PRIMARY FIBROBLAST CELL CYCLE SYNCHRONIZATION AND EFFECTS ON HANDMADE CLONED (HMC) BOVINE EMBRYOS

Spatial and temporal synchrony and compatibility between the receptor oocyte and the donor cell nucleus are necessary for the process of embryo cloning to allow nuclear reprogramming and early embryonic development. The objective of the present study was to evaluate three cell cycle synchronization methods on a primary bovine fibroblast culture for 24, 48, or 72 h. These fibroblasts were used as nuclear donors to evaluate their in vitro developmental potential and the quality of the embryos produced through handmade cloning (HMC). No differences were found between the methods used for fibroblast synchronization in G0/G1 (p > 0.05). Production of clones from fibroblasts in four groups- no treatment at 0 h and using serum restriction SR, high culture confluence HCC, and SR+HCC at 24 h- resulted in high cleavage rates that were not different. Embryo production rates were 37.9%, 29.5%, and 30.9% in the 0h, SR24h, and SR+HHC24h groups, respectively, and 19.3% in the HCC group, which was significantly different from the other three (p < 0.05). There were no differences in the quality parameter among the clones produced with fibroblasts subjected to the different synchronization. Finally, when overall clone production was compared versus parthenotes and IVF embryos, the only difference was between clones and parthenogenetic embryos with zona pellucida (30.2% vs 38.6%). The number of blastomeres from the blastocytes produced through IVF was significantly greater than those from embryos activated parthenogenetically and from clones (117, 80, 75.9, and 67.1, respectively). The evaluation of three synchronization methods at different time points did not demonstrate an increase in the percentage of fibroblasts in the G0/G1 phases of the cell cycle; however, good quality and high cloning rates were obtained, suggesting that it is not always necessary to subject the cells to any synchronization treatments, as they would yield equally good cloning results.

Mouse zygotes as recipients in embryo cloning

Zygotes have not been recognized as nuclear recipients since enucleated zygotes receiving nuclei from beyond two-cell stage embryos are not able to form blastocysts. In the present study, a new technique of zygote enucleation is presented, which consists in selectively removing the nuclear membrane with genetic material of pronuclei, but leaving other pronuclear components in the cytoplasm. With selective enucleation it is possible – after transfer of eight-cell stage nuclei – to obtain 70.5 and 7.8% of preimplantation and full-term development respectively. Origin of cloned mice from introduced nuclei was confirmed by the coat colour and glucose phosphate isomerase (GPI) isozyme of the donor. We suggest that some pronuclear factors – taken away from the zygotes in the karyoplasts upon classical enucleation – are needed to reprogram the introduced nuclei.

Sucrose-exposed chemically enucleated mouse oocytes support blastocyst development of reconstituted embryos

This study was carried out to test the ability of sucrose-exposed chemically enucleated mouse oocytes to support the development of reconstituted embryos in vitro. Cumulus-enclosed germinal-vesicle-stage mouse oocytes were matured in vitro to metaphase I stage and were chemically enucleated with 50 µg mL–1 etoposide in tissue culture medium 199. The chemically enucleated oocytes were grouped into two groups. Group I was exposed to 0.75 m sucrose and group II was not exposed to sucrose. The zonae pellucidae of the chemically enucleated oocytes were removed with acid Tyrode’s solution (pH 2.7). They were then aggregated into couplets with karyoplasts from pronuclear-stage embryos using phytohemagglutinin-P. The couplets were electrically fused to form reconstituted embryos. The reconstituted embryos were activated with 7% ethanol and cultured in vitro in simplex optimisation medium to test their developmental ability to the blastocyst stage. Some of the reconstituted embryos that developed to the blastocyst stage were used for chromosome counts to test their ploidy. The results of the present study showed that chemically enucleated oocytes exposed to sucrose supported the development of reconstituted embryos to the blastocyst stage (21.5%), whereas those not exposed to sucrose did not. The chromosome counts showed that the reconstituted embryos had normal ploidy (40 chromosomes). It is concluded that sucrose exposure improves the quality of chemically enucleated mouse oocytes. Thus they can be used as recipients for mouse embryo cloning and nucleocytoplasmic interaction studies.