Uncoupled embryonic and extra-embryonic tissues compromise blastocyst development after somatic cell nuclear transfer.

Somatic cell nuclear transfer (SCNT) is the most efficient cell reprogramming technique available, especially when working with bovine species. Although SCNT blastocysts performed equally well or better than controls in the weeks following embryo transfer at Day 7, elongation and gastrulation defects were observed prior to implantation. To understand the developmental implications of embryonic/extra-embryonic interactions, the morphological and molecular features of elongating and gastrulating tissues were analysed. At Day 18, 30 SCNT conceptuses were compared to 20 controls (AI and IVP: 10 conceptuses each); one-half of the SCNT conceptuses appeared normal while the other half showed signs of atypical elongation and gastrulation. SCNT was also associated with a high incidence of discordance in embryonic and extra-embryonic patterns, as evidenced by morphological and molecular "uncoupling". Elongation appeared to be secondarily affected; only 3 of 30 conceptuses had abnormally elongated shapes and there were very few differences in gene expression when they were compared to the controls. However, some of these differences could be linked to defects in microvilli formation or extracellular matrix composition and could thus impact extra-embryonic functions. In contrast to elongation, gastrulation stages included embryonic defects that likely affected the hypoblast, the epiblast, or the early stages of their differentiation. When taking into account SCNT conceptus somatic origin, i.e. the reprogramming efficiency of each bovine ear fibroblast (Low: 0029, Med: 7711, High: 5538), we found that embryonic abnormalities or severe embryonic/extra-embryonic uncoupling were more tightly correlated to embryo loss at implantation than were elongation defects. Alternatively, extra-embryonic differences between SCNT and control conceptuses at Day 18 were related to molecular plasticity (high efficiency/high plasticity) and subsequent pregnancy loss. Finally, because it alters re-differentiation processes in vivo, SCNT reprogramming highlights temporally and spatially restricted interactions among cells and tissues in a unique way.

Indistinguishable transcriptional profiles between in vitro- and in vivo-produced bovine fetuses.

During the past several decades, in vitro fertilization (IVF) has been increasingly used both in animal production and human infertility treatment. Animals derived from in vitro manipulation are occasionally associated with abnormal offspring syndrome (AOS) and other developmental abnormalities. By studying gene expression of in vitro-produced (IVP) embryos/animals, we gain an indicator of how well this procedure mimics the in vivo environment. Most previous studies of this nature have focused on only a few genes at a time or have been limited to studying the pre-implantation stage; a global view of how gene transcription may be influenced by in vitro procedures during fetal development has yet to be ascertained. To this end, we collected liver and placental tissue samples from IVP and in vivo control bovine fetuses at days 90 and 180 of gestation. We used a bovine 13K oligonucleotide microarray to investigate the transcriptional profiles in both tissues from IVP fetuses, and compared them with those of their age-matched in vivo counterparts. Surprisingly, in both liver and placental tissues, the transcriptional profiles between IVP and control fetuses, at either 90 or 180 days of gestation, were indistinguishable. A total of 879 genes were found to be significantly regulated during liver development from 90 to 180 days of gestation, but there were no gene expression changes in the placental tissue during this developmental period. Quantitative real-time RT-PCR on 11 selected genes confirmed these results. Our results have certain implications for IVF technologies, both in agriculture and in human medicine.

Altered gene expression profiles in the brain, kidney, and lung of one-month-old cloned pigs.

Although numerous mammalian species have been successfully cloned by somatic cell nuclear transfer (SCNT), little is known about gene expression of cloned pigs by SCNT. In the present study, expression profiles of 1-month-old cloned pigs generated from fetal fibroblasts (n = 5) were compared to those of age-matched controls (n = 5) using a 13K oligonucleotide microarray. The brain, kidney, and lung were chosen for microarray analysis to represent tissues from endoderm, mesoderm, and ectoderm in origin. In clones, 179 and 154 genes were differentially expressed in the kidney and the lung, respectively (fold change >2, p < 0.05, false discovery rate = 0.05), whereas only seven genes were differentially expressed in the brain of clones. Functional analysis of the differentially expressed genes revealed that they were enriched in diabetic nephropathy in the kidney, delayed alveologenesis as well as downregulated MAPK signaling pathways in the lung, which was accompanied with collapsed alveoli in the histological examination of the lung. To evaluate whether the gene expression anomalies are associated with changes in DNA methylation, global concentration of the methylated cytosine was measured in lung DNA by HPLC. Clones were significantly hypermethylated (5.72%) compared to the controls (4.13%). Bisulfite-pyrosequencing analyses of the promoter regions of differentially expressed genes, MYC and Period 1 (PER1), however, did not show any differences in the degree of DNA methylation between controls and clones. Together, these findings demonstrate that cloned pigs have altered gene expression that may potentially cause organ dysfunction.

Oocyte source and hormonal stimulation for in vitro fertilization using sexed spermatozoa in cattle.

The aim of this study was to investigate the efficiency of in vitro embryo production in cattle utilizing sexed sperm from two bulls and oocytes recovered by OPU. Twenty donor animals were employed in eight OPU replicates: the first four OPU trials were conducted on animals without hormone treatment, and the last four were run on the same animals, following FSH subcutaneous and intramuscular administration. A higher rate of blastocyst development was recorded in stimulated, as compared to nonstimulated animals, (25.2% versus 12.8%, P = .001). Ocytes derived from slaughterhouse (SH) ovaries were also fertilized with sperm from the same bulls. Overall, non-sexed sperm used with oocytes derived from SH ovaries was significantly more efficient for blastocyst development than was sexed sperm with these same SH derived oocytes and sexed sperm with stimulated donor oocytes (39.8% versus 25.0% and 25.2%, P = .001). In conclusion, the use of sexed sperm with OPU-derived oocytes resulted in a significantly higher blastocyst development when donors were hormonally stimulated; furthermore, the level of efficiency achieved was comparable to that attained when the same sexed sperm was tested on oocytes derived from SH ovaries.

Impeding Xist expression from the active X chromosome improves mouse somatic cell nuclear transfer.

Cloning mammals by means of somatic cell nuclear transfer (SCNT) is highly inefficient because of erroneous reprogramming of the donor genome. Reprogramming errors appear to arise randomly, but the nature of nonrandom, SCNT-specific errors remains elusive. We found that Xist, a noncoding RNA that inactivates one of the two X chromosomes in females, was ectopically expressed from the active X (Xa) chromosome in cloned mouse embryos of both sexes. Deletion of Xist on Xa showed normal global gene expression and resulted in about an eight- to ninefold increase in cloning efficiency. We also identified an Xist-independent mechanism that specifically down-regulated a subset of X-linked genes through somatic-type repressive histone blocks. Thus, we have identified nonrandom reprogramming errors in mouse cloning that can be altered to improve the efficiency of SCNT methods.

Altered gene expression profiles in the brain, kidney, and lung of deceased neonatal cloned pigs.

Limited studies have been published analyzing the gene expression patterns of cloned pigs. We compared the expression profiles of brain, kidney, and lung tissues, representing each of the three germ layers, of deceased neonatal cloned pigs with those of age-matched controls using a 13K oligonucleotide microarray. We found 42 (0.7% of total genes analyzed), 178 (2.9%), and 121 (1.9%) genes differentially expressed in the brain, kidney, and lung of clones, respectively, when compared with the corresponding organs from controls (fold change >1.5, p < 0.05, false discovery rate (FDR) = 0.05). These expression aberrations could potentially cause the following pathological anomalies in clones: diabetic nephropathy in the kidney and dysregulated surfactant homeostasis in the lung. Interestingly, upregulated expression of genes belonging to the MAPK pathway was observed in all three organs. To investigate whether the differences in levels of gene expression were caused by differential DNA methylation, the global DNA methylation level was measured by high-performance liquid chromatography. In controls, global concentration of methylated cytosine was 5.35%, whereas clones had significantly hypomethylated genomic DNA (4.57%). Bisulfite-pyrosequencing analyses of the promoter regions of differentially expressed candidate genes, c-MYC, Period 1 (PER1), Cathepsin L (CTSL), and Follistatin (FS), however, did not show any differences in the degree of DNA methylation between controls and clones. Our findings demonstrate that deceased neonatal cloned pigs have considerable gene expression abnormalities, which may have contributed to the death of the animals.

Culture conditions and enzymatic passaging of bovine ESC-like cells.

The goals of the current study were to (1) improve culture conditions and (2) chemical passaging of bovine embryonic stem cell-like (bESC-like) cells. Specifically, the effects of human leukemia inhibitory factor (hLIF), two types of feeders, mouse embryonic fibroblast (MEF) and bovine embryonic fibroblast (BEF), as well as three different enzymatic treatments including Trypsin-EDTA, TrypLE, and Liberase Blendzymes 3 were investigated. The addition of hLIF at 1000 U/mL to the culture medium (41.2 and 36.9%), and the use of either MEF or BEF feeders (40.3 and 38.1%) had no significant effect on the ability of inner cell masses (ICMs) to form primary cell colonies compared to controls. All bESC-like cells were first dissociated mechanically for three passages followed by enzymatic dissociation. The ability to maintain ESC morphology to passage 10 was compared among the three enzymes above. More bESC-like cell lines survived beyond passage 10 when treated with TrypLE compared to Trypson-EDTA (28.8 and 12.6%; p < 0.05), and bESC-like cells differentiated quickly when treated with Liberase Blendzyme 3. The bESC-like cells generated in our study displayed typical stem cell morphology and expressed specific markers such as SSEA-1, AP, OCT-4, and Nanog. When removed from feeders, these bESC-like cells formed embryoid bodies (EBs) in a suspension culture. When EBs were cultured on tissue culture plates, they differentiated into various cell types. In summary, we were able to culture bESC-like cells more than 10 passages by enzymatic dissociation, which is important in gene targeting, maintenance, and banking of bESC lines.

Efficient derivation of embryonic stem cells from nuclear transfer and parthenogenetic embryos derived from cryopreserved oocytes.

Deriving histocompatible embryonic stem (ES) cells by somatic cell nuclear transfer (SCNT) and parthenogenetic activation (PA) requires fresh oocytes, which prevents their applications in humans. Here, we evaluated the efficiency of deriving ES cells from mature metaphase II (MII) and immature metaphase I (MI) vitrified oocytes, by PA or SCNT, in a mouse model. We successfully generated ES cell lines from PA (MII and MI) and SCNT (MII and MI) blastocysts. These cell lines expressed genes and antigens characteristic of pluripotent ES cells and produced full-term pups upon tetraploid embryo complementation. This study established an animal model for efficient generation of patient-specific ES cell lines using cryopreserved oocytes. This is a major step forward in the application of therapeutic cloning and parthenogenetic technology in human regenerative medicine and will serve as an important alternative to the iPS cell technology in countries/regions where these technologies are permitted.

Engineered heart tissue graft derived from somatic cell nuclear transferred embryonic stem cells improve myocardial performance in infarcted rat heart.

The concept of regenerating diseased myocardium by implanting engineered heart tissue (EHT) is intriguing. Yet it was limited by immune rejection and difficulties to be generated at a size with contractile properties. Somatic cell nuclear transfer is proposed as a practical strategy for generating autologous histocompatible stem (nuclear transferred embryonic stem [NT-ES]) cells to treat diseases. Nevertheless, it is controversial as NT-ES cells may pose risks in their therapeutic application. EHT from NT-ES cell-derived cardiomyocytes was generated through a series of improved techniques in a self-made mould to keep the EHTs from contraction and provide static stretch simultaneously. After 7 days of static and mechanical stretching, respectively, the EHTs were implanted to the infarcted rat heart. Four weeks after transplantation, the suitability of EHT in heart muscle repair after myocardial infarction was evaluated by histological examination, echocardiography and multielectrode array measurement. The results showed that large (thickness/diameter, 2-4 mm/10 mm) spontaneously contracting EHTs was generated successfully. The EHTs, which were derived from NT-ES cells, inte grated and electrically coupled to host myocardium and exerted beneficial effects on the left ventricular function of infarcted rat heart. No teratoma formation was observed in the rat heart implanted with EHTs for 4 weeks. NT-ES cells can be used as a source of seeding cells for cardiac tissue engineering. Large contractile EHT grafts can be constructed in vitro with the ability to survive after implantation and improve myocardial performance of infarcted rat hearts.

The oocyte spindle is preserved by 1,2-propanediol during slow freezing.

OBJECTIVE: To investigate the specific changes in oocyte spindle subjected to severe challenges of low temperature, as well as to examine the effect of cryoprotectants in preserving oocyte spindle during cryopreservation. DESIGN: In vitro experimental study. SETTING: Academic research laboratory. ANIMAL(S): B6D2F1 (C57BL/6 X DBA/2) mice. INTERVENTION(S): Mouse oocytes were cryopreserved using a slow freezing method in a sodium-depleted medium with 1.5 mol/l 1,2-propanediol (PROH) and 0.3 M sucrose. To examine the spindle, oocytes were fixed before, during, and after cryopreservation, and oocytes were analyzed by immunocytochemistry and confocal microscopy. RESULT(S): The MII spindle was preserved during the slow freezing, because the cryoprotectant PROH was found to support the organization of MII spindle in resisting the subzero temperature. In contrast, the MII spindle was disassembled gradually during the thawing process with or without PROH. Most of the oocytes were able to recover the MII spindle after thawing, but a portion of thawed oocytes could not sustain the meiotic spindle because of parthenogenetic activation. CONCLUSION(S): 1,2-Propanediol can support the organization of MII spindle to defy the subphysiologic temperature; however, the PROH cannot sustain oocyte spindle structure after the subsequent thawing process.

Calcium release and development of heat-shocked porcine oocytes after nucleus-ooplasm reconstruction.

We determined the effect of heat shock (HS) on the alterations of development and calcium releasing capacity of nuclear-ooplasmic reconstructed porcine oocytes stimulated by thimerosal. The non-HS (39 degrees C) and the HS2h (41.5 degrees C for 2 h) matured oocytes were enucleated and their spindles/chromosomes were exchanged between these two groups followed by parthenogenetic activation. In the Control group (Csp-Coop), the non-HS spindle (Csp) was transferred to the non-HS ooplasm (Coop). Blastocyst and cleavage rates were higher in both Csp-HSoop (non-HS spindle transferred to the HS ooplasm) and HSsp-Coop (HS spindle transferred to non-HS ooplasm) reconstructed oocytes, but no difference was detected in the average cell number per blastocyst. However, intracellular calcium concentrations ([Ca(2+)](i)) generally declined (p < 0.05) in the reconstructed HS oocytes, with a greater blastocyst rate after parthenogenetic activation. In the present study, time for the completion of spindle transfer in these oocytes was 1-2 h, during which some physiological remodeling or adaptation might have been occurred in the oocytes. Therefore, changes in heat-shock protein70 (HSP70) expression and developmental competence of the HS2h oocytes with 1 or 2 h of recovery time under normal culture temperature (39 degrees C) were examined. The results showed that the expression of HSP70 in the HS2h oocytes was higher (p < 0.05) than those had recovery incubation for 1 h (HC1h) after HS, but the cleavage and blastocyst rates were greater (p < 0.05) in the HC1h group. We demonstrated that a recovery period prior to activation of porcine oocytes and reconstructed oocytes is beneficial to further development. Heat shock to either the karyoplast or the ooplasm enhances embryonic development but reduces intracellular calcium release in the cloned porcine oocytes.

Gene expression profiles of bovine caruncular and intercaruncular endometrium at implantation.

At implantation the endometrium undergoes modifications necessary for its physical interactions with the trophoblast as well as the development of the conceptus. We aim to identify endometrial factors and pathways essential for a successful implantation in the caruncular (C) and the intercaruncular (IC) areas in cattle. Using a 13,257-element bovine oligonucleotide array, we established expression profiles at day 20 of the estrous cycle or pregnancy (implantation), revealing 446 and 1,295 differentially expressed genes (DEG) in C and IC areas, respectively (false discovery rate = 0.08). The impact of the conceptus was higher on the immune response function in C but more prominent on the regulation of metabolism function in IC. The C vs. IC direct comparison revealed 1,177 and 453 DEG in cyclic and pregnant animals respectively (false discovery rate = 0.05), with a major impact of the conceptus on metabolism and cell adhesion. We selected 15 genes including C11ORF34, CXCL12, CXCR4, PLAC8, SCARA5, and NPY and confirmed their differential expression by quantitative RT-PCR. The cellular localization was analyzed by in situ hybridization and, upon pregnancy, showed gene-specific patterns of cell distribution, including a high level of expression in the luminal epithelium for C11ORF34 and MX1. Using primary cultures of bovine endometrial cells, we identified PTN, PLAC8, and CXCL12 as interferon-tau (IFNT) target genes and MSX1 and CXCR7 as IFNT-regulated genes, whereas C11ORF34 was not an IFNT-regulated gene. Our transcriptomic data provide novel molecular insights accounting for the biological functions related to the C or IC endometrial areas and may contribute to the identification of potential biomarkers for normal and perturbed early pregnancy.

In-vitro analysis of Pitx3 in mesodiencephalic dopaminergic neuron maturation.

The transcription factor Pitx3 is expressed exclusively by mesodiencephalic dopaminergic neurons; however, ablation of Pitx3 results in selective degeneration of primarily dopaminergic neurons of the substantia nigra pars compacta, the neuronal population that is most vulnerable in Parkinson's disease. Although the exact molecular mechanisms of the action of Pitx3 are unclear, roles in both terminal maturation and/or survival of substantia nigra dopaminergic neurons have been suggested. To investigate the connection between Pitx3 and selective neurodegeneration, we generated embryonic stem cells from a Pitx3-deficient mouse (aphakia) for in-vitro differentiation to dopaminergic neurons. This 'loss of function'in-vitro system allowed us to examine characteristic features in dopaminergic neuron development and to assess the role that Pitx3 plays in the differentiation/maturation process. We found that aphakia embryonic stem cells generated 50% fewer tyrosine hydroxylase-positive/microtubule-associated protein (Map)2-positive mature neurons compared with control cultures. The expression of dopamine transport regulators and vesicle release proteins was reduced and dopamine release was unregulated in the Pitx3-deficient tyrosine hydroxylase-positive neurons generated. Treatment of aphakia embryonic stem cell cultures with retinoic acid resulted in a significant increase in mesodiencephalic tyrosine hydroxylase-positive neurons, providing further support for the role of Pitx3 in dopaminergic neuron specification through the retinoic acid pathway. Our study, using Pitx3-deficient embryonic stem cells in an in-vitro differentiation culture system, allowed us to assess the role of Pitx3 in the specification and final maturation of dopaminergic neurons.

Birth of parthenote mice directly from parthenogenetic embryonic stem cells.

Mammalian parthenogenetic embryos are not viable and die because of defects in placental development and genomic imprinting. Parthenogenetic ESCs (pESCs) derived from parthenogenetic embryos might advance regenerative medicine by avoiding immuno-rejection. However, previous reports suggest that pESCs may fail to differentiate and contribute to some organs in chimeras, including muscle and pancreas, and it remains unclear whether pESCs themselves can form all tissue types in the body. We found that derivation of pESCs is more efficient than of ESCs derived from fertilized embryos, in association with reduced mitogen-activated protein kinase signaling in parthenogenetic embryos and their inner cell mass outgrowth. Furthermore, in vitro culture modifies the expression of imprinted genes in pESCs, and these cells, being functionally indistinguishable from fertilized embryo-derived ESCs, can contribute to all organs in chimeras. Even more surprisingly, our study shows that live parthenote pups were produced from pESCs through tetraploid embryo complementation, which contributes to placenta development. This is the first demonstration that pESCs are capable of full-term development and can differentiate into all cell types and functional organs in the body.

Endometrium as an early sensor of in vitro embryo manipulation technologies.

Implantation is crucial for placental development that will subsequently impact fetal growth and pregnancy success with consequences on postnatal health. We postulated that the pattern of genes expressed by the endometrium when the embryo becomes attached to the mother uterus could account for the final outcome of a pregnancy. As a model, we used the bovine species where the embryo becomes progressively and permanently attached to the endometrium from day 20 of gestation onwards. At that stage, we compared the endometrial genes profiles in the presence of an in vivo fertilized embryo (AI) with the endometrial patterns obtained in the presence of nuclear transfer (SCNT) or in vitro fertilized embryos (IVF), both displaying lower and different potentials for term development. Our data provide evidence that the endometrium can be considered as a biological sensor able to fine-tune its physiology in response to the presence of embryos whose development will become altered much later after the implantation process. Compared with AI, numerous biological functions and several canonical pathways with a major impact on metabolism and immune function were found to be significantly altered in the endometrium of SCNT pregnancies at implantation, whereas the differences were less pronounced with IVF embryos. Determining the limits of the endometrial plasticity at the onset of implantation should bring new insights on the contribution of the maternal environment to the development of an embryo and the success of pregnancy.

Nuclear transfer embryonic stem cells provide an in vitro culture model for Parkinson's disease.

Somatic cell nuclear transfer enables the generation of embryonic stem cells (ESCs) that genetically match the donor and can be used to treat disease through cell replacement therapies or to recapitulate patient-specific disease via in vitro differentiation. We performed a "proof-of-principle" study using tail tip fibroblasts from a mouse model of Parkinson's disease (Aphakia) as the donor cell nuclei for nuclear transfer and derived "customized" ESCs for in vitro analysis. Aphakia mice contain deletions in the pitx3 gene and show selective loss of dopamine neurons of the substantia nigra, specifically the neuron population susceptible to degeneration in Parkinson's disease. Using electrofusion nuclear transfer, we produced cloned Aphakia oocytes at rates similar to those for control, cloned oocytes. Aphakia ESCs were isolated and live mice were generated using tetraploid embryo complementation. In vitro differentiation of Aphakia ESCs to dopaminergic neurons revealed significantly fewer TH+ neurons that expressed MAP2, DAT, synaptophysin, VMAT2, and AHD2 compared to control nuclear transfer ESC cultures, supporting a role for Pitx3 in mesodiencephalic dopamine neuron maturation. Taken together, our studies define a customized in vitro ESC culture system used to analyze gene-specific contribution to dopamine neuron generation, maturation, and susceptibility to degeneration.

Improvement of embryonic stem cell line derivation efficiency with novel medium, glucose concentration, and epigenetic modifications.

Although the first mouse embryonic stem (ES) cell lines were derived 2 decades ago, and standard protocols for ES cell derivation are widely used today, the technical difficulty of these protocols still pose a challenge for many investigators attempting to produce large numbers of ES cell lines, and are limited to only a few mouse strains. Recently, glucose concentration was shown to have a significant effect on the efficiency of ES cell derivation, but the mechanism(s) mediating this effect are still the subject of debate. In this report, we investigated the effect of glucose concentration on ES cell derivation efficiency from blastocysts in the context of a new medium, Minimum Essential Medium alpha (MEMalpha). Furthermore, we propose novel methods to improve mouse ES cell derivation efficiency using in vitro epigenetic modifications during early passages, combined with detection of Oct4-expressing cells. Based on the results reported here, modified MEMalpha containing high glucose improves the efficiency of ES cell derivation remarkably, compared with Knockout Dulbecco's-Modified Eagle Media (KDMEM). Epigenetic modifications are able to improve the efficiency even further.

Embryonic gene expression profiling using microarray analysis.

Microarray technology enables the interrogation of thousands of genes at one time and therefore a systems level of analysis. Recent advances in the amplification of RNA, genome sequencing and annotation, and the lower cost of developing microarrays or purchasing them commercially, have facilitated the analysis of single preimplantation embryos. The present review discusses the components of embryonic expression profiling and examines current research that has used microarrays to study the effects of in vitro production and nuclear transfer.

Nuclear transfer and oocyte cryopreservation.

Somatic cells can be reprogrammed to a totipotent state through nuclear transfer or cloning, because it has been demonstrated that the oocyte has the ability to reprogramme an adult nucleus into an embryonic state that can initiate the development of a new organism. Therapeutic cloning, whereby nuclear transfer is used to derive patient-specific embryonic stem cells, embraces an entire new opportunity for regenerative medicine. However, a key obstacle for human therapeutic cloning is that the source of fresh human oocytes is extremely limited. In the present review, we propose prospective sources of human oocytes by using oocyte cryopreservation, such as an oocyte bank and immature oocytes. We also address some potential issues associated with nuclear transfer when using cryopreserved oocytes. In the future, if the efficacy and efficiency of cryopreserved oocytes are comparable to those of fresh oocytes in human therapeutic cloning, the use of cryopreserved oocytes would be invaluable and generate a great impact to regenerative medicine.

Beneficial effect of young oocytes for rabbit somatic cell nuclear transfer.

This study was designed to examine the effect of the age of rabbit oocytes on the developmental potential of cloned embryos. The metaphase II oocytes used for nuclear transfer (NT) were collected at 10, 12, 14, and 16 h post-hCG injection (hpi). The total number of oocytes collected per donor (21.4-23.7) at 12 to 16 hpi was similar, but significantly higher than that collected at 10 hpi (16.2). Additionally, a significant improvement in blastocyst development was achieved with embryos generated by electrically mediated cell fusion (56.0%), compared to those from nuclear injection (13.1 %) (Experiment 1). Markedly higher blastocyst development (45.8-54.5%) was also achieved with oocytes collected at 10-12 hpi than from those collected 14-16 hpi (8.3-14.3%) (Experiment 2). In Experiment 3, the blastocyst rates of NT embryos derived from oocytes harvested 12 hpi (39.2-42.8 %) were significantly higher than from those collected at 16 hpi (6.8-8.4 %) (p < 0.05), regardless of the donor cell age. Kinase activity assays showed variable changes of activity in rabbit oocytes over the period of 10-16 hpi; however, there was no correlation with preimplantational development (blastocyst rate vs. MPF, R = 0.326; blastocyst rate vs. MAPK, R = -0.131). Embryo transfer of NT embryos utilizing 12 hpi oocytes resulted in one full-term but stillborn, and one live cloned rabbit; thus, an efficiency of 1.7 % (n = 117) (Experiment 4). These results demonstrated that NT utilizing relatively young rabbit oocytes, harvested at 10-12 h after hCG injection, was beneficial for the development of NT embryos.