Effect of roscovitine-treated donor cells on development of porcine cloned embryos.

Synchronization of the donor cell cycle is an important factor for successful animal cloning by nuclear transfer. To improve the efficiency of porcine cloning, in the present report, we evaluated effects of contact inhibition, serum starvation and roscovitine treatment of donor cells on in vitro and in vivo developmental potency of cloned porcine embryos. Fibroblasts derived from a porcine foetus at day 30 of gestation were isolated and cultured to 70% confluency. Then, cells were either cultured to 100% confluency for contact inhibition, or cultured in 0.5% serum for 72 h for serum starvation or with 15 µM roscovitine for 24 h. Cells were most effectively synchronized at G0/G1 in the serum starvation group (87.5%) compared with the contact inhibition and roscovitine treatment groups (76.3% and 79.9% respectively p < 0.05). However, after somatic cell nuclear transfer followed by in vitro culture, the serum starvation group showed a significantly lower blastocyst formation rate (5.6%) compared with the contact inhibition and roscovitine treatment groups (11.6% and 20.0% respectively). Differential expression of apoptosis-related genes and the level of apoptosis in each treatment group explain the variation in developmental competence among the groups. Significantly higher level of apoptosis was observed in the serum starvation group. On the other hand, the roscovitine treatment group shows the lowest level of apoptosis and the best in vitro development among the groups. Cloned embryos derived from roscovitine-treated donor cells were transferred to surrogate pigs. Three healthy live piglets were produced. In conclusion, we suggest that roscovitine treatment of donor cells improves development of cloned porcine embryos and can raise the efficiency of cloned piglet production.

Influence of ovulation status, seasonality and embryo transfer method on development of cloned porcine embryos.

To improve pig cloning efficiency, the present study evaluated the effect of ovulation status, seasonality and embryo transfer (ET) method on in vivo development of cloned porcine embryos. Cloned embryos were transferred to surrogate mothers on the same day of somatic cell nuclear transfer. In pre-ovulation stage (PO), pregnancy rate (PR) and delivery rate (DR) were 36.3% and 9.4%, respectively. In post-ovulation stage, 22.7% PR and 2.1% DR were recorded (both PR and DR are significantly higher in PO). When ET was performed during winter (December-February), spring (March-May), summer (June-August) and autumn (September-November), the PRs were 13.4%, 37.3%, 24.6% and 51.0%, while DRs were 0%, 12.7%, 4.3% and 7.8%, respectively. The highest PRs were recorded in autumn groups. However, DRs were significantly lower in autumn (7.8%) group compared with spring (12.7%) group. The PR was the lowest and no piglets were born in winter group, which might be because of the effect of low temperature during ET. To overcome the low PR in winter group, 0.25 ml straws were used for ET to minimize exposure time of embryos to ambient temperature. The straw ET group showed significantly higher PR in the winter group (23. 9%) compared with the conventional catheter-loading group (7.7%). We suggest that using PO recipient and ET in spring is the best condition for pig cloning. In addition, alternative method to reduce cold shock during ET in winter is necessary.

Electrical activation induces reactive oxygen species in porcine embryos.

The objectives were to determine factors affecting generation of reactive oxygen species (ROS) in porcine embryos after electrical activation of oocytes, and the effects of an antioxidant and chemical agent on ROS generation. Greater ROS were induced by electrical activation compared to IVF (mean+/-S.E.M., 14.6+/-0.8 vs. 9.2+/-0.4, P<0.05). Furthermore, ROS generation in embryos after electrical activation was significantly increased by higher intensity and longer duration electrical pulses and by higher exogenous Ca(2+) concentrations. Cleavage rate and blastocyst formation rate were not directly related to the level of ROS. Supplementation of the IVC medium with 0.5mM glutathione (GSH) reduced ROS (9.2+/-0.4 vs. 14.7+/-0.9, P<0.05). Treatment with the chemical activation agent, 6-dimethylaminopurine (6-DMAP) for 3h did not induce further ROS generation in combination with electrical activation, but it improved blastocyst formation rate (53.8+/-1.1 vs. 23.7+/-3.5, P<0.05). We concluded that generation of ROS should be considered for optimizing electrical activation and that supplementing an antioxidant or combining electrical and chemical activation induced lower ROS generation in electrically activated porcine embryos.