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Prospects for the use of genetically modified crops with improved nutritional properties as feed materials in poultry nutrition

Published online by Cambridge University Press:  18 November 2011

S. SWIATKIEWICZ*
Affiliation:
Department of Animal Nutrition and Feed Science, National Research Institute of Animal Production, ul. Krakowska 1, 32-083 Balice, Poland
A. ARCZEWSKA-WŁOSEK
Affiliation:
Department of Animal Nutrition and Feed Science, National Research Institute of Animal Production, ul. Krakowska 1, 32-083 Balice, Poland
*
Corresponding author: [email protected]
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Abstract

Genetically modified (GM) plants constitute an increasingly significant part of the crops available on the feed market. To date, the most common GM plants have been those with enhanced agronomic traits. Known as ‘first-generation transgenic plants’, they are substantially equivalent to materials from conventional, parental plant lines. Recently, intensive experimental work using genetic engineering methods, have resulted in the production of transgenic plants with substantial changes in chemical composition, these are referred to as second-generation GM plants. The main objective of such transgenesis is to improve the nutritional properties of crops by increasing the level of desirable substances or decreasing the quantity of harmful compounds in the seeds. This review discusses the use of GM crops with enhanced nutritional properties as feed materials for poultry. On the basis of the information presented, it can be concluded that GM crops with improved nutritional value, enhanced available phosphorus content, an increased concentration of limiting amino acids, or containing genes expressing transgenic enzymes or antimicrobial substances could offer poultry producers considerable benefits.

Type
Review Article
Copyright
Copyright © World's Poultry Science Association 2011

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References

ADEOLA, O. (2005) Metabolizable energy and amino acid digestibility of high-oil maize, low-phytate maize and low-phytate soybean meal for White Pekin ducks. British Poultry Science 46: 607-614.CrossRefGoogle Scholar
ARMSTRONG, J.D., INGLIS, G.D., McALLISTER, T.A., KAWCHUK, L.M. and CHENG, K.J. (2002) Expression of a Fibrobacter succinogenes 1,3-1,4-β-glucanase in potato (Solanum tuberosum). American Journal of Potato Research 1: 39-48.CrossRefGoogle Scholar
BAAH, J., SCOTT, T.A., KAWCHUK, L.M., ARMSTRONG, J.D., SELINGER, L.B., CHENG, K.J. and McALLISTER, L.B. (2002) Feeding value in broiler chicken diets of potato expressing a glucanase gene from Fibrobacter succinogenes. Canadian Journal of Animal Science 82: 111-113.CrossRefGoogle Scholar
BEAGLE, J.M., APGAR, G.A., JONES, K.L., GRISWOLD, K.E., RADCLIFFE, J.S., QIU, X., LIGHTFOOT, D.A. and IQBAL, M.J. (2006) The digestive fate of Eschericha coli glutamate dehydrogenase dezoxyribonucleic acid from transgenic corn in diets fed to weanling pigs. Journal of Animal Science 84: 597-607.CrossRefGoogle Scholar
BOHME, H., RUDLOFF, E., SCHONE, F., SCHUMANN, W., HUTHER, L. and FLACHOWSKY, G. (2007) Nutritional assessment of genetically modified rapeseed synthesizing high amounts of mid-chain fatty acids including production responses of growing-finishing pigs. Archives of Animal Nutrition 61: 308-316.CrossRefGoogle ScholarPubMed
BRINCH-PEDERSEN, H., HATZACK, F., STOGER, E., ARCALIS, E., PONTOPIDAN, K. and HOLM, P.B. (2006) Heat-stable phytases in transgenic wheat (Triticum aestivum L.): deposition pattern, thermostability, and phytate hydrolysis. Journal Agricultural and Food Chemistry 54: 4624-4632.CrossRefGoogle ScholarPubMed
CEYLAN, N., SCHEIDELER, S.E. and STILBORN, H.L. (2003) High available phosphorus corn and phytase in layer diets. Poultry Science 82: 789-795.CrossRefGoogle ScholarPubMed
CHENG-CHIH, T., CHIEH-HSIEN, L., CHI-SHENG, Y., CHIEN-KU, L. and HAU-YANG, T. (2008) Toxicological evaluation of transgenic rice flour with an Escherichia coli phytase gene appA by subchronic feeding study in Wistar rats. Journal of the Science of Food and Agriculture 88: 382-388.Google Scholar
DENBOW, M.B., GRABAU, E.A., LACY, G.H., KORNEGAY, E.T., RUSSELL, D.R. and UMBECK, P.F. (1998) Soybeans transformed with a fungi phytase gene improve phosphorus availability for broilers. Poultry Science 77: 878-881.CrossRefGoogle ScholarPubMed
DILGER, R.N. and ADEOLA, O. (2006) Estimation of true phosphorus digestibility and endogenous phosphorus loss in growing chickens fed conventional and low-phytate soybean meals. Poultry Science 85: 661-668.CrossRefGoogle ScholarPubMed
DOUGLAS, M.W., PETER, C.M., BOILING, S.D., PARSONS, C.M. and BAKER, D.H. (2000) Nutritional evaluation of low phytate and high protein corn. Poultry Science 79: 1586-1591.CrossRefGoogle Scholar
DRAKAKAKI, G., MARCEL, S., GLAHN, R.P., LUND, E.K., PARIAGH, S., FISCHER, R., CHRISTOU, P. and STOGER, E. (2005) Endosperm-specific co-expression of recombinant soybean ferritin and Aspergillus phytase in maize results in significant increases in the levels of bioavailable iron. Plant Molecular Biology 59:869-880.CrossRefGoogle ScholarPubMed
EDWARDS, H.M., DOUGLAS, M.W., PARSONS, C.M. and BAKER, D.H. (2000) Protein and energy evaluation of soybean meals processed from genetically modified high-protein soybeans. Poultry Science 79: 525-527.CrossRefGoogle ScholarPubMed
FLACHOWSKY, G., CHESSON, A. and AULRICH, K. (2005) Animal nutrition with feeds from genetically modified plants. Archives of Animal Nutrition 59: 1-4.CrossRefGoogle ScholarPubMed
FLACHOWSKY, G., AULRICH, K., BOHME, H. and HALLE, I. (2007) Studies on feeds from genetically modified plants (GMP) - Contributions to nutritional and safety assessment. Animal Feed Science and Technology 133: 2-30.CrossRefGoogle Scholar
FLACHOWSKY, G. (2010) Prospective of genetically modified feeds for livestock production. Animal Nutrition and Feed Technology 10: 1-10.Google Scholar
GUTHRIE, T.A., APGAR, G.A., GRISWOLD, K.E., LINDEMANN, M.D., RADCLIFFE, J.S. and JACOBSON, B.N. (2004) Nutritional value of a corn containing a glutamate dehydrogenase gene for growing pigs. Journal of Animal Science 82: 1693-1698.CrossRefGoogle ScholarPubMed
HAMMOND, B.G., VICINI, J.L., HARTNELL, G.F., NAYLOR, M.W., KNIGHT, C.D., ROBINSON, E.H., FUCHS, R.L. and PADGETTE, S.R. (1996) The feeding value of soybeans fed to rats, chickens, catfish and dairy cattle is not altered by genetic incorporation of glyphosate tolerance. Journal of Nutrition 126: 717-727.CrossRefGoogle Scholar
HE, , X, Y., TANG, M.Z., LUO, Y.B., LI, X., CAO, S.S., YU, J.J., DELANEY, B. and HUANG, K.L. (2009) A 90-day toxicology study of transgenic lysine-rich maize grain (Y642) in Sprague-Dawley rats. Food and Chemical Toxicology 47: 425-432.CrossRefGoogle ScholarPubMed
HILL, B.E., SUTTON, A.L. and RICHERT, B.T. (2009) Effects of low-phytic acid corn, low-phytic acid soybean meal, and phytase on nutrient digestibility and excretion in growing pigs. Journal of Animal Science 87: 1518-1527.CrossRefGoogle ScholarPubMed
HU, Y., LI, M., PIAO, J. and YANG, X. (2010) Nutritional evaluation of genetically modified rice expressing human lactoferrin gene. Journal of Cereal Science 52: 350-355.CrossRefGoogle Scholar
HUMPHREY, B.D., HUANG, N. and KLASING, K.C. (2002) Rice expressing lactoferrin and lysozyme has antibiotic-like properties when fed to chicks. Journal of Nutrition 132: 1214-1218.Google ScholarPubMed
JAMES, C. (2011) Global Status of Commercialized Biotech/GM Crops: 2010. ISAAA Brief 42-2010. International Service for the Acquisition of Agri-biotech Applications.Google Scholar
LI, Y.C., LEDOUX, D.R., VEUM, T.L., RABOY, V. and ERTL, D.S. (2000) Effects of low phytic acid corn on phosphorus utilization, performance, and bone mineralization in broiler chicks. Poultry Science 79: 1444-1450.CrossRefGoogle ScholarPubMed
LINARES, L.B., BROOMHEAD, J.N., GUAIUME, E.A., LEDOUX, D.R., VEUM, T.L. and RABOY, V. (2007) Effects of low phytate barley (Hordeum vulgare L.) on zinc utilization in young broiler chicks. Poultry Science 86: 299-308.CrossRefGoogle Scholar
LUCAS, D.M., TAYLOR, M.L., HARTNELL, G.F., NEMETH, M.A., GLENN, K.C. and DAVIS, S.W. (2007) Broiler performance and carcass characteristics when fed diets containing lysine maize (LY038 or LY038 x MON, or commercial 810), control, or conventional reference maize. Poultry Science 86: 2152-2161.CrossRefGoogle ScholarPubMed
McNAUGHTON, J., ROBERTS, M., SMITH, B., RICE, D., HINDS, M., SANDERS, C., LAYTON, R., LAMBS, I. and DELANEY, B. (2008) Comparison of broiler performance when diets containing event DP3O5423-1, nontransgenic near-isoline control, or commercial reference soybean meal, hulls, and oil. Poultry Science 87: 2549-2561.CrossRefGoogle ScholarPubMed
MEJIA, L., JACOBS, C.M., UTTERBACK, P.L., PARSONS, C.M., RICE, D., SANDESRS, C., SMITH, B., IIAMS, C. and SMITH, B. (2010) Evaluation of soybean meal with the genetically modified output trait DP-3O5423-1 when fed to laying hens.2010 International Poultry Science Forum, January 25-26, 2010, Abstract P227.Google Scholar
NELSON, T.S., FERRARA, L.W. and STORER, N.L. (1968) Phytate phosphorus content of feed ingredients derived from plants. Poultry Science 47: 1372-1374.CrossRefGoogle ScholarPubMed
NYANNOR, E.K.D. and ADEOLA, O. (2008) Corn expressing an Escherichia coli-derived phytase gene: Comparative evaluation study in broiler chicks. Poultry Science 87: 2015-2022.CrossRefGoogle ScholarPubMed
NYANNOR, E.K.D., BEDFORD, M.R. and ADEOLA, O. (2009) Corn expressing an Escherichia coli-derived phytase gene: Residual phytase activity and microstructure of digesta in broiler chicks. Poultry Science 88: 1413-1420.CrossRefGoogle ScholarPubMed
O'QUINN, P.R., NELSSEN, J.L., GOODBAND, R.D., KNABE, D.A., WOODWORTH, J.C., TOKACH, M.D. and LOHRMANN, T.T. (2000) Nutritional value of a genetically improved high-lysine, high oil corn for young pigs. Journal of Animal Science 78: 2144-2149.CrossRefGoogle ScholarPubMed
PEDERSEN, C., BOERSMA, M.G. and STEIN, H.H. (2007) Energy and nutrient digestibility in NutriDense corn and other cereal grains fed to growing pigs. Journal of Animal Science 85: 2473-2483.CrossRefGoogle ScholarPubMed
PEN, J., VERWOERD, T.C., VAN PARIDON, P.A., BEUDEKER, R.F., VAN DEN ELZEN, P.J.M., GEERSE, K., VAN DER KLIS, J.D., VERSTEEGH, H.A.J., VAN OOYEN, A.J.J. and HOEKEMA, A. (1993) Phytase-containing transgenic seeds as a novel feed additive for improved phosphorus utilization. Nature Biotechnology 11: 811-814.CrossRefGoogle Scholar
POWERS, W.J., FRITZ, E.R., FEHR, W. and ANGEL, R. (2006) Total and water-soluble phosphorus excretion from swine fed low-phytate soybeans. Journal of Animal Science 84: 1907-1915.CrossRefGoogle ScholarPubMed
RAVINDRAN, V., TABE, L.M., MOLVIG, L., HIGGINS, T.J.W. and BRYDEN, W.L. (2002) Nutritional evaluation of transgenic high-methionine lupins (Lupinus angustifolius) with broiler chickens. Journal of the Science of Food and Agriculture 82: 280-285.CrossRefGoogle Scholar
SALARMOINI, M., CAMPBELL, G.L., ROSSNAGEL, B.G. and RABOY, V. (2008) Nutrient retention and growth performance of chicks given low-phytate conventional or hullless barleys. British Poultry Science 49: 321-328.CrossRefGoogle ScholarPubMed
SANDS, J.S., RAGLAND, D., WILCOX, J.R. and ADEOLA, O. (2003) Relative bioavailability of phosphorus in low-phytate soybean meal for broiler chicks. Canadian Journal of Animal Science 83: 95-100.CrossRefGoogle Scholar
SEBASTIAN, S., TOUCHBURN, S.P. and CHAVEZ, E.R. (1998) Implications of phytic acid and supplemental microbial phytase in poultry nutrition: a review. World's Poultry Science Journal 54: 27-47.CrossRefGoogle Scholar
SNOW, J.L., DOUGLAS, M.W., BATAL, A.B., PERSIA, M.E., BIGGS, P.E. and PARSONS, C.M. (2003) Efficacy of high available phosphorus corn in laying hen diets. Poultry Science 82: 1037-1041.CrossRefGoogle ScholarPubMed
SWIATKIEWICZ, S., KORELESKI, J. and ZHONG, D.Q. (2001) The bioavailability of zinc from inorganic and organic sources in broiler chickens as affected by addition of phytase. Journal of Animal and Feed Sciences 10: 317-328.CrossRefGoogle Scholar
TAKADA, R. and OTSUKA, M. (2007) Effects of feeding high tryptophan GM-rice on growth performance of chickens. International Journal of Poultry Science 6: 524-526.CrossRefGoogle Scholar
TAYLOR, M.L., GEORGE, B., HYUN, Y., NEMETH, M.A., KARUNANANDAA, K., LOHRMANN, T.T. and HARTNELL, G.F. (2004) Broiler performance and carcass parameters of broiler fed diets containing lysine maize. Poultry Science 83 (Suppl. 1): 315 (Abstract).Google Scholar
TRUKSA, M., VRINTEN, P. and QIU, X. (2009) . Metabolic engineering of plants for polyunsaturated fatty acid production. Molecular Breeding 23: 1-11.CrossRefGoogle Scholar
UFAZ, S. and GALILI, G. (2008) Improving the content of essential amino acids in crop plants: goals and opportunities. Plant Physiology 147: 954-961.CrossRefGoogle ScholarPubMed
VENEGAS-CALERON, M., SAYANOVA, O. and NAPIER, J.A. (2010) An alternative to fish oils: Metabolic engineering of oil-seed crops to produce omega-3 long chain polyunsaturated fatty acids. Progress in Lipid Research 49: 108-119.CrossRefGoogle ScholarPubMed
VON WETTSTEIN, D., MIKHAYLENKO, G., FROSETH, J.A. and KANNANGARA, C.G. (2000) Improved barley broiler feed with transgenic malt containing heat-stable (1,3-1,4)-β-glucanase. Proceedings of the National Academy of Sciences USA 97: 13512-13517.CrossRefGoogle Scholar
VON WETTSTEIN, D., WARNER, J. and KANNANGARA, C.G. (2003) Supplements of transgenic malt or grain containing (1,3-1,4)-β-glucanase increase the nutritive value of barley-based broiler diets to that of maize. British Poultry Science 44: 438-449.CrossRefGoogle ScholarPubMed
WAKASA, K., HASEGAWA, H., NEMOTO, H., MATSUDA, F., MIYAZAWA, H., TOZAWA, Y., MORINO, K., KOMATSU, A., YAMADA, T., TERAKAWA, , T, and MIYAGAWA, H. (2006) High-level tryptophan accumulation in seeds of transgenic rice and its limited effects on agronomic traits and seed metabolite profile. Journal of Experimental Botany 57: 3069-3078.CrossRefGoogle ScholarPubMed
WALDROUP, P.W., KERSEY, J.H., SALEH, E.A., FRITTS, C.A., YAN, F., STILLBORN, H.L., JrCRUM, R.C. and RABOY, V. (2000) Nonphytate phosphorus requirements and phosphorus excretion of broiler chicks fed diets composed of normal or high available phosphate corn with and without phytase. Poultry Science 79: 1451-1459.CrossRefGoogle ScholarPubMed
YAN, F., KERSEY, J.H., FRITTS, C.A., WALDROUP, P.W., STILBORN, H.L., JrCRUM, D.C., RICE, D.W. and RABOY, V. (2000) Evaluation of normal yellow dent corn and high available phosphorus corn in combination with reduced dietary phosphorus and phytase supplementation for broilers grown to market weights in litter pens. Poultry Science 79: 1282-1289.CrossRefGoogle ScholarPubMed
ZHANG, Z.B., KORNEGAY, E.T., RADCLIFFE, J.S., DENBOW, D.M., VEIT, H.P. and LARSEN, C.T. (2000a) Comparison of genetically engineered microbial and plant phytase for young broilers. Poultry Science 79: 709-717.CrossRefGoogle ScholarPubMed
ZHANG, Z.B., KORNEGAY, E.T., RADCLIFFE, J.S, WILSON, J.H. and VEIT, H.P. (2000b) Comparison of phytase from genetically engineered Aspergillus and canola in weanling pig diets. Journal of Animal Science 78: 2868-2878.CrossRefGoogle ScholarPubMed