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Estimation of endogenous amino acid losses in growing chickens given soya-bean meal supplemented or not with DL-methionine

Published online by Cambridge University Press:  18 August 2016

I. Fernández-Fígares
Affiliation:
Animal Nutrition Unit, Estación Experimental del Zaidín (CSIC), Camino del Jueves s/n, Armilla, 18100 Granada, Spain
R. Nieto
Affiliation:
Animal Nutrition Unit, Estación Experimental del Zaidín (CSIC), Camino del Jueves s/n, Armilla, 18100 Granada, Spain
the late C. Prieto
Affiliation:
Animal Nutrition Unit, Estación Experimental del Zaidín (CSIC), Camino del Jueves s/n, Armilla, 18100 Granada, Spain
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Abstract

An experiment was carried out in growing chickens to study the effect of supplementation of a semi-synthetic diet containing soya-bean meal as the sole protein source with DL-methionine, to improve its biological value, on the excretion of endogenous protein and amino acids measured in lower ileum and total tract using traditional methods. Thirty-two White Rock male broilers (10 days old) were randomly divided into eight groups each of four birds, of similar body weight (mean live weight: 142·8 (s.e. 0·68) g), and individually housed in metabolism cages. Following a paired-feeding design based on metabolic body weight (kgM0·75), each group of birds was given, for an experimental period of 20 days, each of four levels of protein (60, 120, 180 or 240 g/kg; 5 days each) in two groups of isoenergetic (14·5 kJ metabolizable energy per g dry matter) and semi-synthetic diets based on soya-bean meal, either not supplemented or supplemented with 2 g/kg DL-methionine (diets S and SM, respectively). After 3 days of each treatment excreta were collected for 48 h, frozen and stored at –20ºC. At the end of the fourth treatment three chickens of each group were killed and their lower ileal contents collected. The remaining chick of each treatment was fasted for 24 h and given a protein-free diet for 8 days and excreta were collected for the last 4 days. Then (day 39 of age), chickens were killed and lower ileum contents removed and stored at –20ºC. Samples of excreta and lower ileum contents were subjected to nitrogen (N) analysis by Kjeldahl procedure and amino acid (AA) analysis by high-performance liquid chromatography. Supplementation with DL-methionine of the soya-bean meal-based diets halved total tract endogenous AA losses. Regression analysis produced a higher estimation of ileal and faecal endogenous AA excretion than feeding a protein-free diet. Endogenous AA excretion determined in the lower ileum was higher than in excreta no matter which estimation procedure was utilized. In conclusion, supplementation of dietary protein with the first limiting AA to improve its protein quality, causes an important drop in endogenous AA losses, that may have an important effect on the N economy and energy requirements in poultry. The use of regression analysis on excreta data where graded amounts of protein are given to growing chickens, seems a suitable method for determining endogenous AA losses provided that good quality proteins are used.

Type
Research Article
Copyright
Copyright © British Society of Animal Science 2002

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References

Aguilera, J. F. and Prieto, C. 1987. [Energy requirements for maintenance in growing chickens.] Archivos de Zootecnia 36: 165172.Google Scholar
Aguilera, J. F., Prieto, C., Molina, E. and Lachica, M. 1988. A micromethod for routine determination of chromic oxide in nutrition studies. Analysis 16: 454457.Google Scholar
Angkanaporn, K., Ravindran, V. and Bryden, W. L. 1997a. Influence of caecectomy and dietary protein concentration on apparent excreta amino acid digestibility in adult cockerels. British Poultry Science 38: 270276.CrossRefGoogle ScholarPubMed
Angkanaporn, K., Ravindran, V., Mollah, Y. and Bryden, W. L. 1997b. Evaluation of homoarginine as a marker for the determination of endogenous amino acid concentrations in poultry excreta. British Poultry Science 38: 577585.CrossRefGoogle ScholarPubMed
Bielorai, R. and Iosif, B. 1987. Amino acid absorption and endogenous amino acids in the lower ileum and excreta of chicks. Journal of Nutrition 117: 14591462.Google Scholar
Bielorai, R., Iosif, B. and Neumark, H. 1985. Nitrogen absorption and endogenous nitrogen along the intestinal tract of chicks. Journal of Nutrition 115: 568572.Google Scholar
Black, J. L. and Lange, C. F. M. de. 1995. Introduction to principles of nutrient partitioning for growth. In Modelling growth in the pig (ed. Moughan, P. J., Verstegen, M. W. A. and M. I., Visser-Reyneveld), pp. 3346. Wageningen Press, Wageningen.Google Scholar
Bryden, W. L., Siriwan, P. and Annison, E. F. 1990. Developments in the estimation of amino acid availability. Proceedings of the eighth Australian poultry and feed convention, Gold Coast, pp. 274278.Google Scholar
Butts, C. A., Moughan, P. J., Smith, W. C., Reynolds, G. W. and Garrick, D. J. 1993. The effect of food dry matter intake on the endogenous ileal amino acid extraction determined under peptide alimentation in the 50 kg liveweight pig. Journal of the Science of Food and Agriculture 62: 235243.Google Scholar
Cohen, S. A., Meys, M. and Tarvin, T. L. 1989. The Pico-tag method. A manual of advanced techniques for amino acid analysis. Millipore Corporation, Bedford, Massachusetts.Google Scholar
Donkoh, A. and Moughan, P. J. 1994. The effect of crude protein content on apparent and true ileal nitrogen and amino acid digestibilities. British Journal of Nutrition 72: 5968.Google Scholar
Fernández-Fígares, I., Nieto, R., Aguilera, J. F. and Prieto, C. 1996. The use of the excretion of nitrogen compounds as an indirect index of the adequacy of dietary protein in chickens. Animal Science 63: 307314.CrossRefGoogle Scholar
Fisher, H. 1973. Methods of protein evaluation: assays with chicks and rabbits. In Proteins in human nutrition (ed. J. Porter, W. G. and Rolls, B. A.), pp. 263273. Academic Press, London.Google Scholar
Fuller, M. F. 1988. Methods of protein evaluation for non-ruminants. In Feed science (ed. Ørskov, E. R.), pp. 81101. Elsevier Science Publishers, New York.Google Scholar
Hagemeister, H. and Erbersdobler, H. 1985. Chemical labeling of dietary protein by transformation of lysine to homoarginine: new technique to follow intestinal digestion and absorption. Proceedings of the Nutrition Society 44: 133A.Google Scholar
Han, Y. and Baker, D. H. 1993. Effects of excess methionine or lysine for broilers fed a corn-soybean meal diet. Poultry Science 72: 10701074.Google Scholar
Institut National de la Recherche Agronomique. 1984. L’alimentation des animaux monogastriques: pork, lapin, volailles. INRA, Paris.Google Scholar
Ivy, C. A., Bragg, D. B. and Stephenson, E. L. 1968. Surgical exteriorizing the rectum of the growing chick. Poultry Science 47: 17711774.CrossRefGoogle ScholarPubMed
Kelly, J. M., Southorn, B. G., Kelly, C. E., Milligan, L. P. and McBride, B. W. 1993. Quantification of in vitro and in vivo energy metabolism of the gastrointestinal tract of fed or fasted sheep. Canadian Journal of Animal Science 73: 855868.CrossRefGoogle Scholar
Lange, C. F. M. de, Mohn, S. and Nyachoti, C. M. 1995. Partitioning of protein and energy intake in grower-finisher pigs. In Animal science research and development: moving towards a new century (ed. Ivan, M.). Symposium on determinants of production efficiency in swine. 75th anniversary meeting of the Canadian Society of Animal Science, Ottawa, ON, pp. 339360.Google Scholar
Lange, C. F. M. de, Souffrant, W. L., and Sauer, W. C. 1990. Real ileal protein and amino acid digestibilities in feedstuffs for growing pigs as determined with the 15N-isotope dilution technique. Journal of Animal Science 68: 409418.Google Scholar
Leterme, P., Thewis, A., Francois, W., Leeuwen, P. van, Wathelet, B. and Huisman, J. 1996. The use of 15N-labeled dietary proteins for determining true ileal amino acid digestibilities is limited by their rapid recycling in the endogenous secretion of pigs. Journal of Nutrition 126: 21882198.Google Scholar
Li, L., Sauer, W. C. and Fan, M. Z. 1993. The effect of dietary crude protein level on amino acid digestibility in early-weaned pigs. Journal of Animal Physiology and Animal Nutrition 70: 2637.Google Scholar
Lobley, G. E. 1993. Species comparisons of tissue protein metabolism: effects of age and hormonal action. Journal of Nutrition 123: (suppl. ) 337343.Google Scholar
Lobley, G. E., Milne, V., Lovile, J. M., Reeds, P. J. and Pennie, K. 1980. Whole body and tissue protein synthesis in cattle. British Journal of Nutrition 43: 491502.Google Scholar
McNab, J. M. 1994. Amino acid digestibility and availability studies with poultry. In Amino acids in farm animal nutrition (ed. Mello, J. P. F. D), pp. 6398. CAB International, Wallingford.Google Scholar
McNurlan, M. A., Tomkins, A. M. and Garlick, P. J. 1979. The effect of starvation on the rate of protein synthesis in rat liver and small intestine. Biochemistry Journal 178: 373379.Google Scholar
Mason, V. C., Bech-Andersen, S. and Rudemo, M. 1980. Hydrolysate preparation for amino acid determinations in feed constituents. 6. The influence of phenol and formic acid on the recovery of amino acids from oxidized feed proteins. Zeitschrift fur Tierphysiologie, Tierernahrung und Futtermittelkunde 43: 146164.Google Scholar
Moore, S. 1963. On the determination of cystine as cysteic acid. Journal of Biological Chemistry 238: 235237.CrossRefGoogle Scholar
Moughan, P. J. 1995. Modelling protein metabolism in the pig — first principles. In Modelling growth in the pig (ed. Moughan, P. J., Verstegen, M. W. A. and Visser, M. I.), European Association for Animal Production publication no. 78, pp. 5970.Google Scholar
Moughan, P. J., Buttery, P. J., Essex, C. P. and Soar, J. B. 1992. Evaluation of the isotope dilution technique for determining ileal endogenous nitrogen excretion in the rat. Journal of the Science of Food and Agriculture 58: 165172.CrossRefGoogle Scholar
Moughan, P. J., Darragh, A. J., Smith, W. C. and Butts, C. A. 1990. Perchloric and trichloroacetic acids as precipitants of protein in endogenous ileal digesta from the rat. Journal of the Science of Food and Agriculture 52: 1321.Google Scholar
Moughan, P. J., Souffrant, W. B. and Hodgkinson, S. M. 1998. Physiological approaches to determining gut endogenous amino acid flows in the mammal. Archives of Animal Nutrition 51: 237252.Google Scholar
Muramatsu, T., Coates, M. E., Hewitt, D., Salter, D. N. and Garlick, P. J. 1983. The influence of the gut microflora on protein synthesis in liver and jejunal mucosa in chicks. British Journal of Nutrition 49: 453462.Google Scholar
Muztar, A. J. and Slinger, S. J. 1981. A comparison of the true and apparent metabolizable energy measures using corn and soybean meal samples. Poultry Science 60: 611616.Google Scholar
National Research Council. 1994. Nutrient requirements of poultry, ninth revised edition. National Academy Press, Washington, DC.Google Scholar
Nieto, R., Palmer, R. M., Fernández-Fígares, I., L., Pérez and Prieto, C. 1994. Effect of dietary protein quality, feed restriction and short-term fasting on protein synthesis and turnover in tissues of growing chickens. British Journal of Nutrition 72: 499507.Google Scholar
Nyachoti, C. M., Lange, C. F. M. de, McBride, B. W., Leeson, S. and Gabert, V. M. 2000. Endogenous nitrogen losses in growing pigs were not caused by increased protein synthesis rates in the small intestine. Journal of Nutrition 130: 566572.Google Scholar
Nyachoti, C. M., Lange, C. F. M. de, McBride, B. W. and Schulze, H. 1997. Significance of endogenous gut nitrogen losses in the nutrition of growing pigs: a review. Canadian Journal of Animal Science 77: 149163.CrossRefGoogle Scholar
Parsons, C. M., Potter, I. M. and Brown, R. D. 1983. Effects of dietary carbohydrate and of intestinal microflora on excretion of endogenous amino acids by poultry. Poultry Science 62: 483489.Google Scholar
Pérez, L., Fernández-Figares, I., Nieto, R., Aguilera, J. F. and Prieto, C. 1993. Amino acid ileal digestibility of some grain legume seeds in growing chickens. Animal Production 56: 261267.Google Scholar
Ravindran, V. and Bryden, W. L. 1999. Amino acid availability in poultry — in vitro and in vivo measurements. Australian Journal of Agricultural Research 50: 889908.Google Scholar
Ravindran, V., Hew, L. I., Ravindran, G. and Bryden, W. L. 1999. A comparison of ileal digesta and excreta analysis for the determination of amino acid digestibility in food ingredients for poultry. British Poultry Science 40: 266274.Google Scholar
Reeds, P. J., Nicholson, B. A. and Fuller, M. F. 1985. Contribution of protein synthesis to energy expenditure in vivo and in vitro. In Energy metabolism of farm animals (ed. Moe, P. W., Tyrrell, H. F. and Reynolds, P. J.). Proceedings of the 10th European Association for Animal Production, pp. 6–9.Google Scholar
Reynolds, C. K., Tyrrell, H. F. and Reynolds, P. J. 1991. Effects of diet forage-to-concentrate ratio and intake on energy metabolism in growing beef heifers: whole body energy and nitrogen balance and visceral heat production. Journal of Nutrition 121: 9941003.Google Scholar
Schmitz, M., Hagemeister, H. and Erbersdobler, H. F. 1991. Homoarginine labeling is suitable for determination of protein absorption in miniature pigs. Journal of Nutrition 121: 15751580.Google Scholar
Sibbald, I. R. 1987. Estimation of bioavailable amino acids in feedingstuffs for poultry and pigs: a review with emphasis on balance experiments. Canadian Journal of Animal Science 67: 221300.Google Scholar
Siriwan, P., Bryden, W. L. and Annison, E. F. 1994. Use of guanidinated dietary protein to measure losses of endogenous amino acid in poultry. British Journal of Nutrition 71: 515529.Google Scholar
Siriwan, P., Bryden, W. L., Mollah, Y. and Annison, E. F. 1993. Measurement of endogenous amino acid losses in poultry. British Poultry Science 34: 939949.CrossRefGoogle ScholarPubMed
Statistical Analysis Systems Institute. 1985. User’s guide. SAS Institute, Cary, NC.Google Scholar
Summers, J. D. and Leeson, S. 1985. Broiler carcass composition as affected by amino acid supplementation. Canadian Journal of Animal Science 65: 717723.Google Scholar
Terpstra, K. 1978 Total and digestible amino acids. Proceedings of the second European symposium on poultry nutrition (ed. Kan, C. A. and Simmons, P. C. M.), pp. 97101. Beekbergen, The Netherlands.Google Scholar
Yamazaki, M. 1983. A comparison of two methods in determining amino acid availability of feed ingredients. Japanese Journal of Zootechnical Science 54: 1724.Google Scholar