Genetic engineering has applications in medicine, research, industry, and agriculture, and can be used on a wide range of plants, animals, and microorganisms.
Bacteria, the first organisms to be genetically modified, can have plasmid DNA inserted containing new genes that code for medicines or enzymes that process food and other
substrates. Plants have been modified for insect protection,
herbicide resistance, virus resistance, enhanced nutrition, tolerance to environmental pressures, and the production of
edible vaccines. Most commercialised GMOs are insect-resistant or herbicide-tolerant crop plants. Genetically modified animals have been used for research, model animals, and the production of agricultural or pharmaceutical products. The genetically modified animals include animals with
genes knocked out,
increased susceptibility to disease, hormones for extra growth, and the ability to express proteins in their milk.
Medicine Genetic engineering has many applications to medicine that include the manufacturing of drugs, the creation of
model animals that mimic human conditions, and
gene therapy. One of the earliest uses of genetic engineering was to mass-produce human insulin in bacteria. Mouse
hybridomas, cells fused together to create
monoclonal antibodies, have been adapted through genetic engineering to create human monoclonal antibodies.
Genetically engineered viruses are being developed that can still confer immunity, but lack the
infectious sequences. Genetic engineering is also used to create animal models of human diseases.
Genetically modified mice are the most common genetically engineered animal model. They have been used to study and model cancer (the
oncomouse), obesity, heart disease, diabetes, arthritis, substance abuse, anxiety, aging, and
Parkinson's disease. Potential cures can be tested against these mouse models. Gene therapy is the
genetic engineering of humans, generally by replacing defective genes with effective ones.
Clinical research using
somatic gene therapy has been conducted with several diseases, including
X-linked SCID,
chronic lymphocytic leukemia (CLL), and
Parkinson's disease. In 2012,
Alipogene tiparvovec became the first gene therapy treatment to be approved for clinical use. In 2015, a virus was used to insert a healthy gene into the skin cells of a boy suffering from a rare skin disease,
epidermolysis bullosa, in order to grow, and then graft healthy skin onto 80 percent of the boy's body, which was affected by the illness.
Germline gene therapy would result in any change being inheritable, which has raised concerns within the scientific community. In 2015, CRISPR was used to edit the DNA of non-viable
human embryos, leading scientists of major world academies to call for a moratorium on inheritable human genome edits. There are also concerns that the technology could be used not just for treatment, but for enhancement, modification, or alteration of a human beings' appearance, adaptability, intelligence, character, or behavior. The distinction between cure and enhancement can also be difficult to establish. In November 2018,
He Jiankui announced that he had
edited the genomes of two human embryos, to attempt to disable the
CCR5 gene, which codes for a receptor that
HIV uses to enter cells. The work was widely condemned as unethical, dangerous, and premature. Currently, germline modification is banned in 40 countries. Scientists who perform this type of research will often let embryos grow for a few days without allowing them to develop into a baby. Researchers are altering the genome of pigs to induce the growth of human organs, with the aim of increasing the success of
pig-to-human organ transplantation. Scientists are creating "gene drives", changing the genomes of mosquitoes to make them immune to malaria, and then looking to spread the genetically altered mosquitoes throughout the mosquito population in the hopes of eliminating the disease.
Research to allow them to be visualised Genetic engineering is an important tool for
natural scientists, with the creation of transgenic organisms one of the most important tools for the analysis of gene function. Genes and other genetic information from a wide range of organisms can be inserted into bacteria for storage and modification, creating
genetically modified bacteria in the process . Bacteria are cheap, easy to grow,
clonal, multiply quickly, relatively easy to transform, and can be stored at -80 °C almost indefinitely. Once a gene is isolated, it can be stored inside the bacteria, providing an unlimited supply for research. Organisms are genetically engineered to discover the functions of certain genes. This could be the effect on the phenotype of the organism, where the gene is expressed or what other genes it interacts with. These experiments generally involve loss of function, gain of function, tracking, and expression. •
Loss of function experiments, such as in a
gene knockout experiment, in which an organism is engineered to lack the activity of one or more genes. In a simple knockout, a copy of the desired gene has been altered to make it non-functional.
Embryonic stem cells incorporate the altered gene, which replaces the already present functional copy. These stem cells are injected into
blastocysts, which are implanted into surrogate mothers. This allows the experimenter to analyse the defects caused by this
mutation and thereby determine the role of particular genes. It is used especially frequently in
developmental biology. When this is done by creating a library of genes with point mutations at every position in the area of interest, or even every position in the whole gene, this is called "scanning mutagenesis". The simplest method, and the first to be used, is "alanine scanning", where every position in turn is mutated to the unreactive amino acid
alanine. •
Gain of function experiments, the logical counterpart of knockouts. These are sometimes performed in conjunction with knockout experiments to more finely establish the function of the desired gene. The process is much the same as that in knockout engineering, except that the construct is designed to increase the function of the gene, usually by providing extra copies of the gene or inducing synthesis of the protein more frequently. Gain of function is used to tell whether or not a protein is sufficient for a function, but does not always mean it is required, especially when dealing with genetic or functional redundancy.
Industrial Organisms can have their cells transformed with a gene coding for a useful protein, such as an enzyme, so that they will
overexpress the desired protein. Mass quantities of the protein can then be manufactured by growing the transformed organism in
bioreactor equipment using
industrial fermentation, and then
purifying the protein. Some genes do not work well in bacteria, so yeast, insect cells or mammalian cells can also be used. These techniques are used to produce medicines such as
insulin,
human growth hormone, and
vaccines, supplements such as
tryptophan, aid in the production of food (
chymosin in cheese making) and fuels. Other applications with genetically engineered bacteria could involve making them perform tasks outside their natural cycle, such as making
biofuels, cleaning up oil spills, carbon and other toxic waste and detecting arsenic in drinking water. Certain genetically modified microbes can also be used in
biomining and
bioremediation, due to their ability to extract heavy metals from their environment and incorporate them into compounds that are more easily recoverable. In
materials science, a genetically modified virus has been used in a research laboratory as a scaffold for assembling a more environmentally friendly
lithium-ion battery. Bacteria have also been engineered to function as sensors by expressing a fluorescent protein under certain environmental conditions.
Agriculture leaves (bottom image) protect it from extensive damage caused by
lesser cornstalk borer larvae (top image). One of the best-known and
controversial applications of genetic engineering is the creation and use of
genetically modified crops or
genetically modified livestock to produce
genetically modified food. Crops have been developed to increase production, increase tolerance to
abiotic stresses, alter the composition of the food, or to produce novel products. The first crops to be released commercially on a large scale provided protection from insect pests or tolerance to
herbicides. Fungal and virus resistant crops have also been developed or are in development. This makes the insect and weed management of crops easier and can indirectly increase crop yield. GM crops that directly improve yield by accelerating growth or making the plant more hardy (by improving salt, cold or drought tolerance) are also under development. GMOs have been developed that modify the quality of produce by increasing the nutritional value or providing more industrially useful qualities or quantities. The
Amflora potato produces a more industrially useful blend of starches.
Soybeans and
canola have been genetically modified to produce more healthy oils. The first commercialised GM food was a
tomato that had delayed ripening, increasing its
shelf life. Plants and animals have been engineered to produce materials they do not normally make.
Pharming uses crops and animals as bioreactors to produce vaccines, drug intermediates, or the drugs themselves; the useful product is purified from the harvest and then used in the standard pharmaceutical production process. Cows and goats have been engineered to express drugs and other proteins in their milk, and in 2009 the FDA approved a drug produced in goat milk.
Other applications Genetic engineering has potential applications in conservation and natural area management. Gene transfer through
viral vectors has been proposed as a means of controlling invasive species as well as vaccinating threatened fauna from disease. Transgenic trees have been suggested as a way to confer resistance to pathogens in wild populations. With the increasing risks of
maladaptation in organisms as a result of
climate change and other perturbations, facilitated adaptation through gene tweaking could be one solution to reducing extinction risks. Applications of genetic engineering in conservation are thus far mostly theoretical and have yet to be put into practice. Genetic engineering is also being used to create
microbial art. Some bacteria have been genetically engineered to create black and white photographs. Novelty items such as lavender-colored
carnations,
blue roses, and
glowing fish, have also been produced through genetic engineering. ==Regulation==