston, MA. https://doi.org/10.1007/978-1-4757-0031-2_9
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