Hyo Young Park

Efficient generation of virus-free iPS cells using liposomal magnetofection.

The generation of induced pluripotent stem (iPS) cells is a powerful tool in regenerative medicine, and advances in nanotechnology clearly have great potential to enhance stem cell research. Here, we introduce a liposomal magnetofection (LMF) method for iPS cell generation. Efficient conditions for generating virus-free iPS cells from mouse embryonic fibroblast (MEF) cells were determined through the use of different concentrations of CombiMag nanoparticle-DNA(pCX-OKS-2A and pCX-cMyc)-lipoplexes and either one or two cycles of the LMF procedure. The cells were prepared in a short reprogramming time period (≤8 days, 0.032–0.040%). Among the seven LMF-iPS cell lines examined, two were confirmed to be integration-free, and an integration-free LMF-iPS cell line was produced under the least toxic conditions (single LMF cycle with a half-dose of plasmid). This cell line also displayed in vitro/in vivo pluripotency, including teratoma formation and chimeric mouse production. In addition, the safety of CombiMag-DNA lipoplexes for the transfection of MEF cells was confirmed through lactate dehydrogenase activity assay and transmission electron microscopy. These results demonstrated that the LMF method is simple, effective, and safe. LMF may represent a superior technique for the generation of virus-free or integration-free iPS cell lines that could lead to enhanced stem cell therapy in the future.

Generation of functional cardiomyocytes from mouse induced pluripotent stem cells

BACKGROUND Induced pluripotent stem (iPS) cells allow derivation of autologous differentiated cells for cell therapy. The purpose of this study was to compare the cardiac differentiation potential of mouse iPS cells with embryonic stem (ES) cells and demonstrate that they could produce functional cardiomyocytes. METHODS iPS cells were prepared from mouse embryonic fibroblasts by lentiviral mediated expression of four transcription factors (Oct4/Sox2/Klf4/C-myc). To induce cardiac cell differentiation, iPS-S-6 or D3-ES cells were induced to form embryoid bodies (EBs) using a two-medium culture protocol, then plated onto gelatin-coated plates and maintained in DMEM. RESULTS Following classification of the generation periods of contracting EBs into early (d8-d11), middle (d12-d15) and late (d16-20), iPS cells in the early period exhibited characteristics similar to ES cells. In iPS cells from the middle period group, the ratio of contracting EBs was significantly increased compared to ES cells, and the difference persisted in cells from the late period group (p<0.05). The percentage of contracting EBs formed from iPS and ES cells were 44.8% and 33.3%, respectively. In addition, iPS cell-derived cardiomyocytes exhibited mRNA expression of cardiac mesoderm markers such as GATA4 and NKX2.5, and cardiomyocyte markers such as α1s, α1c, α-MHC, β-MHC, Cx40, TnI, TnT, ANF and Hey2. Single cardiomyocytes exhibited typical cross-striated myofibrillar organization, and electrophysiological studies revealed functional cardiac-specific voltage-gated Na(+), Ca(2+) and K(+) channels. CONCLUSIONS These results demonstrate that functional cardiomyocytes can be generated from iPS cells, and suggest that these cells may be useful for the treatment of cardiovascular disease.

Differences between Cellular and Molecular Profiles of Induced Pluripotent Stem Cells Generated from Mouse Embryonic Fibroblasts

Induced pluripotent stem (iPS) cells are a new alternative for the development of patient-specific stem cells, and the aim of this study was to determine whether differences exist between the cellular and molecular profiles of iPS cells, generated using lentiviral vectors, compared to ES cells. The lentiviral infection efficiency differed according to the method of cell culture (adherent cells: 0.085%; suspended cells: 0.785%). Six iPS cell lines exhibited typical ES cell morphology and marker expression, but varied in their in vitro/in vivo differentiation ability. Global gene transcription analysis revealed that core pluripotency genes were expressed at lower levels in iPS cell lines compared to D3-ES cells (Pou5f1: x1.6~2.2-fold, Sox2: x2.58~10.0-fold, Eras: x1.08~2.54-fold, Dppa5a: x1.04~1.41-fold), while other genes showed higher expression in iPS cells (Lin28: x1.43~2.33-fold; Dnmt3b: x1.33~2.64-fold). This pattern was repeated in a survey of specific functional groups of genes (surface markers, cell death, JAK-STAT and P13K-AKT signaling pathways, endothelial, cardiovascular, and neurogenesis genes). Among the iPS cell lines examined, only two showed similar characteristics to ES cells. These results demonstrated that, in addition to cellular characterization, the numerical evaluation of gene expression using DNA microarrays might help to identify the stem cell stability and pluripotency of iPS cells.

Effect of Glycosaminoglycans on In vitro Fertilizing Ability and In vitro Developmental Potential of Bovine Embryos

The glycosaminoglycans (GAGs) present in the female reproductive tract promote sperm capacitation. When bovine sperm were exposed to 10 μg/ml of one of four GAGs (Chondroitin sulfate, CS; Dermatan sulfate, DS; Hyaluronic acid, HA; Heparin, HP) for 5 h, the total motility (TM), straight-line velocity (VSL), and curvilinear velocity (VCL) were higher in the HP- or HA-treated sperm, relative to control and CS- or DS-treated sperm. HP and HA treatments increased the levels of capacitated and acrosome-reacted sperm over time, compared to other treatment groups (p<0.05). In addition, sperm exposed to HP or HA for 1 h before IVF exhibited significantly improved fertilizing ability, as assessed by 2 pronucleus (PN) formation and cleavage rates at d 2. Exposure to these GAGs also enhanced in vitro embryo development rates and embryo quality, and increased the ICM and total blastocyst cell numbers at d 8 after IVF (p<0.05). A real-time PCR analysis showed that the expression levels of pluripotency (Oct 4), cell growth (Glut 5), and anti-apoptosis (Bax inhibitor) genes were significantly higher in embryos derived from HA- or HP-treated sperm than in control or other treatment groups, while pro-apoptotic gene expression (caspase-3) was significantly lower in all GAG treatment groups (p<0.05). These results demonstrated that exposure of bovine sperm to HP or HA positively correlates with in vitro fertilizing ability, in vitro embryo developmental potential, and embryonic gene expression.

Establishment of Bovine Embryonic Stem Cell Lines Using a Minimized Feeder Cell Drop

Bovine embryonic stem cells (ESCs) are a powerful tool for agricultural and biomedical applications. The purpose of this study was to introduce a new method for generating bovine ESCs. Mechanically isolated bovine inner cell masses (ICMs) from in vitro-produced blastocysts were cultured individually on a 10-μL mouse embryonic fibroblast (MEF) feeder cell drop covered with oil. From 126 blastocysts classified by their developmental stage and ICM size, 21 primary bovine ESC-like colonies were formed (16.7%) and established six JNU (Jeju National University)-ibES cell lines (28.6%, 6/21; hatched blastocyst×4, hatching blastocyst×1, and expanded blastocyst×1). These cells exhibited typical ESC morphology, and pluripotency markers were detected through immunocytochemistry, RT-PCR, and real-time RT-PCR, including Oct4, stage-specific embryonic antigen-1 (SSEA-1), Nanog, Tumor rejection antigen-1-81, Rex1, and alkaline phosphatase. Through RT-PCR analysis of spontaneous differentiation, gene expression of all three embryonic germ layers was detected: ectodermal (Pax6 and DBH), mesodermal (CMP and Enolase), and endodermal [alpha fetoprotein (α-FP) and albumin]. In addition, JNU-ibES cell lines were directed differentiated into neuronal (Map2 and Tuj1) and glial (GFAP) cells. Bovine ESC lines had a normal karyotype, with a chromosome count of 58+XY (JNU-ibES-05). This is the first trial investigating a minimized microdrop culture method for the generation of bovine ESCs. These results demonstrated that the minimized MEF feeder cell drop can support the establishment of bovine ESC lines.

Improved cloning efficiency and developmental potential in bovine somatic cell nuclear transfer with the oosight imaging system.

In somatic cell nuclear transfer (SCNT) procedures, exquisite enucleation of the recipient oocyte is critical to cloning efficiency. The purpose of this study was to compare the effects of two enucleation systems, Hoechst staining and UV irradiation (hereafter, irradiation group) and Oosight imaging (hereafter, Oosight group), on the in vitro production of bovine SCNT embryos. In the Oosight group, the apoptotic index (2.8 ± 0.5 vs. 7.3 ± 1.2) was lower, and the fusion rate (75.6% vs. 62.9%), cleavage rate (78.0% vs. 63.7%), blastocyst rate (40.2% vs. 29.2%), and total cell number (128.3±4.8 vs. 112.2 ± 7.6) were higher than those in the irradiation group (all p<0.05). The overall efficiency after SCNT was twice as high in the Oosight group as that in the irradiation group (p<0.05). The relative mRNA expression levels of Oct4, Nanog, Interferon-tau, and Dnmt3A were higher and those of Caspase-3 and Hsp70 were lower in the Oosight group compared with the irradiation group (p<0.05). This is the first report to show the positive effect of the Oosight imaging system on molecular gene expression in the SCNT embryo. The Oosight imaging system may become the preferred choice for enucleation because it is less detrimental to the developmental potential of bovine SCNT embryos.

Post-Death Cloning of Endangered Jeju Black Cattle (Korean Native Cattle): Fertility and Serum Chemistry in a Cloned Bull and Cow and Their Offspring

Abstract To preserve Jeju black cattle (JBC; endangered native Korean cattle), a pair of cattle, namely a post-death cloned JBC bull and cow, were produced by somatic cell nuclear transfer (SCNT) in a previous study. In the present study, we examined the in vitro fertilization and reproductive potentials of these post-death cloned animals. Sperm motility, in vitro fertilization and developmental capacity were examined in a post-death cloned bull (Heuk Oll Dolee) and an extinct nuclear donor bull (BK94-13). We assessed reproductive ability in another post-death cloned cow (Heuk Woo Sunee) using cloned sperm for artificial insemination (AI). There were no differences in sperm motility or developmental potential of in vitro fertilized embryos between the post-death cloned bull and its extinct nuclear donor bull; however, the embryo development ratio was slightly higher in the cloned sperm group than in the nuclear donor sperm group. After one attempt at AI, the post-death cloned JBC cow became pregnant, and gestation proceeded normally until day 287. From this post-death cloned sire and dam, a JBC male calf (Heuk Woo Dolee) was delivered naturally (weight, 25 kg). The genetic paternity/maternity of the cloned JBC bull and cow with regard to their offspring was confirmed using International Society for Animal Genetics standard microsatellite markers. Presently, Heuk Woo Dolee is 5 months of age and growing normally. In addition, there were no significant differences in blood chemistry among the post-death cloned JBC bull, the cow, their offspring and cattle bred by AI. This is the first report showing that a pair of cattle, namely, a post-death cloned JBC bull and cow, had normal fertility. Therefore, SCNT can be used effectively to increase the population of endangered JBC.