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Hepatic xanthine dehydrogenase and plasma uric acid in broiler chickens fed various amounts of dietary methionine, protein and energy

Published online by Cambridge University Press:  27 March 2009

F. O. Amubode
Affiliation:
Department of Animal Science, University of Ibadan, Nigeria
B. L. Fetuga
Affiliation:
Department of Animal Science, University of Ibadan, Nigeria

Summary

In four consecutive experiments, plasma uric acid (PUA), hepatic xanthine dehydrogenase (XDH) and body-weight gains (WG) of broiler chickens were measured under varying dietary methionine, protein and energy. In Expt 1, increases in WG with increasing dietary methionine peaked at 0·60%, a level where the initial decreases in either PUA or XDH reached a minimum. PUA and XDH in broiler finishers (Expt 2) decreased between 0·26 and 0·50% dietary methionine while WG improved between 0·26 and 0·50% methionine. XDH in the 18% protein and 0·68% methionine + cystine (MC) diet combination for Expt 3 was 66·4 μtmol/10 min/total liver weight, a value higher than either the 43·5 or 46·5 μtmol/10 min/total liver weight, respectively obtained in the 21% protein + 0·68% MC and 24% protein + 0·68% MC diet combinations. Both PUA and XDH, however, increased with increasing dietary protein when MC was either 0·76 or 0·84% diet. XDH in Expt 4 decreased between 11·7 and 13·4 MJ ME/kg diet that contained either 0·76 or 0·84% MC, tending not to vary between 13·4 and 15·1 MJ ME/kg diet. This enzyme activity remained essentially similar between 11·7 and 15·1 MJ ME/kg diet that contained 0·68% MC.

Type
Research Article
Copyright
Copyright © Cambridge University Press 1984

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References

Allen, R. D. (1973). Feedstuff analysis table. Feedstuffs Year Book p. 24.Google Scholar
Babatunde, G. M. & Fetuga, B. L. (1976). Determination of the minimum crude protein requirements of broiler starters and finishers in the tropics. Nigerian Journal of Animal Production 3, 126138.CrossRefGoogle Scholar
Babatunde, G. M., Fetuga, B. L. & Kassim, E. (1976). Methionine supplementation of low protein diets for broiler chicks in the tropics. British Poultry Science 17, 461463.CrossRefGoogle ScholarPubMed
Bittner, D. L., Hall, S. G. & McCleary, M. L. (1963). A method for the determination of uric acid using cuprihen-anthroline indicator system. American Journal of Clinical Pathology 401, 423424.Google Scholar
Harper, A. E. (1965). Effect of variations in protein intake on enzymes of amino acid metabolism. Canadian Journal of Biochemistry 43, 15891992.Google Scholar
Milne, W. E. (1949). Numerical Calculus. Princeton: Princeton University Press.Google Scholar
National Research Council (1977). Nutrient Requirements of Domestic Animals. No. 1, Nutrient requirements of poultry. Washington, D.C.Google Scholar
Scholz, A. W. & Featherston, W. R. (1968). Effect of alteration in protein intake on liver xanthine dehydrogenase in the chick. Journal of Nutrition 95, 271277.Google Scholar
Schwartz, H. G. & Litwack, G. (1957). A photometric method for avian liver xanthine dehydrogenase. Nature 180, 761762.Google Scholar
Sheid, B. & Hirschberg, E. (1967). Protein metabolism. In Physiology and Biochemistry of the Domestic Fowl (ed. Freeman, B. W. and Bell, D.), p. 14. London: Academic Press.Google Scholar
Snedecor, G. R. & Cochran, W. L. (1967). Statistical Methods. The Iowa State University Press.Google Scholar
Stripe, F. & Corte, E. D. (1965). Regulation of xanthine dehydrogenase in chick liver. Effect of starvation and the administration of purine and purine nucleotides. Biochemical Journal 94, 309310.CrossRefGoogle Scholar