Hostname: page-component-586b7cd67f-dsjbd Total loading time: 0 Render date: 2024-11-23T04:03:24.479Z Has data issue: false hasContentIssue false

Different modes of food restriction and compensatory growth in double-muscled Belgian Blue bulls: plasma metabolites and hormones

Published online by Cambridge University Press:  18 August 2016

J.F. Cabaraux*
Affiliation:
Department of Animal Production, Nutrition Unit, B43; and
M. Kerrour
Affiliation:
Department of Animal Production, Nutrition Unit, B43; and
C. van Eenaeme
Affiliation:
Department of Animal Production, Nutrition Unit, B43; and
I. Dufrasne
Affiliation:
Experimental Station, Faculty of Veterinary Medicine, University of Liège, Sart-Tilman, 4000 Liège, Belgium
L. Istasse
Affiliation:
Department of Animal Production, Nutrition Unit, B43; and
J.-L. Hornick
Affiliation:
Department of Animal Production, Nutrition Unit, B43; and
*
E-mail: [email protected]
Get access

Abstract

The effects of different sequences of food restriction and fattening have been studied on plasma metabolites and hormones in double-muscled Belgian Blue bulls. Twenty animals were divided into five groups. The first group (control, CG) was given, ad libitum, a fattening diet based on sugar-beet pulp. In G2 and G3, fattening was interrupted after 103 and 187 days, respectively, by a period of food restriction lasting about 2 months during which the animals received a maintenance ration. They were finished with the same diet as CG. The last two groups, G4 and G5, received a limited amount of the restriction diet to support 0·5 and 0 kg gain per day, respectively, for 4 months, before being fattened as CG. Plasma glucose, alpha-amino nitrogen, non-esterified fatty acids, urea, creatinine, thyroxine (T4), 3, 3’, 5’-tri-iodothyroxine (T3), and insulin-like growth factor-1 (IGF-1) were measured in blood samples taken every 2 weeks. Plasma GH and insulin profiles were measured in serial blood samples obtained at three different times during growth. Animals that showed compensatory growth had lower plasma urea, associated with high levels of T3, T4 and IGF–1. Animals from G2 and G3 failed to show compensatory growth. In Belgian Blue bulls, compensatory growth is markedly affected when food restriction is severe or fattening interrupted.

Type
Growth, development and meat science
Copyright
Copyright © British Society of Animal Science 2003

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

Baker, R. D., Young, N. E. and Laws, J. A. 1992. The effect of diet in winter on the body composition of young steers and subsequent performance during the grazing season. Animal Production 54: 211219.Google Scholar
Balsam, A. and Ingbar, S. H. 1979. Observations on the factors that control the generation of triiodothyronine from thyroxine in rat liver and the nature of the defect induced by fasting. Journal of Clinical Investigation 63: 11451156.Google Scholar
Blum, J. W., Gingins, M., Vitins, P. and Bickel, H. 1980. Thyroid hormone levels related to energy and nitrogen balance during weight loss and regain in adult sheep. Acta Endocrinologica 93: 440447.Google Scholar
Blum, J. W. and Kunz, P. 1981. Metabolic effects of fasting in steers. Research in Veterinary Science 31: 127129.Google Scholar
Blum, J. W., Schnyder, W., Kunz, P. L., Blom, A. K., Bickel, H. and Schürch, A. 1985. Reduced and compensatory growth: endocrine and metabolic changes during food restriction and refeeding in steers. Journal of Nutrition 115: 417424.CrossRefGoogle ScholarPubMed
Breier, B. H., Bass, J. J., Butler, J. H. and Gluckman, P. D. 1986. The somatotrophic axis in young steers: influence of nutritional status on pulsatile release of growth hormone and circulating concentrations of insulin-like growth factor 1. Journal of Endocrinology 111: 209215.CrossRefGoogle ScholarPubMed
Breier, B. H., Gluckman, P. D. and Bass, J. J. 1988. The somatotrophic axis in young steers: influence of nutritional status and oestradiol-17ß on hepatic high- and low-affinity somatotrophic binding sites. Journal of Endocrinology 116: 169177.Google Scholar
Cabello, G. and Wrutniak, C. 1989. Thyroid hormone and growth: relationships with growth hormone effects and regulation. Reproduction, Nutrition, Development 29: 387402.Google Scholar
Carstens, G. E., Johnson, D. E., Ellenberger, M. A. and Tatum, J. D. 1991. Physical and chemical components of the empty body during compensatory growth in beef steers. Journal of Animal Science 69: 32513264.Google Scholar
Cassar-Malek, I., Kahl, S., Jurie, C. and Picard, B. 2001. Influence of feeding level during postweaning growth on circulating concentrations of thyroid hormones and extrathyroidal 54-deiodination in steers. Journal of Animal Science 79: 26792687.Google Scholar
Clinquart, A. 1996. Influence de la vitesse de croissance chez des taurillons Blanc Bleu Belge de type mixte. In Variations des performances zootechniques, des caractéristiques de la carcasse et des constituants plasmatiques chez le taurillon Blanc Bleu Belge: influence de la conformation, de la vitesse de croissance et d’un complément de matière grasse, pp. 101150. Presses de la Faculté de Médecine Vétérinaire de l’Université de Liège, Liège.Google Scholar
Closset, J., Maghuin-Rogister, G., Tran Quang, Minh, Lambot, O. and Hennen, G. 1986. Immunological growth promotion of bulls by a synthetic vaccine inhibiting the endogenous somatostatin. Proceedings of the 32nd European meeting of meat research workers, Ghent, p. 19.Google Scholar
Eenaeme, C. van, Clinquart, A., Baldwin, P., Hornick, J. L. and Istasse, L. 1992. Compensatory growth, muscle protein turnover and hormonal status in Belgian Blue bulls. Mededelingen Faculteit Landbouwwetenschappen Universiteit Gent 57: 19631971.Google Scholar
Eenaeme, C.van, Evrard, M., Hornick, J. L., Baldwin, P., Diez, M. and Istasse, L. 1998. Nitrogen balance and myofibrillar protein turnover in double muscled Belgian Blue bulls in relation to compensatory growth after different periods of restricted feeding. Canadian Journal of Animal Science 78: 549559.Google Scholar
Ellenberger, M. A., Johnson, D. E., Cartsens, G. E., Hossner, K. L., Holland, M. D., Nett, T. M. and Nockels, C. F. 1989. Endocrine and metabolic changes during altered growth rates in beef cattle. Journal of Animal Science 67: 14461454.Google Scholar
Elsasser, T. H., Rumsey, T. S. and Hammond, A. C. 1989. Influence of diet on basal and growth hormone-stimulated plasma concentration of IGF-1 in beef cattle. Journal of Animal Science 67: 128141.Google Scholar
Gluckman, P. D., Breier, B. H. and Davis, S. R. 1987. Symposium: growth hormone and biotechnology. Journal of Dairy Science 70: 442446.Google Scholar
Hart, C., Chadwick, M. E., Boone, T. C., Langley, K. E., Rudman, C. and Souza, L. M. 1984. A comparison of the growth-promoting, lipolytic, diabetogenic and immunological properties of pituitary and recombinant-DNA-derived bovine growth hormone (somatotropin). Biochemical Journal 224: 93100.Google Scholar
Hayden, J. M., Williams, J. E. and Collier, R. J. 1993. Plasma growth hormone, insulin-like growth factor, insulin, and thyroid hormone association with body protein and fat accretion in steers undergoing compensatory gain after dietary energy restriction. Journal of Animal Science 71: 33273338.CrossRefGoogle ScholarPubMed
Henry, R. J., Cannon, D. C. and Winkelman, J. W. 1974. Clinical chemistry. Principles and techniques. Harper and Row, New York.Google Scholar
Hornick, J. L., Cremer, V., Eenaeme, C.van and Istasse, L. 2000. Mechanisms of reduced and compensatory growth. Domestic Animal Endocrinology 19: 121132.CrossRefGoogle ScholarPubMed
Hornick, J. L., Eenaeme, C.van, Clinquart, A., Diez, M. and Istasse, L. 1998b. Different periods of feed restriction before compensatory growth in Belgian Blue bulls. I. Animal performances, nitrogen balance, meat characteristics and fat composition. Journal of Animal Science 76: 249259.Google Scholar
Hornick, J. L., Eenaeme, C.van, Clinquart, A., Gerard, O. and Istasse, L. 1999. Different modes of food restriction and compensatory growth in double-muscled Belgian Blue bulls: animal performance, carcass and meat characteristics. Animal Science 69: 563572.Google Scholar
Hornick, J. L., Eenaeme, C.van, Diez, M., Minet, V. and Istasse, L. 1998c. Different periods of feed restriction before compensatory growth in Belgian Blue bulls. II. Plasma metabolites and hormones. Journal of Animal Science 76: 260271.Google Scholar
Hornick, J. L., Raskin, P., Clinquart, A., Dufrasne, I., Eenaeme, C.van and Istasse, L. 1998a. Compensatory growth in Belgian Blue bulls previously grazed at two stocking rates: animal performance and meat characteristics. Animal Science 67: 427434.Google Scholar
Istasse, L., Hovell, F. D. D., Macleod, N. A. and Ørskov, E. R. 1987. The effects of continuous or intermittent infusion of propionic acid on plasma insulin and milk yield in dairy cows nourished by intragastric infusion of nutrients. Livestock Production Science 16: 201214.Google Scholar
Journet, M., Huntington, G. and Peyraud, J. L. 1995. Le bilan des produits terminaux de la digestion. In Nutrition des ruminants domestiques: ingestion et digestion (ed. Jarrige, R., Ruckebusch, Y., Demarquilly, C., Farce, M.H. and Journet, M.), pp. 671720. INRA, Paris.Google Scholar
Keenan, D. M. and Allardyce, C. J. 1986. Changes in plasma creatinine levels of sheep during submaintenance feeding. Australian Veterinary Journal 63: 2930.Google Scholar
McKinnon, J. J., Cohen, R. D. H., Jones, S.D., Laarveld, B. and Christensen, D. A. 1993. The effects of dietary energy and crude protein concentration on growth and serum insulin-like growth factor-1 levels of cattle that differ in mature body size. Canadian Journal of Animal Science 73: 303313.Google Scholar
Massart, S. 2000. Caracterisation et significations biologiques des “insulin-like growth factor-binding proteins” chez le bovin. Ph. D. thesis, Faculté universitaire des Sciences agronomiques, Gembloux, Belgique.Google Scholar
Minet, V., Eenaeme, C.van, Raskin, P., Dufrasne, I., Clinquart, A., Hornick, J. L., Diez, M., Mayombo, A. P., Baldwin, P., Bienfait, J. M. and Istasse, L. 1996. Fiche technique. In Stratégies d’engraissement du taurillon Blanc Bleu Belge culard. Performances, qualité des carcasses et de la viande, approche métabolique et bilan économique, pp. 108117. Ministère des Classes Moyennes et de l’Agriculture, Administration Recherche et Développement, Service Recherche, Bruxelles, Belgium.Google Scholar
Minitab Incorporated. 1995. Minitab reference manual. Data Tech. Industries, Valley Forge, USA.Google Scholar
Müller, H. W. and Binz, K. 1982. Glass capillary gas chromatography of the serum fatty acids fraction via automatic injections of lipid extracts. Journal of Chromatography and Biomedical Applications 228: 7593.Google Scholar
Palmer, D. W. and Peters, J. T. 1969. Automated determination of free amino groups in serum and plasma using 2, 4, 6-trinitrobenzene sulfonate. Clinical Chemistry 19: 891901.Google Scholar
Renaville, R., Eenaeme, C.van, Breier, B. H., Vleurick, L., Bertozzi, C., Gengler, N., Hornick, J. L., Parmentier, I., Istasse, L., Haezebroeck, V., Massart, S. and Portetelle, D. 2000. Feed restriction in young bulls alters the onset of puberty in relationship with plasma insulin-like growth factor-I (IGF-I) and IGF-binding proteins. Domestic Animal Endocrinology 18: 165176.CrossRefGoogle ScholarPubMed
Ronge, H. and Blum, J. 1989. Insulin-like growth factor I during growth in bulls. Reproduction, Nutrition, Development 29: 105111.Google Scholar
Schwartz, F. J., Röpke, R., Schams, D. and Kirchgessner, M. 1992. Effects of sex and growth on plasma concentration of growth hormone, insulin-like growth factor-I and insulin in fattening Simmental cattle. Journal of Animal Physiology and Animal Nutrition 68: 263271.Google Scholar
Tveit, B. and Almlid, T. 1980. T4 degradation rate and plasma levels of TSH and thyroid hormones in ten young bulls during feeding conditions and 48 h of starvation. Acta Endocrinologica 93: 435439.Google Scholar
Tveit, B. and Larsen, F. 1983. Suppression and stimulation of TSH and thyroid hormones in bulls during starvation and refeeding. Acta Endocrinologica 103: 223226.Google Scholar
Vernon, R. G. 1992. Control of lipogenesis and lipolysis. In The control of fat and lean deposition (ed. Buttery, P. J., Boorman, K. N. and Lindsay, D. B.), pp. 5977. Butterworth-Heinemann, Oxford.Google Scholar
Vleurick, L., Renaville, R., Vandehaar, M., Hornick, J. L., Istasse, L., Parmentier, I., Bertozzi, C., Eenaeme, C. van and Portetelle, D. 2000. A homologous radioimmunoassay for plasma insulin-like growth factor binding protein-2 in cattle. Journal of Dairy Science 83: 452458.Google Scholar
Wilson, P. N. and Osbourn, D. F. 1960. Compensatory growth after undernutrition in mammals and birds. Biological Reviews 35: 324363.Google Scholar
Wrutniak, C. and Cabello, G. 1987. Effects of food restriction on cortisol, TSH and iodothyronin concentrations in the plasma of newborn lamb. Reproduction, Nutrition, Development 27: 721732.Google Scholar