Genetically modified organism (GMO),
organism whose genome has been engineered in the laboratory in order
to favour the expression of desired physiological traits or the
production of desired biological products. In conventional livestock production, crop farming, and even pet breeding, it has long been the practice to breed select individuals of a species in order to produce offspring that have desirable traits. In genetic
modification, however, recombinant genetic technologies are employed to
produce organisms whose genomes have been precisely altered at the
molecular level, usually by the inclusion of genes
from unrelated species of organisms that code for traits that would not
be obtained easily through conventional selective breeding.
Genetically
modified (GM) barley grown by researchers on a site belonging to
Giessen University (Justus-Liebig-Universität) in Germany. The GM barley
was investigated for its effects on soil quality.Ralph Orlowski/Getty Images
GMOs are produced through using scientific methods that include recombinant DNA technology and reproductive cloning. In reproductive cloning, a nucleus is extracted from a cell of the individual to be cloned and is inserted into the enucleated cytoplasm of a host egg. The process results in the generation of an offspring that is genetically identical to the donor individual. The first animal
produced by means of this cloning technique with a nucleus from an
adult donor cell (as opposed to a donor embryo) was a sheep named Dolly, born in 1996.
Since then a number of other animals, including pigs, horses, and dogs,
have been generated by reproductive cloning technology. Recombinant DNA
technology, on the other hand, involves the insertion of one or more
individual genes from an organism of one species into the DNA (deoxyribonucleic acid) of another. Whole-genome replacement, involving the transplantation of one bacterial
genome into the “cell body,” or cytoplasm, of another microorganism,
has been reported, although this technology is still limited to basic
scientific applications.
Genetically modified organisms are produced using scientific methods that include recombinant DNA technology.Encyclopædia Britannica, Inc.
GMOs produced through genetic technologies have become a part of everyday life, entering into society through agriculture, medicine,
research, and environmental management. However, while GMOs have
benefited human society in many ways, some disadvantages exist;
therefore, the production of GMOs remains a highly controversial topic
in many parts of the world.
GMOs in agriculture
Genetically modified (GM) foods were first approved for human consumption in the United States in 1994, and by 2014–15 about 90 percent of the corn, cotton, and soybeans
planted in the United States were GM. By the end of 2010, GM crops
covered more than 10 million square kilometres (3.86 million square
miles) of land in 29 countries worldwide—one-tenth of the world’s
farmland. The majority of GM crops were grown in the Americas.
Engineered crops can dramatically increase per area crop yields and, in some cases, reduce the use of chemical insecticides. For example, the application of wide-spectrum insecticides declined in many areas growing plants, such as potatoes, cotton, and corn, that were endowed with a gene from the bacterium Bacillus thuringiensis, which produces a natural insecticide called Bt
toxin. Field studies conducted in India in which Bt cotton was compared
with non-Bt cotton demonstrated a 30–80 percent increase in yield from
the GM crop. This increase was attributed to marked improvement in the
GM plants’ ability to overcome bollworm infestation, which was otherwise
common. Studies of Bt cotton production in Arizona, U.S., demonstrated
only small gains in yield—about 5 percent—with an estimated cost
reduction of $25–$65 (USD) per acre owing to decreased pesticide
applications. In China, where farmers first gained access to Bt cotton
in 1997, the GM crop was initially successful. Farmers who had planted
Bt cotton reduced their pesticide use by 50–80 percent and increased
their earnings by as much as 36 percent. By 2004, however, farmers who
had been growing Bt cotton for several years found that the benefits of
the crop eroded as populations of secondary insect pests, such as
mirids, increased. Farmers once again were forced to spray
broad-spectrum pesticides throughout the growing season,
such that the average revenue for Bt growers was 8 percent lower than
that of farmers who grew conventional cotton. Meanwhile, Bt resistance
had also evolved in field populations of major cotton pests, including
both the cotton bollworm (Helicoverpa armigera) and the pink bollworm (Pectinophora gossypiella).
Other GM plants were engineered for resistance to a specific chemical herbicide, rather than resistance to a natural predator or pest. Herbicide-resistant crops (HRC) have been available since the mid-1980s; these crops enable effective chemical control of weeds,
since only the HRC plants can survive in fields treated with the
corresponding herbicide. Many HRCs are resistant to glyphosate
(Roundup), enabling liberal application of the chemical, which is highly
effective against weeds. Such crops have been especially valuable for
no-till farming, which helps prevent soil erosion. However, because HRCs
encourage increased application of chemicals to the soil, rather than
decreased application, they remain controversial with regard to their
environmental impact. In addition, in order to reduce the risk of
selecting for herbicide-resistant weeds, farmers must use multiple diverse weed-management strategies.
Another example of a GM crop is “golden” rice, which originally was intended for Asia and was genetically modified to produce almost 20 times the beta-carotene of previous varieties. Golden rice was created by modifying the rice genome to include a gene from the daffodil Narcissus pseudonarcissus that produces an enzyme known as phyotene synthase and a gene from the bacterium Erwinia uredovora
that produces an enzyme called phyotene desaturase. The introduction of
these genes enabled beta-carotene, which is converted to vitamin A in the human liver, to accumulate in the rice endosperm—the
edible part of the rice plant—thereby increasing the amount of
beta-carotene available for vitamin A synthesis in the body. In 2004 the
same researchers who developed the original golden rice plant improved
upon the model, generating golden rice 2, which showed a 23-fold
increase in carotenoid production.
Another form of modified rice was generated to help combat iron
deficiency, which impacts close to 30 percent of the world population.
This GM crop was engineered by introducing into the rice genome a
ferritin gene from the common bean, Phaseolus vulgaris, that produces a protein capable of binding iron, as well as a gene from the fungus Aspergillus fumigatus that produces an enzyme capable of digesting compounds
that increase iron bioavailability via digestion of phytate (an
inhibitor of iron absorption). The iron-fortified GM rice was engineered
to overexpress an existing rice gene that produces a cysteine-rich
metallothioneinlike (metal-binding) protein that enhances iron absorption.
A variety of other crops modified to endure the weather extremes common in other parts of the globe are also in production.
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