G. Vichera

A unique method to produce transgenic embryos in ovine, porcine, feline, bovine and equine species

Transgenesis is an essential tool in many biotechnological applications. Intracytoplasmic sperm injection (ICSI)-mediated gene transfer is a powerful technique to obtain transgenic pups; however, most domestic animal embryos do not develop properly after ICSI. An additional step in the protocol, namely assistance by haploid chemical activation, permits the use of ICSI-mediated gene transfer to generate transgenic preimplantation embryos in a wide range of domestic species, including ovine, porcine, feline, equine and bovine. In the present study, spermatozoa from five species were coincubated with pCX-EGFP plasmid and injected into metaphase II oocytes. The chemical activation protocol consisted of ionomycin plus 6-dimethylaminopurine. We detected high proportions of fluorescent EGFP embryos for all five species (23-60%), but with a high frequency of mosaic expression (range 60-85%). To our knowledge, this is the first study to produce exogenous DNA expression in feline and equine embryos. Chemical activation reduces the lag phase of egfp expression in ovine embryos. Our results show that this unique method could be used to obtain ovine, porcine, feline, bovine and equine transgenic preimplantation embryos.

Chemical Activation with a Combination of Ionomycin and Dehydroleucodine for Production of Parthenogenetic, ICSI and Cloned Bovine Embryos

The aim of this study was to evaluate the potential of dehydroleucodine (DhL), a new drug isolated from a medicinal herb used in Argentina, for activation of bovine oocyte. Several DhL concentrations and exposure times after ionomycin (Io) treatment were tested. The optimal DhL treatment, found for parthenogenetic development, was employed to produce bovine embryos by intracytoplasmic sperm injection (ICSI) and somatic cell nuclear transfer (SCNT). The best parthenogenic embryo developments were observed with 5 μM Io for 4 min followed by 5 μM DhL concentration and after 3-h exposure time (52.3% cleavage; 17.4% morulae; 7.3% blastocyst; n = 109). This treatment generated no significant differences with standard Io plus 6-dimethylaminopurine (DMAP) treatment in preimplantation embryo development. In our conditions, the embryo development reached after ICSI and SCNT assisted by the DhL treatment did not differ in terms of cleavage and blastocyst development from activation with standard Io plus DMAP treatment (p > 0.05). In conclusion, DhL utilization to activate oocytes and induce development of parthenogenotes, ICSI-embryos or SCNT-embryos is reported here for first time.

Sperm genome cloning used in biparental bovine embryo reconstruction

The generation of androgenetic haploid embryos enables several haploid blastomeres to be obtained as identical copies of a single spermatozoon genome. In the present study, we compared the developmental ability of bovine androgenetic haploid embryos constructed by different methods, namely IVF and intracytoplasmic sperm injection (ICSI) before and after oocyte enucleation. Once obtained, the blastomeres of these androgenetic haploid embryos were used as male genome donors to reconstruct biparental embryos by fusion with matured oocytes. To verify the cytoplasmic contribution of androgenetic haploid blastomeres, we used spermatozoa incubated previously with exogenous DNA that coded for a green fluorescent protein gene (pCX-EGFP) and the enhanced green fluorescent protein (EGFP)-positive androgenetic haploid blastomeres generated were fused with mature oocytes. Of the reconstructed embryos reaching the cleavage and blastocyst stages, 85.1% and 9.0%, respectively, expressed EGFP (P>0.05). EGFP expression was observed in 100% of reconstructed embryos, with 91.2% exhibiting homogenic expression. To confirm sperm genome incorporation, androgenetic haploid blastomeres generated by ICSI prior to enucleation and using Y chromosome sexed spermatozoa were used for biparental embryo reconstruction. Incorporation of the Y chromosome was confirmed by polymerase chain reaction and fluorescence in situ hybridisation analysis. In conclusion, the results of the present study prove that it is possible to use sperm genome replicates to reconstruct biparental bovine embryos and that it is a highly efficient technique to generate homogeneous transgene-expressing embryos.

Efficient Transgene Expression in IVF and Parthenogenetic Bovine Embryos by Intracytoplasmic Injection of DNA―Liposome Complexes

Transgenic animals constitute an important tool with many biotechnological applications. Although there have been advances in this field, we propose a novel method that may greatly increase the efficiency of transgenic animal production and thereby its application. This new technique consists of intracytoplasmic injection of liposomes, in bovine oocytes and zygotes, to introduce exogenous DNA. In the first experiment, we evaluated embryo development and EGFP expression in In Vitro Fertilization (IVF) embryos injected with different concentrations of exogenous DNA-liposome complexes (0.5, 5, 50, 500 ng pCX-EGFP/μl). The highest EGFP-embryos rates were obtained using 500 ng pCX-EGFP/μl. In the second experiment, we evaluated embryo development and EGFP expression following the injection of DNA-liposome complexes into pre-fertilized oocytes and presumptive zygotes, 16 and 24 h post-fertilization. Approximately 70% of the cleaved embryos and 50% of the blastocysts expressed EGFP, when egfp-liposome was injected 16 h post-fertilization. The percentages of positive embryos for the 24-h post-fertilization and pre-fertilization groups were 30.1 and 6.3, respectively. Blastocysts that developed from injected zygotes were analysed by PCR, confirming the presence of transgene in all embryos. Finally, we examined the embryo development and EGFP expression of parthenogenetic embryos that resulted from the injection of egfp-liposome complexes into pre-activated oocytes, and 3 and 11 h post-activated oocytes. The group with the highest expression rate (48.4%) was the one injected 3 h post-activation. In summary, this study reports the efficient, reproducible and fast production of IVF and parthenogenetic embryos expressing EGFP, by the intracytoplasmic injection of liposomes to introduce the foreign DNA.

Oocyte genome cloning used in biparental bovine embryo reconstruction.

Oocyte genome cloning is a method by which haploid maternal embryos are obtained in such a way that parthenogenetic haploid blastomeres from these embryos can be considered as a clone of the original gamete. Our objective was to generate oocyte genome replicates and use them to reconstruct biparental embryos by fusion with haploid male hemizygotes. Furthermore, we generated biparental homogeneous transgene-expressing embryos using parthenogenetic haploid blastomeres that expressed a transgene (EGFP). In the first experiment, parthenogenetic haploid embryos were generated by incubation of oocytes in ionomycin and 6-dimethylaminopurine (DMAP) with a 3 h interval to permit their second polar body extrusion. The cleavage rate was 87.3%. To generate transgene-expressing blastomeres, activated oocytes were injected with pCX-EGFP-liposome complexes 3 h post ionomycin exposure, resulting in a cleavage rate of 84.4%. In the second experiment, haploid parthenogenetic blastomeres that were positive or negative for EGFP expression were used to reconstruct biparental embryos. Cleavage and blastocyst rates for the reconstructed embryos were 78.4% and 61.1% and 10.8% and 8.4%, using EGFP-positive or -negative blastomeres, respectively (P < 0.05). All of the reconstructed embryos showed EGFP expression, with 96.6% of them showing homogenic expression. Oct-4 expression in the reconstructed blastocysts displayed a similar pattern as IVF-blastocyst controls. In conclusion, our results proved that it is possible to use oocyte genome replicates to reconstruct biparental bovine embryos and that this technique is efficient to generate homogeneous transgene-expressing embryos.

DNA fragmentation, transgene expression and embryo development after intracytoplasmic injection of DNA–liposome complexes in IVF bovine zygotes

Summary This study was designed to evaluate the quality and viability of bovine embryos produced by in vitro fertilization (IVF), after intracytoplasmic injection of pCX-EGFP-liposome complexes or pBCKIP2.8-liposome complexes (plasmids that codify the human insulin gene). Cleavage, blastocysts and expanded blastocysts rates of these both groups were not different from that of controls (IVF or IVF embryos injected with liposomes alone; IVF-L). The percentage of EGFP-positive (EGFP+) blastocysts was 41.8%. In Experiment 2, the blastocysts obtained after injection of pCX-EGFP-liposome complexes that did or did not express the transgene, were analyzed by TUNEL (terminal deoxynucleotidyl transferase dUTP nick-end labelling) assay at days 6, 7 and 8 of culture in vitro(Bd6, Bd7 and Bd8), in order to evaluate DNA fragmentation. The EGFP+ blastocysts showed different proportions of TUNEL-positive cells (T+) at Bd6, Bd7 and Bd8 (91, 73.7 and 99.5%, respectively) while blastocysts without EGFP expression (EGFP-) showed statistically lower numbers of fragmented nuclei (0, 44.6 and 85%, respectively; P < 0.05). There was no evidence of DNA fragmentation in either Bd6 or Bd7 IVF and IVF-L control blastocysts, but T+ nuclei were detected at Bd8 in both groups (66.4 and 85.8% respectively). Finally, IVF blastocysts (n = 21) injected with insulin-liposome complexes, cultured for 6, 7 and 8 days, were transferred to recipient cows. Pregnancy rates of 18.2% (2/11) and 40% (2/5) resulted from the transfer of Bd6 and Bd7 cells, respectively. Two pregnancies developed to term but they were not transgenic for the insulin gene. In conclusion, EGFP expression affects DNA integrity but not embryo development. Moreover, additional transfers are required in order to overcome the drawbacks generated by in vitro culture length and transgene expression.

37 Healthy Foals Produced Using Bone Marrow-Mesenchymal Stem Cells as Nuclear Donors in Horse Cloning

Somatic cell nuclear transfer efficiency is based on the capacity of the donor cell to be reset and reprogrammed to an embryonic state. So, the less differentiated the donor cells are, the more easily they could be reprogrammed by a recipient cytoplasm. Failures on appropriate nuclear reprogramming frequently lead to abnormalities associated with the placenta, umbilical cord, birthweight, and limbs. In the present study, we evaluated the efficiency of bone marrow mesenchymal stem cells (BM-MSC) compared with adult fibroblasts (AF) as nuclear donors in horse cloning and evaluated both in vitro and in vivo development of the embryos generated. Moreover, we focused on comparing the health of the foals generated and on the presence of anatomical abnormalities in foals produced from the different treatments. Embryos produced by AI, recovered by uterine flushing, and transferred to recipient mares were used as controls. All variables were analysed by Fisher test (P < 0.05). The cloning procedure was performed according to Olivera et al. (2016 PLoS One 11, e0164049, 10.1371/journal.pone.0164049). Both cleavage and blastocyst rates were higher when MSC were used as nuclear donors (P < 0.05). Cleavage rates were 85.6% (3875/4527) v. 90.2% (3095/3432) and blastocyst rates were 10.9% (492/4527) and 18.1% (622/3432) for AF and MSC groups, respectively. In the AF group, 476 blastocysts were transferred to recipient mares (232 transfers), and in the MSC group, 594 blastocysts were transferred 297 transfers). In the AI control group, 88 embryos were transferred. Pregnancies were diagnosed by transrectal ultrasonography 15 days after embryo transfer in all the groups. Pregnancy rates were similar between both cloning groups (41/232, 17.7% and 37/297, 12.5%for AF and MSC, respectively), but higher in the AI group (71/88, 80.7%). However, significant differences were observed in the birth of viable offsprings among the cloning groups. Despite similar rates of foal delivery (AF, 17/41, 41.5%; MSC, 21/37, 56.7%), a higher proportion of viable foals were obtained from the MSC group (20/37, 54.1%) compared with the AF group (9/41, 22%; P < 0.05). Surprisingly, as in the AI group (63/63, 100%), all of the viable foals obtained using MSC (20/20, 100%) were considered normal and did not show abnormalities associated with cloning. In contrast, in the AF group, only 4/9 (44.4%) were considered normal foals. The defects present in the other 5 foals were related to flexural and angular limb deformities and umbilical cord malformations. These were corrected rapidly with standard treatments or, in the case of the umbilical cords, minor surgery. This study shows for the first time that BM-MSC can be used as nuclear donors in horse cloning and that the foals obtained are as healthy as those produced by AI, showing no abnormalities related to deficiencies in nuclear reprogramming.

32 PREGNANCY OF EQUINE CLONED EMBRYOS MICROINJECTED WITH PLURIPOTENCY INDUCING GENES (Oct4, Sox2, c-Myc, K1f4)

Animal cloning is a high impact tool for scientific and economical production, but still with inefficient results. The efficiency of the cloning process depends on the state of differentiation of the donor cell. An adult equine somatic cell can be differentiated to a pluripotent stem cell (iPSC) inducing the expression of certain transcription factors (Oct4, Sox2, c-Myc, and K1f4; Breton et al. 2013). The objective of this work was to assess the effect of the intracytoplasmic injection of pluripotency inducing genes on embryo development and pregnancy rates of equine cloned embryos. Cumulus–oocyte complexes (COC) were obtained from slaughterhouse ovaries. Oocyte collection and maturation procedure were performed as described by Lagutina et al. (2007). After the removal of cumulus cells, oocytes showing first polar body were microinjected with a mixture 1/3 of plasmids/liposomes (Mi group). The plasmid used was the pEP4-E02s-EM2k, which encodes the human genes Oct4, Sox2, Myc, and K1f4. The DNA concentration was adjusted to 0.5 μg mL–1. Microinjected oocytes were enucleated using the zona free method. Adult male skin fibroblasts from the same animal were used as donor nucleus cells. These fibroblasts were attached to the ooplasts with phytohemagglutinin and then fused with an electric pulse. Activation was performed using 8.7 mM ionomycin for 4 min, followed by culture for 4 h in a combination of 1 mM 6-DMAP and 5 mg mL–1 cycloheximide. Zona free reconstructed embryos (ZFRE) were cultured for 7 to 8 days in DMEM-F12 in the well of the well (WOW) system, aggregating 3 embryos per well. A control group (CC group) of not microinjected embryos was included. Cleavage and blastocyst development was assessed at Days 2 and 7, respectively. Transcervical transfer of 49 Day 7 to 8 blastocysts was performed 6 days after ovulation. The mares received 2 blastocysts per transfer. Pregnancy was diagnosed by transrectal ultrasonography 15 days after ovulation. Cleavage and blastocyst rates were analysed by Chi-squared test and pregnancy rate by Fisher test (P < 0.05). Cleavage was 92.1% (n = 58/63) for the Mi group and 90.4% (n = 868/960) for the CC group. Blastocyst rate was statistically higher per well, 28.6% (n = 6/21) v. 13.4% (n = 43/320) but not per oocyte, 9.5% (n = 6/63) v. 4.5% (n = 43/960), for the Mi and CC groups, respectively. Pregnancy rate was 17% (n = 1/6) for the Mi group and 7% (n = 3/43) for the CC group. No twin pregnancies were found and all the pregnancies are still ongoing. The higher blastocyst rates obtained with the embryos microinjected with pluripotency inducing genes compared with the control group showed an improvement in embryo quality. In conclusion, the data presented indicate that the intracytoplasmic microinjection of pluripotency inducing genes in equine zona free cloned embryos improved blastocyst rates on a per well basis and showed a tendency to improve the pregnancy rates. The expression of the Oct4, Sox2, c-Myc, and K1f4 genes could be probably generating better reprogrammed donor nucleus compared with adult differentiated cells used in conventional cloning.