N. G. Canel

Activation with Ionomycin followed by Dehydroleucodine and Cytochalasin B for the Production of Parthenogenetic and Cloned Bovine Embryos

In this work, Dehydroleucodine (DhL) was evaluated as a chemical activator of bovine oocytes and somatic cell nuclear transfer (SCNT) reconstituted embryos. Oocytes were activated with 5 microM Ionomycin (Io) and exposed for 3 h to 1 or 5 microM DhL alone (Io-Dhl1 or Io-DhL5) or combined with Cytochalasin B (Io-DhL1/CB; Io-DhL5/CB). Control groups were Io (Io), Io followed by 1.9 mM 6-Dimethylaminopurine (Io-6DMAP), and embryos produced by in vitro fertilization (IVF). Pronuclear formation and development to blastocysts of activated oocytes were evaluated. Embryos obtained by the DhL concentration that induced the highest blastocyst rates (1 microM) were karyotyped. An additional treatment based in Io-DhL1 plus lengthened (6-h) exposure to CB (Io-DhL1/long CB) was included to improve the proportion of diploid blastomeres. Finally, DhL combined with CB was employed to assist cloning by intracytoplasmic injection of whole cumulus cells. Results showed that DhL induces a pronuclear formation dynamic that was more similar to IVF-produced embryos than DMAP. Development to blastocyst stage was higher after activation with 1 microM DhL than with 5 microM DhL, either for groups combined or not with CB (19.15; 21.74 vs. 6.82; 0%, respectively) (p < 0.05). Io-DhL1 and Io-DhL1/CB treatments induced blastocyst-cleaved embryo ratios not statistically different from those of Io-DMAP (35.85%) and IVF (33.33%) groups (p > 0.05). Io-DhL1/long CB induced higher diploid blastomere rates than Io-Dhl1, Io-DhL1/CB and Io-DMAP (63.8 vs. 36.8; 40 and 31.6%, respectively) (p < 0.05). Moreover, all DhL treatments resulted in polyploidy rates that were lower than Io-DMAP (5.2, 12.0, 10.6, and 31.6%, respectively) (p < 0.05). Io-DhL1/CB and Io-DhL1/long CB induced cloned embryo blastocyst rates that were not significantly different from Io-DMAP (6.1, 9.4, and 18.3%, respectively) (p < 0.05). Our results indicate that Io-DhL1/long CB protocol could be useful for SCNT programs.

Intracytoplasmic sperm injection in domestic and wild mammals

Intracytoplasmic sperm injection (ICSI) has become a useful technique for clinical applications in the horse-breeding industry. However, both ICSI blastocyst and offspring production continues to be limited for most farm and wild species. This article reviews technical differences of ICSI performance among species, possible biological and methodological reasons for the variable efficiency and potential strategies to improve the outcomes. One of the major applications of ICSI in animal production is the reproduction of high-value specimens. Unfortunately, some domestic species like the bovine show low rates of pronuclei formation after sperm injection, which led to the development of various artificial activation protocols and sperm pre-treatments that are discussed in this article. The impact of ICSI technique on equine breeding programs is considered in detail, since in contrast to other species, its use for elite horse reproduction has increased in recent years. ICSI has also been used to produce genetically modified animals; however, despite numerous attempts in several domestic species, only transgenic pigs have been consistently produced. Finally, the ICSI is a promising tool for genetic rescue of endangered and wild species. In conclusion, while ICSI has become a consistent ART for some species, it needs further development for others. The low results obtained for some domestic species, the high training needed and the equipment required have limited this technique to the production of elite specimens or for research purposes.

Effect of crotamine, a cell-penetrating peptide, on blastocyst production and gene expression of in vitro fertilized bovine embryos.

The present study investigated the effects of crotamine, a cell-penetrating peptide from rattlesnake venom, at different exposure times and concentrations, on both developmental competence and gene expression (ATP1A1, AQP3, GLUT1 and GLUT3) of in vitro fertilized (IVF) bovine embryos. In Experiment 1, presumptive zygotes were exposed to 0.1 μM crotamine for 6, 12 or 24 h and control groups (vehicle and IVF) were included. In Experiment 2, presumptive zygotes were exposed to 0 (vehicle), 0.1, 1 and 10 μM crotamine for 24 h. Additionally, to visualize crotamine uptake, embryos were exposed to rhodamine B-labelled crotamine and subjected to confocal microscopy. In Experiment 1, no difference (P > 0.05) was observed among different exposure times and control groups for cleavage and blastocyst rates and total cells number per blastocyst. Within each exposure time, mRNA levels were similar (P > 0.05) in embryos cultured with or without crotamine. In Experiment 2, concentrations as high as 10 μM crotamine did not affect (P > 0.05) the blastocyst rate. Crotamine at 0.1 and 10 μM did not alter mRNA levels when compared with the control (P > 0.05). Remarkably, only 1 μM crotamine decreased both ATP1A1 and AQP3 expression levels relative to the control group (P < 0.05). Also, it was possible to visualize the intracellular localization of crotamine. These results indicate that crotamine can translocate intact IVF bovine embryos and its application in the culture medium is possible at concentrations from 0.1-10 μM for 6-24 h.

Production of chimeric embryos by aggregation of bovine egfp eight-cell stage blastomeres with two-cell fused and asynchronic embryos

Embryo disaggregation allows the production of two to four identical offspring from a single cow embryo. In addition, embryo complementation has become the technique of choice to demonstrate the totipotency of embryonic stem cells and induced pluripotent stem cells. Therefore, the aim of this study was to generate a new and simple method by aggregation in the well-of-the-well system to direct each single enhanced green fluorescent protein (egfp) eight-cell blastomere derived from bovine in vitro fertilization embryos to the inner cell mass (ICM) of chimeras produced with fused and asynchronic embryos. To this end, the best conditions to generate in vitro fertilization-fused embryos were determined. Then, the fused (F) and nonfused (NF) embryos were aggregated in two distinct conditions: synchronically (S), with both transgenic and F embryos produced on the same day, and asynchronically (AS), with transgenic embryos produced one day before F embryos. The highest fusion and blastocysts rates were obtained with two pulses of 40 V. The 2ASF and 2ASNF groups showed the best number of blastocysts expressing the EGFP protein (48% and 41%, respectively). Furthermore, the 2ASF group induced the highest localization rates of the egfp-expressing blastomere in the ICM (6/13, 46% of ICM transgene-expressing blastocysts). This technique will have great application for multiplication of embryos of high genetic value or transgenic embryos and also with the generation of truly bovine embryonic stem cells and induced pluripotent stem cells.

Replication of somatic micronuclei in bovine enucleated oocytes

BackgroundMicrocell-mediated chromosome transfer (MMCT) was developed to introduce a low number of chromosomes into a host cell. We have designed a novel technique combining part of MMCT with somatic cell nuclear transfer, which consists of injecting a somatic micronucleus into an enucleated oocyte, and inducing its cellular machinery to replicate such micronucleus. It would allow the isolation and manipulation of a single or a low number of somatic chromosomes.MethodsMicronuclei from adult bovine fibroblasts were produced by incubation in 0.05 μg/ml demecolcine for 46 h followed by 2 mg/ml mitomycin for 2 h. Cells were finally treated with 10 μg/ml cytochalasin B for 1 h. In vitro matured bovine oocytes were mechanically enucleated and intracytoplasmatically injected with one somatic micronucleus, which had been previously exposed [Micronucleus- injected (+)] or not [Micronucleus- injected (−)] to a transgene (50 ng/μl pCX-EGFP) during 5 min. Enucleated oocytes [Enucleated (+)] and parthenogenetic [Parthenogenetic (+)] controls were injected into the cytoplasm with less than 10 pl of PVP containing 50 ng/μl pCX-EGFP. A non-injected parthenogenetic control [Parthenogenetic (−)] was also included. Two hours after injection, oocytes and reconstituted embryos were activated by incubation in 5 μM ionomycin for 4 min + 1.9 mM 6-DMAP for 3 h. Cleavage stage and egfp expression were evaluated. DNA replication was confirmed by DAPI staining. On day 2, Micronucleus- injected (−), Parthenogenetic (−) and in vitro fertilized (IVF) embryos were karyotyped. Differences among treatments were determined by Fisher′s exact test (p≤0.05).ResultsAll the experimental groups underwent the first cell divisions. Interestingly, a low number of Micronucleus-injected embryos showed egfp expression. DAPI staining confirmed replication of micronuclei in most of the evaluated embryos. Karyotype analysis revealed that all Micronucleus-injected embryos had fewer than 15 chromosomes per blastomere (from 1 to 13), while none of the IVF and Parthenogenetic controls showed less than 30 chromosomes per spread.ConclusionsWe have developed a new method to replicate somatic micronuclei, by using the replication machinery of the oocyte. This could be a useful tool for making chromosome transfer, which could be previously targeted for transgenesis.

146 HEPARAN SULFATE IS INVOLVED IN NUCLEAR SPERM DECONDENSATION AFTER FERTILIZATION IN BOVINE

Reduced glutathione (GSH) is an endogenous disulfide bond reducer present in mammalian oocytes. It plays a critical role in sperm decondensation following fertilization, disrupting the protamine bonds that sustain the hypercondensed state of sperm DNA. However, disulfide bond reduction needs to be followed by protamine removal to achieve male pronuclear formation. In humans, heparan sulfate (HS) has been shown to exert this role (Romanato et al. 2008 Hum. Reprod. 23, 1145-1450). Although there are no reports in bovine, we recently demonstrated the presence of HS in cow oocytes by indirect immunofluorescence, using a specific anti-HS monoclonal antibody (Canel et al. 2015, Proc. SSR 48th Annual Meeting). Heparinases are known to cleave HS chains selectively, leading to its depolymerization. In the present work, we analysed the possible role of HS as protamine acceptor after fertilization in cattle. To this aim, we directly injected heparinase into the cytoplasm of IVF presumptive zygotes, and analysed its effect on pronuclei formation. Cumulus-oocyte complexes were collected from slaughtered cow ovaries and matured in vitro under standard conditions (Canel et al. 2012 Cell. Div. 7, 23-33). After 21h, IVF was performed following Brackett and Oliphants protocol (1975 Biol. Reprod. 12, 260-274), using frozen-thawed semen from 1 or 2 bulls at a final concentration of 15×106 spermatozoa/mL (5 replicates). After 5h of incubation, cumulus cells and sperm bound to zona pellucidae were removed from presumptive zygotes. Heparinase III solution (H8891, Sigma, St. Louis, MO, USA) was diluted in 50% (vol/vol) polyvinylpyrrolidone solution in PBS-(polyvinylpyrrolidone) at a final concentration of 50 UmL-1 and ~30 pL was mechanically injected into the cytoplasm of each IVF presumptive zygote (Hep group) using a 9-μm inner diameter injection pipette. A group of zygotes was injected with the same volume of 10% polyvinylpyrrolidone (sham), whereas others were not subjected to injection (control). All zygotes were cultured for 16h from the beginning of IVF in SOF medium (Holm et al. 1999 Theriogenology 52, 693-700). For pronuclear formation assessment, presumptive zygotes were permeabilized with 0.2% Triton X-100 for 15min at room temperature, and their DNA content was stained with 5µgmL-1 propidium iodide and observed under an epifluorescence microscope. Zygotes showing 2 pronuclei (PN) were considered as synchronically fertilized, whereas those showing one PN and one condensed sperm head were considered as asynchronically fertilized. Data were analysed by Fishers exact test (P<0.05). The rate of IVF zygotes showing 2 PN was lower for the Hep group (60.3%, n=131) than those from sham (94.1%, n=119) and control groups (98%, n=101), which did not differ between them (P<0.05). In conclusion, our results show for the first time that HS is involved in bull chromatin sperm decondensation and allow us to propose HS as a putative protamine acceptor during male pronucleus formation after IVF in cattle. Given the high frequency of sperm decondensation failure observed in bovine after intracytoplasmic sperm injection, this work provides new insights for the development of novel sperm/egg treatments that might improve intracytoplasmic sperm injection outcomes in cattle.

35 USE OF METAPHASE DONOR CELLS AND ACTIVATION WITH ROSCOVITINE FOR SOMATIC CELL NUCLEAR TRANSFER IN BOVINE

Cloning of domestic species by somatic cell nuclear transfer (SCNT) continues to be inefficient, probably due to an incomplete reprogramming of the reconstituted embryo. The ability of the embryonic cytoplasm to support reprogramming fluctuates within the cell cycle (Egli et al. 2007 Nature 447, 679-85). In this context, we compared the development capability and second polar body (2PB) extrusion of embryos produced by metaphase (M) cells, in comparison with G0/G1 cells, which are commonly used as nuclear donors. Because M cells have 2 sets of chromosomes (in contrast with G0/G1 cells, which have only 1 set), an activation protocol that impedes 2PB extrusion is required to produce reconstituted embryos with the correct ploidy. Therefore, we performed SCNT with M or G0/G1 cells, followed by different activation protocols, and evaluated in vitro development and 2PB extrusion of the reconstituted embryos. Cow oocytes were in vitro matured and enucleated as described by Gambini et al. (2014 PLoS One 14, 9). A group of cells at 70 to 80% confluence was synchronized in M stage using 0.05μgmL-1 demecolcine for 3 to 4h and used as nuclear donors for SCNT (M group). Another group of cells was induced into quiescence by serum starvation for 3 to 4 days before SCNT (G0/G1 group). For activation, reconstituted embryos were treated with 5µM ionomycin (Io) for 4min followed by 5-h incubation in 50μM roscovitine for M group, or in 50μM roscovitine and 5μgmL-1 cytochalasin B for G0/G1 group. Parthenogenetic controls were activated with Io followed by 50μM roscovitine alone (ROSCO) or with 5μgmL-1 cytochalasin B (ROSCO/CB). Hoescht 33342 staining was performed 16h post-Io to evaluate 2PB extrusion. Other activated oocytes were cultured in SOFaa medium and rates of cleavage, morulas, and blastocysts were evaluated at Days 2, 5 and 7 of in vitro development, respectively. Data were analysed by Fishers exact test (P<0.05). Rates of 2PB extrusion were 72.72 (n=33), 65.63 (n=32), 80 (n=15), and 42.86 (n=14) for M, G0/G1, ROSCO, and ROSCO/CB, respectively. Results of in vitro development are shown in Table 1. In conclusion, somatic M cells can be used as donors to produce cloned embryos. The M and G0/G1 groups were able to induce cloned blastocysts, even though rates did not differed statistically from controls groups (ROSCO and ROSCO/CB). The M group was as effective as G0/G1. Although further analysis is required to establish the quality of the embryos, our results are encouraging for use in SCNT.