Genetically modified food: Difference between revisions

For related content, see Genetic engineering, Genetically modified organism, Genetically modified crops, Genetically modified food controversies, and, and Regulation of the release of genetically modified organisms.

Genetically modified foods or GM foods are foods produced from organisms that have had specific changes introduced into their DNA using the methods of genetic engineering. These techniques allow for the introduction of new traits as well as greater control over traits than previous methods such as selective breeding and mutation breeding.^[1]

Commercial sale of genetically modified foods began in 1994, when Calgene first marketed its Flavr Savr delayed-ripening tomato.^[2] Most food modifications have primarily focused on cash crops in high demand by farmers such as soybean, corn, canola, and cotton seed oil. These have been engineered for resistance to pathogens and herbicides and for better nutrient profiles. GM livestock have been developed, although as of November 2013 none were on the market.^[3]

Some studies concluded that food on the market derived from GM crops poses no greater risk to human health than conventional food.^{[4][5][6][7][8][9]} However, other sources conclude that because of research issues due to intellectual property rights, limited access to research material, differences in methods, analysis and the interpretation of data, it is not possible to state if GMOs are generally safe or unsafe, and instead must be a judged on case-by-case basis.^[10]

History

Food biotechnology is a branch of food science that seeks to improve foods and food production.^[11] Biotechnological processes include industrial fermentation, plant cultures and genetic engineering.^[12]

Food biotechnology dates back to the time of the Sumerians and Babylonians who used yeast to make fermented beverages such as beer.^[13] Plant enzymes such as malts were also used millennia ago.^[14] The invention of the microscope by Anton van Leeuwenhoek allowed humans to discover microorganisms that came to be used in food production.^[14] In 1871 Louis Pasteur discovered that heating juices to a certain temperature kills dangerous bacteria, affecting wine and fermentation. The eponymous pasteurization was applied to milk, to improve food safety.^[14]

The discovery of enzymes and their role in fermentation and digestion of foods led to the use of genetically modified microbes to make enzymes such as the protease chymosin for cheese production. Cheese had typically been made using the enzyme complex rennet that had extracted from cows' stomach lining. Scientists modified bacteria to produce chymosin, which was also able to clot milk, resulting in cheese curds.^[14] Microbial enzymes became the first application of genetically modified organisms in food production and were approved in 1988 by the US Food and Drug Administration.^[15]

Scientists discovered in 1946 that DNA can transfer between organisms.^[16] The first genetically modified plant was produced in 1983, using antibiotic-resistant tobacco. In 1994, the transgenic Flavr Savr tomato was approved by the FDA for marketing in the US. The modification allowed the tomato to delay ripening after picking.^[2] In the early 1990s, recombinant chymosin was approved for use in several countries.^[15][17]

In the US in 1995, the following transgenic crops received marketing approval: canola with modified oil composition (Calgene), Bacillus thuringiensis (Bt) corn/maize (Ciba-Geigy), cotton resistant to the herbicide bromoxynil (Calgene), Bt cotton (Monsanto), Bt potatoes (Monsanto), glyphosate-tolerant soybeans (Monsanto), virus-resistant squash (Monsanto-Asgrow), and additional delayed ripening tomatoes (DNAP, Zeneca/Peto, and Monsanto).^[2] In 2000, with the creation of golden rice, scientists genetically modified food to increase its nutrient value for the first time. As of 2011, the US is the leading country in the production of GM foods. Twenty-five GM crops had received regulatory approval.^[18] As of 2013, roughly 85% of corn, 91% of soybeans, and 88% of cotton produced in the US are genetically modified.^[19]

Process

Main articles: Genetic engineering and Genetically modified crops

Genetically engineered plants are generated in a laboratory by altering their genetic makeup and are tested in the laboratory for desired qualities. The most common modification is to add one or more genes to a plant's genome. Less commonly, genes are removed or silenced.

Once satisfactory plants are produced, the producer applies for regulatory approval to field-test them. Field-testing involves cultivating the plants on farm fields. If these field tests are successful, the producer applies for regulatory approval to grow and market the crop. (see Regulation of the release of genetic modified organisms). Once approved (which can take years) seeds (or cuttings, etc.) are cultivated and sold to farmers. The farmers plant, cultivate and harvest the new strain, which contains the modification. The farmers then sell their crops as commodities in countries where such sales are permitted. In some cases, the approval covers marketing but not cultivation.

GMOs have varying relationships to food. Some are consumed unprocessed, while others are processed in ways that remove DNA and its immediate products (proteins). Others are used to produce unmodified foods. Plant and animal relationship differ.

Foods containing modified DNA/protein

GM foods that include modified DNA and/or protein include fruits, vegetables, corn and soy. Corn and soy are also consumed after modifications that remove most/all DNA/protein.

Fruits and vegetables

3 views of the Sunset papaya cultivar, which was genetically modified to create the SunUp cultivar, resistant to PRSV.^[20]

Papaya was genetically modified to resist the ringspot virus. 'SunUp' is a transgenic red-fleshed Sunset cultivar that is homozygous for the coat protein gene of PRSV; 'Rainbow' is a yellow-fleshed F1 hybrid developed by crossing 'SunUp' and nontransgenic yellow-fleshed 'Kapoho'.^[20] The New York Times stated, "in the early 1990s, Hawaii’s papaya industry was facing disaster because of the deadly papaya ringspot virus. Its single-handed savior was a breed engineered to be resistant to the virus. Without it, the state’s papaya industry would have collapsed. Today, 80% of Hawaiian papaya is genetically engineered, and there is still no conventional or organic method to control ringspot virus."^[21] The GM cultivar was approved in 1998.^[22] In China, a transgenic PRSV-resistant papaya was developed by South China Agricultural University and was first approved for commercial planting in 2006; as of 2012 95% of the papaya grown in Guangdong province and 40% of the papaya grown in Hainan province was genetically modified.^[23]

The New Leaf potato, brought to market by Monsanto in the late 1990s, was developed for the fast food market, but was withdrawn in 2001 after fast food retailers rejected it and food processors ran into export problems.^[24]

As of 2005, about 13% of the Zucchini (a form of squash) grown in the US was genetically modified to resist three viruses; that strain is also grown in Canada.^[25][26]

In 2011, BASF requested the European Union Food Safety Authority's approval for cultivation and marketing of its Fortuna potato as a feed and food. The potato was made resistant to late blight by adding resistant genes blb1 and blb2 that originate from the Mexican wild potato Solanum bulbocastanum.^[27][28] In February 2013, BASF withdrew its application.^[29]

In 2013, the USDA approved the import of a GM pineapple that is pink in color and that "overexpresses" a gene derived from tangerines and suppress other genes, increasing production of lycopene. The plant's flowering cycle was changed to provide for more uniform growth and quality. The fruit "does not have the ability to propagate and persist in the environment once they have been harvested," according to USDA APHIS. According to Del Monte's submission, the pineapples are commercially grown in a "monoculture" that prevents seed production, as the plant's flowers aren't exposed to compatible pollen sources. Importation into Hawaii is banned for plant sanitation reasons.^[30]

In 2014, the USDA approved a genetically modified potato developed by J.R. Simplot Company, which contains 10 genetic modifications that prevent bruising and produce less acrylamide when fried than conventional potatoes; the modifications do not cause new proteins to be made, but rather prevent proteins from being made, via RNA interference.^[31][32]

In February 2015 Arctic Apples were approved by the USDA,^[33] becoming the first genetically modified apple approved for sale in the United States.^[34] Gene silencing is used to reduce the expression of polyphenol oxidase (PPO), thus preventing the fruit from browning.^[35]

Corn

Corn used for food has been genetically modified to tolerate various herbicides and to express a protein from Bacillus thuringiensis (Bt) that kills certain insects.^[36] About 90% of the corn grown in the US has been genetically modified.^[37] Corn can be processed into grits, meal and flour as an ingredient in pancakes, muffins, doughnuts, breadings and batters, as well as baby foods, meat products, cereals, and some fermented products. Masa flour is variety of flour that is produced using the alkaline-cooked process. A related product, masa dough, can be made using corn flour and water. Masa flour and masa dough are used in the production of taco shells, corn chips, and tortillas.^[38]

Soy

Genetically modified soybean has been modified to tolerate herbicides, express Bt, and produce healthier oils.^[37] About 90% of soybeans in the US are genetically modified.^[39] In 2015, 94% of soybean acreage in the U.S. was glyphosate-tolerant.^[40] Soybeans contain about 20% oil. In the most common method used to extract the oil, the soybeans are cracked, adjusted for moisture content, rolled into flakes and solvent-extracted with commercial hexane. The remaining soy meal has a 50% soy protein content. The meal is 'toasted' (a misnomer because the heat treatment is with moist steam) and ground in a hammer mill. Part of the balance is processed further into high protein soy products that are used in a variety of foods, such as salad dressings, soups, meat analogues, beverage powders, cheeses, nondairy creamer, frozen desserts, whipped topping, infant formulas, breads, breakfast cereals, pastas, and pet foods.^[41][42] Processed soy protein appears in foods mainly in three forms: soy flour, soy protein isolates and soy protein concentrates.^[42][43]

Food-grade soy protein isolate first became available on October 2, 1959 with the opening of Central Soya's edible soy isolate production facility on the Glidden Company industrial site in Chicago.^{[44]: 227–28} Soy protein isolate is a highly refined form of soy protein with a minimum protein content of 90% on a moisture-free basis. It is made from soy meal that has had most of the fats and carbohydrates removed. Soy isolates are mainly used to improve the texture of processed meat products and to increase protein content, enhance moisture retention, and as an emulsifier.^[45][46]

Soy protein concentrate is about 70% soy protein and is basically soybean meal without carbohydrates. Soy protein concentrate retains most of the bean fiber. It is used as a functional or nutritional ingredient in a wide variety of food products, mainly in baked foods, breakfast cereals and in some meat products. Soy protein concentrate is used in meat and poultry products to increase water and fat retention and to improve nutritional values (more protein, less fat).^[45][47]

Soy flour is made by grinding soybeans into a fine powder. It comes in three forms: natural or full-fat (contains natural oils); defatted (oils removed) with 50% protein content and with either high water solubility or low water solubility; and lecithinated (lecithin added). As soy flour is gluten-free, yeast-raised breads made with soy flour are dense in texture. Soy grits are similar to soy flour except the soybeans have been toasted and cracked into coarse pieces. Kinako is a soy flour used in Japanese cuisine.^[45][48]

Textured soy protein (TSP) is made by forming a dough from meal with water in a screw-type extruder, and heating with or without steam. The dough is extruded through a die into various shapes and dried in an oven. The extrusion technology changes the structure of the soy protein, resulting in a fibrous, spongy matrix similar in texture to meat. TSP is used as a low-cost substitute in meat and poultry products.^[45][49]

Derivative products

Corn starch and starch sugars, including syrups

Structure of the amylose molecule

Structure of the amylopectin molecule

Starch or amylum is a polysaccharide is produced by all green plants as an energy store. Pure starch is a white, tasteless and odourless powder that is insoluble in cold water or alcohol. It consists of two types of molecules: the linear and helical amylose and the branched amylopectin. Depending on the plant, starch generally contains 20 to 25% amylose and 75 to 80% amylopectin by weight. To make corn starch, corn is steeped for 30 to 48 hours, which ferments it slightly. The germ is separated from the endosperm and those two components are ground separately (still soaked). Next the starch is removed from each by washing. The starch is separated from the corn steep liquor, the cereal germ, the fibers and the corn gluten mostly in hydrocyclones and centrifuges, and then dried. This process is called wet milling and results in pure starch. The products of that pure starch contain no GM DNA or protein.^[50]

Starch can be further modified to create modified starch for specific purposes,^[51] including creation of many of the sugars in processed foods. They include:

• Maltodextrin, a lightly hydrolyzed starch product used as a bland-tasting filler and thickener.
• Various glucose syrups, also called corn syrups in the US, viscous solutions used as sweeteners and thickeners in many kinds of processed foods.
• Dextrose, commercial glucose, prepared by the complete hydrolysis of starch.
• High fructose syrup, made by treating dextrose solutions with the enzyme glucose isomerase, until a substantial fraction of the glucose has been converted to fructose. In the United States, high fructose corn syrup is the principal sweetener used in sweetened beverages because fructose has better handling characteristics, such as microbiological stability, and more consistent sweetness/flavor. One kind of high fructose corn syrup, HFCS-55, is typically sweeter than regular sucrose because it is made with more fructose, while the sweetness of HFCS-42 is on par with sucrose.^[52]

• Sugar alcohols, such as maltitol, erythritol, sorbitol, mannitol and hydrogenated starch hydrolysate, are sweeteners made by reducing sugars.

Lecithin

Corn oil and soy oil, already free of protein and DNA,^{[citation needed]} are sources of lecithin, which is widely used in processed foods as an emulsifier.^{[53][better source needed][54][page needed]} Lecithin is sufficiently processed that protein or DNA from the original crop from which it is derived is often undetectable with standard testing practices.^{[50][failed verification]} Nonetheless, consumer concerns about GM food extend to such products.^{[55][better source needed]} This concern led to policy and regulatory changes in Europe in 2000,^{[citation needed]} when Regulation (EC) 50/2000 was passed^[56] which required labelling of food containing additives derived from GMOs, including lecithin.^{[citation needed]} Because of the difficulty of detecting the origin of derivatives like lecithin with current testing practices, European regulations require those who wish to sell lecithin in Europe to employ a comprehensive system of Identity preservation (IP).^{[57][verification needed][58][page needed]}

Sugar

Structure of sucrose

The US imports 10% of its sugar from other countries, while the remaining 90% is extracted from domestically grown sugar beet and sugarcane. Domestically grown sugar crops come half from beet, and the other half from cane. After deregulation in 2005, glyphosate-resistant sugar beet was extensively adopted in the United States. 95% of beet acres in the US were planted with glyphosate-resistant seed in 2011.^[18] Herbicide-tolerant beets are also approved in Australia, Canada, Colombia, EU, Japan, Korea, Mexico, New Zealand, Philippines, Russian Federation and Singapore.^[59] The food products of sugar beets are refined sugar and molasses. Pulp from the refining process is used as animal feed. The sugar produced from GM sugarbeets contains no DNA or protein—it is just sucrose, chemically indistinguishable from sugar produced from non-GM sugarbeets.^[50][60]

Vegetable oil

Most vegetable oil used in the US is produced from GM crops canola,^[61] corn,^[53][62] cotton^[63] and soybeans.^[64] Vegetable oil is sold directly to consumers as cooking oil, shortening and margarine^[65] and is used in prepared foods. There is a vanishingly small amount of protein or DNA from the original crop in vegetable oil.^[50][66] Vegetable oil is made of triglycerides extracted from plants or seeds and then refined and may be further processed via hydrogenation to turn liquid oils into solids. The refining process^[67] removes all, or nearly all non-triglyceride ingredients.^[68]

Other uses

GM animal feed

Livestock and poultry are raised on animal feed, much of which is composed of the leftovers from processing crops, including GM crops. For example, approximately 43% of a canola seed is oil. What remains after oil extraction is a meal that becomes an ingredient in animal feed and contains canola protein.^[69] Likewise, the bulk of the soybean crop is grown for oil and meal. The high-protein defatted and toasted soy meal becomes livestock feed and dog food. 98% of the US soybean crop goes for livestock feed.^[70][71] In 2011, 49% of the US maize harvest was used for livestock feed (including the percentage of waste from distillers grains).^[72] "Despite methods that are becoming more and more sensitive, tests have not yet been able to establish a difference in the meat, milk, or eggs of animals depending on the type of feed they are fed. It is impossible to tell if an animal was fed GM soy just by looking at the resulting meat, dairy, or egg products. The only way to verify the presence of GMOs in animal feed is to analyze the origin of the feed itself."^[73]

Artificially produced proteins

Rennet is a mixture of enzymes used to coagulate milk into cheese. Originally it was available only from the fourth stomach of calves, and was scarce and expensive, or was available from microbial sources, which often produced unpleasant tastes. Genetic engineering made it possible to extract rennet-producing genes from animal stomachs and insert them into bacteria, fungi or yeasts to make them produce chymosin, the key enzyme in rennet.^[74][75] The modified microorganism is killed after fermentation. Chymosin is isolated from the fermentation broth, so that the Fermentation-Produced Chymosin (FPC) used by cheese producers has an amino acid sequence that is identical to bovine rennet.^[76] The majority of the applied chymosin is retained in the whey. Some chymosin may remain in cheese in trace quantities.^[76]

FPC was the first artificially produced enzyme to be registered and allowed by the US Food and Drug Administration.^[15][17] FPC products have been on the market since 1990 and have been considered in the last 20 years to be the ideal milk-clotting enzyme.^[77] In 1999, about 60% of US hard cheese was made with FPC.^[78] Its global market share approaches 80%.^[79] By 2008, approximately 80% to 90% of commercially made cheeses in the US and Britain were made using FPC.^[76] The most widely used FPC is produced either by the fungus Aspergillus niger (CHY-MAX®)^[80] by Danish company Chr. Hansen, or produced by Kluyveromyces lactis (MAXIREN®)^[81] by Dutch company DSM.

In some countries, recombinant (GM) bovine somatotropin (also called rBST, or bovine growth hormone or BGH) is approved for administration to increase milk production. rBST may be present in milk from rBST treated cows, but it is destroyed in the digestive system and even if directly injected into the human bloodstream, has no direct effect on humans.^[82][83] The Food and Drug Administration, World Health Organization, American Medical Association, American Dietetic Association and the National Institutes of Health have independently stated that dairy products and meat from rBST-treated cows are safe for human consumption.^[84] However, on 30 September 2010, the United States Court of Appeals, Sixth Circuit, analyzing submitted evidence, found that there is a "compositional difference" between milk from rBGH-treated cows and milk from untreated cows.^[85][86] The court stated that milk from rBGH-treated cows has: increased levels of the hormone Insulin-like growth factor 1 (IGF-1); higher fat content and lower protein content when produced at certain points in the cow's lactation cycle; and more somatic cell counts, which may "make the milk turn sour more quickly."^[86]

GM animals

As of November 2013 no genetically modified animals approved had been for use as food, but a GM salmon had been awaiting regulatory approval^[87][88][89] since 1997.^[90] Some mammals typically used for food production have been modified to produce non-food products, a practice sometimes called Pharming. Genetically modified goats have been approved by the FDA and EMA to produce recombinant antithrombin, an anticoagulant protein drug.^[91] Research and experiments have gone into adding promoter genes into animals to accelerate growth and to increase disease resistance (e.g., injection of a-lactalbumin gene into pigs.)^[92]

Controversies

Main article: Genetically modified food controversies

The genetically modified foods controversy is a dispute over the use of food and other goods derived from genetically modified crops and other uses of genetic engineering in food production. The dispute involves consumers, farmers, biotechnology companies, governmental regulators, non-governmental organizations, activists and scientists. The key areas of controversy are whether GM food should be labeled, the role of government regulators, objectivity of scientific research and publication, and the effects on health, the environment,^[93][94] pesticide resistance, farmers and on feeding the world population. Other concerns include contamination of the conventional food supply,^[95] rigor of the regulatory process,^[96][97] and control of the food supply by GM seed companies.^[93]

There is broad scientific consensus that food on the market derived from GM crops poses no greater risk than conventional food.^[4][98][99] No reports of ill effects have been documented in the human population from GM food.^[5][7][100] The starting point for assessing GM food safety is to evaluate its similarity to the non-modified version. Further testing is then done on a case-by-case basis to ensure that concerns over potential toxicity and allergenicity are satisfied. Although labeling of GMO products in the marketplace is required in 64 countries,^[101] the US does not require this. The FDA's policy is to require a label given significant differences in composition or health impacts. They have not identified such differences in any food currently approved for sale.^[102]

Opponents such as the advocacy groups Organic Consumers Association, the Union of Concerned Scientists, and Greenpeace claim risks have not been adequately identified and managed, and they have questioned the objectivity of regulatory authorities.^{[citation needed]} Some health groups claim that the potential long-term impact on human health have not been adequately assessed and propose mandatory labeling^[103][104] or a moratorium on such products.^[93][94][96]

Regulation

See also: Regulation of the release of genetic modified organisms and Regulation of genetic engineering

Green: Mandatory labeling required; Red:Ban on import and cultivation of genetically engineered food.

Governments invoke varied processes to assess and manage the use of genetic engineering technology and GMO development and release, including crops and fish. Marked differences separate the US and Europe. Regulation varies idepending on the intended product use. For example, a crop not intended for food use is generally not reviewed by authorities responsible for food safety.^[24]

In the United States, three different government organizations are responsible for regulating GMOs. The Food and Drug Administration (FDA) checks the chemical composition of the organism for any potential allergens. The United States Department of Agriculture (USDA) supervises field testing and monitors the distribution of GM seeds. The United States Environmental Protection Agency (EPA) is responsible for monitoring pesticide usage, including plants modified to contain proteins toxic to insects. Like the USDA, the EPA also oversees field testing and the distribution of crops that have had contact with pesticides to ensure the GMOs are safe for the environment.^{[105][better source needed]} In 2015 the Obama administration announced that it would update the way the government regulated genetically modified crops.^[106]

One of the key issues concerning regulators is whether GM products should be labeled.^{[citation needed]} Labeling can be mandatory when a product exceeds a threshold content level (which varies between countries) or voluntary. A study that investigated voluntary labeling in South Africa, found that 31% of products labeled as GMO-free had a GM content above 1.0%.^[107] In Canada and the USA labeling is voluntary,^{[108][citation needed]} while in Europe all food (including processed food) or feed that contains greater than 0.9% of GMOs must be labelled.^[109]

As of 2015, 64 countries require GMO labeling;^[110] more than a third of these in compliance with a single EU ruling.^{[citation needed]}

Detection

Main article: Detection of genetically modified organisms

Testing on GMOs in food and feed is routinely done using molecular techniques such as PCR and bioinformatics.^[111]

In a January 2010 paper,^[112] the extraction and detection of DNA along a complete industrial soybean oil processing chain was described to monitor the presence of Roundup Ready (RR) soybean: "The amplification of soybean lectin gene by end-point polymerase chain reaction (PCR) was successfully achieved in all the steps of extraction and refining processes, until the fully refined soybean oil. The amplification of RR soybean by PCR assays using event-specific primers was also achieved for all the extraction and refining steps, except for the intermediate steps of refining (neutralisation, washing and bleaching) possibly due to sample instability. The real-time PCR assays using specific probes confirmed all the results and proved that it is possible to detect and quantify genetically modified organisms in the fully refined soybean oil. To our knowledge, this has never been reported before and represents an important accomplishment regarding the traceability of genetically modified organisms in refined oils."

See also

• California Proposition 37 (2012)
• Chemophobia
• Genetic engineering
• Genetically modified crops
• Genetically modified food controversies
• Genetically modified organisms
• Regulation of the release of genetic modified organisms
• Starlink corn recall

References

1. GM Science Review First Report, Prepared by the UK GM Science Review panel (July 2003). Chairman Professor Sir David King, Chief Scientific Advisor to the UK Government, P 9
2. James, Clive (1996). "Global Review of the Field Testing and Commercialization of Transgenic Plants: 1986 to 1995" (PDF). The International Service for the Acquisition of Agri-biotech Applications. Retrieved 17 July 2010.
3. "Consumer Q&A". Fda.gov. 2009-03-06. Retrieved 2012-12-29.
4. American Association for the Advancement of Science (AAAS), Board of Directors (2012). Statement by the AAAS Board of Directors On Labeling of Genetically Modified Foods, and associated Press release: Legally Mandating GM Food Labels Could Mislead and Falsely Alarm Consumers
5. American Medical Association (2012). Report 2 of the Council on Science and Public Health: Labeling of Bioengineered Foods
6. World Health Organization. Food safety: 20 questions on genetically modified foods. Accessed December 22, 2012.
7. United States Institute of Medicine and National Research Council (2004). Safety of Genetically Engineered Foods: Approaches to Assessing Unintended Health Effects. National Academies Press. Free full-text. See pp11ff on need for better standards and tools to evaluate GM food. Cite error: The named reference "NRC2004" was defined multiple times with different content (see the help page).
8. A decade of EU-funded GMO research (2001-2010) (PDF). Directorate-General for Research and Innovation. Biotechnologies, Agriculture, Food. European Union. 2010. p. 16. doi:10.2777/97784. ISBN 978-92-79-16344-9.
9. Other sources:
   • Tamar Haspel for the Washington Post. October 15, 2013. Genetically modified foods: What is and isn’t true
   • Winter CK and Gallegos LK (2006). Safety of Genetically Engineered Food. University of California Agriculture and Natural Resources Communications, Publication 8180.
   • Ronald, Pamela (2011). "Plant Genetics, Sustainable Agriculture and Global Food Security". Genetics. 188 (1): 11–20. doi:10.1534/genetics.111.128553. PMC 3120150. PMID 21546547.
   • Miller, Henry (2009). "A golden opportunity, squandered" (PDF). Trends in Biotechnology. 27 (3): 129–130. doi:10.1016/j.tibtech.2008.11.004. PMID 19185375.
   • Dr. Christopher Preston, AgBioWorld 2011. Peer Reviewed Publications on the Safety of GM Foods.
10. Hilbeck; et al. (2015). "No scientific consensus on GMO safety" (PDF). Environmental Sciences Europe. doi:10.1186/s12302-014-0034-1. {{cite journal}}: Explicit use of et al. in: |author= (help)
11. Lee, B. H. (1996). Fundamentals of food biotechnology. Montreal, QC: Wiley-VCH.
12. Food Insight (2009). Background on Food Biotechnology
13. Biotechnology Online (2009). A food biotechnology timeline
14. Campbell-Platt,G. (2009). Food Science and technology. Ames, IA: Blackwell
15. "FDA Approves 1st Genetically Engineered Product for Food". Los Angeles Times. 24 March 1990. Retrieved 1 May 2014.
16. Lederberg J, Tatum EL (1946). "Gene recombination in E. coli". Nature. 158 (4016): 558. Bibcode:1946Natur.158..558L. doi:10.1038/158558a0.
17. Staff, National Centre for Biotechnology Education, 2006. Case Study: Chymosin
18. James, C (2011). "ISAAA Brief 43, Global Status of Commercialized Biotech/GM Crops: 2011". ISAAA Briefs. Ithaca, New York: International Service for the Acquisition of Agri-biotech Applications (ISAAA). Retrieved 2012-06-02. Cite error: The named reference "James2011" was defined multiple times with different content (see the help page).
19. Center for Food Safety About Genetically Engineered Foods
20. Gonsalves, D. (2004). Transgenic papaya in Hawaii and beyond. AgBioForum, 7(1&2), 36-40
21. Ronald, Pamela and McWilliams, James Genetically Engineered Distortions The New York Times, May 14, 2010, Retrieved July 26, 2010.
22. "The Rainbow Papaya Story". Hawaii Papaya Industry Association. Retrieved April 2015. {{cite web}}: Check date values in: |accessdate= (help)
23. Li Y et al. Biosafety management and commercial use of genetically modified crops in China. Plant Cell Rep. 2014 Apr;33(4):565-73. PMID 24493253
24. "The History and Future of GM Potatoes". Potatopro.com. 2010-03-10. Retrieved 2012-12-29. Cite error: The named reference "PotatoPro" was defined multiple times with different content (see the help page).
25. Johnson, Stanley R. et al Quantification of the Impacts on US Agriculture of Biotechnology-Derived Crops Planted in 2006 National Center for Food and Agricultural Policy, Washington DC, February 2008. Retrieved August 12, 2010.
26. GMO Compass. Page updated November 7, 2007. GMO Database: Zucchini (courgette) Page accessed Feb 28 2015
27. Research in Germany, November 17, 2011. Business BASF applies for approval for another biotech potato
28. Burger, Ludwig (31 October 2011) BASF applies for EU approval for Fortuna GM potato Reuters, Frankfurt. Retrieved 29 December 2011
29. Andrew Turley for Royal Society of Chemistry News. February 7, 2013 BASF drops GM potato projects
30. PERKOWSKI, MATEUSZ (April 16, 2013). "Del Monte Gets Approval to Import GMO Pineapple". Food Democracy Now. {{cite news}}: |access-date= requires |url= (help); Check date values in: |access-date= (help)
31. Andrew Pollack for the New York Times. 7 Nov 2014. U.S.D.A. Approves Modified Potato. Next Up: French Fry Fans
32. Federal Register. May 3, 2013. J.R. Simplot Co.; Availability of Petition for Determination of Nonregulated Status of Potato Genetically Engineered for Low Acrylamide Potential and Reduced Black Spot Bruise
33. Pollack, A. "Gene-Altered Apples Get U.S. Approval" New York Times. Feb 13, 2015.
34. Tennille, Tracy (Feb 13, 2015). "First Genetically Modified Apple Approved for Sale in U.S." Wall Street Journal. Retrieved Feb 2015. {{cite web}}: Check date values in: |access-date= (help)
35. "Apple-to-apple transformation". Okanagan Specialty Fruits. Retrieved 2012-08-03.
36. For a list of all traits, see table at National Corn Growers Association website As of September 2012 that site listed 13 traits in nearly 30 different products.
37. Acreage NASS National Agricultural Statistics Board annual report, 30 June 2010. Retrieved 23 July 2010. Cite error: The named reference "NASS2010" was defined multiple times with different content (see the help page).
38. Staff. South Dakota State University, College of Agriculture and Biological Sciences, Agricultural Experiment Station. June 2004. Corn-Based Food Production in South Dakota: A Preliminary Feasibility Study
39. Jorge Fernandez-Cornejo. "USDA ERS - Adoption of Genetically Engineered Crops in the U.S." usda.gov.
40. {{cite web}}: Empty citation (help)
41. Edmund W. Lusas and Mian N Riaz. (1995) Soy Protein Products: Processing and Use Journal of Nutrition 125 (3_Suppl):573S-580S
42. E.S. Sipos. Edible Uses of Soybean Protein
43. Singh, Preeti; Kumar, R.; Sabapathy, S. N.; Bawa, A. S. (2008). "Functional and Edible Uses of Soy Protein Products". Comprehensive Reviews in Food Science and Food Safety. 7: 14–28. doi:10.1111/j.1541-4337.2007.00025.x.
44. William Shurtleff, Akiko Aoyagi History of Cooperative Soybean Processing in the United States: Extensively Annotated Bibliography and Sourcebook Soyinfo Center, 2008
45. presentation by Dr. Karl Weingartner and Bridget Owen of the National Soybean Research Laboratory, University of Illinois at Urbana-Champaign. March 2009. Soy Protein Applications in Nutrition & Food Technology
46. Isolated Soy Proteins
47. Staff, World Initiative for Soy in Human Health (WISHH) Soy Protein Concentrate Reference Guide
48. Soy Flours
49. Textured Soy Proteins
50. Jaffe,Greg (Director of Biotechnology at the Center for Science in the Public Interest) (February 7, 2013). "What You Need to Know About Genetically Engineered Food". Atlantic.
51. "International Starch: Production of corn starch". Starch.dk. Retrieved 2011-06-12.
52. White JS Sucrose, HFCS, and Fructose: History, Manufacture, Composition, Applications, and Production. Chapter 2 in J.M. Rippe (ed.), Fructose, High Fructose Corn Syrup, Sucrose and Health, Nutrition and Health. Springer Science+Business Media New York 2014. ISBN 9781489980779.
53. "Poster of corn products" (PDF). Retrieved 2012-12-29.
54. "Corn Oil, 5th Edition" (PDF). Corn Refiners Association. 2006.
55. Staff (July 1, 2005). "Danisco emulsifier to substitute non-GM soy lecithin as demand outstrips supply". FoodNavigator.com.
56. "Regulation (EC) 50/2000". Eur-lex.europa.eu.
57. Marx,Gertruida M. (December 2010). "Dissertation submitted in fulfilment of requirements for the degree Doctor of Philosophy in the Faculty of Health Sciences" (PDF). MONITORING OF GENETICALLY MODIFIED FOOD PRODUCTS IN SOUTH AFRICA]. South Africa: University of the Free State.
58. Davison, John & Bertheau, Yves Bertheau (2007). "EU regulations on the traceability and detection of GMOs: difficulties in interpretation, implementation and compliance". CAB Reviews: Perspectives in Agriculture, Veterinary Science, Nutrition and Natural Resources. 2 (77).
59. "ISAAA Pocket K No. 2: Plant Products of Biotechnology". Isaaa.org. Retrieved 2012-12-29.
60. Food and Agriculture Organization of the United Nations (2009). Sugar Beet: White Sugar (PDF). p. 9.
61. "Soyatech.com". Soyatech.com. Retrieved 2012-12-29.
62. Institute of Shortening and Edible Oils, 2006. Food Fats and Oils accessdate=2011-11-19
63. National Cottonseed Producers Association Twenty Facts about Cottonseed Oil
64. Michelle Simon for Food Safety News. August 24, 2011. ConAgra Sued Over GMO ’100% Natural’ Cooking Oils
65. "ingredients of margarine". Imace.org. Retrieved 2012-12-29.
66. "USDA Protein(g) in Fats and Oils". Retrieved 2015-05-31.
67. "How Cooking Oil is Made". Madehow.com. 1991-04-27. Retrieved 2012-12-29.
68. Crevel, R.W.R; Kerkhoff, M.A.T; Koning, M.M.G (2000). "Allergenicity of refined vegetable oils". Food and Chemical Toxicology. 38 (4): 385–93. doi:10.1016/S0278-6915(99)00158-1. PMID 10722892.
69. "What is Canola Oil?". CanolaInfo. Retrieved 2012-12-29.
70. David Bennett for Southeast Farm Press, February 5, 2003 World soybean consumption quickens
71. "Soybean". Encyclopedia Britannica Online. Retrieved February 18, 2012.
72. "2012 World of Corn, National Corn Growers Association" (PDF). Retrieved 2012-12-29.
73. Staff, GMO Compass. December 7, 2006. Genetic Engineering: Feeding the EU's Livestock
74. Emtage, JS; Angal, S; Doel, MT; Harris, TJ; Jenkins, B; Lilley, G; Lowe, PA (1983). "Synthesis of calf prochymosin (prorennin) in Escherichia coli". Proceedings of the National Academy of Sciences of the United States of America. 80 (12): 3671–5. doi:10.1073/pnas.80.12.3671. PMC 394112. PMID 6304731.
75. Harris TJ, Lowe PA, Lyons A, Thomas PG, Eaton MA, Millican TA, Patel TP, Bose CC, Carey NH, Doel MT (April 1982). "Molecular cloning and nucleotide sequence of cDNA coding for calf preprochymosin". Nucleic Acids Res. 10 (7): 2177–87. doi:10.1093/nar/10.7.2177. PMC 320601. PMID 6283469.
76. "Chymosin". GMO Compass. Retrieved 2011-03-03.
77. Law, Barry A. (2010). Technology of Cheesemaking. UK: WILEY-BLACKWELL. pp. 100–101. ISBN 978-1-4051-8298-0.
78. "Food Biotechnology in the United States: Science, Regulation, and Issues". U.S. Department of State. Retrieved 2006-08-14.
79. Johnson, M.E.; Lucey, J.A. (2006). "Major Technological Advances and Trends in Cheese". Journal of Dairy Science. 89 (4): 1174–8. doi:10.3168/jds.S0022-0302(06)72186-5. PMID 16537950.
80. Enzymes - Chr. Hansen | Improving Food & Health. Chr. Hansen. Retrieved on 2014-01-14.
81. DMS cheese enzymes page
82. Dale E. Baumana and Robert J Collier. September 15, 2010 Use of Bovine Somatotropin in Dairy Production
83. Staff, American Cancer Society. Last Medical Review: 02/18/2011; Last Revised: 02/18/2011. Recombinant Bovine Growth Hormone
84. Charlotte P. Brennand, PhD, Extension Food Safety Specialist. "Bovine Somatotropin in Milk" (PDF). Retrieved 2011-03-06.
85. Greg Cima, November for JAVMA News. November 18, 2010. Appellate court gives mixed ruling on Ohio rBST labeling rules
86. leagle.com. "INTERNATIONAL DAIRY FOODS ASS'N v. BOGGS – Argued: June 10, 2010". Leagle.com.
87. Rick MacInnes-Rae for CBC News. November 27, 2013 GMO salmon firm clears one hurdle but still waits for key OKs AquaBounty began seeking American approval in 1995
88. Andrew Pollack for the New York Times. "An Entrepreneur Bankrolls a Genetically Engineered Salmon" Published: May 21, 2012. Accessed September 3, 2012
89. Staff (26 December 2012) Draft Environmental Assessment and Preliminary Finding of No Significant Impact Concerning a Genetically Engineered Atlantic Salmon; Availability Federal Register / Vol. 77, No. 247 / Wednesday, December 26, 2012 / Notices, Retrieved 2 January 2013
90. Naik, Gautam (September 21, 2010). "Gene-Altered Fish Closer to Approval". Wall Street Journal.
91. Andre Pollack for the New York Times. February 6, 2009 F.D.A. Approves Drug From Gene-Altered Goats
92. Bleck, GT; White, BR; Miller, DJ; Wheeler, MB (December 1998). "Production of bovine alpha-lactalbumin in the milk of transgenic pigs". Journal of animal science. 76 (12): 3072–8. PMID 9928612.
93. Canadian Association of Physicians for the Environment (2013) Statement on Genetically Modified Organisms in the Environment and the Marketplace. October, 2013
94. PR Newswire Genetically Modified Maize: Doctors' Chamber Warns of "Unpredictable Results" to Humans. November 11, 2013
95. Chartered Institute of Environmental Health (2006) Proposals for managing the coexistence of GM, conventional and organic crops Response to the Department for Environment, Food and Rural Affairs consultation paper. October 2006
96. Irish Doctors’ Environmental Association IDEA Position on Genetically Modified Foods. Retrieved 3/25/14
97. American Medical Association (2012). Report 2 of the Council on Science and Public Health: Labeling of Bioengineered Foods. "To better detect potential harms of bioengineered foods, the Council believes that pre-market safety assessment should shift from a voluntary notification process to a mandatory requirement." page 7
98. Ronald, Pamela (2011). "Plant Genetics, Sustainable Agriculture and Global Food Security". Genetics. 188 (1): 11–20. doi:10.1534/genetics.111.128553. PMC 3120150. PMID 21546547.
99. Bett, Charles; Ouma, James Okuro; Groote, Hugo De (August 2010). "Perspectives of gatekeepers in the Kenyan food industry towards genetically modified food". Food Policy. 35 (4): 332–340. doi:10.1016/j.foodpol.2010.01.003.
100. Key S, Ma JK, Drake PM (June 2008). "Genetically modified plants and human health". J R Soc Med. 101 (6): 290–8. doi:10.1258/jrsm.2008.070372. PMC 2408621. PMID 18515776.
101. Hallenbeck, Terri (2014-04-27). "How GMO labeling came to pass in Vermont". Burlington Free Press. Retrieved 2014-05-28.
102. Van Eenennaam, Alison; Chassy, Bruce; Kalaitzandonakes, Nicholas; Redick, Thomas (2014). "The Potential Impacts of Mandatory Labeling for Genetically Engineered Food in the United States" (PDF). Council for Agricultural Science and Technology (CAST). 54 (April 2014). ISSN 1070-0021. Retrieved 2014-05-28. To date, no material differences in composition or safety of commercialized GE crops have been identified that would justify a label based on the GE nature of the product.
103. British Medical Association Board of Science and Education (2004). Genetically modified food and health: A second interim statement. March.
104. Public Health Association of Australia (2007) GENETICALLY MODIFIED FOODS PHAA AGM 2007
105. APPDMZ\ccvivr. "Commonly Asked Questions about the Food Safety of GMOs". monsanto.com.
106. Pollack, Andrew (2015-07-02). "White House Orders Review of Rules for Genetically Modified Crops". The New York Times. ISSN 0362-4331. Retrieved 2015-07-03.
107. Botha, Gerda M.; Viljoen, Christopher D. (2009). "South Africa: A case study for voluntary GM labelling". Food Chemistry. 112 (4): 1060–4. doi:10.1016/j.foodchem.2008.06.050.
108. "The Regulation of Genetically Modified Food".
109. Davison, John (2010). "GM plants: Science, politics and EC regulations". Plant Science. 178 (2): 94–8. doi:10.1016/j.plantsci.2009.12.005.
110. Center for Food Safety International Labeling Laws
111. European Commission Join Research Centre EU GMO testing homepage Page accessed May 31, 2015
112. Costa, Joana; Mafra, Isabel; Amaral, Joana S.; Oliveira, M.B.P.P. (2010). "Monitoring genetically modified soybean along the industrial soybean oil extraction and refining processes by polymerase chain reaction techniques". Food Research International. 43: 301. doi:10.1016/j.foodres.2009.10.003.

External links

• Documentary on YouTube
• Library resources in your library and in other libraries about Genetically modified food
• Media related to Genetically modified organisms at Wikimedia Commons