Haploidization in somatic cells is the process of reducing the diploid somatic chromosomes to haploid. Several studies have attempted somatic haploidization using oocytes in mice and humans. Some researchers showed partial somatic haploidization, but none observed embryo development. Our study attempted somatic haploidization using the modified somatic nuclear transfer (SCNT) protocol with various combinations of chemicals or proteins in mice. This study induced the proper segregation of somatic homologous chromosomes and full embryo development in vitro. Furthermore, somatic haploid embryos established embryonic stem cells and produced live births. The current review summarizes this recent study on the success of somatic haploidization and provides an overview of other related studies on somatic haploidization.

난자의 성숙과정과 노화에 관한 이해는 인공수정과 체외수정 최적기를 판단하기 위하여 가장 중요한 연구내용으로 알려져 있다. 이러한 기작은 번식 호르몬들에 의하여 조절되는 것으로 알려져 있으나 난자 세포질 변화에 관한 내용은 잘 알려져 있지 않다. 본 연구에서는 산화질소물(nitric oxide, NO)이 난자 성숙과정에서 증가하는 것을 밝혔으며 난자의 미성숙단계(germinal vesicle stage, GV)와 난자핵막붕괴단계(germinal vesicle breakdown, GVBD) 및 성숙완료단계(metaphase II, MII)단계에서 생산되는 NO의 양을 비교하였다. 또한, 난자를 체외에서 배양할 때, MII단계로 성숙되지 않는 성장 단계의 난자에서는 NO의 증가 현상을 관찰할 수 없었고, 세포질이 불균일한 노화된 난자에서는 NO가 증가된 상태로 유지되는 특성이 있음을 밝혔다. 이러한 결과는 NO의 작용이 난자의 성숙과정과 난자 노화과정에서 중요한 기능을 담당하고 있음을 보여주고 있다.

Transglutaminase (TGM2) belongs to a family of cross-linking enzymes responsible for catalyzing Ca2+-dependent acyl-transfer reactions between the substrate proteins. TGM2 is a cytosolic protein that has also been observed in the nucleus and can be expressed to the cell surface or extracellular matrix. Despite ubiquitous expression, its functions are poorly understood and still need to be elucidated. Moreover, there is no clear data regarding the role of transglutaminase in mammalian oocytes. So, in this study, we have patterned the transglutaminase 2 (TGM2) and anti-N epsilon gamma glutamyl lysine (AB424) activity in heat stressed mouse oocytes. We have collected mouse oocytes from the (6–9 weeks old) mouse and in vitro matured for 20 h. Immunocytochemistry was performed to checked the transglutaminase 2 (TGM2) and anti-N epsilon gamma glutamyl lysine (AB424) activity after 6 h of heat stress (HS) at 39.1 ℃. Both TGM2 and AB424 expression were significantly (P < 0.05) higher compared to control when oocytes were subjected to HS at 6 h of IVM at 39.1 ℃. Our hypothesis is that TGM2 and AB424 activity may be correlated with the cellular regression and also involvement in apoptosis. We hope that, our study will help to elucidate the normal function of mouse oocyte and also identification of the principal proteins as well as the pathogenic mechanism of altered physiology. These results suggest that the nuclear accumulation of the transglutaminase may play an important role in nuclear remodeling during folliculogenesis and early embryonic development

Mitotic spindle formation is regulated by centrosomes, composed of a centriole pair surrounded by pericentriolar materials(PCM) proteins. However, mammalian oocytes rely on acentriolar MTOCs for the function of meiotic spindle. The composition of acentriolar MTOCs and the molecular precesses that regulate the localization and accumulation in mammalian oocyte are not well understood. In this study, we analyzed the mechanisms of spindle microtubule nucleation and stability from MTOCs in mouse oocyte, and indentified Centrosomal protein192(CEP192) as a key regulator for acentriolar MTOC formation. CEP192 specifically colocalized with pericentrin (PCNT) during the oocyte maturaion. CEP192 proteins are localized throughout cytoplasm and around nucleus at GV stage, and then after BD stage, CEP192 proteins were further fragmented into smaller MTOCs around chromosomes. At metaphase, CEP192 proteins were concentrated in spindle pole. Knockdown of CEP192 using siRNAs resulted in metaphase I arrest. The arrested oocytes were characterized by reduced microtubule intensity and misalignment chromosome. Also at BD and ProMI stage, the oocytes reduced microtubule density and PCNT intensity. To confirm the mechanism of CEP192 regulation, we confirmed that PLK1 and AuroraA kinase were involved in CEP192 activation. The investigations for detailed molecular mechanisms of CEP192 and RanGTP for microtubule nucleation in oocytes are underway using various techniques including siRNA, mRNA, and positive or negative dominant injection and inhibitors.

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.

This study was conducted to establish the optimal temperature condition before oocyte activation in B6D2 F1 mouse. In experiment 1, two embryo culture media (CZB vs KSOM) were evaluated for the development of activated mouse oocytes. Parthenogenetic embryos cultured in KSOM showed better blastocyst development than ones cultured in CZB(56.2% vs 81.0%, p<0.01). Two-hour of pre-incubation before activation significantly reduced the number of hatched blastocysts in KSOM (22.0% versus 8.8%, p<0.05). In experiment 2, recovered oocytes were pre-incubated at different temperature conditions before activation. The experimental groups were divided by 5 as follows. Group A: pre-incubation for 120 min at 37℃, Group B: pre-incubation at 37℃ for 90 min then at 25℃ for 30 min, Group C: pre-incubation at 37℃ for 60 min then at 25℃ for 60 min, Group D: pre-incubation at 37℃ for 30 min then at 25℃ for 90 min, and Group E: pre-incubation at 25℃ for 120 min before activation. Group A (67.6%) and B (66.7%) showed better development to the blastocyst stage than other groups (Group C: 50.0%, Group D: 49.2%, Group E: 33.3%, p<0.05). The present study indicates that the temperature before activation affects the development of B6D2 F1 mouse parthenogenetic oocytes and exposure to room temperature should be limited to 30-min when the oocytes are left in HEPES-buffered medium for micromanipulation.

PKC는 그들의 cofactor-requirments에 따라 cPKC, nPKC 그리고 aPKC, 3그룹으로 나어진다. 마우스 난 성숙과정에 있어서 cPKC 및 nPKC의 activators인 PMA의 영향에 대한 많은 결과가 보고되었다. 그러나 각각의 그룹에 대한 차별화된 영향에 대하여는 밝혀져 있지 않다. Mezerein의 analog인 thymeleatoxin은 cPKC의 특이적인 activator로 보고되어져 있다. 본 연구에서는 specific cPKC activator인 thymeleatoxin의 마우스 난 성숙과정에의 영향을 제1감수분열 재개 능(germinal vesicle break down, GVBD)과 제1 극체 형성 능(1st polar body extrusion)을 조사하여 cPKC및 nPKC activator인 PMA와 비교 검토하였다. 그 결과 GVBD IC50는 thymeleatoxin에서 ～400nM, PMA에서는 ～50nM이었으며, 제1극체 방출의 IC50는 thymeleatoxin에서 ～200nM, PMA에서는 ～20nM이었다. 이들 결과는 Thymeleatoxin의 GVBD나 1st polar body extrusion 저해효과가 PMA에 비하여 1/8～1/10인 것으로 나타났다. 이들 결과는 GVBD나 제1극체 형성을 포함하는 난 성숙과정에서 cPKC보다 상대적으로 nPKC의 관여가 깊음을 보여 준다.

This study was undertaken to optimize enucleation and reconstitution methods for the production of cloned mice by somatic cell nuclear transfer Outbred ICR mouse oocytes at the metapahse- II stage were retrieved from female mice superovulated by PMSG and hCG. In Experiment 1, oocytes were enucleated in medium supplemented with cytochalasin B (CCB) of 3 levels (0, 7.5 or 15 /mL), and higher rate of encleation was obtained at 7.5 and 15 /mL than at /mL. In Experiment 2, oocytes enucleated in 7.5 /mL CCB-containing medium were reconstituted with different types of somatic cell by following methods; 1) cumulus cells by direct cell injection, 2) cumulus cells by electric fusion (1.25 kV/cm, 2 pulses for each 70 ) or 3) STO cells by the electrofusion. Electrofusion of STO cells with enucleated oocytes yielded the greatest (P<0.05) rate of reconstitution without lysis (76%) than any other combinations. Although significant decrease in the rate of somatic cell introduction was found, the electrofusion of cumulus cells yielded better rate of reconstitution than direct injection (0 vs. 18%). In Experiment 3, the duration of electric stimulation for the fusion was changed to either 50 or 90 , but no significant improvement of reconstitution efficacy was obtained. In conclusion, this study showed that ICR mouse oocytes could be used for the production of reconstituted oocytes and a fusion method of 1.25 KV/cm with 2 pulses using 570 cell was the optimal.