Adult stem cell transplantation has been increased every year, because of the lack of organ donors for regenerative medicine. Therefore, development of reliable and safety cryopreservation and bio-baking method for stem cell therapy is urgently needed. The present study investigated safety of dimethyl sulfoxide (DMSO) such as common cryoprotectant on porcine bone marrow derived mesenchymal stem cells (pBM-MSCs) by evaluating the activation of Caspase-3 and -7, apoptosis related important signal pathway. pBM-MSCs used for the present study were isolated density gradient method by Ficoll-Paque Plus and cultured in A-DMEM supplemented 10% FBS at in 5% incubator. pBM-MSCs were cryopreserved in A-DMEM supplemented either with 5%, 10% or 20% DMSO by cooling rate at /min in a Kryo 360 (planner 300, Middlesex, UK) and kept into . Survival rate of cells after thawing did not differ between 5% and 10% DMSO but was lowest in 20% DMSO by 0.4% trypan blue exclusion. Activation of Caspase-3 and -7 by Vybrant FAM Caspase-3 and -7 Assay Assay Kit (Molecular probes, Inc.OR, USA) was analyzed with a flow cytometer. Both of cryopreserved and control groups (fresh pBM-MSCs) were observed after the activation of Caspase-3 and -7. The activation did not differ between 5% and 10% DMSO, but was observed highest in 20% DMSO. Therefore 5% DMSO can be possibly used for cell cryopreservation instead of 10% DMSO.

The synovial tissues are a valuable MSCs source for cartilage tissue engineering because these cells are easily obtainable by the intra-articular biopsy during diagnosis. In this study, we isolated and characterized the canine MSCs derived from synovial fluid of female and male donors. Synovial fluid was flushed with saline solution from pre and post-puberty male (cM1-sMSC and cM2-sMSC) and female (cF1-sMSC and cF2-sMSC) dogs, and cells were isolated and cultured in advanced-DMEM (A-DMEM) supplemented with 10% FBS in a humidified 5% atmosphere at . The cells were evaluated for the expression of the early transcriptional factors, such as Oct3/4, Nanog and Sox2 by RT-PCR. The cells were induced under conditions conductive for adipogenic, osteogenic, and chondrogenic lineages, then evaluated by specific staining (Oil red O, von Kossa, and Alcian Blue staining, respectively) and analyzed for lineage specific markers by RT-PCR. All cell types were positive for alkaline phosphatase (AP) activity and early transcriptional factors (Oct3/4 and Sox2) were also positively detected. However, Nanog were not positively detected in all cells. Further, these MSCs were observed to differentiate into mesenchymal lineages, such as adipocytes (Oil red O staining), osteocytes (von Kossa staining), and chondrocytes (Alcian Blue staining) by cell specific staining. Lineage-specific genes (osteocyte; osteonectin and Runx2, adipocytes; PRAR-, FABP and LEP, and chondrocytes; collagen type-2 and Sox9) were also detected in all cells. In this study, we successfully established synovial fluid derived mesenchymal stem cells from female and male dogs, and determined their basic biological properties and differentiation ability. These results suggested that synovial fluid is a valuable stem cell source for cartilage regeneration therapy, and it is easily accessible from osteoarthritic knee.

Various small molecules can be used to control major signaling pathways to enhance stemness and inhibit differentiation in murine embryonic stem cell (mESC) culture. Small molecules inhibiting the fibroblast growth factor (FGF)/ERK pathway can preserve pluripotent cells from stimulation of differentiation. In this study, we aimed to evaluate the effect of pluripotin (SC-1), an inhibitor of the FGF/ERK pathway, on the colony formation of outgrowing presumptive mESCs. After plating the zona pellucida-free blastocyst on the feeder layer, attached cell clumps was cultured with SC-1 until the endpoint of the experiment at passage 10. In this experiment, when the number of colonies was counted at passage 3, SC-1-treated group showed 3.4 fold more mESC colonies when compared with control group. However, after passage 4, there was no stimulating effect of SC-1 on the colony formation. In conclusion, SC-1 treatment can be used to promote mESC generation by increasing the number of early mESC colonies.

Porcine has been known to have a great impact on the studies of organ transplantation, biomaterial production and specific biomodel development such as transgenic animals. To achieve such therapeutic purposes, establishment of porcine embryonic stem cells (pESCs) will be needed. Especially, in vitro differentiation toward neural cells from pESCs can be a useful tool for the study of early neural development and neurodegenerative disorders. In addition, these cells can also be used in cell replacement therapies and drug development for neuroprotective and/or neurotoxic reagents. Although several studies reported the successful isolation of pES-like cells, it has been a big challenge to determine optimal conditions to generate pESCs without loss of pluripotency for a long time. The present study was performed for generation and characterization of putative pESCs, and differentiation into neurons and astrocytes. In this study, porcine blastocysts were produced by parthenogenetically activated oocytes. The putative pESCs were cultured in pESC growth media supplemented with a growth factor and cytokines (bFGF, LIF and SCF). Subculture of pESCs was conducted by mechanical dissociation using syringe needles after 4-5 days of incubation. As results, six putative pESC lines were maintained over thirty passages. The putative pESCs were compact, round, flat, and single layered, which were similar to human embryonic stem cell morphologically. Six pES-like cells were positive for alkaline phosphatase activity at every three passages. Furthermore, Oct-3/4, Sox-2, Nanog and SSEA-4 were shown to be expressed in those cells. Also, normal karyotypes of pESCs were observed by Giemsa-staining. Differentiation potential into the three germ layers of the putative pESCs was demonstrated by the formation of embryoid bodies (EB). Besides, the study of ESC is very important in aspect of its application to not only the cell-based replacement therapies but also cellular differentiation research. Our results also showed that RA and N2 supplements activated the neural differentiation in pESC5. Neurofilament-l60 were expressed in neural precursor cells. The expression of markers for specific neural lineages, such as Microtubule-associated protein-2 expressed in matured neuron, was also induced from embryonic neural progenitors. In summary, the pESCs were generated from the parthenogenetically activated blastocysts and the typical characteristics of the cells were maintained for the long term culture. Furthermore, it was successful to differentiate the pESCs into various neural lineages through in vitro neurogenesis system. Eventually, pESCs will be excellent biomedicine in incurable and/or zoonotic diseases by regenerating the damaged tissue.

The use of high throughput screening (HTS) in drug development is principally for the selection new drug candidates or screening of chemical toxicants. This system minimizes the experimental environment and allows for the screening of candidates at the same time. Umbilical cord-derived stem cells have some of the characteristics of fetal stem cell and have several advantages such as the ease with which they can be obtained and lack of ethical issues. To establish a HTS system, optimized conditions that mimic typical cell culture conditions in a minimal space such as 96 well plates are needed for stem cell growth. We have thus established a novel HTS system using human umbilical cord derived-mesenchymal stem cells (hUC-MSCs). To determine the optimal cell number, hUC-MSCs were serially diluted and seeded at 750, 500, 200 and 100 cells per well on 96 well plates. The maintenance efficiencies of these dilutions were compared for 3, 7, 9, and 14 days. The fetal bovine serum (FBS) concentration (20, 10, 5 and 1%) and the cell numbers (750, 500 and 200 cells/well) were compared for 3, 5 and 7 days. In addition, we evaluated the optimal conditions for cell cycle block. These four independent optimization experiments were conducted using an MTT assay. In the results, the optimal conditions for a HTS system using hUC-MSCs were determined to be 300 cell/well cultured for 8 days with 1 or 5% FBS. In addition, we demonstrated that the optimal conditions for a cell cycle block in this culture system are 48 hours in the absence of FBS. In addition, we candidates using our HTS system which demonstrates the feasibility if using hUC-MSCs for this type of screen. Moreover, the four candidate compounds can be tested for stem cell research application.

Pluripotent stem cells can be derived from both pre- and post-implantation embryos. Embryonic stem cells (ES cells), derived from inner cell mass (ICM) of blastocyst are naïve pluripotent and epiblast stem cells (EpiSCs) derived from post-implantation epiblast are primed pluripotent. The phenotypes and gene expression patterns of the two pluripotent stem cells are different each other and EpiSCs thought to be in a more advanced pluripotent (primed pluripotent state) than mouse ES cells (naïve pluripotent state). Therefore, we questioned whether EpiSCs are less potential to be differentiated into specialized cell types in vitro. EpiSCs were isolated from 5.5～6.5 day post coitum mouse embryos of the post-implantation epiblast. The EpiSCs could differentiate into all tree germ layers in vivo, and expressed pluripotency markers (Oct4, Nanog). Interestingly, EpiSCs also were able to efficiently differentiate into neural stem cells (NSCs). The NSCs differentiated from EpiSCs (EpiSC-NSCs) expressed NSC markers (Nestin, Sox2, and Musasi), self-renewed over passage 20, and could differentiate into two neural subtypes, neurons, astrocytes and oligodendrocytes. Next, we compared global gene expression patterns of EpiSC-NSCs with that of NSCs differentiated from ES cells and brain tissue. Gene expression pattern of brain tissue derived NSCs were closer to ES cell-derived NSCs than EpiSC-NSCs, indicating that the pluripotent stem cell-derived somatic cells could have different characteristics depending on the origin of pluripotent stem cell types. * This work was supported by the Next Generation Bio-Green 21 Program funded by the Rural Development Administration (Grant PJ 008009).

Porcine blastocyst’s quality derived from in vitro is inferior to in vivo derived blastocysts. In this study, to improve in vitro derived blastocyst’s quality and then establish porcine ESCs (pESCs), we treated in vitro fertilized (IVF) embryos and parthenogenetic activated (PA) embryos with three chemicals: porcine granulocyte-macrophage colony stimulating factor (pGM-CSF), resveratrol (RES) and β-mercaptoethanol (β-ME). The control group was produced using M199 media in in vitro maturation (IVM) and porcine zygote medium-3 (PZM3) in in vitro culture (IVC). The treatment group is produced using M199 with 2 μM RES in IVM and PZM5 with 10 ng/mL pGM-CSF, 2 μM RES and 10 μM β-ME in IVC. Data were analyzed with SPSS 17.0 using Duncan’s multiple range test. In total, 1210 embryos in PA and 612 embryos in IVF evaluated. As results, we observed overall blastocyst quality was increased. The blastocyst formation rates were significantly higher (p<0.05) in the treatment groups (54.5%) compared to the control group (43.4%) in PA and hatched blastocysts rates in day 6 and 7 were also increased significantly. Total cell numbers of blastocyst were significantly higher (p<0.05) in the treatment group (55.1) compared to the control group (45.6). In IVF, hatched blastocysts rates in day 7 were increased significantly, too. After seeding porcine blastocyst, the attachment rates were higher in the treatment group (36.2% in IVF and 32.2% in PA) than the control group (26.6% in IVF and 19.5% in PA). Also, colonization rates and cell line derivation rates were higher in treatment group than control group. Colonization rates of control group were 10.8% in IVF and 2.4% in PA, but treatment group were 17.75% in IVF, and 13.1% in PA. And we investigated the correlation between state of blastocysts and attachment rate. The highest attachment rate is in hatched blastocyst (78.35±15.74 %). So, the novel system increased quality of porcine blastocysts produced from in vitro, subsequently increased attachment rates. The cell line derivation rates were 4.2% (IVF) and 2.4% (PA) in control group. In treatment group, they were 10.0% (IVF) and 7.2% (PA). We established 3 cell lines from PA blastocysts (1 cell line in control group and 2 cell lines in treatment group). All cell line has alkaline phosphatase activity and express pluri-potent markers. In conclusion, the novel system of IVM and IVC (the treatment of RES during IVM and RES, β-ME, and pGM-CSF during IVC) increased quality of porcine blastocysts produced from in vitro, subsequently increased derivation rates of porcine putative ESCs.

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. In this study, a pig GV oocyte extract (pGV extract) was developed. Treatment of pig fibroblasts with the pGV extract promoted colony formation after 2–3 weeks in culture, concomitant with the expression of stem cell markers (Oct‐4, Rex1, Nanog, Sox2) and repression of differentiated cell markers (CKAP2, NPR3 ). 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. These transgenic donor cells were injected into 8‐cell embryos. Oct‐4 promoter activity was subsequently detected in most ICM cells of the host blastocyst. Interestingly, reconstructed embryos with pGV extract‐treated Oct4‐ EGFP fibroblast nuclei showed prolonged expression of Oct4 in the ICM of embryos. Additionally, the pGV extract promoted somatic cell reprogramming and cloned embryo development when assessed by measuring histone H3‐K9 hypomethylation, the expression of Oct4 and Nanog in blastocysts, and the production of increased numbers of high‐ quality blastocysts. Under specific culture conditions, pGV extract‐treated fibroblast cells 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.

Since embryonic stem cells (ESCs) were first established from explant cultures of in vivo day 3.5 mouse embryos, the establishment of ESCs from species such as primates and rat has been developed. However, this success relies on the development of culture medium suitable for human and rat cells, which has different requirements from the murine ESC. In general, the establishment of ESC from pig and cow is of great interest both the agricultural perspective and for biomedical application. Large animal models, particularly pig, are likely to provide models of human genetic diseases and transplantation research where rodent models are inappropriate. However, establishment of ESCs establishment from pigs has remained an elusive goal. In the present study, we focused on signaling transduction regulation in pig epiblast stem cells (pEpiSCs). Pig epiblasts were isolated from early tubular stage embryos collected in vivo day 10.5～12 after insemination. Epiblasts were separated from trophoblast and underlying primitive endoderm using 21G needles and fine forceps. Epiblasts were cultured on mitomycin C (10 μl/ml) treated mouse embryonic feeder cells in Dulbecco’s modified Eagle’s medium (DMEM) containing 1% minimal essential medium (MEM) nonessential amino acids, 1% penicillin/ streptomycin, 1% glutamine, 0.007% β-mercaptoethanol, 5 ng/ml bFGF and 1 ng/ml LIF. After plating rapid differentiation of isolated epiblasts to extraembryonic cell types was visualized in most cultures but stem cells were enclosed by these differentiated cells. We have established seven pig epiblast stem cells lines (pEpiSC1-7) from Days 10.5–12 pig embryos. pEpiSC expressed the pluripotent markers including OCT4, NANOG, SOX2 and NODAL at 3-5 passage. In addition, the modification of culture condition by the inclusion of particular protein kinase inhibitor such as Akt inhibitor, PD0325091(PD), delyed rapid differentiation of pEpiSCs. These results showed that stemness of pEpiSCs can be maintained by regulation of signaling pathway. * This work was partly supported by a grant from the NPR (2011-0013703) and the Next-Generation BioGreen 21 Program (No. PJ008209), Rural Development Administration, Republic of Korea.

Hematopoietic stem cells (HSCs) are the self‐renewing, multipotent progenitors that give rise to all types of mature blood cells. The hallmark properties of HSCs are the ability to balance self‐renewal versus differentiation cell fate decisions to provide sufficient primitive cells to sustain haematopoiesis, while generating more mature cells with specialized capacities. In the present experiment, we optimized the techniques for isolation and identification of hematopoietic stem cells from cow peripheral blood. The objective of this study was to optimize the more accurate methodology for separation of mononuclear cells (MNCs) from peripheral blood and identification of HSCs by using a specific cell surface marker i.e. CD34. A total 10 peripheral blood samples were collected from Holstein dairy cows from jugular vein. We used Ficoll 400 in different concentrations from 1 to 12% and Ficollpaque Plus (1.077 g/ml) at different centrifugation speed and time. After Giemsa staining, we found more than 98% recovery of monocytes with Ficollpaque Plus (1.077 g/ml). It was demonstrated that Ficollpaque Plus (1.077 g/ml) and centrifugation at 400xg for 30 min is the best method for separation of MNCs from bovine peripheral blood. Separated MNCs were immediately subjected for magnetic activated cell sorting (MACS) by using CD34 microbead kit. HSCs (CD34+ cells) recovery was 0.307% of peripheral blood. Peripheral blood MNCs and CD34+ cells were morphologically characterized by Giemsa staining. CD34+ cells were also confirmed by immunochemistry using FITC conjugated CD34 antibodies. HSCs were also confirmed by progenitor assay including burst forming unit‐erythroid (BFU‐E), colony forming cells‐ granulocyte (CFC‐G), colony forming cells‐ macrophage (CFC‐M), colony forming cells‐ granulocyte macrophage (CFU‐GM) and colony forming cells‐ granulocyte erythroid macrophage monocyte (CFCGEMM) on Methocult 4435.

Spermatogonial stem cells (SSC) undergo self-renewal division and generate spermatogenesis to produce mature spermatozoa. Very recently in some species, include rodent and farm animals, SSC has been isolated and cultured in vitro. In this study, we analysed SSC marker of both 5 days old and pubertal pig testis by histological method. In 5day pig testis, prior to set of spermatogenic differentiation, the seminiferous tubules contain a relatively large number of SSCs than in pubertal pig testis. Then putative pig SSCs were successfully isolated from 5 day pig testis, and cultured long term using CD34 positive cell culture media contained GDNF, bFGF, LIF and EGF. The SSC colonies were appeared at 3 days after cells were seed. The SSC colonies were alkaline phosphatase positive and strongly expressed PGP 9.5, PLZF and DBA, but not expressed GATA4 and LH receptors. The SSC colonies were stably proliferated in GDNF, bFGF, LIF and EGF contained CD34 positive cell culture media up to 60 days. This study will be facilitated to study of in vitro and ex vivo spermatogenesis and of production of transgenic pigs using sperm vector.

Pig embryonic stem cells (ESC) has been suggested to become important animal model for therapeutic cloning using embryonic stem cells derived by somatic cell nuclear transfer (SCNT). However, the quality of cloned embryo and derivation rate of cloned blastocyst has been presented limits for derivation of cloned embryonic stem cell. In this study, we have tried to overcome these problems by aggregating porcine embryos. Zonafree reconstructed SCNT Embryos were cultured in micro-wells singularly (non-aggregated group) or as aggregates of three (aggregated groups) at the four cell stage. Embryo quality of the cloned embryos and attachment on feeder layer rate significantly increased in the aggregates. The aggregation of pig SCNT embryos at the four-cell stage can be a useful technique for improving the quality of pig cloned blastocyst and improvement in the percentage of attachment on the feeder layer of cloned embryos. * This work was supported by the BioGreen 21 Program (PJ0081382011), Rural Development Administration, Republic of Korea.

Neural stem cells (NSCs) are self-renewing tripotent cell populations and have capacity of neuronal (neurons) and glial (astrocytes and oligodendrocytes) differentiation. Many researchers have reported that NSCs have therapeutic effects in neurological disease by transplantation. However, it is not easy to obtain NSCs in vitro. Recently, Yamanaka and colleagues showed that somatic cells could be reprogrammed into pluripotent state by enforcing reprogramming factors. Induced pluripotent stem (iPS) cells undergo unlimited self-renewal and have differentiation potential into various types of cells like embryonic stem cells. Direct differentiation into a specialized cell types from iPS cells hold considerable promise for regenerative medicine as well as basic research. Here, we induced differentiation of iPS cells into NSCs in vitro and in vivo, which were compared with embryonic stem (ES) cell-derived NSCs and brain derived NSCs. NSCs from ES and iPS cells were morphologically indistinguishable from brain derived NSCs and stained positive for NSCs markers Nestin and Sox2. ES cells derived NSCs were transcriptionally distinguishable from brain derived NSCs. However, global gene expression pattern were similar but distinct between iPS derived NSCs and brain derived NSCs. Moreover, iPS derived NSCs were spontaneously aggregated upon passaging, formed ES cell like colonies, and finally reactivated Oct4-GFP. The spontaneously reverted GFP-positive cells (iPS-NSC-iPS) expressed similar levels of pluripotency markers (Oct4,Nanog) to ES and iPS cells, and could form germ line chimera. One possible explanation for this phenomenon is that spontaneously re-reprogramming was associated with transgene re-activation when iPS cells were differentiated into NSCs. However, NSCs from dox-inducible iPScells could not be reprogrammed into pluripotent state without doxycycline. Taken together, iPS derived NSCs were morphologically and similar to brain derived NSCs, but differ in gene expression pattern and maintenance. * This work was supported by the Next Generation Bio-Green21 Program funded by the Rural Development Administration (Grant PJ008009).

The generation and application of porcine iPSCs (piPSCs) as a large animal model may enable the test for the efficacy and safety of the therapy in the field of human regenerative medicine. Here, we report the generation of piPSC from wild (a 10-day-old Massachusetts General Hospital miniature pig; MGH minipig) and genetically modified pig, alpha1,3-Galactosyltransferase knock-out (—/—) (GalT KO homo) and human CD46 (membrane cofactor protein) knock-in (hCD46 KI) MGH minipig (a 10-day-old). Fibroblasts were isolated from the ear skin of wild and MGH minipigs, respectively. After 2 passages, each of fibroblasts was transduced with cocktail of 6 human factors (POU5F1, NANOG, SOX2, C-MYC, KLF4, and LIN28) and cultured on a mitotically inactive mouse embryonic fibroblast (MEF) monolayer. Both of reprogrammed somatic cells expressed the classical pluripotency markers (POU5F1, NANOG, and SOX2) and surface marker (SSEA1). Similar to mouse ESCs, both piPSCs from wild and transgenic minipigs were negative for SSEA3, Tra-1-60, and Tra-1-81. Further these cells could form embryoid body (EB) and differentiate into 3 germ layers in vitro (ectoderm: FOXJ3 and PAX6, mesoderm: HAND2, and endoderm: SOX17 and GATA6). Our piPSCs may provide useful source as a large animal model for studying approaches that can reduce an immune- rejection of cell or organ transplantation.

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.

Dlx3 and Dlx5 are homeobox domain proteins and are well-known regulators of osteoblastic differentiation. Since possible reciprocal relationships between osteogenic and adipogenic differentiation in mesenchymal stem cells exist, we examined the regulatory role of Dlx3 and Dlx5 on adipogenic differentiation using human dental pulp stem cells. Over-expression of Dlx3 and Dlx5 stimulated osteogenic differentiation but inhibited adipogenic differentiation of human dental pulp stem cells. Dlx3 and Dlx5 suppressed the expression of adipogenic marker genes such as C/EBPα, PPARγ, aP2 and lipoprotein lipase. Adipogenic stimuli suppressed the mRNA levels of Dlx3 and Dlx5, whereas osteogenic stimuli enhanced the expression of Dlx3 and Dlx5 in 3T3-L1 preadipocytes. These results suggest that Dlx3 and Dlx5 exert a stimulatory effect on osteogenic differentiation of stem cells through the inhibition of adipogenic differ¬entiation as well as direct stimulation.

Differential capacity of the parthenogenetic embryonic stem cells (PESCs) is still under controversy and the mechanisms of its neural induction are yet poorly understood. Here we demonstrated neural lineage induction of PESCs by addition of insulin-like growth factor-2 (Igf2), which is an important factor for embryo organ development and a paternally expressed imprinting gene. Murine PESCs were aggregated to embryoid bodies (EBs) by suspension culture under the leukemia inhibitory factor-free condition for 4 days. To test the effect of exogenous Igf2, 30 ng/ml of Igf2 was supplemented to EBs induction medium. Then neural induction was carried out with serum-free medium containing insulin, transferrin, selenium, and fibronectin complex (ITSFn) for 12 days. Normal murine embryonic stem cells derived from fertilized embryos (ESCs) were used as the control group. Neural potential of differentiated PESCs and ESCs were analyzed by immunofluorescent labeling and real-time PCR assay (Nestin, neural progenitor marker; Tuj1, neuronal cell marker; GFAP, glial cell marker). The differentiated cells from both ESC and PESC showed heterogeneous population of Nestin, Tuj1, and GFAP positive cells. In terms of the level of gene expression, PESC showed 4 times higher level of GFAP expression than ESCs. After exposure to Igf2, the expression level of GFAP decreased both in derivatives of PESCs and ESCs. Interestingly, the expression level of Tuj1 increased only in ESCs, not in PESCs. The results show that IGF2 is a positive effector for suppressing over-expressed glial differentiation during neural induction of PESCs and for promoting neuronal differentiation of ESCs, while exogenous Igf2 could not accelerate the neuronal differentiation of PESCs. Although exogenous Igf2 promotes neuronal differentiation of normal ESCs, expression of endogenous Igf2 may be critical for initiating neuronal differentiation of pluripotent stem cells. The findings may contribute to understanding of the relationship between imprinting mechanism and neural differentiation and its application to neural tissue repair in the future.

Suspension culture is a useful tool for culturing embryonic stem (ES) cells in large-scale, but the stability of pluripotency and karyotype has to be maintained in vitro for clinical application. Therefore, we investigated whether the chromosomal abnormality of ES cells was induced in suspension culture or not. The ES cells were cultured in suspension as a form of aggregate with or without mouse embryonic fibroblasts (MEFs), and 0 or 1,000 U/ml leukemia inhibitory factor (LIF) was treated to suspended ES cells. After culturing ES cells in suspension, their karyotype, DNA content, and properties of pluripotency and differentiation were evaluated. As a result, the formation of tetraploid ES cell population was significantly increased in suspension culture in which ES cells were co-cultured with both MEFs and LIF. Tetraploid ES cell population was also generated when ES cells were cultured alone in suspension regardless of the existence of LIF. On the other hand, the formation of tetraploid ES cell population was not detected in LIF-free condition, in which MEFs were included. The origin of tetraploid ES cell population was turned out to be E14 ES cells and not MEFs by microsatellite analysis and the basic properties of them were still maintained despite ploidy-conversion to tetraploidy. Furthermore, we identified the ploidy shift from tetraploidy to near-triploidy as tetraploid ES cells were differentiated spontaneously. From these results, we demonstrated that suspension culture system could induce ploidy-conversion generating tetraploid ES cell population. Moreover, optimization of suspension culture system may make possible mass-production of ES cells.

In order to provide the basis for developing practical mouse embryonic stem cells (mESCs) culture method, how the endogenous level of self-renewal-stimulating factor genes was altered in the mESCs by different extracellular signaling was investigated in this study. For different extracellular signaling, mESCs were cultured in 2 dimension (D), 3D and integrin-stimulating 3D culture system in the presence or absence of leukemia inhibitory factor (LIF) and transcriptional level of Lif, Bmp4 and Wnt3a was evaluated in the mESCs cultured in each system. The expression of three genes was significantly increased in 3D system relative to 2D system under LIF-containing condition, while only Wnt3a expression was increased by 3D culture under LIF-free condition. Stimulation of integrin signaling in mESCs within 3D system with exogenous LIF significantly up-regulated transcriptional level of Bmp4, but did not induce transcriptional regulation of Lif and Wnt3a. In the absence of LIF inside 3D system, the expression of Lif and Bmp4 was significantly increased by integrin signaling, while it significantly decreased Wnt3a expression. Finally, the signal from exogenous LIF significantly caused increased expression of Lif in 2D system, decreased expression of Bmp4 in both 2D and 3D system, and decreased expression of Wnt3a in integrin-stimulating 3D system. From these results, we identified that endogenous expression level of self-renewal-stimulating factor genes in mESCs could be effectively regulated through artificial and proper manipulation of extracellular signaling. Moreover, synthetic 3D niche stimulating endogenous secretion of self-renewal-stimulating factors will be able to help develop growth factor-free maintenance system of mESCs.

Testes‐derived unipotent male germ‐line stem (GS) cells can acquire multipotency under appropriate culture conditions to become mGS cells which can contribute to all three germ‐layers. This study was designed to investigate the epigenetic characteristics of mGS cells derived from adult mouse testes (maGS cells). The GS cells were isolated from 4 6 week DBA mouse and were cultured in Dulbecco’s modified Eagle Medium supplemented with 15% (v/v) fetal bovine serum, 1,000 U/ml LIF, 4 ng/ml GDNF at 37℃ in an humidified atmosphere of 5% CO2 in air to derive the maGS cells. The multipotency of maGS cells were verified by morphological and gene expression analyses, teratoma formation upon transplantation into nude mouse and in vitro differentiation ability. Bisulfite genomic sequencing revealed that GS cells had androgenetic DNA methylation pattern at the Igf2‐H19, Gnas‐Nespas , and Dlk1‐Dio3 imprinted gene clusters which changed to hemi‐zygotic embryonic stem (ES)‐cell like pattern in the maGS cells. Western blot analysis, using modification‐ and residue‐specific antibodies, revealed that both maGS and ES cells had similar level of histone di‐methylation at 4th and 27th lysine residue of histone 3 (H3K4me2 and H3K27me2) which represent “bivalent domain” for regulating self‐renewal and differentiation of mouse ES cells. Both maGS and ES cells also shared similar hisone modification for H3K9me2, H3K79me2, H3K9ac and H3K18ac. However, maGS cells had higher level of H3K- 36me2 and H3S10p. These data suggest that maGS and ES cells share several epigenetic characteristics but they also have their own unique epigenetic marks that may be useful as a molecular marker for their identification.