Hostname: page-component-8448b6f56d-dnltx Total loading time: 0 Render date: 2024-04-23T16:20:29.227Z Has data issue: false hasContentIssue false
  • English
  • Français

Protein utilization during energy undernutrition in sheep sustained by intragastric infusion: effects of protein infusion level, with or without sub-maintenance amounts of energy from volatile fatty acids, on energy and protein metabolism

Published online by Cambridge University Press:  24 July 2007

S. A. Chowdhury ,
E. R. Ørskov ,
F. D. DeB. Hovell ,
J. R. Scaife  and
G. Mollison
S. A. Chowdhury
Affiliation:
Rowett Research Institute, Bucksburn, Aberdeen AB21 9SB
E. R. Ørskov
Affiliation:
Rowett Research Institute, Bucksburn, Aberdeen AB21 9SB
F. D. DeB. Hovell
Affiliation:
Rowett Research Institute, Bucksburn, Aberdeen AB21 9SB
J. R. Scaife
Affiliation:
School of Agriculture, University of Aberdeen, 581 King Street, Aberdeen AB9 IUD
G. Mollison
Affiliation:
Rowett Research Institute, Bucksburn, Aberdeen AB21 9SB
Rights & Permissions [Opens in a new window]

Abstract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

Utilization of endogenous and exogenous energy for protein accretion during energy undernutrition has been studied. Nine lambs nourished by intragastric infusion were given either progressively increasing or decreasing amounts of casein-N up to 2550 mg/kg metabolic weight (W0·75), with or without 250 kJ/kg W0·75 of volatile fatty acids daily. Energy balance (respiration calorimetry) and N balance were measured. While all experimental animals were in negative energy balance, N balance increased curve-linearly with the increase in casein-N infusion and attained positive N balance. Endogenous energy (presumably body fat) was found to meet the energy needs for protein accretion during energy undernutrition. It is concluded that body fat can be effectively utilized to support lean-tissue growth during energy undernutrition, so that the classical nutritional concept of dietary energy:protein ratio is only meaningful when both endogenous and exogenous energy are considered.

Keywords

Intragastric infusionEnergy undernutritionProtein utilizationFat mobilization
Type
Animal Nutrition
Information
British Journal of Nutrition , Volume 77 , Issue 4 , April 1997 , pp. 565 - 576
Copyright
Copyright © The Nutrition Society 1997

References

REFERENCES

Agricultural Research Council (1980). The Nutrient Requirements of Farm Livestock. Slough: Commonwealth Agricultural Bureaux.Google Scholar
Atkinson, T., Fowler, V. R., Garton, G. A. & Lough, A. K. (1972). A rapid method for accurate determination of lipid in animal tissue. Analyst 97, 562568.Google Scholar
Balch, C. C. (1967). Problems in predicting the role of non-protein nitrogen as a substitute for protein in rations for farm ruminants. World Review of Animal Production 3, 8491.Google Scholar
Bergman, E. N. (1973). Glucose metabolism in ruminants as related to hypoglycemia and ketosis. Cornell Veterinarian 63, 341382.Google Scholar
Black, J. L. & Griffiths, D. A. (1975). The effect of live weight and energy intake on nitrogen balance and total nitrogen requirements of lambs. British Journal of Nutrition 33, 339413Google Scholar
Brockway, J. M. (1987). Influence of Activity. Rowett Research Institute Report. Aberdeen: Rowett Research Institute.Google Scholar
Campbell, R. G. (1988). Nutritional constraints to lean tissue accretion in farm animals. Nutrition Research Reviews 1, 233253.Google Scholar
Chowdhury, S. A. (1989). Energy and protein metabolism during undernutrition. MSc Thesis, University of Aberdeen.Google Scholar
Chowdhury, S. A. (1992). Protein utilization during energy undernutrition in sheep. PhD Thesis, University of Aberdeen.Google Scholar
Chowdhury, S. A., Ørskov, E. R. & MacLeod, N. A. (1990). Protein utilization during energy undernutrition in steers. Proceedings of the Nutrition Society 49, 208A.Google Scholar
Davidson, J., Matheison, J. & Boyne, A. W. (1970). The use of automation in determining nitrogen in Kjeldahl method with final calculation by computer. Analyst 95, 181193.Google Scholar
Fuller, M. F. & Croft, M. (1977). The protein sparing effect of carbohydrate. Nitrogen retention of the growing pig in relation to diet. British Journal of Nutrition 39, 479488.Google Scholar
Garlick, P. J., Clugston, G. A. & Waterlow, J. C. (1980). Influence of low energy diets on whole body protein turnover in obese subjects. American Journal of Physiology 238, E235–E244.Google Scholar
Hovell, F. D. DeB., ørskov, E. R., Kyle, D. & MacLeod, N. A. (1983). Basal urinary nitrogen excretion and growth response to supplemental protein by lambs close to energy equilibrium. British Journal of Nutrition 50. 173187.Google Scholar
Krebs, H. A. (1964). The metabolic fate of amino acids. In Mammalian Protein Metabolism, pp. 125176 [Munro, H. N. and Allison, J. N., editors]. New York: Academic Press.Google Scholar
Ku Vera, J. C. (1988). Energy and N metabolism in cattle nourished by intragastric infusion of nutrients. PhD Thesis, University of Aberdeen.Google Scholar
Leat, W. M. F. (1983). Adipose tissue and structural lipid. In Dynamic Biochemistry of Animul Production. World Animal Science A, pp. 109136 [Riis, P. M., editor]. Amsterdam, Oxford, New York, Tokyo: Elsevier.Google Scholar
Livesey, G. (1984). The energy equivalents of ATP and the energy values of food proteins and fats. British Journal of Nutrition 51, 1528.CrossRefGoogle ScholarPubMed
Lobley, G. E. (1990). Energy metabolism reactions in ruminant muscle: response to age, nutrition and hormonal status. Reproduction Nutrition and Development 30, 1334.Google Scholar
Lobley, G. E., Connell, A. & Buchan, V. (1987). Effect of food intake on energy and protein metabolism in finishing beef steers. British Journel of Nutrition 57, 457465.CrossRefGoogle ScholarPubMed
MacLeod, N. A., Corrigal, W., Striton, R. A. & Ørskov, E. R. (1982). Intragastric infusion of nutrients in cattle. British Journal of Nutrition 47, 547552.Google Scholar
Madsen, A. (1983). The molecular basis of animal production: metabolism in liver cells. In Dynamic Biochemistry of Animal Production. World Animal Science, A, pp. 5374 [Riis, P. M., editor]. Amsterdam, Oxford, New York, Tokyo: Elsevier.Google Scholar
Marliss, E. B., Murry, F. T. & Nakhooda, A. F. (1978). The metabolic response to hypocaloric protein diets in obese man. Journal of Clinical Investigation 62. 468479.Google Scholar
Oldham, J. D. (1984). Protein-energy interrelationship in dairy cows. Journal of Dairy Science 10, 10901114.Google Scholar
Ørskov, E. R. (1982). Protein Nutrition in Ruminants. London: Academic Press.Google Scholar
Ørskov, E. R., Grubb, D. A., Wenham, G. & Corrigal, W. (1979). The sustenance of growing and fattening ruminants by intragastric infusion of volatile fatty acids and protein. British Journal of Nutrition 41, 553558.Google Scholar
Ørskov, E. R. & Hovell, F. D. DeB. (1986). Protein metabolism and utilization during undernutrition in ruminants. In Nuclear and Related Techniques in Animal Production Health, pp. 429438. Vienna: International Atomic Energy Agency.Google Scholar
Ørskov, E. R., MacLeod, N. A., Fahmy, S. T. M., Istasse, L. A. & Hovell, F. D. DeB (1983). Investigation of nitrogen balance in dairy cows and steers nourished by intragastric infusion. Effect of submaintenance energy input with or without protein. British Journal of Nutrition 50, 99107.Google Scholar
Sidhu, K. S., Emery, R. S., Parr, A. F. & Merkel, R. A. (1973). Fat mobilization lipase in relation to fatness in lambs. Journal of Animal Science 36, 658662.Google Scholar
Technicon Instrument Co. Ltd (1967). Technicon Autoanalyser Methodology Urea-N. Sheet no. N-1C. Terrytown: Technicon Instrument Corporation.Google Scholar
Winterer, J., Bistrian, B. R., Bilmazes, C., Blackburn, G. L. & Young, V. R. (1980). Whole body protein turnover study with 15N-glycine and muscle protein breakdown in mildly obese subjects during a protein sparing diet and a brief total fast. Metabolism 29, 575581.Google Scholar