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Comparative aspects of copper metabolism in silage-fed sheep and deer (Cervus elaphus)

Published online by Cambridge University Press:  27 March 2009

D. O. Freudenberger ,
A. S. Familton  and
A. R. Sykes
D. O. Freudenberger
Affiliation:
Animal Sciences Group, Lincoln College, University of Canterbury, New Zealand
A. S. Familton
Affiliation:
Animal Sciences Group, Lincoln College, University of Canterbury, New Zealand
A. R. Sykes
Affiliation:
Animal Sciences Group, Lincoln College, University of Canterbury, New Zealand
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Summary

Ten yearling red deer stags (Cervus elaphus) and ten yearling Coopworth wether sheep were housed in individual pens and offered ryegrass-white clover silage, containing 9–10 mg Cu, 1·4–1·7 mg Mo and 2·4 g S/kg D.M., in amounts close to maintenance energy requirement. For six animals of each species the diet was enhanced with 4·8 mg Mo and 3 g S/kg D.M. Liver biopsy samples were obtained during weeks 1, 6 and 12. The animals were then re-randomized and five of each species offered the basal diet and the remainder the basal diet supplemented with 4 mg Cu/kg D.M. Liver biopsy samples were obtained after a further 4½ weeks. Plasma samples for estimation of total and trichloroacetic acid-soluble Cu were taken weekly.

The mean liver Cu concentration in sheep was 11-fold greater than in deer. Both diets induced liver Cu depletion, though there was a trend for a greater rate of depletion on the Mo- and S-enhanced silage. The rate of depletion (mg Cu/kg liver D.M./day) was 7-fold greater in sheep than in deer, although it was not possible to determine whether this reflected a species-, as opposed to a Cu status-induced effect. In both species highly significant linear relationships were observed between initial liver Cu concentration and rate of liver Cu depletion. This was interpreted to indicate that endogenous loss was directly proportional to liver Cu content in both species. Individual estimates for the minimum rate of endogenous loss of Cu (μg/kg W/day) ranged from 0·2 to 2·71, mean 1·43, and from 2·83 to 14·75, mean 8·35 in deer and sheep, respectively.

During repletion the rate of increase of liver Cu in supplemented groups tended to be greater in sheep than in deer and calculated minimum values for availability of Cu were 0·061 and 0·037, respectively.

Liver Cu concentrations of less than 20 mg/kg D.M. were maintained in deer for several weeks without apparent symptoms of deficiency.

Type
Research Article
Information
The Journal of Agricultural Science , Volume 108 , Issue 1 , February 1987 , pp. 1 - 7
Copyright
Copyright © Cambridge University Press 1987

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References

Agricultural Research Council (1980). The Nutrient Requirements of Ruminant Livestock. London: Commonwealth Agricultural Bureaux.Google Scholar
Familton, A. S. (1985). A liver biopsy technique for use in red deer. Proceedings, Deer Course for Veterinarians No. 2. New Zealand Veterinary Association. Ashburton.Google Scholar
Grace, N. D. (1983). Copper. In The Mineral Requirements of Grazing Ruminants (ed. Grace, N. D.), pp. 5666. Wellington: New Zealand Society of Animal Production.Google Scholar
Kellaway, R. C., Sitorus, P. & Leibholz, J. M. L. (1978). The use of copper levels in hair to diagnose hypocuprosis. Research in Veterinary Science 24, 352357.Google Scholar
Lee, J. (1983). Multi-element analysis of animal tissue by inductively-coupled plasma emission spectrometry. I.C.P. Information Newsletter 8, 19.Google Scholar
Long, C. (1961). Biochemists Handbook, pp. 677679. London: E. F. N. Spoon.Google Scholar
Mason, J., Williams, S., Harrington, R. & Sheahan, B. (1984). Some preliminary studies on the metabolism of 99Mo-labelled compounds in deer. Irish Veterinary Journal 38, 171175.Google Scholar
Rowell, J. G. & Walters, D. E. (1976). Analysing data with repeated observations on each experimental unit. Journal of Agricultural Science, Cambridge 87, 423432.Google Scholar
Simpson, A., Mills, C. F., & McDonald, I. (1982). Tissue copper retention or loss in young growing cattle. Proceedings of Fourth International Symposium on Trace Element Metabolism in Man and Animals, Perth W. A. (ed. Gawthorne, J. C.), pp. 133135. Canberra: Australian Academy of Science.Google Scholar
Smith, B. S. W. & Wright, H. (1975). Copper: molybdenum interaction. Effect of dietary molybdenum on the binding of copper to plasma proteins in sheep. Journal of Comparative Pathology 85, 299305.CrossRefGoogle ScholarPubMed
Sinclair, A. G. (1973). An auto-analysis method for determination of extractable sulphate in soil. New Zealand Journal of Agricultural Research 16, 287292.Google Scholar
Suttle, N. F. (1974). A technique for measuring the biological availability of copper to sheep, using hypocupraemic ewes. British Journal of Nutrition 32, 395405.Google Scholar
Suttle, N. F. (1978). Determining the copper requirements of cattle by means of an intravenous repletion technique. In Proceedings of the Third International Symposium on Trace Element Metabolism in Man and Animals, pp. 473480. Freising-Weihanstephan: Technische Universitat Munchen.Google Scholar
Suttle, N. F. (1983 a). Effects of molybdenum concentration in fresh herbage, hay and semi-purified diets on the copper metabolism of sheep. Journal of Agricultural Science, Cambridge 100, 651656.CrossRefGoogle Scholar
Suttle, N. F. (1983 b). Feed information and animal production. In Proceedings of the 2nd International Network of Feed Information Centres (ed. Robards, G. E. and Packham, R. G.), pp. 211237Slough: Commonwealth Agricultural Bureaux.Google Scholar
Suttle, N. F. & Field, A. C. (1983). Effects of dietary supplements of thiomolybdates on copper and molybdenum metabolism in sheep. Journal of Comparative Pathology 93, 379384.CrossRefGoogle ScholarPubMed
Suttle, N. F. & McLaughlin, M. (1976). Predicting the effects of dietary molybdenum and sulphur on the availability of Cu to ruminants. Proceedings of the Nutrition Society 35, 22A.Google Scholar
Sykes, A. R., Coop, R. L. & Rushton, B. (1980). Chronic subclinical fascioliasis in sheep: effects on food intake, food utilization and blood constituents. Research in Veterinary Science 28, 6370.CrossRefGoogle ScholarPubMed
Woolliams, J. A., Suttle, N. F., Wiener, G., Field, A. C. & Woolliams, C. (1983). The long-term accumulation and depletion of copper in the liver of different breeds of sheep fed diets of differing copper content. Journal of Agricultural Science, Cambridge 100, 441449.Google Scholar