Hostname: page-component-cd9895bd7-8ctnn Total loading time: 0 Render date: 2024-12-23T19:47:53.110Z Has data issue: false hasContentIssue false

Transgenic plants in poultry nutrition

Published online by Cambridge University Press:  18 September 2007

A. Chesson*
Affiliation:
Rowett Research Institute, Aberdeen AB 21 95B, UK
G. Flachowsky
Affiliation:
Institute of Animal Nutrition, Federal Agricultural Research Centre (FAL), Bundesallee 50, 38116 Braunschweig, Germany
*
*Corresponding author: [email protected]
Get access

Abstract

Studies on genetically modified (GM) feedstuffs for poultry (and other livestock species) have not added any substance to public concerns in Europe about their safety for human or bird health. The compositions of maize lines engineered for insect resistance (Bt-maize) or herbicide tolerance (glyphosate) and herbicidetolerant soybean have all proved to be essentially indistinguishable from their conventional counterparts. Consequently, and not surprisingly, comparative feeding studies with broilers and layers in which conventional maize (50 to 78%) or soybeans (27%) were replaced in feeds by transgenic varieties, also have failed to show differences of any significance in production parameters. These data indicate that feeding studies with target livestock species contribute very little to the safety assessment of crops engineered for input traits that have little or no detectable effect on chemical composition. However, comparative growth studies made with broiler chicks, particularly sensitive to any change in nutrient supply or the presence of toxic elements in their feed, can be used to screen for any unintended adverse consequence of the recombinant event not detected by compositional analysis. This does, however, depend on whether the GM plant can be matched to a parental line or another suitable control and its suitability for inclusion in broiler diets. The discovery that DNA fragments from the digestive tract can be found in the tissues of animals evoked interest in the fate of ingested transgenes. Plant DNA derived from feed has been detected in the muscle, liver, spleen and kidneys of broilers and layers, although not in eggs. However, no fragments of transgenic DNA or its expressed protein have been found to date in poultry meat or eggs or in any other animal tissues examined.

Type
Reviews
Copyright
Copyright © Cambridge University Press 2003

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

references

Aeschbacher, K., Messikommer, R. and Wenk, K. (2001) Physiological characteristics of Bt 176-corn in poultry and destiny of recombinant plant DNA in poultry products. Annals of Nutrition and Metabolism 45 (Suppl. 1): 376.Google Scholar
Anon (2001) No traces of modified DNA in poultry fed on GM corn. Nature 409: 657.Google Scholar
Ash, J.A., Sceideler, E. and Novak, C.L. (2000) The fate of genetically modified protein from Roundup Ready®, soybeans in the laying hen. Poultry Science 79 (Suppl.1): 26.Google Scholar
Aulrich, K., Böhme, H., Daenicke, R., Halle, I. and Flachowsky, G. (2001) Genetically modified feeds (GMO) in animal nutrition. 1st Com.: Bacillus tkuringiensis (Bt) corn in poultry, pig and ruminant nutrition. Archives of Animal Nutrition 54: 183195.Google Scholar
Aumaitre, L.A., Aulrich, K., Chesson, A., Flachowsky, G. and Piva, G. (2002) New feeds from genetically modified plants. The European approach of substantial equivalence, digestibility nutritional value and safety for animals and the food chain. Livestock Production Science 74: 223238.Google Scholar
Baah, J., Scott, T.A., Kawchuk, L.M., Armstrong, J.D., Selinger, L.B., Cheng, K.J. and Mcallister, T.M. (2002) Feeding value in broiler chicken diets of a potato expressing a β-glncanase gene from Fibrobacter succinogenes. Canadian Journal of Animal Science 82, 111113.CrossRefGoogle Scholar
Brake, J. and Vlachos, D. (1998) Evaluation of transgenic event 176 [Bt] corn in broiler chickens. Poultry Science 77: 648653.CrossRefGoogle ScholarPubMed
Chambers, P.A., Duggart, P.S., Heritage, J. and Forbes, J.M. (2002) The fate of antibiotic resistance marker genes in transgenic plant material fed to chickens. Journal of Antimicrobia1 Chemotherapy 49: 161164.CrossRefGoogle ScholarPubMed
Einspanier, R., Klotz, A., Kraft, J., Aulrich, K., Poser, R., Schwägele, F., Jahreis, G. and Flachowsky, G. (2001) The fate of forage plant DNA in farm animals: A collaboration case-study investigating cattle and chicken fed recombinant material. European Food Research and Technology 212: 129134.CrossRefGoogle Scholar
Faust, M.A. (2000) Livestock products: composition and detection of transgenic DNA/proteins. Proc. Symp. Agri. Biotech. Market. ADAS-ASAS ed Baltimore, Md. USA. 29pp.Google Scholar
Faust, M.A. (2002) New feeds from genetically modified plants: the US approach to safety for animals and the food chain. Livestock Production Science 74: 239254.Google Scholar
Flachowsky, G. and Aulrich, K. (2001 ) Zum einsatz gentechnisch veränderter organismen (GVO) in der Tierernährnng. Übersichten zur Tierernährung 28: 4579.Google Scholar
Gaines, A.M., Allee, G.L. and Ratliff, B.W. (2001) Nutritional evaluation of Bt (MON 810) and Roundup Ready corn compared with commercial hybrids in broilers. J Anim. Sci. 79: Suppl. 1Google Scholar
Gaines, A.M., Allee, G.L. and Ratliff, B.W. (2001) Nutritional evaluation of Bt (MON 810) and Roundup Ready corn compared with commercial hybrids in broilers.J. Dairy Sci. 84, Suppl. 1Google Scholar
Gaines, A.M., Allee, G.L. and Ratliff, B.W. (2001) Nutritional evaluation of Bt (MON 810) and Roundup Ready corn compared with commercial hybrids in broilers. Poultry Sci. 80, Suppl. 1Google Scholar
Gaines, A.M., Allee, G.L. and Ratliff, B.W. (2001) Nutritional evaluation of Bt (MON 810) and Roundup Ready corn compared with commercial hybrids in broilers. 1/54th Annu. Rec. Meat Conf. Vol. 1151.Google Scholar
Hammond, B.G., Vincini, 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: 717727.Google Scholar
Hohlweg, U. and Doerfler, W. (2001) On the fate of plant or other foreign genes upon the uptake in food or after intramuscular injection in mice. Molecular Genetics and Genomics 265: 224233.Google Scholar
James, C. (2001) Global review of commercialised transgenic crops: 2001. ISAAA Briefs No 24, ISAAA, Ithaca, USA. (see http://www.isaaa.org for annual update).Google Scholar
Kan, C.A. and Petz, M. (2000) Residues of veterinary drugs in eggs and their distribution between yolk and white. Journal of Agricultural and Food Chemistry 48: 63976403.CrossRefGoogle ScholarPubMed
Kan, C.A., Versteegh, H.A.J., Uijttenboogaart, T.G., Reimert, H.G.M. and Hartnell, G.F. (2001) Comparison of broiler performance and carcass characteristics when fed Bt. parental control or commercial varieties of dehulled soybean meal. J. Atzim. Sci. 79: Suppl. 1Google Scholar
Kan, C.A., Versteegh, H.A.J., Uijttenboogaart, T.G., Reimert, H.G.M. and Hartnell, G.F. (2001) Comparison of broiler performance and carcass characteristics when fed Bt. parental control or commercial varieties of dehulled soybean meal. J. Dairy Sci. 84, Suppl. 1Google Scholar
Kan, C.A., Versteegh, H.A.J., Uijttenboogaart, T.G., Reimert, H.G.M. and Hartnell, G.F. (2001) Comparison of broiler performance and carcass characteristics when fed Bt. parental control or commercial varieties of dehulled soybean meal. Poultry Sci. 80: Suppl. 1Google Scholar
Kan, C.A., Versteegh, H.A.J., Uijttenboogaart, T.G., Reimert, H.G.M. and Hartnell, G.F. (2001) Comparison of broiler performance and carcass characteristics when fed Bt. parental control or commercial varieties of dehulled soybean meal. 1/54th Annu. Rec. Meat Conf. Vol. 11, 203.Google Scholar
Khumnirdpetch, V., Intarachote, U., Treemance, S., Tragoonroong, S. and Thummabood, S. (2001) Detection of GOMs in the broilers that utilized genetically modified soybean meals as a feed ingredient. Plant & Animal Genome TX Conference01, San Diego, USA (Poster 585).Google Scholar
Klotz, A., Mayer, J. and Einspanier, R. (2002) Degradation and possible carry over of feed DNA monitored in pigs and poultry. European Food Research and Technology 214: 271275.CrossRefGoogle Scholar
Mireles, A., Kim, S., Thompson, R. and Amundsen, B. (2000) GMO (Bt) corn is similar in composition and nutrient availability to broilers as non-GMO corn. Poultry Science 79 Suppl. 1, 65.Google Scholar
Molvig, L., Tabe, L.M., Eggum, B.O., Moore, A.E., Craig, S., Spencer, D. and Higgins, T.J.V. (1997) Enhanced methionine levels and increased nutritive value of seeds of transgenic lupins (Lupinus angustifolius L) expressing a sunflower seed albumin gene. Proceedings of the National Acadenmy of Science USA 94: 83938398.CrossRefGoogle ScholarPubMed
Munkvold, G.P. and Hellmich, R.L. (1999) Comparison of fumonisin concentrations in kernels of transgenic Bt maize hybrids and non transgenic hybrids. Plant Disease 83: 130138.CrossRefGoogle Scholar
Nikiforova, V., Kempa, S., Zeh, M., Maimann, S., Kreft, O., Casazza, A.P., Riedel, K., Tauberger, E., Hoefgen, R. and Hesse, H. (2002) Engineering of cysteine and methionine biosynthesis in potato. Amino Acids 22: 259278.Google Scholar
Piva, G., Morlacchini, M., Pietri, A., Rossi, F. and Grandini, A. (2001) Growth performance of broilers fed insect protected (MON810) or near isogenic control corn. J. Anim. Sri. 79 Suppl. 1Google Scholar
Piva, G., Morlacchini, M., Pietri, A., Rossi, F. and Grandini, A. (2001) Growth performance of broilers fed insect protected (MON810) or near isogenic control corn. J. Dairy Sci. 84, Suppl. 1Google Scholar
Piva, G., Morlacchini, M., Pietri, A., Rossi, F. and Grandini, A. (2001) Growth performance of broilers fed insect protected (MON810) or near isogenic control corn. Poultry Sci. 80: Suppl. 1Google Scholar
Piva, G., Morlacchini, M., Pietri, A., Rossi, F. and Grandini, A. (2001) Growth performance of broilers fed insect protected (MON810) or near isogenic control corn. 1/54th Annu. Rec. Meat Conf. Vol. 11, 320.Google Scholar
Schubbert, R., Renz, D. and Doerfler, W. (1997) Foreign (M13) DNA ingested by mice reaches peripheral leucocytes, spleen and liver via the intestinal wall mucosa and can be covalently linked to mouse DNA. Proceedings of the National Academy of Science 94: 961966.CrossRefGoogle ScholarPubMed
Schubbert, R., Hohlweg, U., Renz, D. and Doerfler, W. (1998) On the fate of orally ingested foreign DNA in mice: chromosomal association and placental transmission to the fetus. Molecular and General Genetics 259: 569576.CrossRefGoogle ScholarPubMed
Sldhu, R.S., Hammond, B.C. and Fuchs, R.L. (2000) Glyphosate — tolerant corn: The composition and feeding value of grain from glyphosate-tolerant corn is equivalent to that of conventional corn (Zen nzuys L.) Journal of Agricirlture and Food Chemistry 48: 23052312.Google Scholar
Spencer, J.D., Allee, G.L. and Sauder, T.E. (2000a) Phosphorus bioavailability and digestibility of normal and genetically modified low-phytate corn for pigs. Journal of Animal Science 78: 675681.CrossRefGoogle ScholarPubMed
Tony, M., Broll, H., Zagon, J., Halle, I., Faronk, F., Edris, B., Awadalla, S., BÖgi, K., Schauzu, M. and Flachowsky, G. (2002) Detection and impact of Bt 176 maize on broiler health and performance. Proceedings of the Society for Nutrition and Physiology II: 197.Google Scholar
Taylor, M.L., Hartnell, G.F., Nemeth, M.A., Georgge, B. and Astwood, J.D. (2001a) Comparison of broiler performance when fed containing YieldGard corn, YieldGard and Roundup Ready corn parental lines, or commercial corn. J. Anim. Sci. 79: Suppl. 1Google Scholar
Taylor, M.L., Hartnell, G.F., Nemeth, M.A., Georgge, B. and Astwood, J.D. (2001a) Comparison of broiler performance when fed containing YieldGard corn, YieldGard and Roundup Ready corn parental lines, or commercial corn. J. Dairy Sci. 84, Suppl. 1Google Scholar
Taylor, M.L., Hartnell, G.F., Nemeth, M.A., Georgge, B. and Astwood, J.D. (2001a) Comparison of broiler performance when fed containing YieldGard corn, YieldGard and Roundup Ready corn parental lines, or commercial corn. Poultry Sci. 80: Suppl. 1Google Scholar
Taylor, M.L., Hartnell, G.F., Nemeth, M.A., Georgge, B. and Astwood, J.D. (2001a) Comparison of broiler performance when fed containing YieldGard corn, YieldGard and Roundup Ready corn parental lines, or commercial corn. 1/54th Annu. Rec. Meat Conf. Vol. II, 319.Google Scholar
Taylor, M.L., Hartnell, G.F. and Cook, D.R. (2001b) Comparison of broiler performance when fed diets containing Roundup Ready corn event NK603, parental lines, or commercial corn. J. Anim. Sci. 79: Suppl. 1Google Scholar
Taylor, M.L., Hartnell, G.F. and Cook, D.R. (2001b) Comparison of broiler performance when fed diets containing Roundup Ready corn event NK603. parental line or commercial corn. J. Dairy Sci. 84, Suppl. 1Google Scholar
Taylor, M.L., Hartnell, G.F. and Cook, D.R. (2001b) Comparison of broiler performance when fed diets containing Roundup Ready corn event NK603. parental line or commercial corn. Poultry Sci. 80: Suppl. 1Google Scholar
Taylor, M.L., Hartnell, G.F. and Cook, D.R. (2001b) Comparison of broiler performance when fed diets containing Roundup Ready corn event NK603. parental line or commercial corn. 1/54th Annu. Rec. Meat Conf. Vol. II, 320.Google Scholar
Valenta, H., Daenicke, S., Flachowsky, G. and Böhme, T. (2001) Comparative studies on concentration of the Fusarium mycotoxins deoxynivalenol and zearalenone in kernels of transgenic Bt maize hybrids and non-transgenic hybrids. Proceedings of the Society for Nutrition and Physiology 10: 164.Google Scholar