J. H. Pryor

A cat cloned by nuclear transplantation.

Sheep, mice, cattle, goats and pigs have all been cloned by transfer of a donor cell nucleus into an enucleated ovum, and now we add the successful cloning of a cat (Felis domesticus) to this list. However, this cloning technology may not be readily extendable to other mammalian species if our understanding of their reproductive processes is limited or if there are species-specific obstacles.

Cell biology: A cat cloned by nuclear transplantation

Sheep, mice, cattle, goats and pigs have all been cloned by transfer of a donor cell nucleus into an enucleated ovum, and now we add the successful cloning of a cat (Felis domesticus) to this list. However, this cloning technology may not be readily extendable to other mammalian species if our understanding of their reproductive processes is limited or if there are species-specific obstacles.

Genome edited sheep and cattle.

Genome editing tools enable efficient and accurate genome manipulation. An enhanced ability to modify the genomes of livestock species could be utilized to improve disease resistance, productivity or breeding capability as well as the generation of new biomedical models. To date, with respect to the direct injection of genome editor mRNA into livestock zygotes, this technology has been limited to the generation of pigs with edited genomes. To capture the far-reaching applications of gene-editing, from disease modelling to agricultural improvement, the technology must be easily applied to a number of species using a variety of approaches. In this study, we demonstrate zygote injection of TALEN mRNA can also produce gene-edited cattle and sheep. In both species we have targeted the myostatin (MSTN) gene. In addition, we report a critical innovation for application of gene-editing to the cattle industry whereby gene-edited calves can be produced with specified genetics by ovum pickup, in vitro fertilization and zygote microinjection (OPU-IVF-ZM). This provides a practical alternative to somatic cell nuclear transfer for gene knockout or introgression of desirable alleles into a target breed/genetic line.

Cloning to reproduce desired genotypes

Cloned sheep, cattle, goats, pigs and mice have now been produced using somatic cells for nuclear transplantation. Animal cloning is still very inefficient with on average less than 10% of the cloned embryos transferred resulting in a live offspring. However successful cloning of a variety of different species and by a number of different laboratory groups has generated tremendous interest in reproducing desired genotypes. Some of these specific genotypes represent animal cell lines that have been genetically modified. In other cases there is a significant demand for cloning animals characterized by their inherent genetic value, for example prize livestock, household pets and rare or endangered species. A number of different variables may influence the ability to reproduce a specific genotype by cloning. These include species, source of recipient ova, cell type of nuclei donor, treatment of donor cells prior to nuclear transfer, and the techniques employed for nuclear transfer. At present, there is no solid evidence that suggests cloning will be limited to only a few specific animals, and in fact, most data collected to date suggests cloning will be applicable to a wide variety of different animals. The ability to reproduce any desired genotype by cloning will ultimately depend on the amount of time and resources invested in research.

Reducing the amount of cytoplasm available for early embryonic development decreases the quality but not quantity of embryos produced by in vitro fertilization and nuclear transplantation

The effect of reducing the amount of cytoplasm available for early embryonic development was investigated in embryos produced by in vitro fertilization (IVF) and nuclear transplantation. In Experiment 1, approximately 1/2 or 1/20 of the cytoplasm was removed from bovine embryos at the pronuclear-stage of development. The percentage of embryos developing to the compact morula or blastocyst stage was significantly higher in non-manipulated controls (26%) than in embryos with 1/20 of the cytoplasm removed (16%), and those with 1/2 of the cytoplasm removed (10%; P < 0.05). There was also a significant difference in the average number of cells between blastocysts in which 1/20 of their cytoplasm was removed (67), those with 1/2 of their cytoplasm removed (55), and nonmanipulated controls (77; P < 0.05). In Experiment 2, nuclear transfer embryos were produced in which approximately 1/2 or 1/20 of the cytoplasm was removed during oocyte enucleation. The percentage of embryos developing to the blastocyst stage was 17% for both groups of nuclear transfer embryos compared to 44% for control embryos (P < 0.05). The mean number of cells in blastocysts produced by nuclear transfer in which 1/20 of the cytoplasm was removed during oocyte enucleation (61) was no different than that in control embryos (66), but significantly higher than the mean number of cells in blastocysts produced by nuclear transfer in which 1/2 of the cytoplasm was removed (42; P < 0.05). There was no indication that altering the amount of cytoplasm available for early embryonic development of IVF embryos affected the timing of differentiation events, including those of embryo compaction and blastocyst formation.

Regenerated bovine fetal fibroblasts support high blastocyst development following nuclear transfer.

Regenerated bovine fetal fibroblast cells were derived from a fetus cloned from an adult cow and passaged every 2-3 days. Serum starvation was performed by culturing cells in DMEM/F-12 supplemented with 0.5% FCS for 1-3 days. In vitro matured bovine oocytes were enucleated by removing the first polar body and a small portion of cytoplasm containing the metaphase II spindle. Cloned embryos were constructed by electrofusion of fetal fibroblast cells with enucleated bovine oocytes, electrically activated followed by 5 h culture in 10 microg/mL cycloheximide + 5 microg/mL cytochalasin B, and then cultured in a B2 + vero-cell co-culture system. A significantly higher proportion of fused embryos developed to blastocysts by day 7 when nuclei were exposed to oocyte cytoplasm prior to activation for 120 min (41.2%) compared to 0-30 min (28.2%, p < 0.01). Grade 1 blastocyst rates were 85.1% and 73.3%, respectively. The mean number of nuclei per grade 1 blastocyst was significantly greater for 120 min exposure (110.63 +/- 7.19) compared to 0-30 min exposure (98.67 +/- 7.94, p < 0.05). No significant differences were observed in both blastocyst development (37.4% and 30.6%) and mean number of nuclei per blastocyst (103.59 +/- 6.6 and 107.00 +/- 7.12) when serum starved or nonstarved donor cells were used for nuclear transfer (p > 0.05). Respectively, 38.7%, 29.4%, and 19.9% of the embryos reconstructed using donor cells at passage 5-10, 11-20 and 21-36 developed to the blastocyst stage. Of total blastocysts, the percentage judged to be grade 1 were 80.9%, 79.2%, and 54.1%, and mean number of nuclei per grade 1 blastocysts, were 113.18 +/- 9.06, 100.04 +/- 6.64, and 89.25 +/- 6.19, respectively. The proportion of blastocyst percentage of grade 1 blastocysts, and mean number of nuclei per grade 1 blastocyst decreased with increasing passage number of donor cells (p < 0.05). These data suggest that regenerated fetal fibroblast cells support high blastocyst development and embryo quality following nuclear transfer. Remodeling and reprogramming of the regenerated fetal fibroblast nuclei may be facilitated by the prolonged exposure of the nuclei to the enucleated oocyte cytoplasm prior to activation. Serum starvation of regenerated fetal cells is not beneficial for embryo development to blastocyst stage. Regenerated fetal fibroblast cells can be maintained up to at least passage 36 and still support development of nuclear transfer embryos to the blastocyst stage.

Cryopreservation of in vitro produced bovine embryos: effects of lipid segregation and post-thaw laser assisted hatching

The objective was to determine if lipid segregation, with or without post-thaw laser assisted hatching (LAH) of in vitro produced (IVP) bovine embryos, would enhance in vitro survivability and development 24 h post-thaw. On Day 6 of culture (Day 0 = IVF), in vitro produced bovine embryos were divided into three developmental stages: 32-cell (n = 78), compact morula (CM n = 223), and blastocyst (n =56). Embryos within each stage were allocated to the following treatments prior to cryopreservation in 1.5M ethylene glycol: no treatment (Control), 7.5 μg/mL Cytochalasin B for 20 min (CB), or CB with centrifugation (16,000 × g) for 20 min (CBCF). All CB treatments were extended to include embryo freezing. Immediately post-thaw, one-half of the CBCF and Control groups were subjected to zona pellucida drilling (LAH), using the XY Clone® system, creating groups CBCFLAH and LAH, respectively. All thawed embryos were cultured for 24 h and evaluated. No treatment differences were observed for either post-thaw survival or 24 h development. Within the CM stage, CBCFLAH and LAH exhibited a greater number of both total and live cells than Control (total: 69.4, 69.3, 53.0, live: 56.4, 54.7, 39.3 respectively; P < 0.05). In conclusion, LAH post-thaw alone or in combination with CBCF improved embryo viability following cryopreservation.

Histone-lysine N-methyltransferase SETDB1 is required for development of the bovine blastocyst

Transcripts derived from select clades of transposable elements are among the first to appear in early mouse and human embryos, indicating transposable elements and the mechanisms that regulate their activity are fundamental to the establishment of the founding mammalian lineages. However, the mechanisms by which these parasitic sequences are involved in directing the developmental program are still poorly characterized. Transposable elements are regulated through epigenetic means, where combinatorial patterns of DNA methylation and histone 3 lysine 9 trimethylation (H3K9me3) suppress their transcription. From studies in rodents, SET domain bifurcated 1 (SETDB1) has emerged as the core methyltransferase responsible for marking transposable elements with H3K9me3 and temporally regulating their transcriptional activity. SETDB1 loss of function studies in mice reveal that although extraembryonic tissues do not require this methyltransferase, establishment of the embryo proper fails without it. As the bovine embryo initiates the processes of epigenetic programming earlier in the preimplantation phase, we sought to determine whether suppressing SETDB1 would block the formation of the inner cell mass. We report here that bovine SETDB1 transcripts are present throughout preimplantation development, and RNA interference-based depletion blocks embryo growth at the morula stage of development. Although we did not observe alterations in global histone methylation or transposable element transcription, we did observe increased global levels of H3K27 acetylation, an epigenetic mark associated with active enhancers. Our observations suggest that SETDB1 might interact with the epigenetic machinery controlling enhancer function and that suppression of this methyltransferase may disrupt the bovine developmental program.

Oxygen-induced alterations in the expression of chromatin modifying enzymes and the transcriptional regulation of imprinted genes

Embryo culture and assisted reproductive technologies have been associated with a disproportionately high number of epigenetic abnormalities in the resulting offspring. However, the mechanisms by which these techniques influence the epigenome remain poorly defined. In this study, we evaluated the capacity of oxygen concentration to influence the transcriptional control of a selection of key enzymes regulating chromatin structure. In mouse embryonic stem cells, oxygen concentrations modulated the transcriptional regulation of the TET family of enzymes, as well as the de novo methyltransferase Dnmt3a. These transcriptional changes were associated with alterations in the control of multiple imprinted genes, including H19, Igf2, Igf2r, and Peg3. Similarly, exposure of in vitro produced bovine embryos to atmospheric oxygen concentrations was associated with disruptions in the transcriptional regulation of TET1, TET3, and DNMT3a, along with the DNA methyltransferase co-factor HELLS. In addition, exposure to high oxygen was associated with alterations in the abundance of transcripts encoding members of the Polycomb repressor complex (EED and EZH2), the histone methyltransferase SETDB1 and multiple histone demethylases (KDM1A, KDM4B, and KDM4C). These disruptions were accompanied by a reduction in embryo viability and suppression of the pluripotency genes NANOG and SOX2. These experiments demonstrate that oxygen has the capacity to modulate the transcriptional control of chromatin modifying genes involved in the establishment and maintenance of both pluripotency and genomic imprinting.

207 EFFICIENT GENERATION OF MYOSTATIN PROMOTER MUTATIONS IN BOVINE EMBRYOS USING THE CRISPR/Cas9 SYSTEM

The myostatin gene or growth differentiation factor 8 is a member of the transforming growth factor-β superfamily that acts as a negative regulator of muscle growth. Mutations inactivating this gene occur naturally in Piedmontese and Belgian Blue cattle breeds, resulting in a dramatic increase in muscle mass, albeit with unwanted consequences of increased dystocia and decreased fertility. Modulation of muscle mass increase without the unwanted effects would be of great value for improving livestock growth and economic value of livestock. The objective of our work was to use the CRISPR-Cas9 genetic engineering tool to generate deletions of different elements in the myostatin promoter in order to decrease the level of expression and obtain an attenuated phenotype without the detrimental consequences of an inactivating mutation. To achieve this objective 4 different small guide RNA (sgRNA) targeting the promoter near the mutation were designed with PAM positions from transcription starting site of -1577, -689, -555, and -116. These sgRNA were cloned individually into the Cas9 plasmids (px461, and px462; Addgene®). These plasmids allow for a dual puromycin resistance (px462) and green fluorescent protein (px461) selection. We first tested the functionality of these sgRNA in vitro by co-transfecting bovine fetal fibroblasts with a combination of both plasmids (Set 1=sgRNA 1-4; Set 2=sgRNA 2-3). Cells were exposed to puromycin (0.2µgmL-1) for 72h, then single and mixed colonies positive for green fluorescent protein expression were separated for propagation. The DNA was extracted for PCR amplification of the targeted region. Multiple deletions and a few insertion events were observed after PCR, bands were cloned into TOPO® vector (Thermo Fisher Scientific, Waltham, MA, USA) and sequenced. Sequencing results confirmed the PCR products as insertions or deletions in the myostatin promoter region. We proceeded to modify the myostatin promoter directly in bovine zygotes. For this, IVF-derived zygotes were randomly assigned to 3 different treatment groups Set 1, Set 2, or Null (no sgRNA) for microinjections. Each zygote was injected with ~100 pL of trophectoderm buffer containing 50ngµL-1 of total sgRNA, 10ngµL-1 of Cas9 mRNA, and 30ngµL-1 of Cas9 protein with 1mgmL-1 of fluorescent dextran. Day 7 post-IVF blastocysts were lysed and DNA was extracted for PCR amplification of the target region. In Set 1, 16 of 19 embryos (94.12%) were successfully edited, whereas in Set 2 there were 11 of 17 embryos (64.7%) edited. In both sets of sgRNA there was a high degree of mosaicism, with only 1 embryo demonstrating a homozygous deletion. In conclusion, CRISPR/Cas9 acts over the course of the first few cleavage divisions Further research is necessary to refine the CRISPR/Cas9 system for inducing genetic mutations in bovine embryos.