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The effect of environmental temperature during pregnancy on thermoregulation in the newborn lamb

Published online by Cambridge University Press:  02 September 2010

A. W. Stott  and
J. Slee
A. W. Stott
Affiliation:
AFRC Animal Breeding Research Organisation, West Mains Road, Edinburgh EH9 3JQ
J. Slee
Affiliation:
AFRC Animal Breeding Research Organisation, West Mains Road, Edinburgh EH9 3JQ
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Abstract

Twenty-four pregnant Scottish Blackface ewes were divided into three temperature-treatment groups 14 days before expected lambing: closely shorn and kept at 6°C (cold treatment, CD); in full fleece at 26°C (warm treatment, WM); and in full fleece at 6°C (controls, CL). Food allocation and intakes were similar for each group. Their lambs were tested for cold-induced summit metabolic rate capability (SMR) on the day of birth at a mean age of 12 h using water immersion to provide cooling. On the following day, the calorigenic response to subcutaneous injections of noradrenaline (NA) was measured to assess non-shivering thermogenesis capability. The ewes were blood-sampled during pregnancy and the lambs before and after the SMR test.

In the ewes, blood glucose and free fatty acid levels were higher during cold treatment, but not significantly so. Blood glucose was lower in lambs from CD ewes (CD lambs) before SMR tests; other differences were not significant.

During the cold test, SMR was highest in CD lambs, but not significantly so. Rectal temperature declined least during test in the CD lambs (P < 0·05).

The peak metabolic response (PMR) following NA injection was about 1·5 times greater in CD lambs than in the CL and WM lambs (P < 0·05). The mean elevation of PMR over thermoneutral metabolic rate was respectively: 2·8, 1·8 and 1·7 times in the CD, CL and WM lambs (P < 0·05), and this elevation was sustained for longer in the CD lambs (P < 0·01). Thus, the total metabolic response to NA was markedly greater in CD lambs.

It was concluded that cold exposure during late pregnancy favoured the deposition of (or checked the normal decline in) foetal brown adipose tissue, so raising the neonatal capacity for non-shivering thermogenesis.

Type
Research Article
Information
Animal Production , Volume 41 , Issue 3 , December 1985 , pp. 341 - 347
Copyright
Copyright © British Society of Animal Science 1985

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References

Alexander, G. 1962. Temperature regulation in the new-born lamb. V. Summit metabolism. Aust. J. agric. Res. 13: 100121.Google Scholar
Alexander, G. 1978. Quantitative development of adipose tissue in foetal sheep. Aust. J. biol. Sci. 31: 489503.CrossRefGoogle ScholarPubMed
Alexander, G. 1979. Cold thermogenesis. In Environmental Physiology III Vol. 20 (ed. Robertshaw, D.), pp. 43155. Univ. Park Press, Baltimore.Google Scholar
Alexander, G. and Bell, A. W. 1975. Quantity and calculated oxygen consumption during summit metabolism of brown adipose tissue in newborn lambs. Biol. Neonate 26: 214220.CrossRefGoogle Scholar
Alexander, G. and Williams, D. 1968. Shivering and non-shivering thermogenesis during summit metabolism in young lambs. J. Physiol., Lond. 198: 251276.CrossRefGoogle ScholarPubMed
Alexander, G. and Williams, D. 1971. Heat stress and development of the conceptus in domestic sheep. J. agric. Sci., Camb. 76: 5372.Google Scholar
Austin, A. R. and Young, N. E. 1977. The effect of shearing pregnant ewes on lamb birth weights. Vet. Rec. 100: 527529.Google Scholar
Bruck, K. 1970. Non-shivering thermogenesis and brown adipose tissue in relation to age and their integration in the thermoregulatory system. In Brown Fat (ed. Lindberg, O.), pp. 117154. Elsevier, New York.Google Scholar
Davey, A. W. F. and Holmes, C. W. 1977. The effects of shearing on the heat production and activity of sheep receiving dried grass or ground hay. Anim. Prod. 24: 355361.Google Scholar
Eales, F. A., Gilmour, J. S., Barlow, R. M., and Small, J. 1982. Causes of hypothermia in 89 lambs. Vet. Rec. 110: 118120.Google Scholar
Eales, F. A. and Small, J. 1980. Summit metabolism in newborn lambs. Res. vet. Sci. 29: 211218.CrossRefGoogle ScholarPubMed
Foster, D. O. and Frydman, M. L. 1978. Non-shivering thermogenesis in the rat. II. Measurements of blood flow with microspheres point to brown adipose tissue as the dominant site of the calorigenesis induced by noradrenaline. Can. J. Physiol. Pharmac. 56: 110122.Google Scholar
Graham, N. McC. 1964. Influence of ambient temperature on the heat production of pregnant ewes. Aust. J. agric. Res. 15: 982988.Google Scholar
Gutteridge, J. M. C. and Wright, E. B. 1968. A simple automated guaconium glucose-oxidase method. J. med. Lab. Technol. 25: 385386.Google Scholar
Harvey, W. R. 1972. Least squares and maximum likelihood general purpose program. Ohio State University. (Mimeograph).Google Scholar
Himms-Hagen, J. 1969. The role of brown adipose tissue in the calorigenic effect of adrenaline and noradrenaline in cold-acclimated rats. J. Physiol., Lond. 205: 393403.CrossRefGoogle ScholarPubMed
Jansky, L. 1973. Non-shivering thermogenesis and its thermoregulatory significance. Biol. Rev. 48: 85132.CrossRefGoogle ScholarPubMed
Patterson, D. S. P. 1963. Some observations on the estimation of non-esterified fatty acid concentrations in cow and sheep plasma. Res. vet. Sci. 4: 230237.CrossRefGoogle Scholar
Rutter, W., Laird, T. R. and Broadbent, P. J. 1971. The effects of clipping pregnant ewes at housing and of feeding different basal roughages. Anim. Prod. 13: 329336.Google Scholar
Rutter, W., Laird, T. R. and Broadbent, P. J. 1972. A note on the effects of clipping pregnant ewes at housing. Anim. Prod. 14: 127130.Google Scholar
Samson, D. E. 1982. Genetic aspects of resistance to hypothermia in relation to neonatal lamb survival. PhD Thesis, Univ. Edinburgh.Google Scholar
Samson, Deborah E. and Slee, J. 1981. Factors affecting resistance to induced body cooling in newborn lambs of 10 breeds. Anim. Prod. 33: 5965.Google Scholar
Shelton, M. 1964. Relation of environmental temperature during gestation to birth weight and mortality of lambs. J. Anim. Sci. 23: 360364.Google Scholar
Slee, J. 1977. Cold stress and lamb mortality. Proc. Symp. Perinatal Losses in Lambs, Stirling, 1975, pp. 3034. East of Scotland College of Agriculture, Edinburgh.Google Scholar
Slee, J. 1979. Mortality and resistance to hypothermia in young lambs. In Biometeorology Survey (ed. Tromp, S. W. and Bouma, J. J.) pp. 6065. Heyden, London.Google Scholar
Slee, J. 1981. A review of genetic aspects of survival and resistance to cold in newborn lambs. Livest. Prod. Sci. 8: 419429.CrossRefGoogle Scholar
Slee, J., Griffiths, R. G. and Samson, D. E. 1980. Hypothermia in newborn lambs induced by experimental immersion in a water bath and by natural exposure outdoors. Res. vet. Sci. 28: 275280.Google Scholar
Slee, J. and Halliday, R. 1968. Some effects of cold exposure, nutrition and experimental handling on serum free fatty-acid levels in sheep. Anim. Prod. 10: 6776.Google Scholar
Slee, J. and Sykes, A. R. 1967. Acclimatisation of Scottish Blackface sheep to cold. 1. Rectal temperature responses. Anim. Prod. 9: 333347.Google Scholar
Stott, A. W. 1983. Genetic and physiological factors affecting thermoregulation and resistance to body cooling in newborn lambs. Ph.D Thesis, Univ. Edinburgh.Google Scholar
Thompson, G. E., Bassett, J. M., Samson, Debbie E. and Slee, J. 1982. The effects of cold exposure of pregnant sheep on foetal plasma nutrients, hormones and birth weight. Br. J. Nutr. 48: 5964.Google Scholar
Thompson, G. E. and Jenkinson, D. M. 1969. Non-shivering thermogenesis in the newborn lamb. Can. J. Physiol. Pharmac. 47: 249253.Google Scholar
Wiener, G., Deeble, F. K., Broadbent, J. S. and Talbot, M. 1973. Breed variation in lambing performance and lamb mortality in commercial sheep flocks. Anim. Prod. 17: 229243.Google Scholar
Young, B. A. and Degen, A. A. 1981. Thermal influences on ruminants. In Environmental Aspects of Housing for Animal Production (ed. Clark, J. A.), pp. 167180. Butterworth, London.Google Scholar