Genomic reprogramming factors in the GV cytoplasm improved cloning efficiency in mice through the pre‐exposure of somatic cell nuclei to a GV cytoplasmic extract prior to nuclear transfer. To overcome difficulties in preparing mice oocyte extract, a pig GV oocyte extract (pGV extract) was developed to investigate the epigenetic reprogramming events in treated somatic cell nuclei. The pGV extract promoted colony formation concomitant with the expression of stem cell markers and repression of differentiated cell markers in treated cells. Using fibroblasts transfected with human Oct‐4 promoter‐ driven enhanced green fluorescent protein (Oct4‐EGFP), pGV extract treatment induced the reactivation of the Oct‐4 promoter in Oct4‐EGFP cells by 10 days post‐treatment. Interestingly, reconstructed embryos with pGV extract‐treated Oct4‐EGFP fibroblast nuclei showed prolonged expression of Oct4 in the ICM of embryos. Using donor nuclei treated with pGV extract, increase the number of high‐quality blastocysts that expressed Me‐H3‐K9, Oct4 and Nanog at levels comparable to in vitro fertilized embryos. The pGV extracttreated fibroblast cells can differentiated into neuronal, pancreas, cardiac, and endothelial lineages that were confirmed by antibodies against specific marker proteins. These data provide evidence for the generation of stem‐like cells from differentiated somatic cells by treatment with GV oocyte extracts in pig. Next, we identified germ line stem cells that supported oogenesis. female germ line stem cells (FGSC) from neonatal pig was established and cultured for more than 6 months. After long‐term culture and many passages, ovarian germ line stem cells maintained their characteristics and telomerase activity, expressed germ cell and stem cell markers and revealed normal karyotype. To further study developmental potential of oocyte‐like cells generated from FGSCs, these cells were aggregated with granulosa cells collected from neonatal pig ovaries. Interestingly after overnight culture in hanging drops, oocyte‐like cells aggregated with granulosa cells and formed structures very similar to primordial follicles containing the oocyte‐like cell in the middle and a layer of granulosa cells around it. Our results demonstrate the presence of a population of germ line stem cells in postnatal pig ovary with the ability to self‐renew and differentiate to oocyte‐like cells that might be useful for follicle engineering and assisted reproductive technologies. However, the functionality of FGSC‐derived oocytes us-ing in vitro maturation, fertilization and embryo development as well as ovarian transplantation is currently under investigation. In conclusion, gene manipulation of FGSCs or iPS cells is a rapid and efficient method of animal transgenesis and may serve as a powerful tool for biomedical science and biotechnology.

Gene targeting is a genetic technique that utilizes homologous recombination between an engineered exogenous DNA fragments with the endogenous genome of an organism. In domestic animal, gene targeting has provided an important tool for producing Knock-out pig for GGTA1 gene to use xenotransplantation. The frequency of homologous recombination is a critical parameter for the success of gene targeting. The efficiency of homologous recombination in somatic cells is lower than that in mouse ES cells. So the application of gene targeting in somatic cells has been limited by its low efficiency. Recently, knock-out rat and mouse was generated by introducing nonhomologous end joining (NHE)-mediated deletion or insertion at the target site using zinc-finger nucleases (ZFN). Therefore, the development of effective knock-out and knock-in techniques in domestic animal is very important in biomedical research. In this present study, we investigated whether homologous recombination events occurs at cytidine monophospho-N-acetylneuraminic acid hydroxylase (CMAH) gene locus using ZFN in porcine primary fibroblast. CMAH-targeted ZFN DNA and mRNA were purchased from SIGMA-Aldrich. CMAH neo targeting vector consists of the neomycin resistance gene as a positive selectable marker gene, 789 bp 5’ arm and 763 bp 3’ arm from Exon 8 of CMAH gene. For transfection, the targeting vector and ZFN DNA or mRNA were introduced into ear fibroblasts cells of Chicago miniature pig by electroporation. After selection of G-418, PCR analysis was performed using 213 colonies transfected with ZFN DNA or mRNA. As a result, 39 positive colonies were identified in colonies transfected with ZFN DNA or mRNA. To our knowledge, this study provides the first evidence that the efficiency of gene targeting using ZFN was higher than that of conventional gene targeting in the porcine fibroblast. These cell lines may be used in the production of CMAH knock-out for xenotransplantation.

This study was conducted to investigate the effects of donor cell treatments on the production of transgenic cloned piglets. Ear fibroblast cell obtained from NIH MHC Inbred minipig was used as control. The GalT knock-out/CD46 knock-in (GalT/CD46) transgenic cell lines were established and used as donor cells. The reconstructed GalT/CD46 embryos were surgically transferred into oviduct of naturally cycling surrogate sows (Landrace × Yorkshire) on the second day of standing estrus. Unlike control (1.2 kV/cm,, 75.4%), the fusion rate of the GalT/CD46 donor cells was significantly higher in 1.5 kV/cm, (84.5%) than that of 1.25 kV/cm, (20.2%) (p<0.01). When the number of the transferred embryos were more than 129, the pregnancy and delivery rates were increased to 13/20 (65%) and 5/20 (25%) compared to less than 100 group [1/6 (16.7%) and 0/6 (0%)], respectively. To analyze the effect of donor cell culture condition on pregnancy and delivery rates, the GalT/CD46 donor cells were cultured with DMEM or serum reduced medium. In serum reduced medium group, the pregnancy and delivery rates were improved to 8/12 (66.7%) and 5/12 (41.7%) compared to DMEM group [3/7 (42.9%) and 0/7 (0%)], respectively. In conclusion, it can be postulated that an appropriate fusion condition and culture system is essential factors to increase the efficiency of the production of transgenic cloned piglets.

Insulin-like growth factor II (IGF2) and H19 genes are mutually imprinted genes which may be responsible for abnormalities in the cloned fetuses and offspring. This study was performed to identify putative differentially methylated regions (DMRs) of porcine H19 locus and to explore its genomic imprinting in in vitro fertilized (IVF) and somatic cell nuclear transferred (SCNT) embryos. Based on mice genomic data, we identified DMRs on H19 and found porcine H19 DMRs that included three CTCF binding sites. Methylation patterns in IVF and SCNT embryos at the 2-, 4-, 8～16-cells and blastocyst stages were analyzed by BS (Bisulfite Sequencing)-PCR. The CpGs in CTCF1 was significantly unmethylated in the 2-cell stage IVF embryos. However, the 4- (29.1%) and 8～16-cell (68.2%) and blastocyst (48.2%) stages showed higher methylation levels (p<0.01). On the other hand, SCNT embryos were unmethylayted (0～2%) at all stages of development. The CpGs in CTCF2 showed almost unmethylation levels at the 2-, 4- and 8～16-cell and blastocyst stages of development in both IVF (0～14.1%) and SCNT (0～6.4%) embryos. At all stages of development, CTCF3 was unmethylated in IVF (0～17.3%) and SCNT (0～1.2%) embryos except at the blastocyst stage (54.5%) of IVF embryos. In conclusion, porcine SCNT embryos showed an aberrant methylation pattern comprised to IVF embryos. Therefore, we suggest that the aberrant methylation pattern of H19 loci may be a reason for increased abnormal fetus after embryo transfer of porcine SCNT embryos.