Crops Genetically modified crops (GM crops) are genetically modified plants that are used in
agriculture. The first crops developed were used for animal or human food and provide resistance to certain pests, diseases, environmental conditions,
spoilage or chemical treatments (e.g. resistance to a
herbicide). The second generation of crops aimed to improve the quality, often by altering the
nutrient profile. Third generation genetically modified crops could be used for non-food purposes, including the production of
pharmaceutical agents,
biofuels, and other industrially useful goods, as well as for
bioremediation. GM crops have been produced to improve harvests through reducing insect pressure, increase nutrient value and tolerate different
abiotic stresses. As of 2018, the
commercialised crops are limited mostly to
cash crops like cotton, soybean, maize/corn and canola and the vast majority of the introduced traits provide either herbicide tolerance or insect resistance. Most currently available genes used to engineer insect resistance come from the
Bacillus thuringiensis (Bt) bacterium and code for
delta endotoxins. A few use the genes that encode for
vegetative insecticidal proteins. The only gene commercially used to provide insect protection that does not originate from
B. thuringiensis is the
Cowpea trypsin inhibitor (CpTI). CpTI was first approved for use in cotton in 1999 and is currently undergoing trials in rice. Less than one percent of GM crops contained other traits, which include providing
virus resistance, delaying
senescence and altering the plants composition. Adoption by farmers has been rapid, between 1996 and 2013, the total surface area of land cultivated with GM crops increased by a factor of 100. Geographically though the spread has been uneven, with strong growth in the
Americas and parts of Asia and little in Europe and Africa most studies have found growing GM crops to be beneficial to farmers through decreased pesticide use as well as increased crop yield and farm profit.
Fruits and vegetables Sweet potato domestication, which began approximately 8,000–10,000 years ago, involved the incorporation of
Agrobacterium tumefaciens DNA into the crop's genome through horizontal gene transfer. Research by Kyndt et al. (2015) identified sequences of
Agrobacterium tumefaciens DNA persisting in modern sweet potato genomes; while this natural transgenic event demonstrates that horizontal gene transfer has long affected crop genetics, the specific traits enhanced by this transfer remain incompletely characterized.
Papaya was genetically modified to resist the
ringspot virus (PSRV). "SunUp" is a transgenic red-fleshed Sunset papaya
cultivar that is
homozygous for the coat protein gene PRSV; "Rainbow" is a yellow-fleshed
F1 hybrid developed by crossing 'SunUp' and nontransgenic yellow-fleshed "Kapoho". and by 2010 80% of Hawaiian papaya was genetically engineered. 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. In
Hong Kong, where there is an exemption on growing and releasing any varieties of GM papaya, more than 80% of grown and imported papayas were transgenic. The New Leaf potato, a GM food developed using
Bacillus thuringiensis (Bt), was made to provide in-plant protection from the yield-robbing
Colorado potato beetle. The New Leaf potato, brought to market by
Monsanto in the late 1990s, was developed for the fast food market. It was withdrawn in 2001 after retailers rejected it and food processors ran into export problems. In 2011,
BASF requested the
European Food Safety Authority's approval for cultivation and marketing of its Fortuna potato as 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. In February 2013, BASF withdrew its application. In 2014, the USDA approved a
genetically modified potato developed by
J. R. Simplot Company that contained ten genetic modifications that prevent bruising and produce less
acrylamide when fried. The modifications eliminate specific proteins from the potatoes, via
RNA interference, rather than introducing novel proteins. As of 2005, about 13% of the
Zucchini grown in the US was genetically modified to resist three viruses; that variety is also grown in Canada. s genetically engineered for resistance to
plum pox, a disease carried by
aphids 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. The US FDA approved sales of the pineapples in December 2016, and Del Monte launched sales of their pink pineapples in October 2020, marketed under the name "Pinkglow". In February 2015
Arctic Apples were approved by the USDA, becoming the first genetically modified apple approved for sale in the US.
Gene silencing is used to reduce the expression of
polyphenol oxidase (PPO), thus preventing the fruit from browning.
Tomatoes Following the withdrawal of the
Flavr Savr tomato from the market in 1999, genetically modified tomatoes were not sold in the United States for decades. In February 2024, the Purple Tomato, created by the UK-based Norfolk Plant Sciences, was launched to the public. It is distinguished by its striking purple color, which comes from the antioxidant
anthocyanin. Proponents suggest these tomatoes could provide health benefits due to their elevated antioxidant content.
Cathie Martin, who developed these tomatoes, reported in a study that mice fed these tomatoes lived 30% longer than control mice. Also in development in the UK are tomatoes enhanced with
Vitamin D. This tomato has increased provitamin D3 that when exposed to UVB light, converts to
Vitamin D3.
Maize/corn Maize/corn used for food and
ethanol has been genetically modified to tolerate various
herbicides and to express a protein from
Bacillus thuringiensis (Bt) that kills certain insects. About 90% of the corn grown in the US was genetically modified in 2010. In the US in 2015, 81% of corn acreage contained the Bt trait and 89% of corn acreage contained the glyphosate-tolerant trait.
Soy Soybeans accounted for half of all genetically modified crops planted in 2014. In 2015, 94% of
soybean acreage in the U.S. was genetically modified to be glyphosate-tolerant. It is intended to produce a fortified food to be grown and consumed in areas with a
shortage of dietary vitamin A, a deficiency which each year is estimated to kill 670,000 children under the age of 5 and cause an additional 500,000 cases of irreversible childhood blindness. The original golden rice produced 1.6μg/g of the
carotenoids, with further development increasing this 23 times. In 2018 it gained its first approvals for use as food.
Wheat As of December 2017,
genetically modified wheat has been evaluated in field trials, but has not been released commercially.
Alfalfa Alfalfa, a flowering plant in the legume family, has also been genetically modified. GMO alfalfa is typically used to feed dairy cattle. One particular genetic modification that has been made involves increased resistance to pesticides and herbicides. This modification allows farmers to spray surrounding areas for weeds without harming the alfalfa crops. If left unchecked, these destructive weeds can reduce the nutritional value of alfalfa.
Mushroom In April 2016, the USDA determined that a white button mushroom (
Agaricus bisporus) modified using CRISPR-Cas9 gene editing was exempt from regulatory review. Because the editing process deleted DNA sequences (rather than introducing foreign genetic material), the USDA classified the edited mushroom outside its regulatory authority under the Plant Protection Act. This exemption effectively permitted commercialization of the mushroom without formal pre-market safety assessment.
Livestock Genetically modified livestock are organisms from the group of cattle, sheep, pigs, goats, birds, horses and fish kept for human consumption, whose genetic material (
DNA) has been altered using
genetic engineering techniques. In some cases, the aim is to introduce a new
trait to the animals which does not occur naturally in the species, i.e.
transgenesis. A 2003 review published on behalf of
Food Standards Australia New Zealand examined transgenic experimentation on terrestrial livestock species as well as aquatic species such as fish and shellfish. The review examined the molecular techniques used for experimentation as well as techniques for tracing the
transgenes in animals and products as well as issues regarding transgene stability. Some mammals typically used for food production have been modified to produce non-food products, a practice sometimes called
Pharming.
Cows Transgenic cows, or cows that have had foreign DNA artificially inserted into their genome, were introduced in 2000 by
AgResearch scientists. The specific modification made was to provide these genetically altered cows with proteins in their milk to help treat human diseases.
Salmon A
GM salmon, awaiting regulatory approval since 1997, was approved for human consumption by the American
FDA in November 2015, to be raised in specific land-based hatcheries in Canada and Panama. This salmon, called the
AquAdvantage salmon, was designed to reach stages in growth sooner than non-GMO salmon. However, the producer of this salmon,
AquaBounty Technologies, closed their salmon facilities in December 2024 due to loss of funds.
Microbes Bacteriophages are an economically significant cause of
culture failure in
cheese production. Various culture microbes - especially
Lactococcus lactis and
Streptococcus thermophilus - have been studied for genetic analysis and modification to improve
phage resistance. This has especially focused on
plasmid and
recombinant chromosomal modifications.
Genetically modified microbes are also being utilized for farming and soil health. Proven, a genetically edited product created by the biotechnology company Pivot Bio, uses
nitrogen-fixing microbes instead of synthetic nitrogen in soil for crops such as corn. ==Derivative products==