Current applications of SCNT in advanced breeding and genome editing in livestock

SCNT (Somatic Cell Nuclear Transfer) has complemented the toolbox of ARTs offering yet another technique to reproduce animals in an unprecedented way. Despite remarkable achievements, SCNT suffers of low efficiency, high pregnancy losses and higher than normal stillbirth rates that makes it an expensive technique to reproduce animals. Moreover, due to welfare issues associated with gestation and the newborn offspring, it is banned in some countries. It has become evident that these problems are of epigenetic nature associated with incomplete genome reprogramming, observed more frequently in ruminants and less often and of minor degree in pigs and horses. Genome editing is enormously benefiting from SCNT to turn genome edited cells into animals, even if zygote microinjection of CRISPR/Cas9 will become an alternative route in some occasions. SCNT will also be a route to reprogram somatic cell to pluripotency since bona fide iPSC in livestock are missing while embryonic stem cells have been now established. This opens the way to other technologies like the development of artificial gametes or interspecies nuclear transfer. To strengthen its commercial applications, SCNT will face three major challenges, i.e. intellectual property (extremely unclear in genome editing), regulatory approval by the relevant authorities of the potential products resulting and finally acceptance by the public who will eventually decide with its behavior the life or the death of the technology.

Effects of donor sex and different cell treatments on development of yak–bovine interspecies nuclear transfer embryos

The purpose of this study was to evaluate the effects of donor sex, treatments of cell cycle synchronization and donor nuclei obtained from fresh or frozen–thawed conditions on developmental competence of yak–bovine interspecies nuclear transfer embryos. Bovine (Bos taurus) oocytes were used as recipients and yak (Bos grunniens) ear fibroblast cells were used as donors. Results indicated that the development rate of male blastocysts was higher than that of female (56.6% versus 39.5%, P<0.05), whereas cleavage and total cell number showed no difference between the two groups. No significant difference was observed in the development and quality of blastocysts with donor cells treated by serum starvation or contact inhibition, and there was no significant difference in embryo development with fresh or frozen–thawed donor cells, whereas the cleavage rate in the group of frozen–thawed cells was significantly lower than that of the fresh cell group (54.5% versus 78.2%, P<0.05). The results demonstrated that donor sex could impact the developmental competence of yak–bovine interspecies nuclear transfer embryos, whereas different treatments of cell cycle synchronization and freezing had little influence.

52 INITIATION OF PREGNANCIES IN SOUTH AFRICAN RIVERINE RABBIT (BUNOLAGUS MONTICULARES) BY INTERSPECIES NUCLEAR TRANSFER USING ADIPOSE-DERIVED SOMATIC CELLS

The riverine rabbit (Bunolagus monticulares), one of South Africa's most threatened mammals, with an estimated population size under 250, was upgraded from endangered to critically endangered in 2002. The low number of riverine rabbits precludes any attempts of nuclear transfer (NT) using intraspecific oocytes; therefore, the overall aim of this study was to assess the ability of the domestic rabbit (Oryctolagus cuniculus) oocyte to reprogram the somatic cell of the endangered riverine rabbit by interspecies NT. A preliminary study evaluated the effect of timing of enucleation after induction of ovulation (h post-hCG). A second study assessed the effects of two activation protocols. In addition, since the unique characteristics of the rabbit zona pellucida affect the speed of micromanipulation, different exposure periods to UV light at enucleation were evaluated. Adult domestic Californian rabbits were treated with eCG for 72 h, and ovulation was induced by hCG administration. Oocytes were collected by retrograde flushing at 12–14 h or 16–18 h post-hCG administration and stripped of cumulus investments with 0.5% hyaluronidase in Ca-Mg-free PBS. Metaphase-II oocytes were selected by visualizing the first polar body. Oocytes were stained with 2 mg mL–1 Hoechst 33342 for 5 min, and metaphase plates were removed with a 25–30 μm (O.D.) borosilicate beveled, spiked pipette after exposure to <5 or 30–40 s of UV light. Adult adipose-derived riverine rabbit fibroblasts grown to confluency in DMEM with 10% FCS were used as donor cells and fused with 2 consecutive DC pulses (3.2 kV cm–1, 45 μs). After reconstruction, couplets were randomly assigned for activation by either a second set of electrical pulses or incubation with ionomycin, followed by 1 h of incubation in 2 mm 6-DMAP. Embryos were co-cultured with a bovine oviductal cell monolayer in DMEM with 10% FCS and assessed for cleavage after 36 h of in vitro culture. There was a significant difference in the number of cleaved embryos from oocytes collected at 12–14 h post-hCG (n = 50) or 16–18 h post-hCG (n = 51) administration (57% v. 0% cleaved; P < 0.05). No significant difference was detected in embryos developing after electrofusion v. ionomycin activation treatments. However, a significantly greater number (P < 0.05) of embryos cleaved from oocytes exposed to <5 s UV than from oocytes exposed to 30–40 s UV (Table 1). A total of 20 embryos (4-cell to 16-cell stages) were surgically transferred to the oviducts of 4 adult New Zealand white synchronized recipients after 48 h of in vitro culture. Two recipients (<5 s UV exposure treatment group) were diagnosed pregnant by abdominal palpation at 15 days post-transfer; pregnancies were subsequently lost by Day 30, with placental tissues recovered. This preliminary study indicates the domestic rabbit oocyte is capable of reprogramming riverine rabbit donor cells. In addition, the time of oocyte collection after ovulation induction and the UV exposure period during enucleation have an effect on the efficiency of interspecies NT and embryo development in this species. Table 1. Effect of UV exposure during enucleation on the in vitro development of interspecies nuclear transfer riverine rabbit embryos