Cloning to reproduce desired genotypes

Cloned sheep, cattle, goats, pigs and mice have now been produced using somatic cells for nuclear transplantation. Animal cloning is still very inefficient with on average less than 10% of the cloned embryos transferred resulting in a live offspring. However successful cloning of a variety of different species and by a number of different laboratory groups has generated tremendous interest in reproducing desired genotypes. Some of these specific genotypes represent animal cell lines that have been genetically modified. In other cases there is a significant demand for cloning animals characterized by their inherent genetic value, for example prize livestock, household pets and rare or endangered species. A number of different variables may influence the ability to reproduce a specific genotype by cloning. These include species, source of recipient ova, cell type of nuclei donor, treatment of donor cells prior to nuclear transfer, and the techniques employed for nuclear transfer. At present, there is no solid evidence that suggests cloning will be limited to only a few specific animals, and in fact, most data collected to date suggests cloning will be applicable to a wide variety of different animals. The ability to reproduce any desired genotype by cloning will ultimately depend on the amount of time and resources invested in research.     

Comparative aspects of somatic cell nuclear transfer with conventional and zona-free method in cattle, horse, pig and sheep

Nuclear transfer (NT) is a complex procedure that requires considerable technical skills. Over the years attempts have been made to simplify the micromanipulations involved and to make the procedure more user-friendly. A significant step forwards has been the development of the zona-free NT methods. We have used zona-free NT with mechanical aspiration of the metaphase plate as a mean of enucleation, in a comparative approach with the conventional nuclear transfer zona-enclosed method in cattle, horse, sheep and pig. The absence of the zona considerably facilitates the enucleation step and significantly increases cell fusion success. On the other hand, the culture of zona-free NT embryos requires the embryos to be cultured individually or anyway separated from each other to avoid aggregation and also requires to prolong the in vitro culture up to the blastocyst stage before transfer. Blastocyst rate is equal or higher with zona-free method as compared to zona-enclosed method while survival after cryopreservation and development to term is comparable. In conclusion, our findings, together with published data, demonstrate that the zona-free system described in this paper can significantly increase the output of NT blastocysts over the conventional zona-enclosed system.     

Cloning cattle

Over the past six years, hundreds of apparently normal calves have been cloned worldwide from bovine somatic donor cells. However, these surviving animals represent less than 5% of all cloned embryos transferred into recipient cows. Most of the remaining 95% die at various stages of development from a predictable pattern of placental and fetal abnormalities, collectively referred to as the "cloning-syndrome." The low efficiency seriously limits commercial applicability and ethical acceptance of somatic cloning and enforces the development of improved cloning methods. In this paper, we describe our current standard operating procedure (SOP) for cattle cloning using zona-free nuclear transfer. Following this SOP, the output of viable and healthy calves at weaning is about 9% of embryos transferred. Better standardization of cloning protocols across and within research groups is needed to separate technical from biological factors underlying low cloning efficiency.     

Improved in vitro development rates of sheep somatic nuclear transfer embryos by using a reverse-order zona-free cloning method

This paper describes a modified zona-free cloning protocol for examining the effects of short-term exposure of donor nuclei to maternal chromosomal components and associated factors. In vitro matured zona-free sheep oocytes were enucleated by micromanipulator-assisted aspiration either before or after fusion with adult fibroblast or granulosa donor cells. Subsequent kinetics of donor nuclei and maternal chromatin as well as in vitro embryo development rates were recorded. The effect of an additional activation stimulus in connection with the reverse-order cloning (fusion before enucleation) and the feasibility of manual enucleation by metal blade were also studied. As a result of the simultaneous fusion and activation, most donor nuclei remained in interphase but swelled in size. Maternal chromosomes reached anaphase II-telophase II stages within 1-2 h of activation, effectively facilitating telophase enucleation with both the micromanipulator-assisted aspiration and manual bisection. A significantly higher development rate to the blastocyst stage was achieved with the reverse-order protocol, suggesting further investigation into the possible role of oocyte nucleus-associated factors in reprogramming is warranted. Overall, the reverse-order zona-free cloning method was efficient in the production of transferable cloned sheep blastocysts and may offer yet another choice of methodology in the practical application of nuclear transfer technology.     

Transgenic technology and applications in swine.

The introduction of foreign DNA into the genome of livestock and its stable integration into the germ line has been a major technical advance in agriculture. Production of transgenic livestock provides a method to rapidly introduce "new" genes into cattle, swine, sheep and goats without crossbreeding. It is a more extreme methodology, but in essence, not really different from crossbreeding or genetic selection in its result. Several recent developments will profoundly impact the use of transgenic technology in livestock production. These developments are: 1) the ability to isolate and maintain in vitro embryonic stem (ES) cells from preimplantation embryos, embryonic germ (EG) and somatic cells from fetuses; and somatic cells from adults, and 2) the ability to use these embryonic and somatic cells as nuclei donors in nuclear transfer or "cloning" strategies. Cell based (ES, EG, and somatic cells) strategies have several distinct advantages for use in the production of transgenic livestock that cannot be attained using pronuclear injection of DNA. There are many potential applications of transgenic methodology to develop new and improved strains of livestock. Practical applications of transgenesis in livestock production include enhanced prolificacy and reproductive performance, increased feed utilization and growth rate, improved carcass composition, improved milk production and/or composition and increased disease resistance. Development of transgenic farm animals will allow more flexibility in direct genetic manipulation of livestock.     

Simple, fast, and efficient method of manual oocyte enucleation using a pulled Pasteur pipette

Cloning mammals by somatic cell nuclear transfer entails the replacement of oocyte chromosomes with the nucleus of a somatic cell. A major step in this technique is to efficiently produce large batches of enucleated oocytes, a process that requires considerable micromanipulation skills and expensive equipments. Here, a simple, fast, and efficient method of manual oocyte enucleation was introduced that can be adopted in every laboratory with the minimum equipments. Common laboratory glass pipettes were pulled on the flame of a burner and then used for manual bisection or enucleation of sheep and goat zona-free oocytes by passing them through the discontinuous cutting border of culture medium and mineral oil. The described techniques showed a certain efficiency to conveniently bisect or enucleate large batches of sheep, and goat oocytes being pre-treated with demecolcine. The method may be straightforward for simple manipulation of oocytes of other species and for development of automated cloning methods as well.     

Genomic potential in mammals

Embryos of amphibians, fish, sheep, cattle, swine and rabbits have been multiplied by nuclear transfer. Successful nuclear transfer in these species has been accomplished by transfer of a blastomere from a late stage embryo into an enucleated oocyte or egg with large scale multiplication achieved by serial repetition of the procedure using blastomeres from nuclear transfer embryos. This allows the production of clonal lines, which when appropriately selected for performance in a given trait, can be reproduced to capture in the offspring expression of both additive and nonadditive inheritance. The efficiency of producing offspring from nuclear transfer is low in mammals in both frequency of morula or blastocyst produced and maintenance of pregnancy after embryo transfer. In domestic animals the largest number of offspring from one embryo has been eight calves. Embryos as late as the 64-cell stage in cattle and 120-cell blastocyst in sheep have been used successfully as donors of blastomeres. Recloning has also been done in cattle. Potentially, nuclear transfer provides a mechanism for multiplication and production testing of clonal lines, a method for rapid genetic improvement and a means for rapid propagation of a selected genotype.     

Efficient PRNP gene targeting in bovine fibroblasts by adeno-associated virus vectors

Gene-targeted livestock can be created by combining ex vivo manipulation of cultured nuclear donor cells with cloning by nuclear transfer. However, this process can be limited by the low gene targeting frequencies obtained by transfection methods, and the limited ex vivo life span of the normal nuclear donor cells. We have developed an alternative gene targeting method based on the delivery of linear, single-stranded DNA molecules by adeno-associated virus (AAV) vectors, which can be used to introduce a variety of different mutations at single copy loci in normal human cells. Here we show that AAV vectors can efficiently target the PRNP gene encoding the prion protein PrP in bovine fetal fibroblasts, which can be used as nuclear donors to clone cattle. Cattle with both PRNP genes disrupted should be resistant to bovine spongiform encephalopathy.     

Cloned cattle derived from a novel zona-free embryo reconstruction system

As the demand for cloned embryos and offspring increases, the need arises for the development of nuclear transfer procedures that are improved in both efficiency and ease of operation. Here, we describe a novel zona-free cloning method that doubles the throughput in cloned bovine embryo production over current procedures and generates viable offspring with the same efficiency. Elements of the procedure include zona-free enucleation without a holding pipette, automated fusion of 5-10 oocyte-donor cell pairs and microdrop in vitro culture. Using this system, zona-free embryos were reconstructed from five independent primary cell lines and cultured either singularly (single-IVC) or as aggregates of three (triple-IVC). Blastocysts of transferable quality were obtained at similar rates from zona-free single-IVC, triple-IVC, and control zona-intact embryos (33%, 25%, and 29%, respectively). In a direct comparison, there was no significant difference in development to live calves at term between single-IVC, triple-IVC, and zona-intact embryos derived from the same adult fibroblast line (10%, 13%, and 15%, respectively). This zona-free cloning method could be straightforward for users of conventional cloning procedures to adopt and may prove a simple, fast, and efficient alternative for nuclear cloning of other species as well.     

Cloning of sheep and cow embryos

The results of experiments aimed at cloning of sheep and cattle embryos are described. Two experimental approaches were used to study the developmental potential of blastomeres from sheep and cow embryos: (i) blastomere separation followed by culture and (ii) fusion of isolated blastomeres with enucleated eggs followed by culture. Both approaches allow embryos to be cloned, but whereas blastomere separation allows only a relatively small number of genetically identical animals to be produced, nuclear transplantation will probably open the way for large-scale cloning of livestock.     

The US FDA and animal cloning: risk and regulatory approach

The Food and Drug Administration's (FDA's) Center for Veterinary Medicine issued a voluntary request to producers of livestock clones not to introduce food from clones or their progeny into commerce until the agency had assessed whether production of cattle, swine, sheep, or goats by somatic cell nuclear transfer (SCNT) posed any unique risks to the animal(s) involved in the process, humans, or other animals by consuming food from those animals, compared with any other assisted reproductive technology (ART) currently in use. Following a comprehensive review, no anomalies were observed in animals produced by cloning that have not also been observed in animals produced by other ARTs and natural mating. Further systematic review on the health of, and composition of meat and milk from, cattle, swine, and goat clones and the progeny of cattle and sheep did not result in the identification of any food-consumption hazards. The agency therefore concluded that food from cattle, swine, and goat clones was as safe to eat as food from animals of those species derived by conventional means. The agency also concluded that food from the progeny of the clone of any species normally consumed for food is as safe to eat as those animals. The article also describes the methodology used by the agency to analyze data and draw these conclusions, the plans the agency has proposed to manage any identified risks, and the risk communication approaches the agency has used.     

Live lambs born from zona-pellucida denuded embryos

Progress with techniques using zona-pellucida denuded embryos has resulted in the birth of live cattle, pigs, and mice. The application of zona-free methods in sheep has been restricted to in vitro studies. In this report, we demonstrate that live lambs can be produced from zona-free IVF embryos. We are pursuing this method as a prerequisite to developing viral vector co-culture delivery strategies.     

Handmade somatic cell cloning in cattle: analysis of factors contributing to high efficiency in vitro

Widespread application of somatic cell cloning has been hampered by biological and technical problems, which include complicated and time-consuming procedures requiring skilled labor. Recently, zona-free techniques have been published with limited or no requirement for micromanipulators. The purpose of the present work was to optimize certain steps of the micromanipulator-free (i.e., handmade) procedure, to analyze the morphology of the developing blastocysts, and to explain factors involved in the high efficiencies observed. Optimization of the procedure included selection of the appropriate medium for enucleation, orientation of pairs at fusion, timing of fusion, and culture conditions. As a result of these improved steps, in vitro efficiency as measured by blastocysts per reconstructed embryo and blastocysts per working hour was among the highest described so far. The cattle serum used in our experiments was superior to other protein sources for in vitro embryo development. One possible explanation of this effect is the considerable mitogenic activity of the cattle serum compared with that of commercially available fetal calf serum. Morphological analysis of blastocysts by inverted microscopy, inner cell mass-trophoblast differential staining, and transmission electron microscopy revealed high average quality. A high initial pregnancy rate was achieved after the transfer of single blastocysts derived by aggregation of two nuclear transfer embryos into recipients. The improved handmade somatic cell nuclear transfer method may become a useful technology as a simple, inexpensive, and efficient alternative to traditional somatic cell nuclear transfer.     

Application of reproductive biotechnology in animals: implications and potentials. Applications of reproductive cloning

The development of new methods of nuclear transfer in mammals is creating many new opportunities in research, medicine and agriculture. The method of cloning is repeatable and has been established in many laboratories worldwide. However, the present procedure is inefficient with fewer than 4% of embryos becoming viable offspring. A considerable improvement in efficiency is required before wide scale use for livestock improvement. The opportunity to introduce precise genetic changes to livestock is available for the first time through the use of gene targeting procedures in cultured cells that are used as nuclear donors. This has potential application in the production of organs for transplantation to humans, studies of human genetic disease and basic research in to the control of gene expression and function.     

Cloning animals by somatic cell nuclear transfer – biological factors

Cloning by nuclear transfer using mammalian somatic cells has enormous potential application. However, somatic cloning has been inefficient in all species in which live clones have been produced. High abortion and fetal mortality rates are commonly observed. These developmental defects have been attributed to incomplete reprogramming of the somatic nuclei by the cloning process. Various strategies have been used to improve the efficiency of nuclear transfer, however, significant breakthroughs are yet to happen. In this review we will discuss studies conducted, in our laboratories and those of others, to gain a better understanding of nuclear reprogramming. Because cattle are a species widely used for nuclear transfer studies, and more laboratories have succeeded in cloning cattle than any other specie, this review will be focused on somatic cell cloning of cattle.     

Specific genetic modifications of domestic animals by gene targeting and animal cloning

The technology of gene targeting through homologous recombination has been extremely useful for elucidating gene functions in mice. The application of this technology was thought impossible in the large livestock species until the successful creation of the first mammalian clone "Dolly" the sheep. The combination of the technologies for gene targeting of somatic cells with those of animal cloning made it possible to introduce specific genetic mutations into domestic animals. In this review, the principles of gene targeting in somatic cells and the challenges of nuclear transfer using gene-targeted cells are discussed. The relevance of gene targeting in domestic animals for applications in bio-medicine and agriculture are also examined.     

Paternal mitochondrial DNA transmission during nonhuman primate nuclear transfer

Offspring produced by nuclear transfer (NT) have identical nuclear DNA (nDNA). However, mitochondrial DNA (mtDNA) inheritance could vary considerably. In sheep, homoplasmy is maintained since mtDNA is transmitted from the oocyte (recipient) only. In contrast, cattle are heteroplasmic, harboring a predominance of recipient mtDNA along with varying levels of donor mtDNA. We show that the two nonhuman primate Macaca mulatta offspring born by NT have mtDNA from three sources: (1) maternal mtDNA from the recipient egg, (2) maternal mtDNA from the egg contributing to the donor blastomere, and (3) paternal mtDNA from the sperm that fertilized the egg from which the donor blastomere was isolated. The introduction of foreign mtDNA into reconstructed recipient eggs has also been demonstrated in mice through pronuclear injection and in humans through cytoplasmic transfer. The mitochondrial triplasmy following M. mulatta NT reported here forces concerns regarding the parental origins of mtDNA in clinically reconstructed eggs. In addition, mtDNA heteroplasmy might result in the embryonic stem cell lines generated for experimental and therapeutic purposes ("therapeutic cloning").     

The possible role of cell cycle stage in mammalian cloning

Progress in mammalian cloning started from cloning embryos (of mice, rats, rabbits, sheep, goats, pigs, cattle and rhesus monkeys) and culminated in obtaining clones of sheep, cattle, pigs and mice from adult somatic cells. Knowing the relationship between the cell cycles of the recipient and the donor of cell nucleus in embryonic cloning by nuclear transfer one can adjust the phases of the cell cycle properly. Metaphase II recipients accept G1 (in most species) or G2 donors (in the mouse). Interphase recipients can harbour nuclei in all stages of cell cycle. Relatively little is known about somatic cloning. Two attitudes are applied: either the donor is in the G0 phase or the recipient is in a prolonged MII phase.     

Science and technology of farm animal cloning: state of the art

Details of the first mammal born after nuclear transfer cloning were published by Steen Malte Willadsen in 1986. In spite of its enormous scientific significance, this discovery failed to trigger much public concern, possibly because the donor cells were derived from pre-implantation stage embryos. The major breakthrough in terms of public recognition has happened when Ian Wilmut et al. [Wilmut, I., Schnieke, A.E., McWhir, J., Kind, A.J., Campbell, K.H., 1997. Viable offspring derived from fetal és adult mammalian cells. Nature 385, 810-813] described the successful application of almost exactly the same method, but using the nuclei of somatic cells from an adult mammal, to create Dolly the sheep. It has become theoretically possible to produce an unlimited number of genetic replicates from an adult animal or a post-implantation foetus. Since 1997 a number of different species including pigs, goats, horses, cats, etc. have been cloned with the somatic cell nuclear transfer technique. Although the technology still has relatively low success rates and there seems to be substantial problems with the welfare of some of the cloned animals, cloning is used both within basic research and the biomedical sector. The next step seems to be to implement cloning in the agricultural production system and several animals have been developed in this direction. This article reviews the current state of the art of farm animal cloning from a scientific and technological perspective, describes the animal welfare problems and critically assess different applications of farm animal cloning. The scope is confined to animal biotechnologies in which the use of cell nuclear transfer is an essential part and extends to both biomedical and agricultural applications of farm animal cloning. These applications include the production of genetically identical animals for research purposes, and also the creation of genetically modified animals. In the agricultural sector, cloning can be used as a tool within farm animal breeding. We do not intend to give an exhaustive review of the all the literature available; instead we pinpoint issues and events pivotal to the development of current farm animal cloning practices and their possible applications.     

Animal reproduction biotechnology in Poland

The key research areas of the Department are: in vitro production of embryos, embryo cryopreservation, animal transgenesis, cloning, cytometric semen sexing and evaluation. Research has been focused on the in vitro production of animal embryos, including the development of complex methods for oocyte maturation, fertilization and embryo culture. Moreover, experiments on long-term culturing of late preantral and early antral bovine ovarian follicles have been developed. Studies on the cloning of genetically modified pigs with "humanized" immunological systems have been undertaken. A cloned goat was produced from oocytes reconstructed with adult dermal fibroblast cells. The novel technique of rabbit chimeric cloning for the production of transgenic animals was applied; additionally, the recipient-donor-cell relationship in the preimplantation developmental competences of feline nuclear transfer embryos has been studied. Regarding transgenic animal projects, gene constructs containing growth hormone genes connected to the mMt promoter were used. Modifications of milk composition gene constructs with tissue-specific promoters were performed. Moreover, pigs for xenotransplantation and animal models of human vascular diseases have been produced. Over the last 15 years, our flow cytometry research group has focused its work on new methods for sperm quality assessment and sex regulation. In the 1970s, our team initiated studies on embryo cryopreservation. As a result of vitrification experiments, the world's first rabbits and sheep produced via the transfer of vitrified embryos were born.