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Effects of oral administration of brassica secondary metabolites, allyl cyanide, allyl isothiocyanate and dimethyl disulphide, on the voluntary food intake and metabolism of sheep

Published online by Cambridge University Press:  09 March 2007

Alan J. Duncan  and
John A. Milne
Alan J. Duncan
Affiliation:
Macaulay Land Use Research Institute, Craigiebuckler, Aberdeen AB9 2QJ
John A. Milne
Affiliation:
Macaulay Land Use Research Institute, Craigiebuckler, Aberdeen AB9 2QJ
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Abstract

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Glucosinolates, such as sinigrin, and S-methyl cysteine sulphoxide (SMCO), which are found in forage brassica species have been implicated in the low intakes observed among lambs consuming such diets. To test both the individual and interactive effects of these compounds in sheep, all combinations of the sinigrin breakdown products, allyl cyanide (ACN) and allyl isothiocyanate (AITC; 10 mmol/d), and the SMCO metabolite dimethyl disulphide (DMDS; 25 mmol/d) were orally administered twice daily for 5 weeks to forty sheep offered dried grass pellets ad lib. As well as measuring voluntary food intake (VFI), a number of haematological and clinical function tests were conducted to assess the physiological effects of the compounds. VFI was significantly depressed by both ACN and AITC but not by DMDS. DMDS significantly ameliorated the effects of ACN on VFI (P < 0.001). Concentrations of reduced glutathione in the blood were depressed by ACN and AITC and elevated by DMDS but no significant interactions were evident. Elevated plasma γ-glutamyl transpeptidase (EC 2.3.2.1) activity on ACN and AITC treatments indicated possible liver damage. DMDS elicited a rise in Heinz bodies to 11 % by week 2 but this was not reflected in packed cell volume and blood haemoglobin levels which were unaffected by treatment. The increased Heinz body count caused by DMDS was not further influenced by ACN or AITC. In conclusion, the depressive effects of sinigrin breakdown products on VFI were not compounded by the additional presence of DMDS which, on the contrary, lessened the depression of VFI caused by ACN.

Keywords

Glucosinolate breakdown productsVoluntary food intakeBrassica speciesLambs
Type
Effects of Non-Nutrient Constituents of Plants on the Nutrition of Sheep
Information
British Journal of Nutrition , Volume 70 , Issue 2 , September 1993 , pp. 631 - 645
Copyright
Copyright © The Nutrition Society 1993

References

REFERENCES

Ahmed, P. & Farooqui, M. Y. H. (1982). Comparative toxicities of aliphatic nitriles. Toxicology Letters 12, 157163.Google Scholar
Barry, T. N., Manley, T. R. & Millar, K. R. (1982). Nutritional evaluation of kale diets. 4. Responses to supplementation with synthetic S-methyl cysteine sulphoxide (SMCO). Journal of Agricultural Science, Cambridge 99, 112.Google Scholar
Beutler, E., Duran, O. & Kelly, B. M. (1963). Improved method for the determination of blood glutathione. Journal of Laboratory and Clinical Medicine 61, 882888.Google Scholar
Bjorkman, R. (1973). Interaction between proteins and glucosinolate isothiocyanate and oxazolidinethiones from B. napus seed. Phytochemistry 12, 15851590.Google Scholar
Bowler, R. G. (1944). The determination of thiocyanate in blood serum. Biochemical Journal 38, 385388.CrossRefGoogle ScholarPubMed
Bradshaw, J. E., Heaney, R. K., Macfarlane Smith, W. H., Gowers, S., Gemmel, D. J. & Fenwick, G. R. (1984). The glucosinolate content of some fodder brassicas. Journal of the Science of Food and Agriculture 35, 977981.Google Scholar
Butler, A. R. (1975). The Jaffe reaction. Identification of the coloured species. Clinica Chimica Acta 59, 227232.CrossRefGoogle ScholarPubMed
Campbell, L. D. (1987). Intact glucosinolates and glucosinolate hydrolysis products as causative agents in liver hemorrhage in laying hens. Nutrition Reports ~nternational 36, 491496.Google Scholar
Cooperstein, S. J. & Lazarow, A. (1951). A microspectrophotometric method for the determination of cytochrome oxidase. Journal of Biological Chemistry 189, 665670.Google Scholar
Drobnica, L. (1967). Wirkungsmechanismus einiger lsothiocyanate auf Hefen und Bakterien. [Mechanical effects of some isothiocyanates with yeasts and bacteria]. In Mechanisms of Action of Fungicides and Antibiotics, pp. 131139 [Girbardt, M., editor]. Berlin: Akademie-Verlag.Google Scholar
Duncan, A. J. & Milne, J. A. (1992). Effect of long-term intra-ruminal infusion of the glucosinolate metabolite allyl cyanide on the voluntary food intake and metabolism of lambs. Journal of the Science of Food and Agriculture 58, 914.CrossRefGoogle Scholar
Fenwick, G. R. & Heaney, R. K. (1983). Glucosinolates and their breakdown products in cruciferous crops, foods and feeding stuffs. Food Chemistry 11, 249271.Google Scholar
Fuke, H., Yagi, H., Takegoshi, C. & Kondo, T. (1976). A sensitive automated colorimetric method for the determination of serum gamma-glutamyl transpeptidase. Clinica Chimica Acta 69, 4351.Google Scholar
Gordon-Smith, E. C. & White, J. M. (1974). Oxidative haemolysis and Heinz body anaemia. British Journal of Haemutology 26, 513517.Google Scholar
Could, D. H., Fettman, M. J., Daxenbichler, M. E. & Bartuska, B. M. (1985). Functional and structural alterations of the rat kidney induced by the naturally occurring organonitrile, 2s-I-cyano-2-hydroxy-3, 4-epithiobutane. Toxicology and Applied Pharmacology 78, 190201.Google Scholar
Greenhalgh, J. F. D., Sharman, G. A. M. & Aitken, J. N. (1970). Kale anaemia. II. Further factors concerned in the occurrence of the disease under experimental conditions. Research in Veterinary Science 11, 232238.Google Scholar
Hartley, R. D. & Akin, D. E. (1989). Effect of forage cell wall phenolic acids and derivatives on rumen microflora. Journal of the Science of Food and Agriculture 49, 405411.Google Scholar
Johnston, T. D. & Jones, D. I. H. (1966). Variation in the thiocyanate content of kale varieties. Journal of the Science of Food and Agriculrure 17, 7071.Google Scholar
Kappas, A., Anderson, K. E., Conney, A. H. & Alvares, A. P. (1977). Influence of dietary protein and carbohydrate on antipyrine and theophylline metabolism in man. Clinical Pharmacology and Therapeutics 20, 643653.Google Scholar
Kawakishi, S., Goto, T. & Namiki, M. (1983). Oxidative scission of the disulphide bond of cystine and polypeptides by the action of allyl isothiocyanate. Agricultural and Biological Chemistry 47, 20712076.Google Scholar
Kawakishi, S. & Namiki, M. (1982). Oxidative cleavage of the disulfide bond of cystine by ally1 isothiocyanate. Journal of Agricultural and Food Cheniistry 30, 618620.Google Scholar
Langer, P. (1964). Study of the chemical representatives of the goitrogenic activity of raw cabbage. Physiologia Bohemoslovenica 3, 542549.Google Scholar
Langer, P. & Stolc, V. (1965). Goitrogenic activity of allylisothiocyanate – a widespread natural mustard oil. Endocrinology 76, 151155.Google Scholar
Lawes Agricultural Trust (1988). Genstat 5, Release 1.3. Harpenden, Herts: Rothamsted Experimental Station.Google Scholar
Martin, S. A. (1988). Effects ofp-coumaric acid and ferulic acid on methane production and fibre digestion by mixed rumen micro-organisms in vitro. Letters in Applied Microbiology 7, 113114.CrossRefGoogle Scholar
Mennicke, W. H., Gorler, K. & Krumbiegel, G. (1983). Metabolism of some naturally occurring isothiocyanates in the rat. Xenobiotica 13, 203207.Google Scholar
Mennicke, W. H., Kral, T., Krumbiegel, G. & Rittman, N. (1987). Determination of N-acetyl-S-(N-alkylthiocarbamoyl)-L-cysteine, a principal metabolite of alkyl isothiocyanates in rat urine. Journal of Chromatography 414, 1924.Google Scholar
Milne, J. A. (1990). Brassica leaf and root crops – a review of research findings in relation to animal production. In Milk mnd Meat from Forage Crops. British Grassland Society Occasional Publication no. 24 [Pollot, G. E., editor]. Maidenhead, Berkshire: British Grassland Society.Google Scholar
Nishie, K. & Daxenbichler, M. E. (1980). Toxicology of glucosinolates, related compounds (nitriles, R-goitrin, isothiocyanates) and vitamin U found in Cruciferae. Food and Cosmetic Toxicology 18, 159172.CrossRefGoogle ScholarPubMed
Oh, H. K., Sakai, T., Jones, M. B. & Longhurst, W. M. (1967). Effect of various essential oils isolated from Douglas Fir needles upon sheep and deer rumen microbial activity. Appled Microbiology 15, 777784.Google Scholar
Ohkawa, H., Ohkawa, R., Yamamoto, L. & Casida, J. E. (1972). Enzymatic mechanisms and toxicological significance of hydrogen cyanide liberation from various organothiocyanates and organonitriles in mice and houseflies. Pesticide Biochemistry and Physiology 2, 95112.Google Scholar
Orrenius, S. & Moldeus, P. (1984). The multiple roles of glutathione in drug metabolism. Trends in Pharmacological Science 5, 432435.Google Scholar
Paxman, P. J. & Hill, R. (1974). The goitrogenicity of kale and its relation to thiocyanate content. Journal of the Science of Food and Agriculture 25, 329337.Google Scholar
Pearson, A. W., Butler, E. J. & Fenwick, G. R. (1979). Rapeseed meal and liver damage: effect on plasma enzyme activity in chicks. Veterinary Record 105, 200201.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
Scofield, A. M., Rossiter, J. T., Witham, P., Kite, G. C. & Nash, R. J. (1990). Inhibition of thioglucoside-catalysed glucosinolate hydrolysis by castdnospermine and related alkaloids. Phytochemistry 29, 107109.Google Scholar
Silver, E. H., Kuttab, S. H. & Hasan, T. (1982). Structural considerations in the metabolism of nitriles to cyanide in vivo. Drug Metabolism and Disposition 10, 495498.Google Scholar
Smith, R. H. (1974). Kale poisoning. Report ofthe Rowetr Research Instirute 30, 112131.Google Scholar
Smith, R. H. (1980). Kale poisoning: the brassica anaemia factor. Veterinary Record 107, 1215.Google Scholar
Spencer, K. & Price, C. P. (1977). Influence of reagent quality and reaction conditions on determination of serum albumin by the bromo-cresol dye-binding method. Annals of Clinical Biochemstry 14, 105115.Google Scholar
Srivastava, V. K., Philbrick, D. J. & Hill, D. C. (1975). Responses of rats and chicks to rapeseed meal subjected to different enzymatic treatments. Canadian Journal of Animal Science 55, 331335.Google Scholar
Steven, F. S., Griffin, M. M. & Smith, R. H. (1981). Dimethyl exchange reactions in the control of enzymic activity. Evidence for the participation of dimethyl disulphide in exchanges. European Journal of Biochemistry 119, 7578.Google Scholar
Suberville, C., Higueret, P., Taruaoura, D., Garciu, H. & Higueret, D. (1988). Glutathione deficiency and peripheral metabolism of thyroid hormones during dietary cysteine deprivation in rats. British Journal of Nutrition 59, 451456.Google Scholar
Tang, C. S. (1974). Benzyl isothiocyanate as a naturally occurring papain inhibitor. Journal of Food Science 39, 9496.Google Scholar
Tanii, H. & Hashimoto, K. (1984). Studies on the mechanism of acute toxicity of nitriles in mice. Archives of Toxicology 55, 4754.CrossRefGoogle ScholarPubMed
VanEtten, C. H., Gagne, W. E., Robbins, D. J., Booth, A. N. & Daxenbichler, M. E. (1969). Biological evaluation of crambe seed meals and derived products by rat feeding. Cereal Chemistry 46, 145155.Google Scholar
Van Soest, P. J. (1963). Use of detergents in the analysis of fibrous feeds. II. A rapid method for the determination of fiber and lignin. Journal ofthe Association of OBcial Analytical Chemists 46, 829835.Google Scholar
Van Soest, P. J. & Wine, R. H. (1967). Use of detergents in the analysis of fibrous feeds. IV. Determination of plant cell-wall constituents. Journal of the Association of Oficial Analytical Chemists 50, 5055.Google Scholar
Wilcox, A. A., Coroll, W. E., Sterling, R. E., Davis, H. A. & Ware, A. G. (1966). Use of the Berthelot reaction in the automated analysis of serum urea nitrogen. Cknical Chembtry 12, 151157.Google Scholar
Willhite, C. C. & Smith, R. P. (1981). The role of cyanide liberation in the acute toxicity of aliphatic nitriles. Toxicology and Applied Pharmacology 59, 589602.Google Scholar
Young, J. D. & Tucker, E. M. (1983). Erythrocyte glutathione deficiency in sheep. In Functions of Glutathione: Physiological, Toxicologic [Larsson, A., Orrenius, S., Holmgren, A. and Mannervik, B., editors]. New York: Raven Press.Google Scholar