Somatic cell nuclear transfer in horses: effect of oocyte morphology, embryo reconstruction method and donor cell type.

The objective of the present work was to investigate and clarify the factors affecting the efficiency of somatic cell nuclear transfer (NT) in the horse, including embryo reconstruction, in vitro culture to the blastocyst stage, embryo transfer, pregnancy monitoring and production of offspring. Matured oocytes, with zona pellucida or after zona removal, were fused to cumulus cells, granulosa cells, and fetal and adult fibroblasts, and fused couplets were cultured in vitro. Blastocyst development to Day 8 varied significantly among donor cells (from 1.3% to 16%, P < 0.05). In total, 137 nuclear transfer-embryos were transferred nonsurgically to 58 recipient mares. Pregnancy rate after transfer of NT-embryos derived from adult fibroblasts from three donor animals was 24.3% (9/37 mares transferred corresponding to 9/101 blastocysts transferred), while only 1/18 (5.6%) of NT-blastocysts derived from one fetal cell line gave rise to a pregnancy (corresponding to 1/33 blastocysts transferred). Overall, seven pregnancies were confirmed at 35 days, and two went to term delivering two live foals. One foal died 40 h after birth of acute septicemia while the other foal was healthy and is currently 2 months old. These results indicate that (a) the zona-free method allows high fusion rate and optimal use of equine oocytes, (b) different donor cell cultures have different abilities to support blastocyst development, (c) blastocyst formation rate does not correlate with pregnancy fate and (d) healthy offspring can be obtained by somatic cell nuclear transfer in the horse.

Effect of prematuration, meiosis activating sterol and enriched maturation medium on the nuclear maturation and competence to development of calf oocytes.

New strategies were proposed to improve the developmental competence of calf oocytes through in vitro technologies. Cumulus-oocyte complexes were first prematured for 24 h in the presence of meiosis inhibitors. Both Roscovitine alone (50 microM) or in combination with Butyrolactone-I (12.5 microM Rosco+6.25 microM BL-I) prevented the progression of meiosis. Their effect on nuclear maturation was reversible after a further 17 or 24 h maturation step. However, a dramatic decrease in embryo development was observed after fertilization (abattoir oocytes: 4-9% blastocyst rate versus 14-17% for control embryos). Similar results were obtained with oocytes collected by Ovum Pick Up from living donors. No pregnancy was obtained after single transfer of two blastocysts obtained from prematured oocytes (0/2 versus 4/12 for control embryos). Adding low concentrations (1, 3 or 10 microM) of follicular fluid-meiosis activating sterol (FF-MAS) during the maturation step had a beneficial effect on nuclear maturation (73-86% metaphase II versus 58% for control oocytes). However, subsequent embryo development was not improved. Enriching the maturation medium, namely with hormones, growth factors and precursors of glutathione, induced a sixfold increase in glutathione in the oocyte and had a beneficial effect on embryo development (38% increase in blastocyst rate). In conclusion, in opposition to the results reported with adult oocytes, prematuring calf oocytes had a negative impact on their developmental potential. Although FF-MAS improved nuclear maturation, its addition in the maturation medium did not increase embryo development. However, enriching the maturation medium had a positive effect on embryo development, indicating that cytoplasmic maturation was improved.

Pregnancy: a cloned horse born to its dam twin.

Several animal species, including sheep, mice, cattle, goats, rabbits, cats, pigs and, more recently, mules have been reproduced by somatic cell cloning, with the offspring being a genetic copy of the animal donor of the nuclear material used for transfer into an enucleated oocyte. Here we use this technology to clone an adult horse and show that it is possible to establish a viable, full-term pregnancy in which the surrogate mother is also the nuclear donor. The cloned offspring is therefore genetically identical to the mare who carried it, challenging the idea that maternal immunological recognition of fetal antigens influences the well-being of the fetus and the outcome of the pregnancy.

Kinetics of oocyte maturation and subsequent development of IVF, parthenogenetic, and NT bovine embryos after meiotic inhibition with roscovitine.

The developmental competence of bovine oocytes meiotically arrested with specific cdk2 inhibitor roscovitine was studied. After removal of the 32-h block with roscovitine, 82.7 +/- 5.4% reached the metaphase II stage at the end of maturation, which was lower than in controls (96.3 +/- 1.3%, p < 0.001). The process of polar body formation started at 11 h of maturation in the roscovitine group, that is 4 h earlier than in controls and its kinetics was quite similar to controls up to 16 h of maturation, when nearly 70% of oocytes extruded their polar bodies. The rate of blastocyst formation of roscovitine oocytes and their cell number after IVF, parthenogenetic activation, and nuclear transfer (NT) were equal to controls, which demonstrates the possibility of artificially maintaining bovine oocytes in the GV stage for 32 h without altering their preimplantation developmental competence. This approach can be very useful for the management of an NT program where enucleated oocytes are required at specific times or locations.

Embryonic and foetal development of bovine oocytes treated with a combination of butyrolactone I and roscovitine in an enriched medium prior to IVM and IVF.

Cattle oocytes were maintained at germinal vesicles (GV) stage for 24 hr using a combination of two specific and potent inhibitors of M-phase promoting factor (MPF) kinase activity, butyrolactone I (BL-I) and roscovitine (ROS). The media used for inhibition were (a) TCM-199 only and (b) TCM-199 supplemented with serum, hormones and growth factors. The effective doses of inhibitors were 6.25 microM BL-I and 12.5 microM ROS in medium (a) and 50 microM BL-I and 12.5 microM ROS in medium (b). After inhibition, about 90% of the oocytes resumed meiosis and reached the metaphase II (MII) stage during 24 hr of maturation. Following fertilisation the percentage of cleavage (D +2), compacted morula (D +6), blastocysts on D +7 and D +8 and the survival to freezing and thawing of grade 1 embryos frozen on D +7 were not different between the experimental treated groups and the control. In order to evaluate early foetal development, two groups of five grade 1 D +7 blastocysts derived from treated oocytes and two groups of five control embryos were transferred nonsurgically in four synchronised recipient heifers. On D +27, the recipients were slaughtered and the foetuses were recovered. In both groups, six foetuses developed out of the 10 embryos transferred. In conclusion, several supplements can be added to the prematuration medium of bovine oocytes without reducing the quality of inhibition but also without improving their subsequent developmental competence versus treated oocytes in TCM-199 only and versus untreated control. Furthermore, the prematuration step used in this study does not interfere with normal foetal development during the first stages of organogenesis.