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Alternative ingredients for providing adequate methionine in organic poultry diets in the United States with limited synthetic amino acid use

Published online by Cambridge University Press:  04 September 2015

H.K. BURLEY*
Affiliation:
Department of Animal Science, The Pennsylvania State University, University Park, PA, USA
P.H. PATTERSON
Affiliation:
Department of Animal Science, The Pennsylvania State University, University Park, PA, USA
K.E. ANDERSON
Affiliation:
Prestage Department of Poultry Science, North Carolina State University, Raleigh, NC, USA
*
Corresponding author: [email protected]
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Abstract

Synthetic methionine use is currently limited to 1 kg and 1.5 kg per metric tonne (2, 2, and 3 lbs per short ton) of feed for organic laying hens, broilers, and turkeys and other poultry, respectively, in the United States of America. All other synthetic amino acids (AA) have been banned from use in organic poultry diets in this country. It is challenging to provide sufficient methionine (Met) to maintain bird growth and productive performance up to current industry standards given the recent restrictions that have been placed on synthetic Met. Without synthetic AA, Met requirements can alternatively be obtained for organic poultry by dramatically increasing dietary crude protein (CP) e.g. via additional inclusion of expeller-pressed soybean meal to the diets. However, this strategy leads to both major increases in feed costs and environmental concerns due to increasing nitrogen excretion, with concurrent rises in ammonia emissions, and corresponding welfare issues due to ammonia and litter quality. This review aims to examine feed ingredients that may contribute to a solution to this issue. Otherwise, further negative impacts may soon be felt from the current limitation on synthetic Met or a potential ban on its entire use in the future.

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Reviews
Copyright
Copyright © World's Poultry Science Association 2015 

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References

AMBROSEN, T. and PETERSEN, V. (1997) The influence of protein level in the diet on cannibalism and quality of plumage of layers. Poultry Science 76: 559-563.CrossRefGoogle ScholarPubMed
AL-HARTHI, M.A., EL-DEEK, A.A. and ATTIA, Y.A. (2011) Impacts of dried whole eggs on productive performance, quality of fresh and stored eggs, reproductive organs and lipid metabolism of laying hens. British Poultry Science 52: 333-344.CrossRefGoogle ScholarPubMed
ALMQUIST, H.J. (1946) Proteins and Amino Acids, in: Animal Nutrition: Revised Edition, pp. 1-5 (F. E. Booth Co., Inc., San Francisco, CA, USA).Google Scholar
ANDERSON, D.M., MACISAAC, J.L. and SAFAMEHR, A. (2012) Dilution of broiler chicken diets with whole hulless barley. Journal of Applied Poultry Research 21: 399-406.CrossRefGoogle Scholar
ANNISON, G. and CHOCT, M. (1991) Anti-nutritive activities of cereal non-starch polysaccharides in broiler diets and strategies minimizing their effects. World's Poultry Science Journal 47: 232-242.CrossRefGoogle Scholar
BALLOUN, S.L. (1962) Lysine, Arginine and Methionine Balance of Diets for Turkeys to 24 Weeks of Age. Poultry Science 41: 417-424.CrossRefGoogle Scholar
BANJO, A.D., LAWAL, O.A. and SONGONUGA, E.A. (2006) The nutritional value of fourteen species of edible insects in southwestern Nigeria. African Journal of Biotechnology 5 (3): 289-301.Google Scholar
BLAIR, R. (2008) Nutrition and feeding of organic poultry. CABI, Wallingford, UK.CrossRefGoogle Scholar
BURLEY, H.K. (2009) Effects of reduced crude protein, amino acid balanced diets on performance, economics, and ammonia emission in a large-scale commercial laying hen flock. M.S. Thesis, The Pennsylvania State University, USA.Google Scholar
BURLEY, H.K. (2012) Enrichment of methionine from naturally concentrated feedstuffs for use in organic poultry diets. Ph.D. Thesis, The Pennsylvania State University, USA.Google Scholar
BURLEY, H.K. (2013) Organic livestock production challenges in the United States given current dietary ingredient restrictions. Proceedings of the 11th Mid-Atlantic Nutrition Conference, Timonium, MD, USA.Google Scholar
BURTON, J.W., PURCELL, A.E. and WALTER, W.M. Jr. (1982) Methionine concentration in soybean protein from populations selected for increased percent protein. Crop Science 22: 430-432.CrossRefGoogle Scholar
CAREW, L.B., MCMURTRY, J.P. and ALSTER, F.A. (2003) Effects of methionine deficiencies on plasma levels of thyroid hormones, insulin-like growth factors-I and -II, liver and body weights, and feed intake in growing chickens. Poultry Science 82: 1932-1938.CrossRefGoogle ScholarPubMed
CHANDRA, M., SINGH, B., SONI, G.L. and AHUJA, S.P. (1984) Renal and biochemical changes produced in broilers by high-protein, high-calcium, urea-containing, and vitamin-A-deficient diets. Avian Diseases 28 (1): 1-11.CrossRefGoogle Scholar
CHATTOPADHYAY, K., MONDAL, M.K. and ROY, B. (2006) Comparative efficacy of DL-methionine and herbal methionine on performance of broiler chicken. International Journal of Poultry Science 5 (11): 1034-1039.Google Scholar
CHRISTMAS, R.B. and HARMS, R.H. (1979) The effect of supplemental copper and methionine on the performance of turkey poults. Poultry Science 58 (2): 382-384.CrossRefGoogle Scholar
COATS, P.M. (2005) Encyclopedia of dietary supplements. ISBN 0-8247-5504-9.Google Scholar
CORZO, A., KIDD, M.T., DOZIER III, W.A., SHACK, L.A. and BURGESS, S.C. (2006) Protein expression of pectoralis major muscle in chickens in response to dietary methionine status. British Journal of Nutrition 95: 703-708.CrossRefGoogle ScholarPubMed
DEFOLIART, G. (1992) Insects as human food. Crop Protection 11: 395-399.CrossRefGoogle Scholar
DEGUSSA (1990) The amino acid composition of feedstuffs. Degussa Corp. (Allendale, NJ, USA).Google Scholar
DESPINS, J.L. and AXTELL, R.C. (1994) Feeding behavior and growth of turkey poults fed larvae of the darkling beetle. Poultry Science 73: 1526-1533.CrossRefGoogle ScholarPubMed
DIARRA, S.S. and USMAN, B.A. (2008) Performance of laying hens fed graded levels of soaked sesame (Sesamum indicum) seed meal as a source of methionine. International Journal of Poultry Science 7: 323-327.CrossRefGoogle Scholar
EL BOUSHY, A.R.Y. and VAN DER POEL, A.F.B. (2000) Handbook of poultry feed from waste. 2nd ed. Kluwer Academic Publishers, Dordrecht, The Netherlands.CrossRefGoogle Scholar
EVONIK INDUSTRIES (2010) AminoDat 4.0 Platinum Version, Germany.Google Scholar
ELWINGER, K., TUFVESSON, M., LAGERKVIST, G. and TAUSON, R. (2008) Feeding layers of different genotypes in organic feed environments. British Poultry Science 49: 654-665.CrossRefGoogle ScholarPubMed
FANATICO, A. (2010) Organic poultry production: providing adequate methionine. ATTRA-National Sustainable Agriculture Information Service, 19 pp. USDA ARS.Google Scholar
FINKE, M.D., SUNDE, M.L. and DEFOLIART, G.R. (1985) An evaluation of the protein quality of Mormon crickets (Anabrus simplex Haldeman) when used as a high protein feedstuff for poultry. Poultry Science 64: 708-712.CrossRefGoogle Scholar
FINKE, M.D. (2004) Encyclopedia of Entomology. Amino Acid Content of selected insect species. Kluwer Academic Pub., Boston, MA, USA. ISBN 0-7923-8670-1, pp: 1562-1575.Google Scholar
FOSGATE, O.T. and BABB, M.R. (1972) Biodegradation of animal waste by Lumbricus terrestris. Journal of Dairy Science 55: 870-872.CrossRefGoogle ScholarPubMed
FRY, J.L., VANWALLEGHEM, P., WALDROUP, P.W. and HARMS, R.H. (1965) Fish meal studies: 2. Effects of levels and sources on ‘fishy flavor’ in broiler meat. Poultry Science 44: 1016-1019.CrossRefGoogle ScholarPubMed
GERPACIO, A.L. and CASTILLO, L.S. (1979) Nutrient composition of some Philippine feedstuffs. Extension Division, Department of Animal Science, College of Agriculture, University of the Philippines at Los Baños, Laguna 21 (4): 117.Google Scholar
GISH, C.D. and CHRISTENSEN, R.E. (1973) Cadmium, nickel, lead, and zinc in earthworms from roadside soil. Environmental Science and Technology 7: 1060-1061.CrossRefGoogle ScholarPubMed
GOMES, J. and KUMAR, D. (2005) Production of L-methionine by submerged fermentation: A review. Enzyme and Microbial Technology 37: 3-18.CrossRefGoogle Scholar
GONZALES-ESQUERRA, R., VÁZQUEZ-AÑÓN, M., HAMPTON, T., YORK, T., FEINE, S., WUELLING, C. and KNIGHT, C. (2007) Evidence of a different dose response in turkeys when fed 2-hydroxy-4(methylthio) butanoic acid versus DL-methionine. Poultry Science 86 (3): 517-524.CrossRefGoogle Scholar
HALDER, G. and ROY, B. (2007) Effect of herbal or synthetic methionine on performance, cost benefit ratio, meat and feather quality of broiler chicken. International Journal of Agricultural Research 2 (12): 987-996.CrossRefGoogle Scholar
HARTENSTEIN, R., NEUHAUSER, E.F. and COLLIER, J. (1980) Accumulation of heavy metals in the earthworm Eisenia foetida. Journal of Environmental Quality 9: 23-26.CrossRefGoogle Scholar
IGBASAN, F.A., IBRAHIM, A.M. and OSHO, B.I. (2012) Comparative efficacy of herbal and synthetic methionine on performance of some haematological and biochemical parameters in domestic laying hens. African Journal of Biotechnology 11 (46): 10617-10625.Google Scholar
IGBASAN, F.A. and OLUGOSI, O.A. (2013) Performance characteristics, biochemical and haematological profiles of broiler chickens fed synthetic and herbal methionine supplemented diets. African Journal of Food Science 7 (6): 159-167.CrossRefGoogle Scholar
JACOB, J.P., LEVENDOSKI, N. and GOLDSTEIN, W. (2008) Inclusion of high methionine corn in pullet diets. Journal of Applied Poultry Research 17: 440-445.CrossRefGoogle Scholar
JACOB, J. (2013) Synthetic Methionine and Organic Poultry Diets. E-extension; Organic Agriculture. http://www.extension.org/pages/69042/synthetic-methionine-and-organic-poultry-diets#.UkQ4z_LD9D9. Accessed: August 27, 2013.Google Scholar
JANSSEN, W.M.M.A. (1971) The influence of feeding on gizzard erosion in broilers. Archiv für Geflügelkunde 4: 137.Google Scholar
KALBANDE, V.H., RAVIKANTH, K., MAINI, S. and REKHE, D.S. (2009) Methionine supplementation options in poultry. International Journal of Poultry Science 8: 588-591.CrossRefGoogle Scholar
KITAMURA, K. and KAIZUMA, N. (1981) Mutant strains with low level of subunits of 7S globulin in soybean (Glycine max Merr.) seed. Japanese Journal of Breeding 31: 353-359.Google Scholar
KOEHLER, H.H. and BEARSE, G.E. (1975) Egg flavor quality as affected by fish meals or fish oils in laying rations. Poultry Science 54: 881.CrossRefGoogle Scholar
LECLERCQ, B. (1983) The influence of dietary protein content on the performance of genetically lean or fat growing chickens. British Poultry Science 24: 581-587.CrossRefGoogle ScholarPubMed
LIANG, Y., XIN, H., WHEELER, E.F., GATES, R.S., LI, H., ZAJACZKOWSKI, J.S., TOPPER, P.A., CASEY, K.D., BEHRENDS, B.R., BURNHAM, D.J. and ZAJACZKOWSKI, F.J. (2005) Ammonia emissions from U.S. laying hen houses in Iowa and Pennsylvania. ASABE 48: 1927-1941.CrossRefGoogle Scholar
MAST, M.G., LEACH, R.M. and MACNEIL, J.H.. (1984) Performance, composition, and quality of broiler chickens fed dried whole eggs. Poultry Science 63: 1940-1945.CrossRefGoogle Scholar
MAURICE, D.V., JONES, J.E., HALL, M.A., CASTALDO, D.J., WHISENHUNT, J.E. and MCCONNELL, J.C. (1985) Chemical composition and nutritive value of naked oats (Avena nuda L.). Poultry Science 64: 529-535.CrossRefGoogle Scholar
MCINORY, D.M. (1971) Evaluation of earthworm Eisenia foetida as a food for man and domestic animals. Feedstuffs 43: 37-46.Google Scholar
MEHRI, M., POURREZA, J. and SADEGHI, G. (2010) Replacing maize with pearl millet in laying hens’ diets. Tropical Animal Health and Production 42: 439-444.CrossRefGoogle ScholarPubMed
MELUZZI, A., SIRRI, F., TALLARICO, N. and FRANCHINI, A. (2001) Nitrogen retention and performance of brown laying hens on diets with different protein content and constant concentration of amino acids and energy. British Poultry Science 42: 213-217.CrossRefGoogle ScholarPubMed
NRC (1994) Nutrient Requirements of Poultry. 9th rev. ed. National Academy Press, Washington, D.C., USA.Google Scholar
PESTI, G.M. (2009) Impact of dietary amino acid and crude protein levels in broiler feeds on biological performance. Journal of Applied Poultry Research 18: 477-486.CrossRefGoogle Scholar
PETER, C.M., HAN, Y., BOLING-FRANKENBACH, S.D., PARSONS, C.M. and BAKER, D.H. (2000) Limiting order of amino acids and the effects of phytase on protein quality in corn gluten meal fed to young chicks. Journal of Animal Science 78: 2150-2156.CrossRefGoogle ScholarPubMed
RAO, R.S.V., NAGALAKSHMI, D. and RAJU, M.V.L.N. (2005) Sunflower seed meal in poultry diets. Feed Mix 13: 28-30.Google Scholar
RAVINDRAN, V. and BLAIR, R. (1992) Feed resources for poultry production in Asia and the Pacific. II. Plant protein sources. World's Poultry Science Journal 49: 219-235.CrossRefGoogle Scholar
REMBRANT ENTERPRISES INC. (2010) Ovabind RSD 80: product specification sheet.Google Scholar
REMBRANT ENTERPRISES INC. (2012) Spray dried high protein egg product RSD 65: product specification sheet.Google Scholar
ROBERTS, S.A., XIN, H., KERR, B.J., RUSSELL, J.R. and BREGENDAHL, K. (2007) Effects of dietary fiber and reduced crude protein on ammonia emission from laying hen manure. Poultry Science 86: 1625-1632.CrossRefGoogle ScholarPubMed
ROMERO, B.A., BOU-MAROUN, E., REPARET, J.M., BLANQUET, J. and CAYOT, N. (2009) Impact of lipid extraction on the dearomatisation of an Eisenia foetida protein powder. Food Chemistry 119: 459-466.CrossRefGoogle Scholar
SABINE, J.R. (1981) Vermiculture as an option for resource recovery in the intensive animal industries. Pages 241-252 in Workshop on the role of earthworms in the stabilization of organic residues (M. Appelhof, Compiler). Kalamazoo, MI, USA.Google Scholar
SALOME, I., DAFWANG, I.I. and BAWA, G.S. (2010) Evaluation of Methiorep as a substitute for methionine in broiler diets. International Journal of Poultry Science 9 (8): 809-812.CrossRefGoogle Scholar
SCHUTTE, J.B., VAN WEERDEN, E.J. and BERTRAM, H.L. (1983) Sulphur amino acid requirement of laying hens and the effects of excess dietary methionine on laying performance. British Poultry Science 24: 319-326.CrossRefGoogle ScholarPubMed
SHAFER, D.J., CAREY, J.B. and PROCHASKA, J.F. (1996) Effect of dietary methionine intake on egg component yield and composition. Poultry Science 75: 1080-1085.CrossRefGoogle ScholarPubMed
SHARIFI, S.D., SHARIATMADARI, F. and YAGHOBFAR, A. (2012) Effects of inclusion of hull-less barley and enzyme supplementation of broiler diets on growth performance, nutrient digestion, and dietary metabolisable energy content. Journal of Central European Agriculture 13: 193-207.CrossRefGoogle Scholar
SUN, S.M., LEUNG, F.W. and TOMIC, J.C. (1987) Brazil nut (Bertholletia excelsa HBK) proteins: fractionation, composition, and identification of a sulfur-rich protein. Journal of Agricultural and Food Chemistry 35: 232-235.CrossRefGoogle Scholar
TABOGA, L. (1980) The nutritional value of earthworms for chickens. British Poultry Science 21: 405-410.CrossRefGoogle Scholar
TERAISHI, M., TAKAHASHI, M., HAJIKA, M., MATSUNAGA, R., UEMATSU, Y. and ISHIMOTO, M. (2001) Suppression of soybean β-conglycinin genes by a dominant gene, Scg-1. Theoretical and Applied Genetics 103: 1266-1272.CrossRefGoogle Scholar
USDA (2012a) USDA AMS National Organic Program. http://www.ams.usda.gov/nop Accessed Sept. 2012.Google Scholar
USDA (2012b) National list of allowed and prohibited substances. Electronic Code of Federal Regulations: Part 205 - National Organic Program. USA?Google Scholar
USDA (2012c) National organic program; amendment to the national list of allowed and prohibited substances (livestock). Federal Register 77:57985-57990.Google Scholar
USDA (2012d) National Nutrient Database for Standard Reference. Agricultural Research Service, U.S. Department of Agriculture, Washington, D.C.Google Scholar
VENKATACHALAM, M. and SATHE, S.K. (2006) Chemical composition of selected edible nut seeds. Journal of Agricultural and Food Chemistry 54: 4705-4714.CrossRefGoogle ScholarPubMed
VIEIRA, S.L., LEMME, A., GOLDENBERG, D.B. and BRUGALLI, I. (2004) Responses of growing broilers to diets with increased sulfur amino acids to lysine ratios at two dietary protein levels. Poultry Science 83: 1307-1313.CrossRefGoogle ScholarPubMed
WARD, J.M. Jr, MCNABB, R.A. and MCNABB, F.M. (1975) The effects of changes in dietary protein and water availability on urinary nitrogen compounds in the rooster, Gallus domesticus - I. Urine flow and the excretion of uric acid and ammonia. Comp. Biochem. Physiology 51A: 165-169.Google Scholar
WASKAR, V., RAVIKANTH, K., MAINI, S. and REKHE, D.S. (2010) Effect of phytoadditive Methiorep on carcass and cooked meat quality attributes in chicken. Internet Journal of Veterinary Medicine 8: 1.Google Scholar
WILCOX, J.R. and SHIBLES, R.M. (2001) Interrelationships among seed quality attributes in soybean. Crop Science 41: 11-14.CrossRefGoogle Scholar
YUAN, J., KARIMI, A.J., GOODGAME, S.D., LU, C., MUSSINI, F.J. and WALDROUP, P.W. (2012) Evaluation of herbal methionine source in broiler diets. Journal of Poultry Science 11 (4): 247-250.Google Scholar