Hostname: page-component-cd9895bd7-8ctnn Total loading time: 0 Render date: 2024-12-27T19:25:05.607Z Has data issue: false hasContentIssue false

The response of growing pigs to amino acids as influenced by environmental temperature. 1. Threonine

Published online by Cambridge University Press:  18 August 2016

N.S. Ferguson
Affiliation:
School of Agricultural Sciences and Agribusiness, Discipline of Animal and Poultry Science, University of Natal, P. Bag X 01, Scottsville 3209, South Africa
G.A. Arnold
Affiliation:
School of Agricultural Sciences and Agribusiness, Discipline of Animal and Poultry Science, University of Natal, P. Bag X 01, Scottsville 3209, South Africa
G. Lavers
Affiliation:
School of Agricultural Sciences and Agribusiness, Discipline of Animal and Poultry Science, University of Natal, P. Bag X 01, Scottsville 3209, South Africa
R.M. Gous
Affiliation:
School of Agricultural Sciences and Agribusiness, Discipline of Animal and Poultry Science, University of Natal, P. Bag X 01, Scottsville 3209, South Africa
Get access

Abstract

Two similar experiments (1 and 2) were conducted to measure the effects of a range of dietary threonine concentrations and environmental temperatures on the performance of pigs grown from 13 to 25 kg live weight. In both experiments 48 Large White x Landrace entire male pigs were assigned at 13 kg to one of six dietary threonine treatments (8·9 (T1), 7·6 (T2), 6·2 (T3), 4·9 (T4), 3·6 (T5) g/kg and T5 + supplemented threonine (T6)) and one of four temperature treatments (18, 22, 26 and 30°C). Animals were given ad libitum access to food until 25 kg live weight. There were significant interactions (P < 0·05) between temperature and threonine content on the rate of growth (ADG) with the highest gains on T1 and at 22°C. Similarly the response in food intake (FI) to dietary threonine was significantly (P < 0·01) modified by the ambient temperature. An increase in the supply of threonine in the diet resulted in significant increases (P < 0·001) in the gain per unit of food (FCE). A similar response to temperature occurred with the highest FCE recorded at 26°C and the lowest at 18°C. There was a 0·20 proportional reduction in body protein content at 25 kg live weight in pigs given T5 compared with those given T1 and similarly, excluding T6 because threonine may not have been the most limiting amino acid, the fat content was 1·37 higher for pigs on T5 versus T1, which had the lowest fat content. Similar trends occurred in protein and lipid growth rates with maximum protein deposition recorded on T1 (86 (s.e. 3·5) g/day) and maximum lipid deposition on T5 (108 (s.e. 5·8) g/day), over all temperatures. The response in total heat loss was similar to that observed in FI with the effect of decreasing threonine content being dependent on the environmental temperature. Linear regression of daily empty body threonine accretion on daily digestible threonine intake showed an average efficiency of threonine utilization for pigs between 12 kg and 25 kg live weight of 0·59 (s.e. 0·03). There were no differences in efficiency between temperatures. In conclusion, decreasing the threonine concentration below the requirement of the animal ‘resulted in a significant decrease in ADG, reduced FCE and fatter animals. Pigs given a diet deficient in threonine will attempt to maintain threonine intake as the concentration declines by increasing food intake but this compensation is dependent on the environmental temperature. Pigs are able to compensate better for a deficiency in threonine at 18°C and 22°C than at higher temperatures due to the animals being able to dissipate more heat at the lower temperatures.

Type
Non-ruminant nutrition, behaviour and production
Copyright
Copyright © British Society of Animal Science 2000

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

Adeola, O. 1995. Dietary lysine and threonine utilization by young pigs: Efficiency for carcass growth. Canadian Journal of Animal Science 75: 445452.CrossRefGoogle Scholar
Agricultural Research Council . 1981. The nutrient requirements of pigs. Commonwealth Agricultural Bureaux, Farnham Royal.Google Scholar
Association of Official Analytical Chemists. 1984. Official methods of analysis, 14th edition. Association of Official Analytical Chemists, Washington, DC.Google Scholar
Baker, D. H. 1991. Partitioning of nutrients for growth and other metabolic functions: efficiency and priority considerations. Poultry Science 70:17951805.Google Scholar
Batterham, E. S., Giles, L. R. and Dettman, B. E. 1985. Amino acid and energy interactions in growing pigs. 1. Effects of food intake, sex and live weight on the responses of growing pigs to lysine concentration. Animal Production 40: 331343.Google Scholar
Beech, S. A., Batterham, E. S. and Elliot, R. 1991. Utilization of ileal digestible amino acids by growing pigs: threonine. British Journal of Nutrition 65: 381390.Google Scholar
Campbell, R. G. and Dunkin, A. C. 1983. The influence of protein nutrition in early life on growth and development of the pig. 1. Effects on growth performance and body composition. British Journal of Nutrition 50: 605617.CrossRefGoogle ScholarPubMed
Campbell, R. G. and Taverner, M. R. 1988. Relationships between energy intake and protein and energy metabolism, growth and body composition of pigs kept at 14 or 32°C from 9 to 20 kg. Livestock Production Science 18: 289303.Google Scholar
Chung, T. K. and Baker, D. H. 1992. Efficiency of dietary methionine utilization by young pigs. Journal of Nutrition 122:18621869.Google Scholar
Close, W. H., Mount, L. E. and Brown, D. 1978. The effects of plane of nutrition and environmental temperature on the energy metabolism of the growing pig. 2. Growth rate, including protein and fat deposition. British Journal of Nutrition 40: 423431.Google Scholar
Close, W. H. and Stanier, M. W. 1984. Effects of plane of nutrition and environmental temperature on the growth and development of the early-weaned piglet. Animal Production 38: 211220.Google Scholar
Eckert, R., Randall, D. and Augustine, G. 1988. Animal physiology: mechanisms and adaptations. W. H. Freeman and Co., New York.Google Scholar
Emmans, G.C. and Fisher, C. 1986. Problems in nutritional theory. In Nutrient requirements of poultry and nutritional research (ed. Fisher, S. and Boorman, K.N.), pp. 939. Butterworths, London.Google Scholar
Emmans, G.C. and Oldham, J. D. 1988. Modelling of growth and nutrition in different species. In Modelling of livestock production systems (ed. Korver, S. and Arendonk, J.A.M. van), pp. 1321. Kluwer Academic Publishers, Dordrecht.Google Scholar
Ferguson, N. S. and Gous, R. M. 1997. The influence of heat production on voluntary food intake in growing pigs given protein-deficient diets. Animal Science 64: 365378.Google Scholar
Ferguson, N. S., Gous, R. M. and Emmans, G. C. 1994. Preferred components for the construction of a new simulation model of growth, feed intake and nutrient requirements of growing pigs. South African Journal of Animal Science 24: 1017.Google Scholar
Ferguson, N. S., Nelson, L. and Gous, R. M. 1999. Diet selection in pigs: choices made by growing pigs when given foods differing in nutrient density. Animal Science 68: 691699.CrossRefGoogle Scholar
Fisher, C. and Morris, T. R. 1970. The determination of the methionine requirement of laying pullets by a diet dilution technique. British Poultry Science 11: 6782.Google Scholar
Fuller, M. F. and Boyne, A. W. 1971. The effects of environmental temperature on the growth and metabolism of pigs given different amounts of food. 1. Nitrogen metabolism, growth and body composition. British Journal of’Nutrition 25: 259272.Google Scholar
GENSTAT 5 Committee. 1993. GENSTAT 5 release 3 reference manual. Clarendon Press, Oxford.Google Scholar
Goodbrand, R. D., Hines, R. H., Nelssen, J. L. and Thaler, R. C. 1988. The effects of dietary lysine level on the performance of pigs weaned at two weeks of age. Journal of Animal Science 66: 315.Google Scholar
Henry, Y. and Seve, B. 1993. Feed intake and dietary amino acid balance in growing pigs with special reference to lysine, tryptophan and threonine. Pig News and Information 14: 35N43N.Google Scholar
Holmes, C.W. and Close, W. H. 1977. The influence of climatic variables on energy metabolism and associated aspects of productivity in the pig. In Nutrition and the climatic environmen. (ed. Haresign, W., Swan, H. and Lewis, D.), pp. 5173. Butterworths, London.Google Scholar
Kyriazakis, I., Emmans, G.C. and McDaniel, R. 1993. Whole body amino acid composition of the growing pig. Journal of the Science of Food and Agriculture 62: 2933.Google Scholar
McCracken, K. J., Eddie, S. M. and Stevenson, N. G. 1980. Energy and protein nutrition of early weaned pigs. 1. Effect of energy intake and energy: protein on growth, efficiency and nitrogen utilization of pigs between 8-32d. British Journal of Nutrition 43: 289303.Google Scholar
Mount, L. E. 1979. Adaptations to thermal environment: man and his productive animals. Edward Arnold, London.Google Scholar
Noblet, J. and Le Dividich, J. 1982. Effect of environmental temperature and feeding level on energy balance traits of early-weaned piglets. Livestock Production Science 9: 619632.Google Scholar
Rinlado, D. and Le Dividich, J. 1991. Assessment of optimal temperature for performance and chemical body composition of growing pigs. Livestock Production Science 29: 6175.Google Scholar
Schenck, B.C., Stáhly, T.S., Cromwell, G.L. 1992. Interactive effects of thermal environment and dietary amino acid and fat levels on rate and efficiency of growth of pigs housed in a conventional nursery. Journal of Animal Science 70: 38033811.Google Scholar
Verstegen, M.W.A., Close, W.H., Start, I. B. and Mount, L.E. 1973. The effects of environmental temperature and plane of nutrition on heat loss, energy retention and deposition of protein and fat in groups of growing pigs. British Journal of Nutrition 30: 2135.CrossRefGoogle ScholarPubMed
Zhang, Y, Partridge, I.G., Keal, H.D. and Mitchell, K.G. 1984. Dietary amino acid balance and requirements for pigs weaned at 3 weeks of age. Animal Production 39: 441448.Google Scholar
Whittemore, C. 1993. The science and practice of pig production. Longman Scientific and Technical, Essex.Google Scholar