The vast majority of genetically modified animals are at the research stage with the number close to entering the market remaining small. As of 2018 only three genetically modified animals have been approved, all in the USA. A goat and a chicken have been engineered to produce medicines and a salmon has increased its own growth. Despite the differences and difficulties in modifying them, the end aims are much the same as for plants. GM animals are created for research purposes, production of industrial or therapeutic products, agricultural uses, or improving their health. There is also a market for creating genetically modified pets.
Mammals , like the blotched mouse shown, are created through genetic modification techniques like
gene targeting. The process of genetically engineering mammals is slow, tedious, and expensive. However, new technologies are making genetic modifications easier and more precise. The first transgenic mammals were produced by injecting viral DNA into embryos and then implanting the embryos in females. model of
hemophilia A Mammals are the best models for human disease, making genetic engineered ones vital to the discovery and development of cures and treatments for many serious diseases. Knocking out genes responsible for
human genetic disorders allows researchers to study the mechanism of the disease and to test possible cures.
Genetically modified mice have been the most common mammals used in
biomedical research, as they are cheap and easy to manipulate. Pigs are also a good target as they have a similar body size and anatomical features,
physiology,
pathophysiological response and diet. Nonhuman primates are the most similar model organisms to humans, but there is less public acceptance towards using them as research animals. In 2009, scientists announced that they had successfully transferred a gene into a
primate species (
marmosets) for the first time. Their first research target for these marmosets was
Parkinson's disease, but they were also considering
amyotrophic lateral sclerosis and
Huntington's disease. Human proteins expressed in mammals are more likely to be similar to their natural counterparts than those expressed in plants or microorganisms. Stable expression has been accomplished in sheep, pigs, rats and other animals. In 2009, the first human biological drug produced from such an animal, a
goat, was approved. The drug,
ATryn, is an
anticoagulant which reduces the probability of
blood clots during
surgery or
childbirth and is extracted from the goat's milk. Human
alpha-1-antitrypsin is another protein that has been produced from goats and is used in treating humans with this deficiency. Another medicinal area is in creating pigs with greater capacity for
human organ transplants (
xenotransplantation). Pigs have been genetically modified so that their organs can no longer carry retroviruses or have modifications to reduce the chance of rejection. Chimeric pigs could carry fully human organs. The first human transplant of a genetically modified pig heart occurred in 2023, and kidney in 2024. Livestock are modified with the intention of improving economically important traits such as growth-rate, quality of meat, milk composition, disease resistance and survival. Animals have been engineered to grow faster, be healthier and resist diseases. Modifications have also improved the wool production of sheep and udder health of cows. A GM pig called
Enviropig was created with the capability of digesting plant
phosphorus more efficiently than conventional pigs. They could reduce water pollution since they excrete 30 to 70% less phosphorus in manure.
Dairy cows have been genetically engineered to produce milk that would be the same as human breast milk. This could potentially benefit mothers who cannot produce breast milk but want their children to have breast milk rather than formula. Researchers have also developed a genetically engineered cow that produces allergy-free milk. Scientists have genetically engineered several organisms, including some mammals, to include
green fluorescent protein (GFP), for research purposes. GFP and other similar reporting genes allow easy visualization and localization of the products of the genetic modification. In 2011, green-fluorescent cats were created to help find therapies for
HIV/AIDS and other diseases as
feline immunodeficiency virus is related to
HIV. There have been suggestions that genetic engineering could be used to bring animals
back from extinction. It involves changing the genome of a close living relative to resemble the extinct one and is currently being attempted with the
passenger pigeon. Genes associated with the
woolly mammoth have been added to the genome of an
African Elephant, although the lead researcher says he has no intention of creating live elephants and transferring all the genes and reversing years of genetic evolution is a long way from being feasible. It is more likely that scientists could use this technology to conserve endangered animals by bringing back lost diversity or transferring evolved genetic advantages from adapted organisms to those that are struggling.
Humans Gene therapy uses genetically modified viruses to deliver genes which can cure disease in humans. Although gene therapy is still relatively new, it has had some successes. It has been used to treat
genetic disorders such as
severe combined immunodeficiency, and
Leber's congenital amaurosis. Treatments are also being developed for a range of other currently incurable diseases, such as
cystic fibrosis,
sickle cell anemia,
Parkinson's disease,
cancer,
diabetes,
heart disease and
muscular dystrophy. These treatments only effect
somatic cells, meaning any changes would not be inheritable.
Germline gene therapy results 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. In November 2018,
He Jiankui announced that he had
edited the genomes of two human embryos, in an attempt to disable the
CCR5 gene, which codes for a receptor that HIV uses to enter cells. He said that twin girls,
Lulu and Nana, had been born a few weeks earlier and that they carried functional copies of CCR5 along with disabled CCR5 (
mosaicism) and were still vulnerable to HIV. The work was widely condemned as unethical, dangerous, and premature.
Fish Genetically modified fish are used for scientific research, as pets and as a food source.
Aquaculture is a growing industry, currently providing over half the consumed fish worldwide. Through genetic engineering it is possible to increase growth rates, reduce food intake, remove allergenic properties, increase cold tolerance and provide disease resistance. Fish can also be used to detect aquatic pollution or function as bioreactors. Several groups have been developing
zebrafish to detect pollution by attaching fluorescent proteins to genes activated by the presence of pollutants. The fish will then glow and can be used as environmental sensors. The
GloFish is a brand of genetically modified fluorescent
zebrafish with bright red, green, and orange fluorescent color. It was originally developed by one of the groups to detect pollution, but is now part of the ornamental fish trade, becoming the first genetically modified animal to become publicly available as a pet when in 2003 it was introduced for sale in the USA. GM fish are widely used in basic research in genetics and development. Two species of fish, zebrafish and
medaka, are most commonly modified because they have optically clear
chorions (membranes in the egg), rapidly develop, and the one-cell embryo is easy to see and microinject with transgenic DNA. Zebrafish are model organisms for developmental processes,
regeneration, genetics, behavior, disease mechanisms and toxicity testing. Their transparency allows researchers to observe developmental stages, intestinal functions and tumour growth. The generation of transgenic protocols (whole organism, cell or tissue specific, tagged with reporter genes) has increased the level of information gained by studying these fish. GM fish have been developed with promoters driving an over-production of
growth hormone for use in the
aquaculture industry to increase the speed of development and potentially reduce fishing pressure on wild stocks. This has resulted in dramatic growth enhancement in several species, including
salmon,
trout and
tilapia.
AquaBounty Technologies, a biotechnology company, have produced a salmon (called
AquAdvantage salmon) that can mature in half the time as wild salmon. It obtained regulatory approval in 2015, the first non-plant GMO food to be commercialized. As of August 2017, GMO salmon is being sold in Canada. Sales in the US started in May 2021.
Insects of
methyl-CpG–binding protein 2 in
Drosophila impairs climbing ability (
right) compared to the control group (
left). In biological research, transgenic fruit flies (
Drosophila melanogaster) are
model organisms used to study the effects of genetic changes on development. Fruit flies are often preferred over other animals due to their short life cycle and low maintenance requirements. They also have a relatively simple genome compared to many
vertebrates, with typically only one copy of each gene, making
phenotypic analysis easy.
Drosophila have been used to study genetics and inheritance, embryonic development, learning, behavior, and aging. The discovery of
transposons, in particular the
p-element, in
Drosophila provided an early method to add transgenes to their genome, although this has been taken over by more modern gene-editing techniques. Due to their significance to human health, scientists are looking at ways to control mosquitoes through genetic engineering. Malaria-resistant mosquitoes have been developed in the laboratory by inserting a gene that reduces the development of the malaria parasite and then use
homing endonucleases to rapidly spread that gene throughout the male population (known as a
gene drive). This approach has been taken further by using the gene drive to spread a lethal gene. In trials the populations of
Aedes aegypti mosquitoes, the single most important carrier of dengue fever and Zika virus, were reduced by between 80% and by 90%. Other insect pests that make attractive targets are
moths.
Diamondback moths cause US$4 to $5 billion of damage each year worldwide. The approach is similar to the sterile technique tested on mosquitoes, where males are transformed with a gene that prevents any females born from reaching maturity. They underwent field trials in 2017. In this case a strain of
pink bollworm that were sterilized with radiation were genetically engineered to express a
red fluorescent protein making it easier for researchers to monitor them. Silkworm, the larvae stage of
Bombyx mori, is an economically important insect in
sericulture. Scientists are developing strategies to enhance silk quality and quantity. There is also potential to use the silk producing machinery to make other valuable proteins. Proteins currently developed to be expressed by silkworms include;
human serum albumin,
human collagen α-chain, mouse
monoclonal antibody and
N-glycanase. Silkworms have been created that produce
spider silk, a stronger but extremely difficult to harvest silk, and even novel silks.
Other |alt=|left Systems have been developed to create transgenic organisms in a wide variety of other animals. Chickens have been genetically modified for a variety of purposes. This includes studying
embryo development, preventing the transmission of
bird flu and providing evolutionary insights using
reverse engineering to recreate dinosaur-like phenotypes. A GM chicken that produces the drug
Kanuma, an enzyme that treats a rare condition, in its egg passed US regulatory approval in 2015. Genetically modified frogs, in particular
Xenopus laevis and
Xenopus tropicalis, are used in
developmental biology research. GM frogs can also be used as pollution sensors, especially for
endocrine disrupting chemicals. There are proposals to use genetic engineering to control
cane toads in Australia. The
nematode Caenorhabditis elegans is one of the major model organisms for researching
molecular biology.
RNA interference (RNAi) was discovered in
C. elegans and could be induced by simply feeding them bacteria modified to express
double stranded RNA. It is also relatively easy to produce stable transgenic nematodes and this along with RNAi are the major tools used in studying their genes. The most common use of transgenic nematodes has been studying gene expression and localization by attaching reporter genes. Transgenes can also be combined with RNAi techniques to rescue phenotypes, study gene function, image cell development in real time or control expression for different tissues or developmental stages. toxicology, diseases, and to detect environmental pollutants. The gene responsible for
albinism in
sea cucumbers has been found and used to engineer
white sea cucumbers, a rare delicacy. The technology also opens the way to investigate the genes responsible for some of the cucumbers more unusual traits, including
hibernating in summer,
eviscerating their intestines, and dissolving their bodies upon death.
Flatworms have the ability to regenerate themselves from a single cell. Until 2017 there was no effective way to transform them, which hampered research. By using microinjection and radiation scientists have now created the first genetically modified flatworms. The
bristle worm, a marine
annelid, has been modified. It is of interest due to its reproductive cycle being synchronized with lunar phases, regeneration capacity and slow evolution rate.
Cnidaria such as
Hydra and the sea anemone
Nematostella vectensis are attractive model organisms to study the evolution of
immunity and certain developmental processes. Other animals that have been genetically modified include
snails,
geckos,
turtles,
crayfish,
oysters,
shrimp,
clams,
abalone and
sponges. == Regulation ==