Hostname: page-component-848d4c4894-sjtt6 Total loading time: 0 Render date: 2024-06-24T01:45:54.508Z Has data issue: false hasContentIssue false
  • English
  • Français

2.2 Genetic Variation in Trace Element Metabolism

Published online by Cambridge University Press:  27 February 2018

G. Wiener  and
J. A. Woolliams
G. Wiener
Affiliation:
Animal Breeding Research Organization, West Mains Road, Edinburgh, EH9 3JQ
J. A. Woolliams
Affiliation:
Animal Breeding Research Organization, West Mains Road, Edinburgh, EH9 3JQ
Get access

Extract

This paper reviews evidence showing that heredity is involved in the utilization of trace elements by animals. Underwood (1981) has stressed the importance of achieving dietary balance in the provision of minerals in animal nutrition and Howell (1983) has emphasized that although a small amount of a trace element may be essential for health a larger amount could be injurious. In these circumstances, information which can be used to meet the essential requirements for trace elements more precisely is likely to help in optimizing animal performance and avoiding risks to health and life. An understanding of the role of heredity in influencing trace element requirements is important in this context. Genetic variation in requirements also suggests the possibility that genetic solutions to trace element deficiency or toxicity problems may provide an alternative strategy to prophylaxis and other nutritional and management aids.

Type
2. Factors Influencing Requirements
Information
BSAP Occasional Publication , Volume 7: Trace Elements in Animal Production and Veterinary Practice , 1983 , pp. 27 - 35
Copyright
Copyright © British Society of Animal Production 1983

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Allcroft, R., Clegg, F. G. and Uvarov, O. 1959. Prevention of swayback in lambs. Vet. Rec. 17: 884889.Google Scholar
Anderson, P. H., Berrett, S. and Patterson, D. S. P. 1979. The biological selenium status of livestock in Britain as indicated by sheep erythrocyte glutathione peroxidase activity. Vet. Rec. 104: 235238.CrossRefGoogle ScholarPubMed
Atroshi, F., Sankari, S., Österberg, S. and Sandholm, M. 1981. Variation of erythrocyte glutathione peroxidase activity in Finn sheep. Res. vet. Sci. 31: 267271.Google Scholar
Bannerman, R. M. 1976. Genetic defects of iron transport. Fed. Prod., Fed. Am. Soc. Exp. Biol. 35: 22812285.Google ScholarPubMed
Butler, E. J. and Barlow, R. M. 1963. Factors influencing the blood and plasma copper levels of sheep in swayback flocks. J. comp. Path. 73: 107118.Google Scholar
Danks, D. M. 1981. Trace elements in human disease, with particular reference to copper and zinc. Proc. 4th Int. Symp. Trace Element Metabolism in Man and Animals, pp. 479486. Australian Academy of Science, Canberra.Google Scholar
Hayter, S., Wiener, G. and Field, A. C. 1973. Variation in the concentration of copper in the blood plasma of Finnish Landrace and Merino sheep and their crosses with reference to reproductive performance and age. Anim. Prod. 16: 261269.Google Scholar
Herbert, J. G., Wiener, G. and Field, A. C. 1978. The effect of breed and of dried seaweed meal in the diet on the levels of copper in liver, kidney and plasma of sheep fed on a high-copper diet. Anim. Prod. 26: 193201.Google Scholar
Howell, J. McC. 1968. The effect of experimental copper deficiency on growth, reproduction and haemopoiesis in the sheep. Vet. Rec. 83: 226227.Google Scholar
Howell, J. McC. 1983. Toxicity problems associated with trace elements in domestic animals. In Trace Elements in Animal Production and Veterinary Practice (ed. Suttle, N. F., Gunn, R. G., Allen, W. M., Linklater, K. A. and Wiener, G.), Occ. Pub. Br. Soc. Anim. Prod. No. 7.Google Scholar
Hunt, D. M. 1974. Primary defect in copper transport underlies mottled mutants in the mouse. Nature (London) 294: 852854.CrossRefGoogle Scholar
Hurley, L. S. 1976. Interactions of genes and metals in development. Fed. Proc., Fed. Am. Soc. Exp. Biol. 35: 22712275.Google Scholar
Hurley, L. S., Keen, C. L. and Lönnerdal, B. 1980. Copper in fetal and neonatal development. CIBA Foundation Symposium, No. 79, pp. 227245.Google Scholar
Jones, D. G. and Suttle, N. F. 1981. Some effects of copper deficiency on leucocyte function in sheep and cattle. Res. vet. Sci. 31: 151156.Google Scholar
Kroneman, J., Van der Mey, G.J.W, and Helder, A. 1975. Hereditary zinc deficiency in Dutch Friesian cattle. Zentralbl, Veterinaermed. Reihe, A. 22: 201208.Google Scholar
Langlands, J. P., Bowles, J. E., Donald, G. E., Ch'ano, T. S., Evans, R., Hearnshaw, H. and Post, T. B. 1980. Genotype as a source of variation in selenium concentration and glutathione peroxidase activity of whole blood from grazing sheep and cattle. Aust. J. agric. Res. 31: 839848.Google Scholar
Lüke, F. and Wiemann, H. 1970. Chronic copper poisoning and copper retention in the liver of sheep of different types. Berl. Münch. Teirärztl. Wochenschr. 83: 253255.Google Scholar
Mann, J. R., Camakaris, J., Gillespie, J., Koellreuter, B., Matthieu, J.-M., Royce, P. M. and Danks, D. M. 1981. Failure to confirm abnormal copper utilization in crinkled (cr) mice. Biol. Trace Element Res. 3: 117131.Google Scholar
Mayo, G. M. E. and Mulhearn, C. J. 1969. Inheritance of congenital goitre due to a thyroid defect in Merino sheep. Aust. J. agric. Res. 20: 533547.Google Scholar
O'Kelly, J. C. 1977. Plasma protein-bound iodine and lipids in genetically different types of cattle grazing in a tropical environment. Br. vet. J. 133:579584.Google Scholar
Poole, D. B. R. 1970. An outbreak of swayback in lambs with particular reference to breed susceptibility. Irish vet. J. 24: 189192.Google Scholar
Rac, R., Hill, G. N., Pain, R. W. and Mulhearn, C. J. 1968. Congenital goitre in Merino sheep due to an inherited defect in the biosynthesis of thyroid hormone. Res. vet. Sci. 9: 209223.Google Scholar
Reetz, I. and Feder, H. 1974. Ceruloplasmin, copper and iron content in the blood plasma of pigs and their correlations with performance traits. Proc. 1st World Congr. Genetics applied to Livestock Production, Madrid, Vol. 3: 11591164.Google Scholar
Reetz, I., Wegner, W. and Feder, H. 1975. Statistics, heritability and correlations between several characters of the circulatory system in female German Landrace fatteners. II. Degree of heritability and gene frequencies. Zentralbl. Veterinaermed., Reihe, A. 22: 741755.Google Scholar
Reis, B. L. and Evans, G. W. 1977. Genetic influence on zinc metabolism in mice. J. Nutr. 107: 16831686.Google Scholar
Rowlands, G. J., Payne, J. M., Dew, S. M. and Mansion, R. 1974. Individuality and heritability of the blood composition of calves with particular reference to the selection of stock with improved growth potential. J agric. Sci., Camb. 82:474481.CrossRefGoogle Scholar
Suttle, N. F. 1974. A technique for measuring the biological availability of copper to sheep using hypocupraemic ewes. Br. J. Nutr. 32: 395405.Google Scholar
Suttle, N. F. 1977. Reducing the potential copper toxicity of concentrates to sheep by the use of molybdenum and sulphur supplements. Anim. Feed. Sci. Technol. 2: 235246.Google Scholar
Underwood, E. J. 1977. Trace Elements in Human and Animal Nutrition, 4th ed. 545 pp. Academic Press, New York.Google Scholar
Underwood, E. J. 1981. The Mineral Nutrition of Livestock, 2nd ed. Commonwealth Agricultural Bureaux, Farnham Royal.Google Scholar
Visscher, A. H., Garssen, G. J. and Zaalmink, W. 1980. Relationship between concentrates fed and the copper concentration in liver dry matter in five sheep genotypes. Proc. Conf. Eur. Ass. Anim. Prod., Munich, West Germany.Google Scholar
Whitelaw, A., Armstrong, R. H., Evans, C. C. and Fawcett, A. R. 1979. A study of the effects of copper deficiency in Scottish Blackface lambs on improved hill pasture. Vet. Rec. 104: 455460.CrossRefGoogle ScholarPubMed
Wiener, G. 1966. Genetic and other factors in the occurrence of swayback in sheep. J. comp. Path. 76: 435447.Google Scholar
Wiener, G. and Field, A. C. 1969. Copper concentrations in the liver and blood of sheep of different breeds in relation to swayback history. J. comp. Path. 79: 714.Google Scholar
Wiener, G. and Field, A. C. 1971. The concentration of minerals in the blood of genetically diverse groups of sheep. V. Concentrations of copper, calcium, phosphorus, magnesium, potassium and sodium in the blood of lambs and ewes. J. agric. Sci., Camb. 76: 513520.Google Scholar
Wiener, G., Field, A. C. and Jolly, G. M. 1970. The concentration of minerals in the blood of genetically diverse groups of sheep. IV. Factors influencing seasonal changes in copper concentration. J. agric. Sci., Camb. 75: 489495.Google Scholar
Wiener, G., Field, A. C. and Smith, C. 1977. Deaths from copper toxicity of sheep at pasture and the use of fresh seaweed. Vet. Rec. 101: 424425.Google Scholar
Wiener, G., Field, A. C. and Wood, J. 1969. The concentration of minerals in the blood of genetically diverse groups of sheep. I. Copper concentration at different seasons in Blackface, Cheviot, Welsh Mountain and crossbred sheep at pasture. J. agric. Sci., Camb. 72: 93101.CrossRefGoogle Scholar
Wiener, G., Hall, J. G. and Hayter, S. 1973. An association between the concentration of copper in whole blood and haemoglobin type in sheep. Anim. Prod. 17: 17.Google Scholar
Wiener, G., Hall, J. G., Hayter, S., Field, A. C. and Suttle, N. F. 1974. Relationships between haemoglobin type and copper concentrations in whole blood and in components in sheep of different breeds. Anim. Prod. 19: 291299.Google Scholar
Wiener, G., Hayter, S. and Field, A. C. 1976. Selection for plasma copper concentrations within haemoglobin type in sheep. Anim. Prod. 22: 385393.Google Scholar
Wiener, G., Hayter, S., Field, A. C. and MacLeod, N. S. M. 1974. Copper levels in liver and brain of dead lambs in relation to breed, age at death and cause of death. J. comp. Path. 84: 2738.CrossRefGoogle ScholarPubMed
Wiener, G., Russell, W. and Field, A. C. 1980. Factors influencing the concentration of minerals and metabolites in the plasma of cattle. J. agric. Sci., Camb. 94: 369376.Google Scholar
Wiener, G., Sales, D. I. and Field, A. C. 1976. Libido and fertility in rams in relation to plasma copper levels. Vet. Rec. 98: 115116.Google Scholar
Wiener, G., Suttle, N. F., Field, A. C., Herbert, J. G. and Woolliams, J. A. 1978. Breed differences in copper metabolism in sheep. J. agric. Sci., Camb. 91: 433441.CrossRefGoogle Scholar
Wiener, G., Woolliams, J. A. and Vagg, M. J. 1983. Selenium concentration in the blood and wool and glutathione peroxidase activity in the blood of three breeds of sheep. Res. vet. Sci. (In press).Google Scholar
Woolliams, J. A., Suttle, N. F., Wiener, G., Field, A. C. and Woolliams, C. 1982. The effect of breed of sire on the accumulation of copper in lambs, with particular reference to copper toxicity. Anim. Prod. 35: 299307.Google Scholar
Woolliams, J. A., Suttle, N. F., Wiener, G., Field, A. C. and Woolliams, C. 1983a. Long-term accumulation and depletion of copper in the liver of different breeds of sheep fed diets of different copper content. J. agric. Sci., Camb. 100:441449.CrossRefGoogle Scholar
Woolliams, J. A., Wiener, G., Anderson, P. H. and McMurray, C. H. 1983b. Variation in the activities of glutathione peroxidase and superoxide dismutase and in the concentration of copper in the blood of various breed crosses of sheep. Res. vet. Sci. (In press).Google Scholar