In 2009, the American Academy of Environmental Medicine (AAEM) stated that, “Several animal studies indicate serious health risks associated with genetically modified (GM) food,” including infertility, immune problems, accelerated aging, faulty insulin regulation, and changes in major
organs and the gastrointestinal system. The AAEM has asked physicians to advise all patients to avoid GM foods.
Starting in 1996, Americans have been eating genetically modified (GM) ingredients in most processed foods. Why isn’t the FDA protecting us?
In 1992, the Food and
Drug Administration claimed they had no information showing that GM foods were
substantially different from conventionally grown foods. Therefore they are
safe to eat, and absolutely no safety studies were required. But internal memos
made public by a lawsuit reveal that their position was staged by political appointees who were under orders from the White House to promote
GMOs. In addition, the FDA official in charge of creating this policy was
Michael Taylor, the former attorney for Monsanto, the largest biotech company,
and later their vice president.
In reality, FDA
scientists had repeatedly warned that GM foods can create unpredictable,
hard-to-detect side effects, including allergies, toxins, new diseases, and
nutritional problems. They urged long-term safety studies, but were
Today, the same biotech companies who have been found guilty of hiding toxic effects of their
chemical products are in charge of determining whether their GM foods are safe.
Industry-funded GMO safety studies are too superficial to find most of the
potential dangers, and their voluntary consultations with the FDA are widely
criticized as a meaningless façade.
GM plants, such as soybean, corn, cottonseed, and canola, have had
foreign genes forced into their DNA. The inserted genes come from species, such
as bacteria and viruses, which have never been in the human food supply.
transfers genes across natural species barriers. It uses imprecise laboratory
techniques that bear no resemblance to natural breeding, and is based on
outdated concepts of how genes and cells work. Gene insertion is done either by shooting genes from a “gene gun” into a plate of cells or by using bacteria to invade the cell with foreign DNA. The altered cell is then cloned into a plant.
The genetic engineering process creates massive collateral damage, causing mutations in
hundreds or thousands of locations throughout the plant’s DNA. Natural genes can be deleted or permanently turned on or off, and hundreds may change their behavior. Even the inserted gene can be damaged or rearranged, and may create proteins that can trigger allergies or promote disease.
GM foods on the market
There are eight GM food crops. The five major varieties—soy, corn, canola, cotton, and sugar beets—have bacterial genes inserted, which allow the plants to survive an otherwise deadly dose of weed killer. Farmers use considerably more herbicides on these GM crops and so the food has higher herbicide residues. About 68% of GM crops are herbicide tolerant.
The second GM trait is a built-in pesticide, found in GM corn and cotton. A gene from the soil bacterium called Bt (for Bacillus thuringiensis) is inserted into the plant’s DNA, where it secretes the insect-killing Bt-toxin in every cell. About 19% of GM crops produce their own pesticide. Another 13% produce a pesticide and are herbicide tolerant.
There is also Hawaiian papaya and a small amount of zucchini and yellow crookneck squash, which are engineered to resist a plant virus.
Growing evidence of harm from GMOs
GM soy and allergic reactions
- Soy allergies skyrocketed by 50% in the UK, soon after GM soy was introduced.
- A skin prick allergy test shows that some people react to GM soy, but not to wild natural soy.
- Cooked GM soy contains as much as 7-times the amount of a known soy allergen.
- GM soy also contains a new unexpected allergen, not found in wild natural soy.
Bt corn and cotton linked to allergies
The biotech industry claims that Bt-toxin is harmless to humans and mammals because the natural bacteria version has been used as a spray by farmers for years. In reality, hundreds of people exposed to Bt spray had allergic-type symptoms, and mice fed Bt had powerful immune responses and damaged intestines. Moreover, the Bt in GM crops is designed to be more toxic than the natural spray and is thousands of times more concentrated.
GMOs fail allergy tests
No tests can guarantee that a GMO will not cause allergies. Although the World Health Organization recommends a screening protocol, the GM soy, corn, and papaya in our food supply fail those tests—because their GM proteins have properties of known allergens.
GMOs may make you allergic to non-GM foods
- GM soy drastically reduces digestive enzymes in mice. If it also impairs your digestion, you may become sensitive and allergic to a variety of foods.
- Mice fed Bt-toxin started having immune reactions to formerly harmless foods.
- Mice fed experimental GM peas also started reacting to a range of other foods. (The peas had already passed all the allergy tests normally done before a GMO gets on the market. Only this advanced test, which is never used on the GMOs we eat, revealed that the peas could actually be deadly.)
GMOs and liver problems
- Rats fed GM potatoes had smaller, partially atrophied livers.
- The livers of rats fed GM canola were 12-16% heavier.
- GM soy altered mouse liver cells in ways that suggest a toxic insult. The changes reversed after they switched to non-GM soy.
GMOs, reproductive problems, and infant mortality
- More than half the babies of mother rats fed GM soy died within three weeks.
- Male rats and mice fed GM soy had changed testicles, including altered young sperm cells in the mice.
- The DNA of mouse embryos functioned differently when their parents ate GM soy
- The longer mice were fed GM corn, the less babies they had, and the smaller their babies were.
- Babies of female rats fed GM soy were considerably smaller, and more than half died within three weeks (compared to 10% of the non-GM soy controls).
- Female rats fed GM soy showed changes in their ovaries and uterus.
- By the third generation, most hamsters fed GM soy were unable to have babies.
Bt crops linked to sterility, disease, and death
- Thousands of sheep, buffalo, and goats in India died after grazing on Bt cotton plants after harvest. Others suffered poor health and reproductive problems.
- Farmers in Europe and Asia say that cows, water buffaloes, chickens, and horses died from eating Bt corn varieties.
- About two dozen US farmers report that Bt corn varieties caused widespread sterility in pigs or cows.
- Filipinos in at least five villages fell sick when a nearby Bt corn variety was pollinating.
- The stomach lining of rats fed GM potatoes showed excessive cell growth, a condition that may lead to cancer. Rats also had damaged organs and immune systems.
Functioning GM genes remain inside you
Unlike safety evaluations for drugs, there are no human clinical trials of GM foods. The only published human feeding experiment revealed that the genetic material inserted into GM soy transfers into bacteria living inside our intestines and continues to function. This means that long after we stop eating GM foods, we may still have their GM proteins produced continuously inside us.
- If the antibiotic gene inserted into most GM crops were to transfer, it could create super diseases, resistant to antibiotics.
- If the gene that creates Bt-toxin in GM corn were to transfer, it might turn our intestinal bacteria into living pesticide factories.
- Animal studies show that DNA in food can travel into organs throughout the body, even into the fetus.
GM food supplement caused deadly epidemic
In the 1980s, a contaminated brand of a food supplement called L-tryptophan killed about 100 Americans and caused sickness and disability in another 5,000-10,000 people. The source of contaminants was almost certainly the genetic engineering process used in its production. The disease took years to find and was almost overlooked. It was only identified because the symptoms were unique, acute, and fast-acting. If all three characteristics were not in place, the deadly GM supplement might never have been identified or removed.
If GM foods on the market are causing common diseases or if their effects appear only after long-term exposure, we may not be able to identify the source of the problem for decades, if at all. There is no monitoring of GMO-related illnesses and no long-term animal studies. Heavily invested biotech corporations are gambling with the health of our nation for their profit.
Help end the genetic engineering of our food supply
When the tipping point of consumer concern about GMOs was achieved in Europe in 1999, within a single week virtually all major food manufacturers committed to remove GM ingredients. The Campaign for Healthier Eating in America is designed to reach a similar tipping point in the US soon.
Our growing network of manufacturers, retailers, healthcare practitioners, organizations, and the media, is informing consumers of the health risks of GMOs and helping them select healthier non-GMO alternatives with our Non-GMO Shopping Guides.
Start buying non-GMO today. Help us stop the genetic engineering of our food supply.
The health information featured on this page is excerpted fromGenetic Roulette: The Documented Health Risk of Genetically Engineered Foods, by Jeffrey M. Smith. © Copyright 2010. Institute for Responsible Technology.
 See Part 2, Jeffrey M. Smith, Genetic Roulette: The Documented Health Risks of Genetically Engineered Foods, Yes! Books, Fairfield, IA 2007
 See for example 233-236, chart of disproved assumptions, in Jeffrey M. Smith, Genetic Roulette: The Documented Health Risks of Genetically Engineered Foods, Yes! Books, Fairfield, IA 2007
 J. R. Latham, et al., “The Mutational Consequences of Plant Transformation,” The Journal of Biomedicine and Biotechnology 2006, Article ID 25376: 1-7; see also Allison Wilson, et. al., “Transformation-induced mutations in transgenic plants: Analysis and biosafety implications,” Biotechnology and Genetic Engineering Reviews – Vol. 23, December 2006.
 Srivastava, et al, “Pharmacogenomics of the cystic fibrosis transmembrane conductance regulator (CFTR) and the cystic fibrosis drug CPX using genome microarray analysis,” Mol Med. 5, no. 11(Nov 1999):753–67.
 Latham et al, “The Mutational Consequences of Plant Transformation, Journal of Biomedicine and Biotechnology 2006:1-7, article ID 25376, http://www.hindawi.com/
 Mark Townsend, “Why soya is a hidden destroyer,” Daily Express, March 12, 1999.
 Hye-Yung Yum, Soo-Young Lee, Kyung-Eun Lee, Myung-Hyun Sohn, Kyu-Earn Kim, “Genetically Modified and Wild Soybeans: An immunologic comparison,” Allergy and Asthma Proceedings 26, no. 3 (May–June 2005): 210-216(7).
 A. Pusztai and S. Bardocz, “GMO in animal nutrition: potential benefits and risks,” Chapter 17, Biology of Nutrition in Growing Animals, R. Mosenthin, J. Zentek and T. Zebrowska (Eds.) Elsevier, October 2005.
 Hye-Yung Yum, Soo-Young Lee, Kyung-Eun Lee, Myung-Hyun Sohn, Kyu-Earn Kim, “Genetically Modified and Wild Soybeans: An immunologic comparison,” Allergy and Asthma Proceedings 26, no. 3 (May–June 2005): 210-216(7).
 M. Green, et al., “Public health implications of the microbial pesticide Bacillus thuringiensis: An epidemiological study, Oregon, 1985-86,” Amer. J. Public Health 80, no. 7(1990): 848–852; and M.A. Noble, P.D. Riben, and G. J. Cook, Microbiological and epidemiological surveillance program to monitor the health effects of Foray 48B BTK spray (Vancouver, B.C.: Ministry of Forests, Province of British Columbi, Sep. 30, 1992)
 Vazquez et al, “Intragastric and intraperitoneal administration of Cry1Ac protoxin from Bacillus thuringiensis induces systemic and mucosal antibody responses in mice,” 1897–1912; Vazquez et al, “Characterization of the mucosal and systemic immune response induced by Cry1Ac protein from Bacillus thuringiensis HD 73 in mice,” Brazilian Journal of Medical and Biological Research 33 (2000): 147–155; and Vazquez et al, “Bacillus thuringiensis Cry1Ac protoxin is a potent systemic and mucosal adjuvant,” Scandanavian Journal of Immunology 49 (1999): 578–584. See also Vazquez-Padron et al., 147 (2000b).
 Nagui H. Fares, Adel K. El-Sayed, “Fine Structural Changes in the Ileum of Mice Fed on Endotoxin Treated Potatoes and Transgenic Potatoes,” Natural Toxins 6, no. 6 (1998): 219–233.
 See for example “Bt cotton causing allergic reaction in MP; cattle dead,” Bhopal, Nov. 23, 2005
 http://news.webindia123.com Ashish Gupta et. al., “Impact of Bt Cotton on Farmers’ Health (in Barwani and Dhar District of Madhya Pradesh),” Investigation Report, Oct–Dec 2005; and M. Green, et al., “Public health implications of the microbial pesticide Bacillus thuringiensis: An epidemiological study, Oregon, 1985-86,” Amer. J. Public Health 80, no. 7(1990): 848–852; and M.A. Noble, P.D. Riben, and G. J. Cook, Microbiological and epidemiological surveillance program to monitor the health effects of Foray 48B BTK spray (Vancouver, B.C.: Ministry of Forests, Province of British Columbi, Sep. 30, 1992)
 Alberto Finamore, et al, “Intestinal and Peripheral Immune Response to MON810 Maize Ingestion in Weaning and Old Mice,” J. Agric. Food Chem., 2008, 56 (23), pp 11533–11539, November 14, 2008
 Joël Spiroux de Vendômois, François Roullier, Dominique Cellier and Gilles-Eric Séralini. 2009, A Comparison of the Effects of Three GM Corn Varieties on Mammalian Health . International Journal of Biological Sciences 2009; 5(7):706-726; and Seralini GE, Cellier D, Spiroux de Vendomois J. 2007, New analysis of a rat feeding study with a genetically modified maize reveals signs of hepatorenal toxicity. Arch Environ Contam Toxicol. 2007;52:596-602
 FAO-WHO, “Evaluation of Allergenicity of Genetically Modified Foods. Report of a Joint FAO/WHO Expert Consultation on Allergenicity of Foods Derived from Biotechnology,” Jan. 22–25, 2001; http://www.fao.org/es/ESN/food/pdf/allergygm Gendel, “The use of amino acid sequence alignments to assess potential allergenicity of proteins used in genetically modified foods,” Advances in Food and Nutrition Research 42 (1998), 45–62; G. A. Kleter and A. A. C. M. Peijnenburg, “Screening of transgenic proteins expressed in transgenic food crops for the presence of short amino acid sequences indentical to potential, IgE-binding linear epitopes of allergens,” BMC Structural Biology 2 (2002): 8–19; H. P. J. M. Noteborn, “Assessment of the Stability to Digestion and Bioavailability of the LYS Mutant Cry9C Protein from Bacillus thuringiensis serovar tolworthi,” Unpublished study submitted to the EPA by AgrEvo, EPA MRID No. 447343-05 (1998); and H. P. J. M. Noteborn et al, “Safety Assessment of the Bacillus thuringiensis Insecticidal Crystal Protein CRYIA(b) Expressed in Transgenic Tomatoes,” in Genetically modified foods: safety issues, American Chemical Society Symposium Series 605, eds. K.H. Engel et al., (Washington, DC, 1995): 134–47.
 M. Malatesta, M. Biggiogera, E. Manuali, M. B. L. Rocchi, B. Baldelli, G. Gazzanelli, “Fine Structural Analyses of Pancreatic Acinar Cell Nuclei from Mice Fed on GM Soybean,” Eur J Histochem 47 (2003): 385–388.
 Vazquez et al, “Bacillus thuringiensis Cry1Ac protoxin is a potent systemic and mucosal adjuvant,” Scandanavian Journal of Immunology 49 (1999): 578–584. See also Vazquez-Padron et al., 147 (2000b).
 V. E. Prescott, et al, “Transgenic Expression of Bean r-Amylase Inhibitor in Peas Results in Altered Structure and Immunogenicity,” Journal of Agricultural Food Chemistry (2005): 53.
 Arpad Pusztai, “Can science give us the tools for recognizing possible health risks of GM food,” Nutrition and Health, 2002, Vol 16 Pp 73-84
 Comments to ANZFA about Applications A346, A362 and A363 from the Food Legislation and Regulation Advisory Group (FLRAG) of the Public Health Association of Australia (PHAA) on behalf of the PHAA, “Food produced from glyphosate-tolerant canola line GT73,” http://www.iher.org.au/
 M. Malatesta, C. Caporaloni, S. Gavaudan, M. B. Rocchi, S. Serafini, C. Tiberi, G. Gazzanelli, “Ultrastructural Morphometrical and Immunocytochemical Analyses of Hepatocyte Nuclei from Mice Fed on Genetically Modified Soybean,” Cell Struct Funct. 27 (2002): 173–180.
 M. Malatesta, C. Tiberi, B. Baldelli, S. Battistelli, E. Manuali, M. Biggiogera, “Reversibility of Hepatocyte Nuclear Modifications in Mice Fed on Genetically Modified Soybean,” Eur J Histochem, 49 (2005): 237-242.
 I.V. Ermakova, “Diet with the Soya Modified by Gene EPSPS CP4 Leads to Anxiety and Aggression in Rats,” 14th European Congress of Psychiatry. Nice, France,
 Irina Ermakova, “Experimental Evidence of GMO Hazards,” Presentation at Scientists for a GM Free Europe, EU Parliament, Brussels, June 12, 2007
 L. Vecchio et al, “Ultrastructural Analysis of Testes from Mice Fed on Genetically Modified Soybean,” European Journal of Histochemistry 48, no. 4 (Oct–Dec 2004):449–454.
 Oliveri et al., “Temporary Depression of Transcription in Mouse Pre-implantion Embryos from Mice Fed on Genetically Modified Soybean,” 48th Symposium of the Society for Histochemistry, Lake Maggiore (Italy), September 7–10, 2006.
 Alberta Velimirov and Claudia Binter, “Biological effects of transgenic maize NK603xMON810 fed in long term reproduction studies in mice,” Forschungsberichte der Sektion IV, Band 3/2008
 I.V. Ermakova, “Diet with the Soya Modified by Gene EPSPS CP4 Leads to Anxiety and Aggression in Rats,” 14th European Congress of Psychiatry. Nice, France, March 4-8, 2006; “Genetically modified soy affects posterity: Results of Russian scientists’ studies,” REGNUM, October 12, 2005; http://www.regnum.ru/english/526651.html; Irina Ermakova, “Genetically modified soy leads to the decrease of weight and high mortality of rat pups of the first generation. Preliminary studies,” Ecosinform 1 (2006): 4–9.
 “Mortality in Sheep Flocks after Grazing on Bt Cotton Fields—Warangal District, Andhra Pradesh” Report of the Preliminary Assessment, April 2006, http://gmwatch.org/latest-listing/1-news-items/6416-mortality-in-sheep-flocks-after-grazing-on-bt-cotton-fields-warangal-district-andhra-pradesh-2942006
 Mae-Wan Ho, “GM Ban Long Overdue, Dozens Ill & Five Deaths in the Philippines,” ISIS Press Release, June 2, 2006; and Mae-Wan Ho and Sam Burcher, “Cows Ate GM Maize & Died,” ISIS Press Release, January 13, 2004, http://www.isis.org.uk/CAGMMAD.php
 Personal communication with Jerry Rosman and other farmers, 2006; also reported widely in the farm press.
 See for example Mae-Wan Ho, “GM Ban Long Overdue, Dozens Ill & Five Deaths in the Philippines,” ISIS Press Release, June 2, 2006; “Study Result Not Final, Proof Bt Corn Harmful to Farmers,” BusinessWorld, 02 Mar 2004; and “Genetically Modified Crops and Illness Linked,” Manila Bulletin, 04 Mar 2004.
 Arpad Pusztai, “Can science give us the tools for recognizing possible health risks of GM food,” Nutrition and Health, 2002, Vol 16 Pp 73-84; Stanley W. B. Ewen and Arpad Pusztai, “Effect of diets containing genetically modified potatoes expressing Galanthus nivalis lectin on rat small intestine,” Lancet, 1999 Oct 16; 354 (9187): 1353-4; and Arpad Pusztai, “Facts Behind the GM Pea Controversy: Epigenetics, Transgenic Plants & Risk Assessment,” Proceedings of the Conference, December 1st 2005 (Frankfurtam Main, Germany: Literaturhaus, 2005)
 Netherwood et al, “Assessing the survival of transgenic plant DNA in the human gastrointestinal tract,” Nature Biotechnology 22 (2004): 2.
 Ricarda A. Steinbrecher and Jonathan R. Latham, “Horizontal gene transfer from GM crops to unrelated organisms,” GM Science Review Meeting of the Royal Society of Edinburgh on “GM Gene Flow: Scale and Consequences for Agriculture and the Environment,” January 27, 2003; Traavik and Heinemann, Genetic Engineering and Omitted Health Research; citing Schubbert, et al, “Ingested foreign (phage M13) DNA survives transiently in the gastrointestinal tract and enters the bloodstream of mice,” Mol Gen Genet. 242, no. 5 (1994): 495–504; Schubbert et al, “Foreign (M13) DNA ingested by mice reaches peripheral leukocytes, spleen, and liver via the intestinal wall mucosa and can be covalently linked to mouse DNA,” Proc Natl Acad Sci USA 94, no. 3 (1997): 961–6; Schubbert et al, “On the fate of orally ingested foreign DNA in mice: chromosomal association and placental transmission to the fetus,” Mol Gen Genet. 259, no. 6 (1998): 569–76; Hohlweg and Doerfler, “On the fate of plants or other foreign genes upon the uptake in food or after intramuscular injection in mice,” Mol Genet Genomics 265 (2001): 225–233; Palka-Santani, et al., “The gastrointestinal tract as the portal of entry for foreign macromolecules: fate of DNA and proteins,” Mol Gen Genomics 270 (2003): 201–215; Einspanier, et al, “The fate of forage plant DNA in farm animals; a collaborative case-study investigating cattle and chicken fed recombinant plant material,” Eur Food Res Technol 212 (2001): 129–134; Klotz, et al, “Degradation and possible carry over of feed DNA monitored in pigs and poultry,” Eur Food Res Technol 214 (2002): 271–275; Forsman, et al, “Uptake of amplifiable fragments of retrotransposon DNA from the human alimentary tract,” Mol Gen Genomics 270 (2003): 362–368; Chen, et al, “Transfection of mEpo gene to intestinal epithelium in vivo mediated by oral delivery of chitosan-DNA nanoparticles,” World Journal of Gastroenterology 10, no 1(2004): 112–116; Phipps, et al, “Detection of transgenic and endogenous plant DNA in rumen fluid, duodenal digesta, milk, blood, and feces of lactating dairy cows,” J Dairy Sci. 86, no. 12(2003): 4070–8.
 William E. Crist,Toxic L-tryptophan: Shedding Light on a Mysterious Epidemic; and Jeffrey M. Smith, Seeds of Deception, Yes! Books, Fairfield, IA 2003, chapter 4, Deadly Epidemic