Interspecies somatic cell nuclear transfer is dependent on compatible mitochondrial DNA and reprogramming factors

Interspecies somatic cell nuclear transfer (iSCNT) involves the transfer of a nucleus or cell from one species into the cytoplasm of an enucleated oocyte from another. Once activated, reconstructed oocytes can be cultured in vitro to blastocyst, the final stage of preimplantation development. However, they often arrest during the early stages of preimplantation development; fail to reprogramme the somatic nucleus; and eliminate the accompanying donor cell’s mitochondrial DNA (mtDNA) in favour of the recipient oocyte’s genetically more divergent population. This last point has consequences for the production of ATP by the electron transfer chain, which is encoded by nuclear and mtDNA. Using a murine-porcine interspecies model, we investigated the importance of nuclear-cytoplasmic compatibility on successful development. Initially, we transferred murine fetal fibroblasts into enucleated porcine oocytes, which resulted in extremely low blastocyst rates (0.48%); and failure to replicate nuclear DNA and express Oct-4, the key marker of reprogramming. Using allele specific-PCR, we detected peak levels of murine mtDNA at 0.1460.055% of total mtDNA at the 2-cell embryo stage and then at ever-decreasing levels to the blastocyst stage (,0.001%). Furthermore, these embryos had an overall mtDNA profile similar to porcine embryos. We then depleted porcine oocytes of their mtDNA using 10 mM 29,39- dideoxycytidine and transferred murine somatic cells along with murine embryonic stem cell extract, which expressed key pluripotent genes associated with reprogramming and contained mitochondria, into these oocytes. Blastocyst rates increased significantly (3.38%) compared to embryos generated from non-supplemented oocytes (P,0.01). They also had significantly more murine mtDNA at the 2-cell stage than the non-supplemented embryos, which was maintained throughout early preimplantation development. At later stages, these embryos possessed 49.9962.97% murine mtDNA. They also exhibited an mtDNA profile similar to murine preimplantation embryos. Overall, these data demonstrate that the addition of species compatible mtDNA and reprogramming factors improves developmental outcomes for iSCNT embryos

The generation of live offspring from vitrified oocytes

Oocyte cryopreservation is extremely beneficial for assisted reproductive technologies, the treatment of infertility and biotechnology and offers a viable alternative to embryo freezing and ovarian grafting approaches for the generation of embryonic stem cells and live offspring. It also offers the potential to store oocytes to rescue endangered species by somatic cell nuclear transfer and for the generation of embryonic stem cells to study development in these species. We vitrified mouse oocytes using a range of concentrations of trehalose (0 to 0.3 M) and demonstrated that 0.1 and 0.3 M trehalose had similar developmental rates, which were significantly different to the 0.2 M cohort (P < 0.05). As mitochondria are important for fertilisation outcome, we observed that the clustering and distribution of mitochondria of the 0.2 M cohort were more affected by vitifrication than the other groups. Nevertheless, all 3 cohorts were able to develop to blastocyst, following in vitro fertilisation, although developmental rates were better for the 0.1 and 0.3 M cohorts than the 0.2 M cohort (P < 0.05). Whilst blastocysts gave rise to embryonic stem-like cells, it was apparent from immunocytochemistry and RT-PCR that these cells did not demonstrate true pluripotency and exhibited abnormal karyotypes. However, they gave rise to teratomas following injection into SCID mice and differentiated into cells of each of the germinal layers following in vitro differentiation. The transfer of 2-cell embryos from the 0.1 and 0.3 M cohorts resulted in the birth of live offspring that had normal karyotypes (9/10). When 2-cell embryos from vitrified oocytes underwent vitrification, and were thawed and transferred, live offspring were obtained that exhibited normal karyotypes, with the exception of one offspring who was larger and died at 7 months. We conclude that these studies highlight the importance of the endometrial environment for the maintenance of genetic stability and thus the propagation of specific genetic traits

Degradation of mitochondrial DNA in cryoprotectant-treated hard coral (Echinopora spp.) oocytes

A critical step for successful cryopreservation is to determine the optimal cryoprotectant treatment that can provide protective effects against cryoinjury during freezing and with minimal toxicity. Most cryoprotectants have chemical and osmotic effects when used at high concentrations. Cryoprotectants can damage coral mitochondrial distributions and membrane potentials, which results in reduced ATP production. As mitochondrial DNA (mtDNA) encodes for components of the electron transport chain (ETC) and plays a critical role in ATP synthesis capacity, we determined the effects of cryoprotectants on mtDNA in hard coral (Echinopora spp.) oocytes using quantitative real-time PCR. Our results showed that an insult from a cryoprotectant may be compensated for by the genetic defense mechanisms of these cells. Methanol was found to have the least effect on coral oocytes with regard to their energy status. A single oocyte without cryoprotectant treatment produced an average of 4,220,645 ± 169,990 mtDNA copies, which was greater than that in mammals. However, relatively lower mtDNA copy numbers (<2,000,000) were observed when oocytes were treated with dimethyl sulfoxide (DMSO), propylene glycol (PG), ethylene glycol (EG), or glycerol at a concentration of 3 M for 20 min. These results provide direct evidence that hard coral (Echinopora spp.) oocytes are extremely susceptible to cryoprotectants and support the concerns with regard to the adverse effects of cryoprotectants

Human–animal cytoplasmic hybrid embryos, mitochondria, and an energetic debate

Scientists are seeking permission to generate human embryonic stem cells to study disease by introducing human genetic material into an animal oocyte. this has raised ethical questions that centre on whether the entities being generated are actually human. the answer to these questions will determine how this area of research will be regulated and whether such work will be legal. the function of the extra-nuclear mitochondrial genome lies at the heart of these issues and forms the focus of this commentary