Genetically Modified Foods:
Are They a Risk to Human/Animal Health?
ARPAD PUSZTAI / actionbioscience.org / American Institute of Biological Sciences 1jun2001
Scarcity of safety tests
How can the public make informed decisions about genetically modified (GM) foods when there is so little information about its safety? The lack of data is due to a number of reasons, including:
- It's more difficult to evaluate the safety of crop-derived foods than individual chemical, drug, or food additives. Crop foods are more complex and their composition varies according to differences in growth and agronomic conditions.
- Publications on GM food toxicity are scarce. An article in Science magazine said it all: "Health Risks of Genetically Modified Foods: Many Opinions but Few Data".1 In fact, no peer-reviewed publications of clinical studies on the human health effects of GM food exist. Even animal studies are few and far between.
- The preferred approach of the industry has been to use compositional comparisons between GM and non-GM crops. When they are not significantly different the two are regarded as "substantially equivalent", and therefore the GM food crop is regarded as safe as its conventional counterpart. This ensures that GM crops can be patented without animal testing. However, substantial equivalence is an unscientific concept that has never been properly defined and there are no legally binding rules on how to establish it.2
When food-crops are genetically modified, ("genetically modified" food is a misnomer!) one or more genes are incorporated into the crop's genome using a vector containing several other genes, including as a minimum, viral promoters, transcription terminators, antibiotic resistance marker genes and reporter genes. Data on the safety of these are scarce even though they can affect the safety of the GM crop. For example:
- DNA does not always fully break down in the alimentary tract.3,4 Gut bacteria can take up genes and GM plasmids5 and this opens up the possibility of the spread of antibiotic resistance.
- Insertion of genes into the genome can also result in unintended effects, which need to be reduced/eliminated by selection, since some of the ways the inserted genes express themselves in the host or the way they affect the functioning of the crop's own genes are unpredictable. This may lead to the development of unknown toxic/allergenic components, which we cannot analyze for and seriously limiting the selection criteria.
Currently, toxicity in food is tested by chemical analysis of macro/micro nutrients and known toxins. To rely solely on this method is at best inadequate and, at worst, dangerous. Better diagnostic methods are needed, such as mRNA fingerprinting, proteomics and secondary metabolite profiling.6 However, consuming even minor constituents with high biological activity may have major effects on the gut and body's metabolism, which can only be revealed from animal studies. Thus novel toxicological/nutritional methods are urgently needed to screen for harmful consequences on human/animal health and to pinpoint these before allowing a GM crop into the food chain.7
Safety tests on commercial GM crops
GM tomatoes: The first and only safety evaluation of a GM crop, the FLAVR SAVRTM tomato, was commissioned by Calgene, as required by the FDA. This GM tomato was produced by inserting kanr genes into a tomato by an 'antisense' GM method. The test has not been peer-reviewed or published but is on the internet.8 The results claim there were no significant alterations in total protein, vitamins and mineral contents and in toxic glycoalkaloids.9 Therefore, the GM and parent tomatoes were deemed to be "substantially equivalent."
In acute toxicity studies with male/female rats, which were tube-fed homogenized GM tomatoes, toxic effects were claimed to be absent. In addition, it was concluded that mean body and organ weights, weight gains, food consumption and clinical chemistry or blood parameters were not significantly different between GM-fed and control groups. However:
- The unacceptably wide range of rat starting weights (±18% to ±23%) invalidated these findings.
- No histology on the intestines was done even though stomach sections showed mild/moderate erosive/necrotic lesions in up to seven out of twenty female rats but none in the controls. However, these were considered to be of no importance, although in humans they could lead to life-endangering hemorrhage, particularly in the elderly who use aspirin to prevent thrombosis.
- Seven out of forty rats on GM tomatoes died within two weeks for unstated reasons.
- These studies were poorly designed and therefore the conclusion that FLAVR SAVRTM tomatoes were safe does not rest on good science, questioning the validity of the FDA's decision that no toxicological testing of other GM foods will in future be required.
GM maize: Two lines of Chardon LL herbicide-resistant GM maize expressing the gene of Phosphinothricin Acetyltransferase Enzyme (PAT-PROTEIN) before and after ensiling showed significant differences in fat and carbohydrate contents compared with non-GM maize and were therefore substantially different. Toxicity tests were only performed with the PAT-PROTEIN even though with this the unpredictable effects of the gene transfer or the vector or gene insertion could not be demonstrated or excluded. The design of these experiments was also flawed because:
- The starting weight of the rats varied by more than ± 20% and individual feed intakes were not monitored.
- Feed conversion efficiency on PAT-PROTEIN was significantly reduced.
- Urine output increased and several clinical parameters were also different.
- The weight and histology of the digestive tract (and pancreas) was not measured.
Thus, GM maize expressing PAT-PROTEIN may present unacceptable health risks.
GM soybeans: To make soybeans herbicide resistant, the gene of 5-enolpyruvylshikimate-3-phosphate synthase from Agrobacterium was used. Safety tests claim the GM variety to be "substantially equivalent" to conventional soybeans.10 The same was claimed for GTS (glyphosate-resistant soybeans) sprayed with this herbicide.11 However, several significant differences between the GM and control lines were recorded10 and the statistical method used was flawed because:
- Instead of comparing the amounts of components in a large number of samples of each individual GTS with its appropriate parent line grown side-by-side and harvested at the same time, the authors compared samples from different locations and harvest times.
- There were also differences in the contents of natural isoflavones (genistein, etc.) with potential importance for health.12
- Additionally, the trypsin inhibitor (a major allergen) content was significantly increased in GTS.10
Because of this, and the large variability (± 10% or more), the lines could not be regarded as "substantially equivalent."
GM potatoes: There is only one peer-reviewed publication on GM potatoes that express the soybean glycinin gene.13 However, the expression level was very low and no improvements in the protein content or amino acid profile were obtained.
GM rice: The kind that expresses soybean glycinin gene (40-50 mg glycinin/g protein) has been developed14 and is claimed to contain 20% more protein. However, the increased protein content was probably due to a decrease in moisture rather than true increase in protein putting a question mark over the significance of this GM crop.
GM cotton: Several lines of GM cotton plants have been developed using a gene from Bacillus thuringiensis subsp. kurstaki providing increased protection against major lepidopteran pests. The lines were claimed to be "substantially equivalent" to parent lines15 in levels of macronutrients and gossypol, cyclopropenoid fatty acids and aflatoxin levels were less than those in conventional seeds. However, because of the use of inappropriate statistics it is questionable whether the GM and non-GM lines were truly equivalent, particularly as environmental stresses could have unpredictable effects on antinutrient/toxin levels.16
Herbicide-resistant soybean: Studies have been conducted on the feeding value17 and possible toxicity18 for rats, broiler chickens, catfish and dairy cows of two GM lines of glyphosate-resistant soybean (GTS). The growth, feed conversion efficiency, catfish fillet composition, broiler breast muscle and fat pad weights and milk production, rumen fermentation and digestibilities in cows were claimed to be similar for GTS and non-GTS. However:
- These experiments were poorly designed since the high dietary protein concentration and the low inclusion level of GTS could have masked any GM effect.
- No individual feed intakes, body or organ weights were given and no histology was performed, except some qualitative microscopy on the pancreas.
- The feeding value of the two GTS lines was not substantially equivalent either because the rats grew significantly better on one of the GTS lines than on the other.
- The experiment with broiler chicken was a commercial and not a scientific study.
- The catfish experiment showed again that the feeding value of one of the GTS lines was superior to the other.
- Milk production and performance of lactating cows also showed significant differences between cows fed GM and non-GM feeds.
- Moreover, testing of the safety of 5-enolpyruvylshikimate-3-phosphate synthase which renders soybeans glyphosate-resistant18 was irrelevant because in the gavage studies an E. coli recombinant and not the GTS product was used. Their effects could be different as the differences in post-translational modification could have impaired their stability to gut proteolysis.
Thus, the claim that the feeding value of GTS and non-GTS lines was substantially equivalent is at best premature.
In a separate study19 it was claimed that rats and mice which were fed 30% toasted GTS or non-GTS in their diet had no significant differences in nutritional performance, organ weights, histopathology and production of IgE and IgG antibodies. However, under the unphysiological -- basically, starvation -- conditions of these experiments when, instead of the normal daily growth of 5-8 g per day, the rats grew less than 0.3 g and mice not at all, no valid conclusions could be drawn.
GM corn: One broiler chicken feeding study with rations containing transgenic Event 176 derived Bt corn (Novartis) has been published.20 However, the results of this trial are more relevant to commercial than academic scientific studies.
GM peas: The nutritional value of diets containing GM peas expressing bean alpha-amylase inhibitor when fed to rats for 10 days at two different (30% or 65%) dietary inclusions, was shown to be similar to that of parent-line peas.21
- Even at 65% level the difference was small mainly because the alpha-amylase inhibitor expressed in the peas was quickly digested in the rat gut and its antinutritive effect abolished. Unfortunately no gut histology was done or lymphocyte responsiveness measured.
- Although some organ weights, mainly the caecum and pancreas were different, those of others were remarkably similar suggesting that GM peas may be used in the diets of farm animals at low/moderate levels if their progress was carefully monitored.
However, to establish its safety for humans a more rigorous specific risk assessment will have to be carried out with several GM lines. This should include:
- An initial nutritional/toxicological testing on laboratory animals
- If no harmful effects are then detected, it should be followed by clinical, double-blind, placebo-type tests with human volunteers, keeping in mind that any possible harmful effects would be particularly serious with the young, old, and disabled. A protocol for such testing was given at the OECD conference in Edinburgh, February 2000 and subsequently published.22
GM potatoes: In a short feeding study to establish the safety of GM potatoes expressing the soybean glycinin gene, rats were daily force-fed with 2 g of GM or control potatoes/kg body weight.23 Although no differences in growth, feed intake, blood cell count and composition and organ weights between the groups was found, the potato intake of the animals was too low and unclear, whether the potatoes were raw or boiled.
Feeding mice with potatoes transformed with a Bacillus thuringiensis var. kurstaki Cry1 toxin gene or the toxin itself was shown24 to have caused villus epithelial cell hypertrophy and multinucleation, disrupted microvilli, mitochondrial degeneration, increased numbers of lysosomes and autophagic vacuoles and activation of crypt Paneth cells. The results showed that despite claims to the contrary, CryI toxin was stable in the mouse gut and therefore GM crops expressing it need to be subjected to "thorough tests...to avoid the risks before marketing.24
In another study, young, growing rats were pair-fed on iso-proteinic and iso-caloric balanced diets containing raw or boiled non-GM potatoes and GM potatoes with the snowdrop (Galanthus nivalis) bulb lectin (GNA) gene.25 The results showed that the mucosal thickness of the stomach and the crypt length of the intestines of rats fed GM potatoes was significantly increased. Most of these effects were due to the insertion of the construct and not to GNA which had been been pre-selected as a non-mitotic lectin unable to induce hyperplastic intestinal growth26 and epithelial T lymphocyte infiltration. Although there is controversy about the tests, most of the adverse comments on this Lancet paper were personal, non-peer reviewed opinions and, as such, of limited scientific value. The findings, on the other hand, were published in a peer-reviewed publication25 and the criticism replied to.7 The work, however, has not been repeated nor results contradicted and it is therefore imperative that the effects on the gut structure and metabolism of all other GM crops developed using similar techniques and genetic vectors should be thoroughly investigated before their release into the food chain.
GM tomatoes: This study with a GM tomato expressing B. thuringiensis toxin CRYIA(b) gene was published in a book and not in a peer-reviewed journal. However, its importance was underlined by the immunocytochemical demonstration of in vitro binding of Bt toxin to the caecum/colon from humans and rhesus monkeys.27 Although in vivo the Bt toxin was not bound by the rat gut, this was possibly due to the authors' use of recombinant Bt toxin.
One of the major health concerns with GM food is its potential to increase allergies and anaphylaxis in humans eating unlabeled GM foodstuffs.
- When the gene is from a crop of known allergenicity, it is easy to establish whether the GM food is allergenic using in vitro tests, such as RAST or immunoblotting, with sera from individuals sensitised to the original crop. This was demonstrated in GM soybeans expressing the brasil nut 2 S protein28 or in GM potatoes expressing cod protein genes.29
- It is also relatively easy to assess whether genetic engineering affected the potency of endogenous allergens.30 Some farm workers exposed to B. thuringiensis pesticide were shown to have developed skin sensitization and IgE antibodies to the Bt spore extract. With their sera it may now therefore be possible to test for the allergenic potential of GM crops expressing Bt toxin.31 It is all the more important because Bt toxin Cry1Ac has recently been shown to be a potent oral/nasal antigen and adjuvant.32
Assessment of the allergenicity of a GM foodcrop, however, is difficult when the gene is transferred from a source not eaten before or with unknown allergenicity or on gene transfer/insertion a new allergen or adjuvant is developed or the expression of a minor allergen is increased. Unfortunately, while there are good animal models for nutritional/toxicological testing, no such models exist for allergenicity testing.
- Presently only indirect and rather scientifically unsound methods, such as finding SHORT sequence homologies (at least 8 contiguous amino acids) to any of the about 200 known allergens, are used for the assessment of allergenicity.
- The decision-tree type of indirect approach based on factors (such as size and stability) of the transgenically expressed protein33 is even more unsound, particularly as its stability to gut proteolysis is assessed by an in vitro (simulated) testing34 instead of in vivo (human/animal) testing and this is fundamentally wrong. The concept that most allergens are abundant proteins is also misleading because for example Gad c 1, the major allergen in codfish, is not a predominant protein.29
- However, when the gene responsible for the allergenicity is known, such as the gene of the alpha-amylase/trypsin inhibitors/allergens in rice, cloning and sequencing opens the way for reducing their level by antisense RNA strategy.35
Thus, in the absence of reliable methods for allergenicity testing, it is at present impossible to definitely establish whether a new GM crop is allergenic or not before its release into the human/animal food/feed chain.
One has to agree with the piece in Science1 that there are many opinions but scarce data on the potential health risks of GM food crops, even though these should have been tested for and eliminated before their introduction. Our present data base is woefully inadequate. Moreover, the scientific quality of what has been published is, in most instances not up to expected standards. If, as claimed, our future is dependent on the success of the promise of genetic modification delivering wholesome, plentiful, more nutritious and safe GM foods, the inescapable conclusion of this review is that the present crude method of genetic modification has so far not delivered these benefits and the promise of a superior second generation is still in the future. Although it is argued by some that small differences between GM and non-GM crops have little biological meaning, it is clear that most GM and parental line crops fall short of the definition of "substantial equivalence." In any case, this crude, poorly defined and unscientific concept outlived its possible previous usefulness and we need novel methods and concepts to probe into the compositional, nutritional/toxicological and metabolic differences between GM and conventional crops and into the safety of the genetic techniques used in developing GM crops if we want to put this technology on a proper scientific foundation and allay the fears of the general public. We need more science, not less.6,7
© 2001, American Institute of Biological Sciences. Educators have permission to reprint articles for classroom use; other users, please contact editor for reprint permission. See reprint policy.
About the author: Arpad Pusztai, Ph.D., received his degree in Chemistry in Budapest, Hungary and his B.Sc. in Physiology and Ph.D. in Biochemistry at the University of London in England. Over his nearly 50-year career, he worked at universities and research institutes in Budapest; London; Chicago, U.S.; and Aberdeen, Scotland (Rowett Research Institute). He has published close to 300 primary peer-reviewed papers and wrote or edited 12 scientific books. In the last 30 years he pioneered research into the effects of dietary lectins (carbohydrate-reactive proteins), including those transgenically expressed in GM crop plants, on the gastrointestinal tract. Since his contract was not renewed with Rowett as a result of disagreements, Dr. Pusztai has been lecturing on his GM potato research all over the world and acting as a consultant to groups starting up research into the health effects of GM food. http://www.freenetpages.co.uk/hp/a.pusztai/
1) Domingo, J.L. (2000) Health risks of genetically modified foods: Many opinions but few data. Science 288, 1748-1749.
2) Millstone, E., Brunner, E. and Mayer, S. (1999) Beyond substantial equivalence. Nature 401, 525-526.
3) Schubbert, R., Lettmann, C. and Doerfler, W. (1994) Ingested foreign (phage M13) DNA survives transiently in the gastrointestinal tract and enters the blood stream of mice. Molecules, Genes and Genetics 242, 495-504.
4) 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 in the fetus. Molecules, Genes and Genetics 259, 569-576.
5) Mercer, D.K., Scott, K.P., Bruce-Johnson, W.A., Glover, L.A. and Flint, H.J. (1999) Fate of free DNA and transformation of oral bacterium Streptococcus gordonii DL1 plasmid DNA in human saliva. Applied and Environmental Microbiology 65, 6-10.
6) Kuiper, H.A., Noteborn, H.P.J.M. and Peijnenburg, A.A.C.M. (1999) Adequacy of methods for testing the safety of genetically modified foods. The Lancet 354, 1315-1316.
7) Ewen, S.W.B. and Pusztai, A. (1999a) Authors' reply. The Lancet 354, 1727-1728.
8) Alliance for Biointegrity website: http://www.biointegrity.org (1998), including Calgene FLAVR SAVRTM tomato report, pp. 1-604; International Research and Development Corp. first test report, pp. 1736-1738; Conclusions of the expert panel regarding the safety of the FLAVR SAVRTM tomato, ENVIRON, Arlington VA, USA pp. 2355-2382; Four week oral (intubation) toxicity study in rats by IRDC, pp. 2895-3000.
9) Redenbaugh, K., Hatt, W., Martineau, B, Kramer, M., Sheehy, R., Sanders, R., Houck, C. and Emlay, D. (1992) A case study of the FLAVR SAVRTM tomato. In: Safety Assessment of Genetically Engineered Fruits and Vegetables. CRC Press Inc. Boca Raton.
10) Padgette, S.R. Taylor, N.B., Nida, D.L., Bailey, M.R., MacDonald, J., Holden, L.R. and Fuchs, R.L. (1996) The composition of glyphosate-tolerant soybean seeds is equivalent to that of conventional soybeans. Journal of Nutrition 126, 702-716.
11) Taylor, N.B., Fuchs, R.L., MacDonald, J.,Shariff, A.B. and Padgette, S.R. (1999) Compositional analysis of glyphosate-tolerant soybeans treated with glyphosate. Journal of Agriculture and Food Chemistry 47, 4469-4473.
12) Lappé, M.A., Bailey, E.B., Childress, C. and Setchell, K.D.R. (1999) Alterations in clinically important phytoestrogens in genetically modified, herbicide-tolerant soybeans. Journal of Medical Food 1, 241-245.
13) Hashimoto, W., Momma, K., Katsube, T., Ohkawa, Y., Ishige, T., Kito, M., Utsumi, S. and Murata, K. (1999) Safety assessment of genetically engineered potatoes with designed soybean glycinin: compositional analyses of the potato tubers and digestibility of the newly expressed protein in transgenic potatoes. Journal of Science of Food and Agriculture 79, 1607-1612.
14) Momma, K., Hashimoto, W., Ozawa, S., Kawai, S., Katsube, T., Takaiwa, F., Kito, M, Utsumi, S. and Murata, K. (1999) Quality and safety evaluation of genetically engineered rice with soybean glycinin: Analyses of the grain composition and digestibility of glycinin in transgenic rice. Bioscience Biotechnology Biochemistry 63, 314-318.
15) Berberich, S.A., Ream, J.E, Jackson, T.L., Wood, R., Stipanovic, R., Harvey, P., Patzer, S. and Fuchs, R.L. (1996) The composition of insect-protected cottonseed is equivalent to that of conventional cottonseed. Journal of Agricultural Food Chemistry 44, 365-371.
16) Novak, W.K. and Haslberger, A.G. (2000) Substantial equivalence of antinutrients and inherent plant toxins in genetically modified novel foods. Food and Chemical Toxicology 38, 473-483.
17) 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.
18) Harrison, L.A., Bailey, M.R., Naylor, M.W., Ream, J.E., Hammond, B.G., Nida, D.L., Burnette, B.L., Nickson, T.E., Mitsky, T.A., Taylor, M.L, Fuchs, R.L. and Padgette, S.R. (1996) The expressed protein in glyphosate-tolerant soybean, 5-enolpyruvylshikimate-3-phosphate synthase from Agrobacterium sp. strain CP4, is rapidly digested in vitro and is not toxic to acutely gavaged mice. Journal of Nutrition 126, 728-740.
19) Teshima, R., Akiyama, H., Okunuki, H., Sakushima, J-i, Goda, Y., Onodera, H., Sawada, J-i and Toyoda, M. (2000) Effect of GM and Non-GM soybeans on the immune system of BN rats and B10A mice. Journal of Food Hygiene Society of Japan 41, 188-193.
20) Brake, J. and Vlachos, D. (1998) Evaluation of transgenic Event 176 "Bt" corn in broiler chicken. Poultry Science 77, 648-653.
21) Pusztai, A., Grant, G., Bardocz, S., Alonso, R., Chrispeels, M.J., Schroeder, H.E., Tabe, L.M. and Higgins, T.J.V. (1999) Expression of the insecticidal bean alpha-amylase inhibitor transgene has minimal detrimental effect on the nutritional value of peas fed to rats at 30% of the diet. Journal of Nutrition 129, 1597-1603.
22) Pusztai, A. (2000) The need for rigorous risk assessment. Chemistry & Industry 8, 280.
23) Hashimoto, W., Momma, K., Yoon, H.J., Ozawa, S., Ohkawa, Y., Ishige, T., Kito, M., Utsumi, S. and Murata, K. (1999) Safety assessment of transgenic potatoes with soybean glycinin by feeding studies in rats. Bioscience Biotechnology Biochemistry 63, 1942-1946.
24) Fares, N.H. and El-Sayed, A.K. (1998) Fine structural changes in the ileum of mice fed on delta-endotoxin-treated potatoes and transgenic potatoes. Natural Toxins 6, 219-233.
25) Ewen, S.W.B. and Pusztai, A. (1999b) Effects of diets containing genetically modified potatoes expressing Galanthus nivalis lectin on rat small intestine. The Lancet 354, 1353-1354.
26) Pusztai, A., Ewen, S.W.B., Grant. G., Peumans, W.J., van Damme, E.J.M., Rubio, L., Bardocz, S. (1990) Relationship between survival and binding of plant lectins during small intestinal passage and their effectiveness as growth factors. Digestion, 46 (suppl. 2), 308-316.
27) Noteborn, H.P.J.M., Bienenmann-Ploum, M.E., van den Berg, J.H.J., Alink, G.M., Zolla, L., Raynaerts, A., Pensa, M. and Kuiper, H.A. (1995) Safety assessment of the Bacillus thuringiensis insecticidal crystal protein CRYIA(b) expressed in transgenic tomatoes. In: ACS Symposium series 605 Genetically Modified Foods - Safety Issues, Eds. Engel, K.H, Takeoka, G.R. and Teranishi, R. Chapter 12, pp. 135-147. American Chemical Society, Washington, D.C.
28) Nordlee, J.A., Taylor, S.L., Townsend, J.A. and Thomas, L.A. (1996) Identification of a Brazil nut allergen in transgenic soybean. New England Journal of Medicine 334, 688-692.
29) Bindslev-Jensen, C. and Poulsen, L.K. (1997) Hazards of unintentional/intentional introduction of allergens into foods. Allergy 52, 1184-1186.
30) Burks, A.W. and Fuchs, R.L. (1995) Assessment of the endogenous allergens in glyphosate-tolerant and commercial soybean varieties. Journal of Allergy and Clinical Immunology 96, 1008-1010.
31) Bernstein, I.L., Bernstein, J.A., Miller, M., Tierzieva, S., Bernstein, D.I., Lummus, Z., Selgrade, M.K., Doerfler, D.L. and Seligy, V.L. (1999) Immune responses in farm workers after exposure to Bacillus thuringiensis pesticides. Environmental Health Perspectives 107, 575-582.
32) Vazquez-Padron, R.I., Moreno-Fierros, L., Neri-Bazan, L., Martinez-Gil, A.F., de la Riva, G.A. and Lopez-Revilla, R. (2000) Characterization of the mucosal and sytemic immune response induced by Cry1Ac protein from Bacillus thuringiensis HD 73 in mice. Brazilian Journal of Medical and Biological Research 33, 147-155.
33) O'Neil, C., Reese, G. and Lehrer, S.B. (1998) Allergenic potential of recombinant food proteins. Allergy and Clinical Immunology International 10, 5-9.
34) Metcalf, D.D., Astwood, J.D., Townsend, R., Sampson, H.A., Taylor, S.L. and Fuchs, R.L. (1996) Assessment of the allergenic potential of foods derived from genetically engineered crop plants. In: Critical Reviews in Food Science and Nutrition 36(S):S165-186. CRC Press Inc. Boca Raton, USA.
35) Nakamura, R. and Matsuda, T. (1996) Rice allergenic protein and molecular-genetic approach for hypoallergenic rice. Bioscience Biotechnology Biochemistry 60, 1215-1221.
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