, like the blotched mouse shown, are created through genetic modification techniques like
gene targeting. GM mammals 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.
Medicine 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. Examples include
humanized mice created by
xenotransplantation of human gene products, so as to be utilized as murine
human-animal hybrids for gaining relevant insights in the
in vivo context for understanding of human-specific physiology and pathologies. Pigs are also a good target, because they have a similar body size, anatomical features,
physiology,
pathophysiological response, and diet. Nonhuman primates are the most similar model organisms to humans, but there is less public acceptance toward using them as research animals. In 2009, scientists announced that they had successfully transferred a gene into a
primate species (
marmosets) and produced a stable line of breeding transgenic primates 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 was extracted from the goat's milk. Human
alpha-1-antitrypsin is another protein that is used in treating humans with this deficiency. Another 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. Pig lungs from genetically modified pigs are being considered for transplantation into humans. There is even potential to create chimeric pigs that can carry human organs.
Livestock 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. The goat gene sequence has been modified, using fresh umbilical cords taken from kids, in order to code for the human enzyme
lysozyme. Researchers wanted to alter the milk produced by the goats, to contain lysozyme in order to fight off bacteria causing
diarrhea in humans. Enviropig was a genetically enhanced line of
Yorkshire pigs in Canada created with the capability of digesting plant
phosphorus more efficiently than conventional Yorkshire pigs. The A
transgene construct consisting of a
promoter expressed in the
murine parotid gland and the
Escherichia coli phytase gene was introduced into the pig embryo by pronuclear
microinjection. This caused the pigs to produce the enzyme
phytase, which breaks down the indigestible phosphorus, in their saliva. As a result, they excrete 30 to 70% less phosphorus in manure depending upon the age and diet. and as no new partners were found the pigs were killed. However, the genetic material will be stored at the Canadian Agricultural Genetics Repository Program. In 2006, a pig was engineered to produce
omega-3 fatty acids through the expression of a
roundworm gene. In 1990, the world's first transgenic
bovine, Herman the Bull, was developed. Herman was genetically engineered by micro-injected embryonic cells with the human gene coding for
lactoferrin. The
Dutch Parliament changed the law in 1992 to allow Herman to reproduce. Eight calves were born in 1994 and all calves inherited the lactoferrin gene. With subsequent sirings, Herman fathered a total of 83 calves. Dutch law required Herman to be
slaughtered at the conclusion of the
experiment. However the Dutch Agriculture Minister at the time,
Jozias van Aartsen, granted him a reprieve provided he did not have more offspring after public and scientists rallied to his defence. In 2011, Chinese scientists generated
dairy cows genetically engineered with genes from human beings 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. The researchers claim these transgenic cows to be identical to regular cows. Two months later, scientists from
Argentina presented Rosita, a transgenic cow incorporating two human genes, to produce milk with similar properties as human breast milk. In 2016
Jayne Raper and a team announced the first trypanotolerant transgenic cow in the world. This team, spanning the
International Livestock Research Institute,
Scotland's Rural College, the
Roslin Institute's Centre for Tropical Livestock Genetics and Health, and the
City University of New York, announced that a
Kenyan Boran bull had been born and had already successfully had two children. Tumaini - named for the
Swahili word for "hope" - carries a
trypanolytic factor from a
baboon via
CRISPR/Cas9. In October 2017, Chinese scientists announced they used
CRISPR gene editing technology to create of a line of pigs with better body temperature regulation, resulting in about 24% less body fat than typical livestock.
Research 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 visualisation and localisation of the products of the genetic modification. Fluorescent pigs have been bred to study human organ transplants, regenerating ocular
photoreceptor cells, and other topics. In 2011
green-fluorescent cats were created to find therapies for
HIV/AIDS and other diseases as
feline immunodeficiency virus (FIV) is related to HIV. Researchers from the University of Wyoming have developed a way to incorporate spiders' silk-spinning genes into goats, allowing the researchers to harvest the silk protein from the goats' milk for a variety of applications.
Conservation Genetic modification of the
myxoma virus has been proposed to conserve
European wild rabbits in the
Iberian peninsula and to help regulate them in Australia. To protect the Iberian species from viral diseases, the myxoma virus was genetically modified to immunize the rabbits, while in Australia the same myxoma virus was genetically modified to lower fertility in the Australian rabbit population. There have also 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 using live elephants.
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 affect
somatic cells, which means that 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, to 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==