The CRISPR/Cas9 system is widely applied in genome engineering due to its simplicity and versatility. Although this has revolutionized genome-editing technology, knock-in animal generation via homology directed repair (HDR) is not as efficient as non-homologous end-joining DNA-repair-dependent knockout. Although its double-strand break activity may vary, Cas9 derived from Streptococcus pyogenens allows robust design of single-guide RNAs (sgRNAs) within the target sequence; However, prescreening for different sgRNA activities delays the process of transgenic animal generation. To overcome this limitation, multiple sets of different sgRNAs were examined for their knock-in efficiency. We discovered profound advantages associated with single-stranded oligo-donor-mediated HDR processes using overlapping sgRNAs (sharing at least five base pairs of the target sites) as compared with using non-overlapping sgRNAs for knock-in mouse generation. Studies utilizing cell lines revealed shorter sequence deletions near target mutations using overlapping sgRNAs as compared with those observed using non-overlapping sgRNAs, which may favor the HDR process. Using this simple method, we successfully generated several transgenic mouse lines harboring loxP insertions or single-nucleotide substitutions with a highly efficiency of 18~38%. Our results demonstrate a simple and efficient method for generating transgenic animals harboring foreign-sequence knock-ins or short-nucleotide substitutions by the use of overlapping sgRNAs.

Post-ejaculation of sperms into the female reproductive tract, acquisition of sperm capacitation is an essential step in the fertilization process. Accordingly, during in-vitro fertilization, the successful fertilization requires necessarily induction of capacitation in the retrieved sperms. To date, many candidate substances have been considered as capacitation inducers. However, there were no reports about the comparison of efficiency inducing sperm capacitation among diverse capacitation inducers. Therefore, we tried to determine an inducer showing the best capacitation performance in mouse sperms by comparing the preimplantation development of in-vitro-fertilized embryos using sperms experiencing capacitation by a variety of capacitation inducers. For these, calcium, progesterone, bovine serum albumin (BSA), heparin, lysophosphaticylcholine (Lyso-PC) were used as candidate capacitation inducers. Optimized concentration of each inducer were determined by accessing ratio of sperms experiencing acrosome reaction using coomassie G-250 blue staining. Subsequently, in vitro fertilization was performed using sperms incubated in each optimized concentration inducer. The ratio of fertilized oocytes was observed. As the results, Calcium at 2.7 mM and 0.3% (w/v) BSA showed the highest fertilization rates compared to 15 μM progesterone, 50 mM heparin, and 100 μM Lyso-PC. From these results, we found that 2.7 mM calcium and 0.3% (w/v) BSA were the most effective sperm capacitation inducers of mouse sperm for in vitro fertilization. From these results, we could identify that, among diverse sperm capacitation inducers, 2.7mM calcium and 0.3% (w/v) BSA were the most effective inducers for in vitro fertilization.

Transcription factor called activating enhancer binding protein 2C (AP2-gamma) is found in a variety of species and expressed from oocyte stage onwards, particularly restricted to the trophectoderm. Recent studies demonstrated that ablation of Tfap2c led to failure of tight junction biogenesis, particularly the knock-down embryos of Tfap2c did not form cavity from morula to blastocyst in mouse and pig. We speculated that the Tfa2pc may also be involved in desmosome biogenesis because blastocoel formation is coincident with the establishment of desmosome. To determine this, we depleted Tfap2c injecting siRNA into one-cell zygote and analysed the expression levels of genes that are required for desmosome complex such as PkP2, Pkp3, Dsc2, and Dsg2. We found only Pkp3 was up-regulated in the knockdowned morula embryos. Interestingly, upstream region of Pkp3 had putative Tfap2c binding sites. In conclusion, our results suggest that Tfap2c is not a crucial factor but somehow it might be involved in desmosome biogenesis directly or indirectly via Pkp3.

Programmed cell death or apoptosis is associated with changes in K+ concentration in many cell types. Recent studies have demonstrated that two-pore domain K+ (K2P) channels are involved in mouse embryonic development and apoptotic volume decrease of mammalian cells. In cerebellar granule neurons that normally undergo apoptosis during the early developmental stage, TASK-1 and TASK-3, members of K2P channels, were found to be critical for cell death. This study was performed to identify the role of K+ channels in the H2O2-induced or cryo-induced cell death of mouse and bovine embryos. Mouse and bovine two-cell stage embryos (2-cells) exposed to H2O2 for 4 h suffered from apoptosis. The 2-cells showed positive TUNEL staining. Treatment with high concentration of KCl (25mM) inhibited H2O2-induced apoptosis of 2-cells by 19%. Cryo-induced death in bovine blastocysts showed positive TUNEL staining only in the cells near the plasma membrane. Cryoprotectant supplemented with 25 mM KCl reduced apoptosis slightly compared to cryoprotectant supplemented with 5 mM KCl. However, the combination of antioxidants (β-mercaptoethanol) with 25 mM KCl significantly decreased the rate of H2O2-induced and cryo-induced apoptosis compared to treatments with only antioxidants or 25 mM KCl. These results show that blockage of K+ channel efflux for a short-time reduces H2O2- and cryo-induced apoptosis in mouse and bovine embryos. Our findings suggest that apoptosis in mouse and bovine embryos might be controlled by modulation of K+ channels which are highly expressed in a given cell type.

Autophagy is conserved response to starvation by which cells catabolize their components to create an internal supply of essential nutrients. Ceramide is known to induce autophagy in many cells through down-regulation of amino acid and glucose transporters. The mechanism of starvation induced-autophagy in mouse embryo remains unclear. In order to understand the mechanism by which starvation regulates autophagy, in this study, we investigated nutrient transporters expression and the effect of c2-ceramide on the in vitro development, apoptosis and autophagy via starvation in mouse embryo. Glucose transporters (Glut1 and Glut 3), high levels of transcript were expressed from 1 to 2 cells and gradually decreased through the morula and blastocyst (BL) stages. Amino acid transporters (LAT-1 and 4F2hc) gradually decreased from the zygote to the BL stage. Furthermore, the expression of nutrient transporters (Glut1, 3, LAT-1 and 4F2hc) were significantly reduced at the BL stage after ceramide treatment. Especially, mTOR expression after ceramide treatment of embryos was significantly higher than controls. Ceramide treated embryos exhibited significantly reduced developmental rates and total cell numbers, and increased apoptotic cell death at the BL stage. Consequently, we next evaluated the effect of ceramide treatment on mitochondrial number and morphology. There was a significant decrease in the average mtDNA copy number and the mitochondrial area in ceramide treated BL stage embryos. Both the expression of autophagy-related genes, Lc3, Gabarap, Atg4A and Atg4B, and the synthesis of LC3 were significantly induced at the BL stage. These results suggest that autophagy under starvation condition influences the in vitro development and apoptosis and autophagy, and may play a role in early mouse embryogenesis.

The objective of this study was to investigate the effectiveness of cryopreservation methods for the effect of various vitrification containers, such as EM-grid, OPS, or cryo-loop on the survival and developmental rate of vitrified mouse pronuclear embryos, and mouse cleavage embryo, at 21, 24, 27 and 30 hr after hCG injection. Post-thaw cleavage was similar among treatments, while the developmental rates of mouse blastocyst and hatched blastocyst were higher ( <0.05) in 27 hr and 30 hr than 21 hr. The developmental rate of hatched blastocyst at vitrified cleavage mouse embryos in cryo-loop was significantly higher than vitrified pronuclear embryos of control group as well as EM-grid and OPS ( <0.05). The developmental rate using cryo-loop was higher than EM-grid, but in case of OPS at vitrified cleavage and mouse pronuclear embryos, no significant difference was noticed. These results of our study show that the developmental rates of mouse embryos were unaffected by various vitrification containers, but in case of mouse embryos and hatched blastocysts at late vitrified pronuclear embryos the developmental rates were higher than early vitrified pronuclear embryos. Moreover, the developmental rate of hatched blastocyst at vitrified cleavage mouse embryos was significantly higher than vitrified pronuclear embryos. For better execution of this study, it will be mandatory to include improvement of vitrification containers, cryopreservation methods and conditions, higher survival rate, safe preservation, contamination and embryo loss.

Nicotine, a major teratogen of cigarettes smoke induces embryonic abnormalities during the early stages of organogenesis. In this study, the protective effect of β-carotene against nicotine–induced embryos was evaluated by morphologic scoring, nile blue staining, lipid peroxidation, SOD activity assay and real-time PCR. The embryos exposed to nicotine (1 μM) revealed remarkable morphological anomalies compared to normal control group (p<0.05), but when β-carotene (1×10‒4 μM or 5×10‒4 μM) was added concurrently to the embryos exposed to nicotine, morphological parameters were significantly improved (p<0.05). Nicotine induced oxidative stress by increased lipid peroxidation, expression of proinflammatory cytokines (TNF-α and IL-1β), caspases-3 and decreased SOD activity. However, administration of β-carotene (1×10‒4 μM or 5×10‒4 μM) restored the SOD level and decreased oxidative damage in the embryos. These results indicate that β-carotene effectively counteracts the deleterious effects of nicotine on embryos and attenuates oxidative damage possibly through its antioxidant effects.

Nicotine, a major toxic component in tobacco smoke, leads to severe embryonic damages on organogenesis. We investigated if resveratrol can inhibit the nicotine–induced teratogenesis in the cultured mouse embryos (embryonic day 8.5) for 48 hours using a whole embryo culture system. The embryos exposed to nicotine (1 μM) revealed severe morphological anomalies, the increased levels of caspase-3 mRNA and lipid peroxidation, and further the lowered levels of mitochondrial manganese superoxide dismutase (SOD), cytosolic glutathione peroxidase (GPx), phospholipid hydroperoxide GPx, hypoxia-inducible factor 1α, and sirtuin mRNAs and SOD activity significantly compared to normal control group (p<0.05). However, whenre sveratrol(1×10‒5 μMor1 ×10‒4 μM) was added concurrently to the embryos exposed to nicotine, these all parameters were significantly improved (p<0.05).These findings indicate that resveratrol has a protective effect against nicotine-induced teratogenesis in mouse embryos throughout antioxidative and anti-apoptotic activities.

This study was conducted to examine the effect of oocyte donor age and micromanipulation medium on the development of mouse cloned embryos receiving cumulus cells. Mouse oocytes were obtained from 6 to 11 week-old mice BDF1 female mice(experiment 1) and cumulus cells were used as donor cells. Micromanipulation procedures for nuclear transfer(NT) were performed in FHM, M2 or Hepes-buffered TCM199(TCM199) medium(experiment 2). After nuclear transfer, the reconstructed oocytes were activated by 10 mM SrCl2 in Ca-free CZB medium in the presence of 5 μg/ml cytochalasin B for 5 h and cultured in KSOM medium for 4 days. In experiment 1, the survival rate of oocytes after injection of cumulus cells were significantly(p<0.05) lower in oocytes from 6～7 week-old mice(53.3%) than in oocytes from 8～9(80.9%) and 10～11 week-old mice(77.1%). In experiment 2, the survival rate of oocytes after cell injection were significantly(p<0.05) higher in FHM and M2 medium(71.7% and 76.9%) than in TCM199 medium (51.2%). The activation rates of cloned embryos were not different among the micromanipulation media. However, the embryos developed to blastocyst stage were significantly(p<0.05) higher in FHM medium(13.9%) than in M2 and TCM199 medium(0.0% and 0.0%). In conclusion, the present study suggest that oocytes from above 8 week-old mice are superior to oocytes from 6～7 week-old mice as a source of recipient cytoplasm and FHM is superior to M2 and TCM199 as a micromanipulation medium for mouse somatic cell cloning.

The present study was performed to investigate the survival and subsequent embryonic developmental rate of immature and mature oocytes after vitrification and pronuclear stage embryos after slow-freezing and vitrification. We have also tried to examine the dependency of concentrations (7.5, 15%) and exposure time (5, 10, 20 min) of ED cryoprotectant on developmental rate of pronuclear stage embryos. The developmental rates of 2-ce1l and blastocyst embryos at mature oocytes were significantly (p<0.05) higher than immature oocytes. After slow freezing, vitrification and thawing of pronuclear stage embryo, the survival and developmental rates of blastocysts and hatched blastocysts were significantly (p<0.05) higher after vitrification than after slow-freezing. On contrary, the developmental rates of 2-cell embryos were significantly (p<0.05) higher after slow freezing than after vitrification. The cryopreservation methods of pronuclear stage embryos vitrified by exposed to 7.5% ED solution for 5 minutes was significantly (p<0.05) higher than other experimental group. The results of our study suggest 1hat the developmental rates of mature oocytes have been more successful than immature oocytes during vitrification. Vitrification was more efficient than slow freezing in case of pronuclear stage embryos. The effective cryopreservation method of pronuclear stage embryos was vitrified by exposed to 7.5% ED solution for 5 minutes.

Drinking of excessive ethanol during pregnancy induces a fetal alcohol syndrome. Genistein is one of naturally occurring isoflavones at relatively high levels in soybeans. In this study, we investigated the effects of genistein ( and /ml) on the ethanol (1 /ml)-induced teratogenesis of developing mouse embryos during the critical period (embryonic days 8.5~10.5) of organogenesis using a whole embryo culture system and then morphological scoring analysis. Ethanol-treated embryos exhibited a variety of developmental abnormalities. However, the total morphological scores for ethanol plus genistein groups were significantly higher than those of ethanol alone group (p<0.05). In particular, there were significant increases in the ethanol plus /ml of genistein group on the scores for heart, optic system, branchial bar, mandibular process, and caudal neural tube and further in the ethanol plus /ml of genistein group on the scores for heart, hind-, mid-, and forebrains, optic system, branchial bars, maxillary and mandibular processes, caudal neural tube, forelimb, hindlimb, and somites as compared with those of ethanol alone group (p<0.05). These results indicate that genistein has a preventive effect against ethanol-induced teratogenesis.

Maternal hypoxia induced by a variety of exogenous oxidative stresses such as ethanol intake, diabetes, and cigarette during pregnancy provokes the impaired embryonic gene expression and developmental malformations. We investigated the gene expression patterns of the representative selenium containing antioxidant enzymes (selenoproteins) such as cytosolic GPx (cGPx), gestrointestinal GPx (GI-GPx), plasma GPx (pGPx), phospholipid hydroperoxide GPx (PHGPx), and selenoprotein P (SePP) in the cultured mouse embryos under normal or hypoxic (low oxygen state, 5% O₂) condition at embryonic day 8.5 for 2 days using real-time PCR analysis. cGPx, pGPx, and SePP mRNAs were significantly decreased, but GI-GPx and PHGPx mRNAs were remarkably increased in the hypoxic state compared to normal gassing state (p<0.05). These findings indicate that hypoxic condition leads to the unusual expressions of selenoproteins during mouse organogenesis.