Polo-like kinase 1 (plk1) shows multiple events of somatic cell and mammalian oocyte division. In mice, Plk1 distributes to the centromeres from prophase to anaphase and compose spindle apparatus at different stages of mitosis in spindle organization. Somatic cell nuclear transfer (SCNT) has a number of advantages however it is difficult to apply to basic or translational researches due to its low cloning efficiency. The causes of this low cloning efficiency are unclear. However, they are attributed to the cumulative results of several biological and technical factors. In this study, a biological factor plk1 was investigated. B6D2F1 mice (7–8 weeks old) were superovulated with 10 IU of pregnant mare’s serum gonadotropin and 9 U of human chorionic gonadotropin (HCG) 48 hr later. The oocytes were then collected 14 hr after HCG injection and cultured on potassium simplex optimized medium (KSOM). The plk1-specific inhibitor BI2536 was used to understand the influence of plk1. The 2-cell stage embryos were assessed by fluorescence immunoassay. In consequence, all BI2536-treated embryos failed in the first mitotic division which showed plk1 have critical role in the first mitotic division of the mouse embryo. SCNT requires enucleation of oocyte and injecting a donor cell into the enucleated cytoplast. In this process, a respectable amount of plk1 that co-localize with nucleus may be removed together. Fluorescence immunoassay and qPCR were used to monitor the change of plk1 level during SCNT. There was significant difference between the control and enucleated embryos in the level of plk1. In all division-failure 2-cell embryos, incorrect positioning of plk1 was found. Taken together, this results demonstrate that plk1 is critical for successful mitotic division of mouse SCNT 1-cell embryos.

Although assisted reproductive technology (ART) has been developed in many mammalian species including cows, the only embryo preservation technology that is available is cryopreservation. In the present study, small molecules were used to preserve embryos at room temperature. The basic medium for embryo preservation consisted of 1% BSA non-cryopreservation medium (BNC) instead of fetal bovine serum (FBS). To maintain survival and prevent damage during embryo storage, three candidate small molecules were selected—CHIR99021, Y-27632 and Thiazovivin—and their concentrations were optimized. Then, the embryos in the small molecule supplemented preservation medium were stored at room temperature. The viability and hatching rate of embryos stored at 10°C were greater for Y-27632-BNC and CHIR99021+Y-27632-BNC compared to BNC. However, the rate was lower for Thiazovivin-BNC compared to BNC. Although there were no surviving embryos after storage at 20°C, the viability and hatching rate of embryos significantly increased in Y-27632-BNC and CHIR99021+Y-27632-BNC compared to BNC. The mechanism by which small molecules enhance survival of embryos during storage was investigated, and expression of heat shock protein 70 was observed to increase. The findings of this work may be useful in improving ART in the agricultural field.

To have a better understanding of pluripotency, whole gene expression of embryo-derived stem cells (EdSCs) in bovine species was investigated. EdSCs were established from the embryos produced by in vitro fertilization, parthenogenesis and somatic cell nuclear transfer. Then, the microarray was performed and analyzed. Differently expressed genes (DEGs) were also confirmed by Real-time PCR. Among 10,203 DEGs, little difference was found in gene expression among three kinds of EdSCs. Conversely, all EdSCs have an immensely different gene expression when compared with somatic cells, consistent with scatter plat results. To investigate shared pathways for pluripotency in all EdSCs, 2,415 co-DEGs were identified which compared with somatic cells. By KEGG database, there were 54 signaling pathways in co-DEGs and some of them were related with pluripotency maintenance such as TGFβ, WNT and JAK-STAT signaling. In TGFβ signaling, BMP family and SMAD family were involved in co-up-regulated DEGs. In WNT signaling, WNT family and receptors were included in co-up-regulated DEGs, while inhibitors of WNT signaling were associated with co-down-regulated DEGs. In JAK-STAT signaling, STAT3 belonged to co-down-regulated DEGs. These DEGs were also confirmed by Real-time PCR. Taken together, BMP and WNT pathways may be activated and paly central roles to retain pluripotency in bovine EdSCs, whereas the LIF/STAT3 pathway may not be operated well. This study was supported by a grant from the National Research Foundation of Korea (NRF-2006-2004042, and No. 2015048003 through the Oromaxillofacial Dysfunction Research Center for the Elderly at Seoul National University) and the Technology Development Program for Agriculture and Forestry, Ministry of Agriculture, Food and Rural Affairs (MAFRA; 111160-04), Republic of Korea.

Human dental pulp stem cells (DPSCs) are multi-potent mesenchymal stem cells that have several differentiation potentials. An understanding of thetissues that differentiate from these cells can provide insights for future regenerative therapeutics and tissue engineering strategies. The mesiodens is the most frequent form of supernumerary tooth from which DPSCs can differentiate into several lineages similar to cells from normal deciduous teeth. Recently, it has been shown that nanoscale structures can affect stem cell differentiation. In our presentstudy, we investigated the effects of a 250-nm nanoscale ridge/groove pattern array on the osteogenic and adipogenic differentiation of dental pulp cells from mesiodenscontaining human DPSCs. To this end, the expression of lineage specific markers after differentiation induction was analyzed by lineage specific staining and RT-PCR. The nanoscale pattern arrayed surface showed apositive effect on the adipogenic differentiation of DPSCs. There was no difference between nanoscale pattern arrayed surface and conventional surface groups onosteogenic differentiation. In conclusion, the nanoscale ridge/groove pattern arrayed surface can be used to enhance the adipogenic differentiation of DPSCs derived from mesiodens. This finding provides an improved understanding of the effects of topography on cell differentiation as well as the potential use of supernumerary tooth in regenerative dental medicine.

This study was designed to determine the effect of electric field strength, duration and fusion buffer in fusion parameters on the rate of membrane fusion between the somatic cell and cytoplast for Korean cattle (HanWoo) somatic cell nuclear transfer (SCNT) procedure. Following electrofusion, effect of 5 or 10 μM Ca2+-ionophore of activation treatment on subsequent development was also evaluated. Cell fusion rates were significantly increased from 23.1% at 20 V/mm to 59.7% at 26 V/mm and 52.9% at 27 V/mm (p<0.05). Due to higher cytoplasmic membrane rupture or cellular lysis, overall efficiency was decreased when the strength was increased to 30 V/mm (18.5%) and 40 V/mm (6.3%) and the fusion rate was also decreased when the strength was at 25 V/mm or below. The optimal duration of electric stimulation was significantly higher in 25 μs than 20 and 30 μs (18.5% versus 9.3% and 6.3%, respectively, p<0.05). Two nonelectrolyte fusion buffers, Zimmermann’s (0.28 M sucrose) and 0.28 M mannitol solution for cell fusion, were used for donor cell and ooplast fusion and the fusion rate was significantly higher in Zimmermann’s cell fusion buffer than in 0.28 M mannitol (91.1% versus 48.4%, respectively, p<0.05). The cleavage and blastocyst formation rates of SCNT bovine embryos activated by 5 μM Ca2+-ionophore was significantly higher than the rates of the embryos activated with 10 μM of Ca2+-ionophore (70.0% versus 42.9% and 22.5% versus 14.3%, respectively; p<0.05). This result is the reverse to that of parthenotes which shows significantly higher cleavage and blastocyst rates in 10 μM Ca2+-ionophore than 5 μM counterpart (65.6% versus 40.3% and 19.5% versus 9.7%, respectively; p<0.05). In conclusion, SCNT couplet fusion by single pulse of 26 V/mm for 25 μs in Zimmermann’s fusion buffer followed by artificial activation with 5 μM Ca2+-ionophore are suggested as optimal fusion and activation methods in Korean cattle SCNT protocol.