Cryoconservation of animal genetic resources explained

Cryoconservation of animal genetic resources is a strategy wherein samples of animal genetic materials are preserved cryogenically.[1]

Animal genetic resources, as defined by the Food and Agriculture Organization of the United Nations, are "those animal species that are used, or may be used, for the production of food and agriculture, and the populations within each of them. These populations within each species can be classified as wild and feral populations, landraces and primary populations, standardised breeds, selected lines, varieties, strains and any conserved genetic material; all of which are currently categorized as Breeds."[2] Genetic materials that are typically cryogenically preserved include sperm, oocytes, embryos and somatic cells.[3] [4] Cryogenic facilities are called gene banks and can vary greatly in size usually according to the economic resources available. They must be able to facilitate germplasm collection, processing, and long term storage, all in a hygienic and organized manner. Gene banks must maintain a precise database and make information and genetic resources accessible to properly facilitate cryoconservation. Cryoconservation is an ex situ conservation strategy that often coexists alongside in situ conservation to protect and preserve livestock genetics.[5]

Cryoconservation of livestock genetic resources is primarily done in order to preserve the genetics of populations of interest, such as indigenous breeds, also known as local or minor breeds. Material may be stored because individuals shared specific genes and phenotypes that may be of value or have potential value for researchers or breeders. Therefore, one of the main goals remains preserving the gene pool of local breeds that may be threatened.[6] Indigenous livestock genetics are commonly threatened by factors such as globalization, modernization, changes in production systems, inappropriate introduction of major breeds, genetic drift, inbreeding, crossbreeding, climate change, natural disasters, disease, cultural changes, and urbanization.[7] [8] [9] Indigenous livestock are critical to sustainable agricultural development and food security, due to their: adaptation to environment and endemic diseases, indispensable part in local production systems, cultural significance, and importance to local rural economies.[4] The genetic resources of minor breeds have value to the local farmers, consumers of the products, private companies and investors interested in crossbreeding, breed associations, governments, those conducting research and development, and non-governmental organizations.[10] Therefore, efforts have been made by national governments and non-governmental organizations, such as The Livestock Conservancy, to encourage conservation of livestock genetics through cryoconservation, as well as through other ex situ and in situ strategies.[11] Cryogenic specimens of livestock genetic resources can be preserved and used for extended periods of time.[12] This advantage makes cryoconservation beneficial particularly for threatened breeds who have low breed populations. Cryogenically preserved specimens can be used to revive breeds that are endangered or extinct, for breed improvement, crossbreeding, research and development. However, cryoconservation can be an expensive strategy and requires long term hygienic and economic commitment for germplasms to remain viable. Cryoconservation can also face unique challenges based on the species, as some species have a reduced survival rate of frozen germplasm.[13] [14]

Description

Cryoconservation is the process of freezing cells and tissues using liquid nitrogen to achieve extreme low temperatures with the intent of using the preserved sample to prevent the loss of genetic diversity.[15] Semen, embryos, oocytes, somatic cells, nuclear DNA, and other types of biomaterial such as blood and serum can be stored using cryopreservation, in order to preserve genetic materials.[4] The primary benefit of cryoconservation is the ability to save germplasms for extended periods of time, therefore maintaining the genetic diversity of a species or breed.[12] There are two common techniques of cryopreservation: slow freezing and vitrification. Slow freezing helps eliminate the risk of intracellular ice crystals.[16] If ice crystals form in the cells, there can be damage or destruction of genetic material. Vitrification is the process of freezing without the formation of ice crystals.[17]

Value

Cryoconservation is an indispensable tool in the storage of genetic material of animal origin and will continue to be useful for the conservation of livestock into the future. Cryoconservation serves as a way to preserve germplasms, which is particularly beneficial for threatened breeds. Indigenous livestock may be conserved for a variety of reasons, including the preservation of local genetics, their importance in local traditions and their value to the culture identity and heritage of the area.[18] The loss of regional livestock diversity could increase instability, decreases future possibilities and challenge production systems. Moreover, the maintenance of indigenous breeds can aid in the preservation of traditional lifestyles and livelihoods, even providing income through cultural tourism.[19] Indigenous breeds can contribute to local economies and production systems by utilising land that is unsuitable for crop production to produce food products, as well as providing hides, manure and draft power. Therefore, the conservation and progression of these breeds are of the utmost importance for food security and sustainability.

Another beneficial factor in cryoconservation of indigenous livestock is in terms of food security and economic development.[20] Indigenous livestock often have beneficial traits related to adaptation to local climate and diseases that can be incorporated into major breeds through cryoconservation practices.[21] Cryoconservation is a favorable strategy because it allows germplasms to be stored for extended periods of time in a small confined area. An additional benefit of cryoconservation is the ability to preserve the biological material of both maternal and paternal cells and maintain viability over extended periods of time. Cryoconservation has been successfully used as a conservation strategy for species and breeds that have since been endangered. One drawback is that cryoconservation can only be done if preparation has taken place in advance.[4] With proper preparation of collecting and maintaining genetic material, this method is very beneficial for the conservation of rare and endangered livestock. Cryoconservation can serve as a contingency plan when a breed population needs to be restored or when a breed has become extinct, as well as for breed improvement. This process benefits companies and researchers by making genetic materials available.

Insurance against changes in production conditions
Safeguarding against diseases, disasters, etc.Opportunities for genomic research
Genetic FactorsAllowing continued breed evolution/genetic adaption Increasing knowledge of phenotypic characteristics of breed Minimizing exposed to genetic drafts
Sustainable utilization of total areasOpportunities for development in rural areasMaintenance of agro-ecosystem diversityConservation of rural culture diversity

The support of numerous stakeholders make this process possible in the establishment and operations of cryoconservation. Before every phase is executed, all participating stakeholders must be briefed to understand the possible phase impending. This would include informing the stakeholders of their responsibilities and receiving their consent for the cryoconservation process. The possible stakeholders within the cryoconservation process could include:

Methods

Collection

There are several ways to collect the genetic materials based on which type of germplasm.

Semen

Freezing semen is a commonly used technique in the modern animal agriculture industry, which is well researched with established methods[22] Semen is often collected using an artificial vagina, electroejaculation, gloved-hand technique, abdominal stroking, or epididymal sperm collection. Preferred collection techniques vary based on species and available tools. Patience and technique are keys to successful collection of semen.[23] There are several styles and types of artificial vaginas that can be used depending on the breed and species of the male. During this process the penis enters a tube that is the approximate pressure and temperature of the female's vagina. There is a disposable bag inside the tube that collects the semen. During this process it may be beneficial to have a teaser animal—an animal used to sexually tease but not impregnate the animal—to increase the arousal of the male.[23] Electroejaculation is a method of semen collection in the cattle industry because it yields high quality semen. However, this process requires the animal to be trained and securely held, thus it is not ideal when working with wild or feral animals. When performing this process the electroejaculator is inserted into the rectum of the male.[24] The electroejaculator stimulates the male causing an ejaculation, after which the semen is collected. The glove hand collection technique is used mainly in the swine industry. During this process, the boar mounts a dummy, while the handler grasps the penis of the boar between the ridges of his fingers and collects the semen.[25] Abdominal stroking is exclusively used in the poultry industry. During the technique, one technician will hold the bird, while a second technician massages the bird's cloaca.[26] However, feces and semen both exit the male bird's body through the cloaca, so the semen quality is often low.[27]

Embryo

Embryo collection is more demanding and requires more training than semen collection because the female reproductive organs are located inside of the body cavity. Superovulation is a technique used in order to have a female release more oocytes than normal. This can be achieved by using hormones to manipulate the female's reproductive organs. The hormones used are typically gonadotropin-like, meaning they stimulate the gonads.[28] Follicle stimulating hormone is the preferred hormone in cattle, sheep and goats. While in pigs, equine chorionic gonadotropin is preferred. However, this is not commonly done in the swine industry because gilts and sows (female pigs) naturally ovulate more than one oocyte at one time. Superovulation can be difficult because not all females will respond the same way and success will vary by species. Once the female has released the oocytes, they are fertilized internally—in vivo—and flushed out of her body. In vivo fertilization is more successful than in vitro fertilization.[29] In cattle, usually 10 or more embryos are removed from the flushing process. In order to flush the uterus, a technician will first seal off the female's cervix and add fluid, which allows the ovum to be flushed out of the uterine horns and into a cylinder for analysis. This process typically takes 30 minutes or less.[30] Technicians are able to determine the sex of the embryo, which can be especially beneficial in the dairy industry because it is more desirable for the embryo to be a female.[31] Vitrification is the preferred method of embryo freezing because it yields higher quality embryos.[32] It is crucial technicians handle the embryos with care and freeze them within 3–4 hours in order to preserve viability of the greatest percentage of embryos.

Oocytes

Oocytes can be collected from most mammalian species. Conventional oocyte collection is when ovaries are removed from a donor animal; this is done posthumously in slaughter facilities.[33] The ovaries are kept warm as they are brought back to a laboratory for oocyte collection. Keeping the ovaries warm helps increase the success rate of fertilization.[33] Once collected the oocytes are assessed and categorized into small, medium, and large, and then matured for 20–23 hours.[34] This simple, inexpensive technique can lead to about 24 oocytes collected from a bovine. Conventional oocyte collection is especially useful for females who unexpectedly die or who are incapable of being bred due to injury. A second option for oocyte collection is to utilize the transvaginal ultrasound guided oocyte collection method otherwise known as TUGA. Collection technique varies slightly by species, but the general methods for collection are the same; a needle is inserted into each ovarian follicle and pulled out via vacuum. The major benefit of using this method is the ability to expand the lifetime reproductive productivity, or the number of productive days an animal is in her estrous cycle. Pregnant cows and mares continue to develop new follicles until the middle of pregnancy. Thus, TUGA can be used to substantially increase the fitness of an individual because the female then has the potential produce more than one offspring per gestation.[35]

Somatic cells

Somatic cells are an additional resource which can be retrieved for gene banking, particularly in the cases of emergency wherein gametes cannot be collected or stored. Tissues can be taken from living animals or shortly after death. These tissues can be saved via cryopreservation or dehydrated. Blood cells can also be useful for DNA analysis such as comparing homozygosity[36] [37] It is recommended by the FAO that two vials of blood be drawn to reduce the chance that all samples will be lost from a particular animal. DNA can be extracted using commercial kits, making this an affordable and accessible strategy for collecting germplasms.

SemenSemen and OocytesEmbryos
Number of samples needed to restore a breed2000 100 of each 200
Backcrossing needed?YesNoNo
Mitochondrial genes included?NoYesYes
Collection Possible in livestock speciesMostly, not alwaysYes, in some species. Operational for bovinesYes, in some species. Operational for bovines
Cost of collection$$$$$$$$
Cryopreservation possible?YesStill in experimental stageOperational in bovines, horses and sheep. Promising in pigs. Impossible in poultry
UtilizationSurgical or non-surgical insemination backcrossing for 4 generationsIn vitro maturation/IVF followed by surgical or non-surgical ETSurgical or non-surgical ET
Current feasibilityHighMediumHigh depending on available resources

Freezing

There are two cryopreservation freezing methods: slow freezing and vitrification.[38]

Slow freezing

During slow freezing, cells are placed in a medium which is cooled below the freezing point using liquid nitrogen. This causes an ice mass to form in the medium. As the water in the medium freezes, the concentration of the sugars, salts, and cryoprotectant increase. Due to osmosis, the water from the cells enters the medium to keep the concentrations of sugars, salts, and cryoprotectant equal. The water that leaves the cells is eventually frozen, causing more water to diffuse out of the cell. Eventually, the unfrozen portion—cellular—becomes too viscous for ice crystals to form inside of the cell.[1]

Vitrification

The second technique for cryoconservation is vitrification or flash freezing. Vitrification is the transformation from a liquid to solid state without the formation of crystals. The process and mechanics of vitrification are similar to slow freezing, the difference lying in the concentration of the medium. The vitrification method applies a selected medium which has a higher concentration of solute so the water will leave the cells via osmosis. The medium is concentrated enough so all of the intracellular water will leave without the medium needing to be reconcentrated. The higher concentration of the medium in vitrification allows the germplasms to be frozen more rapidly than with slow freezing. Vitrification is considered to be the more effective technique of freezing germplasms.[16]

Facility design and equipment

Facility design

When designing a facility, there are several things that should be kept in mind including biosecurity, worker safety and efficiency, and animal welfare. Diverse infrastructure is required in order to successfully collect and store genetic material. The buildings needed depend on the size of facilities as well as the extent of the operations.

Biosecurity

Biosecurity, a management measure used to prevent the transmission of diseases and disease agents on the facility, is important to keep in mind when designing a facility.[39] In order to achieve a high level of biosecurity, collection facilities should be placed as far as possible from one another, as well as from farms. According to the FAO's recommendations, facilities should be "at least 3 km from farms or other biological risks and 1 km from main roads and railways". Separation between collection facilities and surrounding farms can improve biosecurity as pests, such as flies and mice, have the potential to travel from farm to facility and vice versa. Other disease agents may be able to travel through the air via wind, furthering the importance of separation of farms and proper air sanitation and ventilation. Additionally, a perimeter fence is used to prevent potential threats that could cause contamination to germplasms, such as unauthorized personnel or unwanted animals, from entering the facilities. Animals may be housed in pens located inside or outside of a barn as long as they are contained within the perimeter fence. When interaction with outside objects, such as feed trucks or veterinary personnel, is necessary, complete sanitation is required to decrease the risk of contamination. There is always the possibility of disease spreading among the animals whose biological data is being collected or from animal to human. An example of a disease that can easily spread through germplasm is Porcine Reproductive and Respiratory Syndrome, otherwise known as PRRS. A highly contagious disease between swine, PRRS causes millions of dollars to be lost annually by producers. The disease can be spread through boar semen.[40] Therefore, biosecurity is particularly important when genetic material will be inserted into another animal to prevent the spread of such diseases.

Human considerations

Worker safety is always a priority when handling livestock. Escape routes and alternative access throughout the facility are crucial for both the handlers and livestock.[41] Germplasm storage and collection sites must include locker rooms for staff, which provide lockers, showers, and storage of clothing and footwear, in order to meet sanitation requirements.

Animal considerations

Animal housing practical when collecting germplasms because they keep donor animals in an easily accessible area, making the process of collecting germplasms easier and more efficient. The species and breeds of animals housed should be considered while planning the facility; facilities should be big enough to meet animal welfare standards, yet small enough to reduce human contact and increase ease of handling while reducing stress of the animal. As the process of collecting germplasm may take several days, the animal may become stressed causing a lower quality of genetic material to be obtained. Thus, training the animal to become familiar with the process is key. Holding facilities for animals may also serve as a quarantine. Quarantine facilities are necessary in order to prevent the transmission of disease from animal to animal, animal to germplasm, germplasm to germplasm, and germplasm to animal. Introducing quarantine to separate the diseased animals from the healthy should be done immediately. However, a quarantine does not always prevent the spread of disease.

Temperature control and ventilation

Temperature control and ventilation should be included in the design of the holding and collection facilities to keep the animals comfortable and healthy, while limiting stress during the germplasm collection process. Ventilation serves as an effective way to keep clean airflow throughout the facilities and eliminate odors Temperature control helps regulate the air quality and humidity level inside the barn.

Equipment

A freezing and processing laboratory for genetic materials can be on the same site as the holding and collecting facility. However, the laboratory must have higher sanitation standards. According to the FAO, a proper germplasm laboratory should include the following.

Cryopreservation requires equipment to collect biological material and test tubes for storage. Price is highly variable based on the quality of the collection and storage materials.[42] The life expectancy of tools should be considered when determining costs.[42] In addition to traditional laboratory equipment, the FAO also suggests the following:

Limitations

Cryoconservation is limited by the cells and tissues that can be frozen and successfully thawed. Cells and tissues that can be successfully frozen are limited by their surface area. To keep cells and tissues viable, they must be frozen quickly to prevent ice crystal formation. Thus, a large surface area is beneficial.[43] Another limitation is the species being preserved. There have been difficulties using particular methods of cryoconservation with certain species. For example, artificial insemination is more difficult in sheep than cattle, goats, pigs, or horses due to posterior folds in the cervix of ovines.[13] Cryopreservation of embryos is dependent on the species and the stage of development of the embryo. Pig embryos are the most difficult to freeze, thaw, and utilize produce live offspring due to their sensitivity to chilling and high lipid content.[14]

Legal issues

The collection and utilization of genetic materials requires clear agreements between stakeholders with regards to their rights and responsibilities. The FAO and others, such as Mendelsohn, suggests that governments establish policies with regards to livestock genetic resources and their collection, storage, distribution, and utilization are governments. The FAO also recommends that national or regional livestock industries establish an advisory committee to advise and provide recommendations on policy. Livestock are traditionally a private good; in order to obtain ownership of genetic materials, gene banks have several strategies that they can deploy. Gene banks may either:

One of the key elements of cryoconservation of livestock is open access to genetic materials, to make the resources of these conserved genetic materials accessible for utilization. Utilization should be based on sustainable use, development, and conservation, as well as improvement for the livestock industry. Government and non-governmental organizations recommend that genetic information should have open access for the following purposes:

Examples

Hungarian Grey cattle

An example of the use of cryoconservation to prevent the extinction of a livestock breed is the case of the Hungarian Grey cattle, or Magyar Szürke. Hungarian Grey cattle were once a dominant breed in southeastern Europe with a population of 4.9 million head in 1884. They were mainly used for draft power and meat. However, the population had decreased to 280,000 head by the end of World War II and eventually reached the low population of 187 females and 6 males from 1965 to 1970.[4] The breed's decreased use was due primarily to the mechanization of agriculture and the adoption of major breeds, which yield higher milk production.[44] The Hungarian government launched a project to preserve the breed, as it possesses valuable traits, such as stamina, calving ease, disease resistance, and easy adaptation to a variety of climates.[4] [45] The government program included various conservation strategies, including the cryopreservation of semen and embryos.[4] The Hungarian government's conservation effort brought the population up to 10,310 in 2012, which shows significant improvement using cryoconservation.

The Gaur

Gaur, also known as the Indian bison, is the heaviest and most powerful of all wild cattle native to South and Southeast Asia.[4] It is indicated in field data that the population of mature animals is about 5,200–18,000.[46] Male and female gaur both have distinctive humps between the head and shoulders, a dorsal ridge, prominent horns, and a dewlap which extends to the front legs. The gaur grows 60% faster than domestic cattle, meaning farmers meat can be harvested at a faster rate, making beef production two to three times more profitable. Gaur meat is preferred over other breeds' meat among local people. Another benefit of the bovine is that it has the ability to sweat and tolerates heat well.[47]

The gaur population experienced a drastic decline of about 90% between the 1960s and 1990s due to poaching, commercial hunting, shrinking habitat, and the spreading of disease.[48] [49] According to the International Union for Conservation of Nature's Red List, the gaur is a vulnerable species due to its declining population in Southeast Asia. Although the global gaur population has declined by 30% over the past 30 years, the gaur has a relatively stable population in India, due to protective efforts such as cryoconservation. The American Association of Zoos and Aquariums, Integrated Conservation Research (ICR), and Advanced Cell Technology have made efforts to use cryopreserved specimens of the gaur through artificial insemination, embryo transfer, and cloning, respectively.[4] [50] [47] Hybridization with domestic cattle has been successfully achieved by ICR, in order to create higher yielding, heat resistant cattle.[47]

Mice

Cryopreservation is also commonly employed in biomedical research to archive and distribute genetically engineered mice (Mus musculus). Both preimplantation embryos at various stages and sperm can be used for this purpose. For distribution, cryopreserved samples are typically transported using dry shipper.[51] Among the two methods, sperm cryopreservation offers clear advantages—it is more cost-effective and requires fewer experimental animals than embryo cryopreservation.[52]

See also

Notes and References

  1. "Cryoconservation of Animal Genetic Resources", Rep. Rome: Food and Agriculture Organization of the United Nations, 2012. FAO Animal Production and Health Guidelines No. 12. Print.
  2. FAO. "Annex 2: Working Definitions for Use in Developing Country Reports and Providing Supporting Data." Animal Genetics Resources Information: Special Issue State of the World 30 (2001): 35–40. Web. May 19, 2016. .
  3. Mazur, P., S.p Leibo, and G. E. Seidel. "Cryopreservation of the Germplasm of Animals Used in Biological and Medical Research: Importance, Impact, Status, and Future Directions." Biology of Reproduction 78.1 (2007): 2–12. Web.
  4. Solti, L., E.g. Crichton, N.m. Loskutoff, and S. Cseh. "Economical and Ecological Importance of Indigenous Livestock and the Application of Assisted Reproduction to Their Preservation." Theriogenology 53.1 (2000): 149–62. Web.
  5. Hiemstra, Sipke Joost, Tette Van Der Lende, and Henri Woelders. "The Potential of Cryopreservation and Reproductive Technologies for Animal Genetic Resources Conservation Strategies." Cryobiology 63.3 (2011): 316–17. Web.
  6. Verrier, E., Danchin-Burge, C., Moureaux, S., Ollivier, L., Tixier-Boichard, M., Boichard, D., ... & Clement, F. 2003. What should be preserved: genetic goals and collection protocols for the French National Cryobank. InProceedings of the Workshop on Cryopreservation of Animal Genetic Resources in Europe: February 23, 2003; Paris (pp. 79–89).
  7. Global Plan of Action for Animal Genetic Resources and the Interlaken Declaration. Rep. Rome: Food and Agriculture Organization of the United Nations, 2007. FAO. Web.
  8. Hoffmann . Irene . Irene Hoffmann . Climate change and the characterization, breeding and conservation of animal genetic resources . . Stichting International Foundation for Animal Genetics (Wiley) . 41 . 2010 . 0268-9146 . 10.1111/j.1365-2052.2010.02043.x . 32–46 . 20500754 . 25923256 . free. Web site: Author's manuscript version . Hoffmann . Irene . Irene Hoffmann . 0 . live . https://web.archive.org/web/20210825201645/http://www.fao.org/3/al188e/al188e.pdf . 2021-08-25.
  9. Mendelsohn, Robert. "The Challenge of Conserving Indigenous Domesticated Animals." Ecological Economics 45.3 (2003): 501–10. Web.
  10. Hiemstra, S. J. "Cryopreservation Strategies for Farm Animal Genetic Resources in Europe." Published in Rare Breeds International 8th Global Conference on the Conservation of Animal Genetic Resources, Terkidag, Turkey. October 2011. 29–34. Web. May 19, 2016. http://rbiglobalconf2011.nku.edu.tr/
  11. "Conservation Successes." The Livestock Conservancy. The Livestock Conservancy, n.d. Web. May 15, 2016.
  12. Mazur, Peter. "Stopping Biological Time." Annals of the New York Academy of Sciences 541.1 (1988): 514–531. Web.
  13. Menzies, Paula I."Artificial Insemination in Sheep." Management of Reproduction: Sheep: Merck Veterinary Manual. Merck Animal Health, June 2015. Web. May 13, 2016. http://www.merckvetmanual.com/mvm/management_and_nutrition/management_of_reproduction_sheep/artificial_insemination_in_sheep.html
  14. Mcevoy, T., G. D. Coull, P. J. Broadbent, J. S.M. Hutchinson, and B. K. Speake. "Fatty Acid Composition of Lipids in Immature Cattle, Pig and Sheep Oocytes with Intact Zona Pellucida." Journal of the Society for Reproduction and Fertility 118.1 (2000): 163–70. Web.
  15. Yawn, David H. "Cryopreservation." Encyclopædia Britannica Online. Encyclopædia Britannica, n.d. Web. May 19, 2016. http://www.britannica.com/technology/cryopreservation
  16. Loutradi, E. M., E. M. Kolibianakis, C. A. Venetis, E. G. Papanikolau, G. Pados, I. Bontis, and B.C. Tarlatizs. "Cryopreservation of Human Embryos by Vitrification or Slow Freezing: A Systematic Review and Meta-analysis." Techniques and Instrumentation 90.1 (2008): 186–93. National Center for Biotechnology Information. Web.
  17. Lovgren, Stefan. "Corpses Frozen for Future Rebirth by Arizona Company." National Geographic. National Geographic Society, March 15, 2005. Web. 13 May 16.
  18. Oldenbroek, Kor, ed. Utilisation and Conservation of Farm Animal Genetic Resources. Wegeningen Academic Publisher, 2007. Web.
  19. Rahman, Gerold."Contribution of Rural Tourism to the Market for Livestock Products in LFAs in Germany." The James Hutton Institute. Livestock Systems in Integrated Rural Development, n.d. Web. May 16, 2016.
  20. Barnes, K., T. Collins, S. Dion, H. Reynolds, S. Riess, A. Stanzyk, A. Wolfe, S. Lonergan, P. Boettcher, U. R. Charrondiere, and B. Stadimayr. "Importance of Cattle Biodiversity and Its Influence on the Nutrient Composition of Beef." Animal Frontiers Oct. 2012: 54–60. American Society of Animal Science. Web.
  21. Bett, Rawlynce, Mwai Okeyo, Birgitta Malmfors, Kjell Johansson, Morris Agaba, Donald Kugonza, A.K.F.H. Bhuiyan, Anibal Filho, Arthur Mariante, Fidalis Mujibi, and Jan Philipsson. "Cattle Breeds: Extinction or Quasi-Extant?" Resources 2.3 (2013): 335–57. Web.
  22. Bowen, R. "Collection and Evaluation of Semen: Introduction and Index." Collection and Evaluation of Semen. Colorado State University, January 27, 2003. Web. May 13, 2016. http://www.vivo.colostate.edu/hbooks/pathphys/reprod/semeneval/
  23. Estienne, Mark, and Allen Harper. "Swine Artificial Insemination Programs: Techniques for Training Boars for Semen Collection." Swine Artificial Insemination Programs: Techniques for Training Boars for Semen Collection. Virginia Cooperative Extension, Jan. 2000. Web. May 17, 2016. http://www.sites.ext.vt.edu/newsletter-archive/livestock/aps-00_01/aps-0178.html
  24. Rouge, Melissa, and R. Bowen. "Semen Collection." Semen Collection. Colorado State University, August 11, 2002. Web. May 13, 2016. http://www.vivo.colostate.edu/hbooks/pathphys/reprod/semeneval/collection.html
  25. "Collecting Semen from Boars." The State of Queensland (Department of Agriculture and Fisheries). Queensland Government, July 2, 2002. Web. May 13, 2016. https://www.daf.qld.gov.au/animal-industries/pigs/improving-your-herd-with-genetics/collecting-semen-from-boars
  26. Miyumo, Sophie. "Artificial Insemination in Chicken." Artificial Insemination in Chicken. Indigenous Chicken Improvement Programme., n.d. Web. May 13, 2016.http://www.incip.org/index.php/component/k2/item/88-artificial-insemination-in-chicken
  27. "Cloaca." Encyclopædia Britannica. Encyclopædia Britannica, n.d. Web. May 17, 2016. http://www.britannica.com/science/cloaca
  28. Roberts. Andrew J.. Sherrill E.. Echternkamp. Superovulation of Cows by Initiating FSH Treatments During the First Few Days After Estrus. Roman L. Hruska U.S. Meat Animal Research Center. 4 . 1993. U.S. Department of Agriculture: Agriculture Research Services. 80–82.
  29. Pomar, F.j. Rubio, K.j. Teerds, A. Kidson, B. Colenbrander, T. Tharasanit, B. Aguilar, and B.AJ. Roelen. "Differences in the Incidence of Apoptosis between in Vivo and in Vitro Produced Blastocysts of Farm Animal Species: A Comparative Study." Theriogenology 63.8 (2005): 2254–268. Science Direct. Web.
  30. Selk, Glenn. Embryo Transfer in Cattle. N.d. Fact Sheet. Oklahoma State University Extension Service. PDF. Web. May 13, 2016. http://www.thejudgingconnection.com/pdfs/Embryo_Transfer.pdf
  31. Hirayama, Hiroki, Soichi Kageyama, Satoru Moriyasu, Ken Sawai, and Akira Minamihashi. "Embryo Sexing and Sex Chromosomal Chimerism Analysis by Loop-Mediated Isothermal Amplification in Cattle and Water Buffaloes." Journal of Reproduction and Development J. Reprod. Dev. 59.4 (2013): 321–26. US National Library of Medicine Nation Institutes of Health. Web.
  32. Valojerdi, Mojtaba Rezazadeh, Poopak Eftekhari-Yazdi, Leila Karimian, Fatemeh Hassani, and Bahar Movaghar. "Vitrification versus Slow Freezing Gives Excellent Survival, Post Warming Embryo Morphology and Pregnancy Outcomes for Human Cleaved Embryos." Journal of Assisted Reproduction and Genetics J Assist Reprod Genet 26.6 (2009): 347–54. US National Library of Medicine National Institutes of Health. Web.
  33. "In Vitro Embryos from Unknown Oocyte Source." C.A.S.E. Reproductive Services. University of Wisconsin-Madison, n.d. Web. May 14, 2016. http://www.ansci.wisc.edu/jjp1/ansci_repro/misc/project_websites_fa06/tues06/oocyte/IVF.htm
  34. Farsi, Mir Mehrdad, Nematollah Kamali, and Mohsen Pourghasem. "Embryological Aspects of Oocyte In Vitro Maturation."International Journal of Molecular and Cellular Medicine 2.3 (2013): 99–109. US National Library of Medicine National Institutes of Health. Babol University of Medical Sciences. Web. May 19, 2016.
  35. Carter, Joel A., Shane Bellow, Marius Meintjes, Oscar Perez, Edward Ferguson, and Robert A. Godke."Transvaginal Ultrasound-guided Oocyte Aspiration for Production of Embryos in Vitro." Leibniz Institute for Farm Animal Biology 45.1 (2002): 99–108. Research Gate. Web.
  36. Riley, Donald E. "DNA Testing: An Introduction For Non-Scientists." Scientific Testimony. University of Washington, April 6, 2005. Web. May 19, 2016. http://www.scientific.org/tutorials/articles/riley/riley.html
  37. Araújo, Adriana Mello De,Simone Eliza Facioni Guimarães, Thea Mírian Medeiros Machado, Paulo Sávio Lopes, Carmen Silva Pereira, Francisco Luiz Ribeiro Da Silva, Marcelo Teixeira Rodrigues, Virgínia De Souza Columbiano, and Cleusa Graça Da Fonseca. "Genetic Diversity between Herds of Alpine and Saanen Dairy Goats and the Naturalized Brazilian Moxotó Breed." Genetics and Molecular Biology Genet. Mol. Biol. 29.1 (2006): 67–74. Scientific Electronic Library. Web. May 18, 2016.
  38. Hart-Johnson . Sarah . Mankelow . Katharine . 2022 . Archiving genetically altered animals: a review of cryopreservation and recovery methods for genome edited animals . Laboratory Animals . en . 56 . 1 . 26–34 . 10.1177/00236772211007306 . 33847177 . 233223208 . 0023-6772.
  39. Floss, Jeanette L., and Roderick C. Tubbs. "Herd Management for Disease Prevention." Herd Management for Disease Prevention. University of Missouri-Columbia, July 1993. University of Missouri Extension Publication Number G2507 16 May 2016. URI:http://hdl.handle.net?10355/710.
  40. Yaeger, Michael J., Thomas Prieve, James Collins, Jane Christopher-Hennings, Eric Nelson, and Davis Benefield. "Evidence for the Transmission of Porcine Reproductive and Respiratory Syndrome (PRRS) Virus in Boar Semen." Swine Health and Production 1.5 (1993): 7–9. American Association of Swine Veterinarians. American Association of Swine Veterinarians. Web. 18 May.
  41. "Behavioural Principles of Handling Cattle and Other Grazing Anima ls Under Extensive Conditions." Livestock Handling and Transport. Ed. Temple Grandin. Wallingford: CABI, 2000. 67–68. Print.
  42. Brockbank, Dr. Kelvin G. M., James C. Covault, and Dr. Michael J. Taylor. "Cryoconservation Guide." Dr. Michael J. Taylor. Web. May 16, 2016.
  43. Özkavukçu, Sinan, and Esra Erdemli. "Cryopreservation: Basic Knowledge And Biophysical Effects." Journal of Ankara Medical School 24.4 (2002): 187–96. Web.
  44. Bartosiewicz, L. "The Hungarian Grey Cattle: A Traditional European Breed ." Animal Genetic Resources Information Anim. Genet. Resour. Inf. 21 (1997): 49–60. Web.
  45. "Magyar Szurke/Hungarian Grey." Domestic Animal Diversity Information System. Food and Agriculture Organization of the United Nations, Web. May 16, 2016. http://dad.fao.org/cgi-bin/EfabisWeb.cgi?sid=0b1613ebf16355cf65f6a05b9a65fe25,reportsreport8a_50001451
  46. Duckworth, J.W., Steinmetz, R., Timmins, R.J., Pattanavibool, A., Than Zaw, Do Tuoc & Hedges, S. 2008. Bos gaurus. The International Union for Conservation of Nature and Natural Resources Red List of Threatened Species 2008: e.T2891A9491805
  47. "Rainforest Beef." Integrated Conservation Research. Web. May 17, 2016.
  48. "Gaur (Bos Gaurus)". Asian Wild Cattle Specialist Group. Asian Wild Cattle Specialist Group, 2015. Web. May 17, 2016.
  49. Ramakrishnan, Priya. "Indian Bison Needs Attention: Researcher | Latest News & Updates at Dailey News & Analysis." DNA. July 14, 2010. Web. 18 May. 2016.
  50. Appleton, Caroline. "The Embryo Project Encyclopedia." The First Successful Cloning of a Gaur (2000), by Advanced Cell Technology. The Embryo Project Encyclopedia, July 26, 2013. Web. May 17, 2016.
  51. Harrison . Charlotte . 2021 . Mice on the move . Lab Animal . en . 50 . 9 . 233–235 . 10.1038/s41684-021-00829-5 . 0093-7355. free . 34373647 .
  52. Wigger . Magdalena . Schneider . Marco . Feldmann . Anni . Assenmacher . Sonja . Zevnik . Branko . Tröder . Simon E. . 2023-08-24 . Successful use of HTF as a basal fertilization medium during SEcuRe mouse in vitro fertilization . BMC Research Notes . en . 16 . 1 . 184 . 10.1186/s13104-023-06452-6 . 1756-0500 . 10463834 . 37620881 . free .