Nuclear Transfer Embryonic Cells Research Articles

Generation of Monogenetic Cattle by Different Techniques of Embryonic Cell and Somatic Cell Cloning – Their Application to Biotechnological, Agricultural, Nutritional, Biomedical and Transgenic Research – A Review

Abstract The development of effective approaches for not only the in vitro maturation (IVM) of heifer/cow oocytes and their extracorporeal fertilization (IVF) but also the non-surgical collection and transfer of bovine embryos has given rise to optimizing comprehensive in vitro embryo production (IVP) technology and improving other assisted reproductive technologies (ART s), such as cattle cloning by embryo bisection, embryonic cell nuclear transfer (ECNT) and somatic cell nuclear transfer (SCNT). The primary goal of the present paper is to demonstrate the progress and achievements in the strategies utilized for embryonic cell cloning and somatic cell cloning in cattle. Moreover, the current article is focused on recognizing and identifying the suitability and reliability of bovine cloning techniques for nutritional biotechnology, agri-food and biopharmaceutical industry, biomedical and transgenic research and for the genetic rescue of endangered or extinct breeds and species of domesticated or wild-living artiodactyl mammals (even-toed ungulates) originating from the family Bovidae.

84 PAIRS OF BLASTOMERES FROM BOVINE DAY 5 MORULAE ARE ABLE TO CONTRIBUTE TO INNER CELL MASS AND TROPHECTODERM IN CHIMERIC EMBRYOS GENERATED BY AGGREGATION WITH TWO DAY 4 MORULAE

The multiplication of high-value embryos by chimera formation using asynchronic aggregation is a promising alternative to embryonic cell nuclear transfer. Single blastomeres from a donor embryo are aggregated with 2 host embryos, thus several chimeras can be constructed per donor embryo. Due to the advanced developmental stage, the donor blastomeres are likely to contribute to the inner cell mass (ICM) and later give rise to the embryo proper, whereas the host embryos form extra-embryonic tissues. To test if pairs of blastomeres from Day 5 morulae are able to form the ICM when aggregated with 2 Day 4 host embryos, we produced transgenic donor embryos carrying a fluorescent reporter gene (enhanced green fluorescent protein, eGFP) by using semen from an eGFP transgenic bull (Reichenbach et al. 2010 Transgenic Res. 19, 549–556) for in vitro fertilization and in vitro host embryos produced by a standard procedure. The zona pellucida of all embryos was removed by treatment with 1 mg mL–1 pronase. Donor embryos were assessed for eGFP expression by fluorescence microscopy and disaggregated by gentle pipetting after incubation in Mg2+- and Ca2+-free medium. Pairs of blastomeres were then placed between 2 host embryos and cultured individually in a well-of-the-well culture dish. On Day 6 after aggregation, fully developed blastocysts were assessed for eGFP fluorescence. In 3 replicates, n = 30 chimeras were produced by aggregation; 13 (43%) developed to blastocysts, of which 2 (15%) showed local eGFP expression in the ICM and 7 (54%) showed a generalized expression. From the results of this study we conclude that Day 5 morulae may be multiplied in an efficient manner by using the chimera formation technique, which makes this approach applicable to ex vivo-derived embryos. In future investigations we will study the effect of using donor blastomeres from either the inside or outside of the donor morula and test the use of tetraploid host embryos to increase the rate of blastocysts with the desired genotype in the ICM. Finally, we aim to introduce this multiplication approach to the production of genotyped embryos with a genomic estimated breeding value (gEBV) and intend to produce calves with identical gEBV.Funded by the Bavarian Research Foundation (AZ-1031–1).

Sheep: The First Large Animal Model in Nuclear Transfer Research

The scope of this article is not to provide an exhaustive review of nuclear transfer research, because many authoritative reviews exist on the biological issues related to somatic and embryonic cell nuclear transfer. We shall instead provide an overview on the work done specifically on sheep and the value of this work on the greater nuclear transfer landscape.

Chemically Assisted Enucleation Results in HigherG6PDExpression in Early Bovine Female Embryos Obtained by Somatic Cell Nuclear Transfer

Despite extensive efforts, low efficiency is still an issue in bovine somatic cell nuclear transfer (SCNT). The hypothesis of our study was that the use of cytoplasts produced by chemically assisted enucleation (EN) would improve nuclear reprogramming in nuclear transfer (NT)-derived embryos because it results in lower damage and higher cytoplasm content than conventional EN. For that purpose, we investigated the expression of two X-linked genes: X inactive-specific transcript (XIST) and glucose 6-phosphate dehydrogenase (G6PD). In the first experiment, gene expression was assessed in day-7 female blastocysts from embryonic cell NT (ECNT) groups [conventional, ECNT conv; chemically assisted, ECNT deme (demecolcine)]. Whereas in the ECNT conv group, only one embryo (25%; n=4) expressed XIST transcripts, most embryos showed XIST expression (75%; n=4) in the ECNT deme group. However, no significant differences in transcript abundance of XIST and G6PD were found when comparing the embryos from all groups. In a second experiment using somatic cells as nuclear donors, we evaluated gene expression profiles in female SCNT-derived embryos. No significant differences in relative abundance (RA) of XIST transcripts were observed among the groups. Nonetheless, higher (p<0.05) levels of G6PD were observed in SCNT deme and in vitro-derived groups in comparison to SCNT conv. To know whether higher G6PD expression in embryos derived from SCNT chemically assisted EN indicates higher metabolism in embryos considered of superior quality or if the presence of higher reactive oxygen species (ROS) levels generated by the increased oxygen consumption triggers G6PD activation, the expression of genes related to stress response should be investigated in embryos produced by that technique.

Production of rabbit chimeric embryos by aggregation of zona-free nuclear transfer blastomeres

The objective of this study was to compare in vitro developmental capacity of zona-free aggregated rabbit chimeric embryos and the allocation of EGFP (enhanced green fluorescence protein) gene expression to the inner cell mass (ICM). We produced chimeric embryos by synchronous aggregation of zona-free blastomeres from embryonic cell nuclear transfer (EMB-NT) or somatic cell nuclear transfer (SC-NT) and blastomeres from normal zona-free embryos (N) at the 16-cell stage. In the control group, transgenic (TR) and normal zona-free embryos were used to produce chimeric embryos (TR<>N). EMB-NT embryos were produced by fusion of enucleated oocytes with embryonic cells, which were derived from 32-cell stage transgenic embryos bearing the EGFP gene. The SC-NT embryos were produced by fusing enucleated oocytes with cumulus cells, which were derived from homozygotes transgenic for the EGFP gene female oocytes at 16h post-coitum. Nuclei of transgenic blastomeres emitted a green signal under fluorescence microscopy. Zona-free EMB-NT or zona-free SC-NT rabbit embryos, both with EGFP fluorescence, as well as TR and zona-free rabbit embryos with no fluorescence (EMB-NT<>N, SC-NT<>N, TR<>N) were aggregated on day 2.5 and evaluated on day 5. The proportion of EMB-NT<>N embryos that developed to the blastocyst stage was significantly higher compared with SC-NT derived cells (p < 0.05), but significantly lower than in TR<>N chimeric blastocysts (p < 0.001). Similarly, a higher proportion (p < 0.001) of EGFP-positive cells allocated to ICM of chimeric blastocysts was revealed in TR<>N chimeras (55%), compared with EMB-NT<>N (35%) and SC-NT<>N (21%). Our results indicate that synchronous chimeric embryos reconstructed from TR embryos were better able to develop and colonize the ICM area than EMB-NT and SC-NT embryos. In this study we have demonstrated for the first time that rabbit NT-derived embryos are able to develop into chimeric blastocysts and participate in the ICM area.

Differential effect of recipient cytoplasm for microtubule organization and preimplantation development in rat reconstituted embryos with two-cell embryonic cell nuclear transfer.

In the present study, we examined the developmental ability of enucleated zygotes, MII oocytes, and parthenogenetically activated oocytes at pronuclear stages (parthenogenetic PNs) as recipient cytoplasm for rat embryonic cell nuclear transfer. Enucleated zygotes as recipient cytoplasm receiving two-cell nuclei allowed development to blastocysts, whereas the development of embryos reconstituted with MII oocytes and parthenogenetic PNs was arrested at the two-cell stage. Previous observations in rat two-cell embryos suggested that the distribution of microtubules is involved in two-cell arrest. Therefore, we also examined the distribution of microtubules using immunofluorescence. At the two-cell stage after nuclear transfer into enucleated zygotes, microtubules were distributed homogeneously in the cytoplasm during interphase, and normal mitotic spindles were observed in cleaving embryos from the two- to four-cell stage. In contrast, embryos reconstituted with MII oocytes and parthenogenetic PNs showed aberrant microtubule organization. In enucleated zygotes, fibrous microtubules were distributed homogeneously in the cytoplasm. In contrast, dense microtubules were localized at the subcortical area in the cytoplasm and strong immunofluorescence intensity was observed at the plasma membrane, while very weak intensity was detected in the central part of enucleated MII oocytes. In enucleated parthenogenetic PNs, high-density and fibrous microtubules were distributed in the subcortical and central areas, respectively. Pre-enucleated parthenogenetic PNs also showed lower intensity of microtubule immunofluorescence in the central cytoplasm than zygotes. In conclusion, the results of the present study showed that zygote cytoplasm is better as recipient than MII oocyte and parthenogenetic PNs for rat two-cell embryonic cell nuclear transfer to develop beyond four-cell stage. Furthermore, microtubule organization is involved in the development of reconstituted embryos to overcome the two-cell arrest.

Production of cloned pigs by using somatic cells as donors.

NUCLEAR TRANSFER is a procedure by which genetically identical individuals can be created. The applications of these techniques for nuclear transfer will be in agricultural, biomedical and basic research. Based on the sources of donor cells, nuclear transfer can be classified into embryonic cell nuclear transfer and somatic cell nuclear transfer. Offspring from cultured cells were first reported in 1994 (Sims and First, 1994) in cattle. Since this paper showed that cells could be cultured at least 28 days prior to nuclear transfer, it held great promise for genetically modifying the cells prior to nuclear transfer, and thus the possibility of producing animals with specific genetic modifications. This concept is exemplified by the generation of transgenic sheep (Schnieke et al., 1997), pigs (Park et al., 2001), calves (Cibelli et al., 1998a), and gene-targeted sheep (McCreath et al., 2000) and pigs (Lai et al., 2002b), derived from nuclear transfer approaches by using transfected somatic cells. For pigs, somatic cell nuclear transfer has another specific significance, as is it would allow the use of genetic modification procedures to produce tissues and organs from cloned pigs with reduced immunogenicity for use in xenotransplantation (Lai et al., 2002b). However, the efficiency of somatic cell nuclear transfer, when measured as development to term as a proportion of oocytes used, has been very low (1–2%). A number of variables 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, the method of artificial oocyte activation, embryo culture, possible loss of somatic imprinting in the nuclei of reconstructed embryos, failure of adequate reprogramming of the transplanted nucleus, and the techniques employed for nuclear transfer. In pig, there are additional difficulties in that the quality of embryos produced in vitro is low, and at least four good embryos are required to initiate and establish a pregnancy. Procedures for nuclear transfer include the following steps: acquisition of recipient oocytes and donor cells, enucleation (removal of the chromosome from recipient oocytes), insertion of donor nuclei into enucleated oocytes, artificial activation of reconstructed oocytes, and embryo transfer (transfer of the reconstructed embryos into a surrogate).

Molecular correlates of primate nuclear transfer failures.

Somatic cell nuclear transfer (SCNT) ([1][1]) in nonhuman primates could accelerate medical research by contributing identical animals for research and clarifying embryonic stem cell potentials ([2][2]). Although rhesus embryos begin development after embryonic cell nuclear transfer (ECNT) ([3–5][

Nuclear transfer in the rhesus monkey: practical and basic implications.

In early 1997, the birth of a lamb after transfer of the nucleus from an adult mammary gland cell into an enucleated oocyte, along with the production of rhesus monkeys by nuclear transfer of embryonic cells, marked a reemergence of the field of mammalian cloning. Clonally derived rhesus monkeys would be invaluable in biomedical research, and the commercial interests in transgenic sheep and cattle propagated by cloning are substantial. Nuclear transfer technology is under consideration in human in vitro fertilization clinics to overcome infertility secondary to advanced maternal age or mitochondrial-based genetic disease. Nuclear transfer involves preparing a cytoplast as a recipient cell, in most cases a mature metaphase II oocyte from which the chromosomes have been removed. A donor nucleus cell is then placed between the zona and the cytoplast, and fusion, as well as cytoplast activation, is initiated by electrical stimulation. Successful reprogramming of the donor cell nucleus by the cytoplast is critical--a step that may be influenced by cell cycle stage. Embryos produced by nuclear transfer are cultured in vitro for several cell divisions before cryopreservation or transfer to the oviduct or uterus of a host mother. The efficiency of producing live young by nuclear transfer in domestic species is low, with a high frequency of developmental abnormalities in both preterm and term animals. However, a number of pregnancies have now been established using fetal cells as the source of donor nuclei. The use of cell lines not only allows large clone sizes but also supports the ability to genetically manipulate cells in vitro before nuclear transfer. Ongoing research focused on the production of clonally derived rhesus monkeys using fetal fibroblasts and embryonic stem cells as the source of donor nuclei will be reviewed.

Recent progress in mammalian cloning.

Our purpose was to review recent progress in the use of nuclear transfer technology to produce genetically identical mammals. A literature review was conducted. The reasons for cloning nonhuman mammals are manyfold including commercial, biomedical, and basic research applications. Individual steps in the nuclear transfer process are itemized, along with a detailed description of the specific approaches used in the production of Dolly, NETI, and DITTO. The potential application of nuclear transfer in the treatment of human infertility is also considered, along with bioethical concerns. Finally, insights are provided concerning the future application of cloning technology in rhesus macaques. The cloning of a lamb (Dolly) from an adult, mammary gland cell coupled with the successful production of rhesus monkeys (NETI and DITTO) by nuclear transfer of embryonic cells marks the beginning of a "Golden Age" in the development and application of somatic cell cloning technology in mammals.