Batchwise assessment of porcine embryos for cryotolerance

The viability or developmental ability of porcine embryos after slow-freezing and thawing differs depending on the embryonic stage or the batch, which is defined as a group of embryos obtained from one donor at one time. We froze porcine blastocysts in batches and assessed their cryotolerance by using two expanded blastocysts (EBs) as samples to predict the developmental potential of other blastocysts from the same batch at different stages. Two EBs from the same batch that had been separately frozen were thawed and cultured in vitro for 48 h to examine their in vitro ability to develop to the hatched blastocyst stage. Thereafter, each batch was assigned to Grade A, B, or C according to the viability of the two EBs, i.e., 100% viability (2/2: number of hatched blastocysts/number of cultured EBs) was Grade A; 50% (1/2) was Grade B; and 0% (0/2) was Grade C. The viability of EBs after freeze-thawing and in vitro culture varied depending on the batch and was lower (31.0+/-10.2%, mean+/-S.E.M.; P<0.01) than that of unfrozen controls (96.8+/-2.3%). The viability of frozen-thawed hatched blastocysts (HBs) did not differ among the graded batches, but the blastocyst diameter decreased (from 409 to 326 microm) as the batch grade decreased (from A to C). When both EBs and HBs from batches of the same grade were transferred to recipients (average 11.7 EBs and 16.0 HBs per recipient), the rate of pregnancy and farrowing in recipients decreased (from 77.8% to 0%) and the number of piglets obtained decreased (from 15.3 to 0) as the batch grade decreased. However, when not only frozen-thawed EBs from Grade B or C batches, but also four helper embryos at the morula to early blastocyst stage (which were expected to support the pregnancy) were transferred, the number of piglets generated was higher from EBs from Grade B batches (16.0) than from EBs from Grade C batches (0.0). When frozen-thawed HBs and helper embryos were transferred, the number of piglets generated was higher from HBs from Grade B batches (12.7) than that from HBs from Grade C batches (1.9). After slow-freezing of porcine blastocysts, their rate of survival to the piglet stage differs batchwise, and in vitro viability assessment of sample EBs after freezing and thawing may help in assessing the post-freezing and post-thawing developmental potential of other blastocysts at different stages from the same batch.     

In vitro production of bovine embryos using sex-sorted sperm

The objective of this study was to investigate the suitability of sex-sorted sperm for producing viable in vitro embryos for subsequent transfer into recipient cows and heifers on commercial dairy farms. From August 2002 to June 2003, ovaries were collected from 104 producer-nominated Holstein donor cows on seven Wisconsin farms via colpotomy or at slaughter. Oocytes (N=3526) were aspirated from these ovaries, fertilized 22+/-0.2h later, and cultured to the morula or blastocyst stage. The fluorescence-activated cell sorting ("Beltsville") approach was used to produce (primarily) X-bearing sperm from the ejaculates of three young Holstein sires, and 365 transferable embryos were produced. On average, 3.6+/-0.3 (means+/-S.E.M.) transferable embryos were produced per donor, including 1.4+/-0.2 (Grade 1), 1.5+/-0.2 (Grade 2), and 0.7+/-0.1 (Grade 3) embryos. Number of usable oocytes per donor (33.9+/-3.3) and percent cleavage (51.1+/-1.9) were significant predictors of the number of blastocysts that developed. Mean conception rates for the resulting in vitro embryos were 34.2+/-1.6% in yearling heifer recipients and 18.2+/-0.7% in lactating cow recipients. Additional oocytes (N=3312) from ovaries of anonymous donors (N unknown) collected at a commercial abattoir were fertilized using unsorted sperm, and the percentage of these that developed to blastocyst stage (20.1+/-2.9) was greater (P<0.05) than the corresponding percentage (12.2+/-2.3) achieved with sex-sorted sperm using oocytes (N=1577) from the same source. In summary, we inferred that in vitro embryo production may be a promising application of sex-sorted sperm in dairy cattle breeding, but that the biological causes of impaired embryo development in vitro and compromised conception rates of transferred embryos should be further investigated.     

Cloning of bovine embryos by multiple nuclear transfer

The in vitro development of multiple generation bovine nuclear transferred embryos to blastocysts and their survival ability after freezing and thawing were examined. Parent donor embryos which had 20 to 50 cells were recovered from superovulated cows. Follicular oocytes matured in vitro were used as recipient oocytes. The recipient oocytes enucleated at 22 to 24 h after the onset of maturation were preactivated at 33 h. Enucleated oocytes with a donor blastomere were fused 9 h after activation by an electric stimulus and the fused oocytes were cultured in vitro (first generation). Reconstituted oocytes that had developed to the 8- to 16-cell stage 3 to 4 d after fusion were used as donor embryos for the next generation. Recloning procedures were performed twice (second and third generations). The proportion of recipient oocytes successfully fused with a blastomere increased with the cycle of nuclear transfer. Eighty to 86% of fused oocytes developed to the 2-cell stage and there was no significant difference with the generation. The proportion of reconstituted embryos receiving blastomeres derived from first generation embryos had higher developmental ability in vitro, than those derived from other generations (43 vs 31% for 8 to 16-cell stage, 37 vs 20 and 21% for blastocyst stage). The number of cloned blastocysts increased with repeated nuclear transfer (once: 6.2 +/- 4.3, twice: 19.8 +/- 9.2 and three times: 30.0 +/- 14.7) but varied greatly with each parent donor embryo. The in vitro viability of cloned blastocysts after freezing and thawing (59%) was low but not significantly different from that obtained for in vitro fertilized blastocysts (72%). After transfer of either fresh or frozen-thawed cloned blastocysts to 21 recipients, 10 of them were pregnant on Day 60. Four and 3 offspring were produced from 20 fresh and 14 frozen-thawed blastocysts,respectively.     

Culture of zygotes increases TRP53 [corrected] expression in B6 mouse embryos, which reduces embryo viability

The expression of TRP53 in blastocysts that had been cultured from the zygote stage in vitro for 90 h was compared with that in blastocysts collected from the uterus in C57BL6 (B6) and in F1 hybrid (B6CBF1) strain mice. In both strains, there was little TRP53 detected in blastocysts collected from the uterus. There was some increased expression in cultured embryos from B6CBF1 mice and marked increased expression in cultured B6 blastocysts. In cultured B6 embryos, there was obvious accumulation of TRP53 within the nuclear region of embryonic cells. Cultured B6 zygotes had significantly poorer rates of blastocyst formation and of capacity to undergo implantation or form viable fetuses than cultured zygotes from B6CBF1 mice or B6 blastocysts collected from the uterus. Trp53-/- zygotes (B6 background) were significantly more likely to form blastocysts than sibling wild-type embryos, with Trp53+/- embryos having an intermediate level of viability (P<0.01). On transfer of blastocysts to recipient females, Trp53-/- blastocysts were more likely to form viable fetuses than wild-type or heterozygous sibling blastocysts when the embryos resulted from culture of zygotes (P<0.001). This shift in viability did not occur when embryos were only subjected to 24 h of culture from the compacted embryo stage. Culture in vitro in the B6 strain caused a marked increase in the expression and nuclear accumulation of TRP53. This expression was a significant cause of the loss of viability that occurs on culture of zygotes from this strain in vitro.     

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.     

Effect of polyethylene glycol and dimethyl sulfoxide on the fusion of bovine nuclear transfer using mammary gland epithelial cells

The effects of polyethylene glycol and dimethyl sulfoxide (PEG/DMSO) treatment of donor cells on the fusion and subsequent development of bovine nuclear transfer embryos using mammary gland epithelial (MGE) cells before electrofusion (fresh MGE cells) was studied. The same study was conducted on those cells that were frozen and stored in liquid nitrogen, and then thawed (frozen-thawed MGE cells). Experiment 1 showed that the exposure time and pH of PEG/DMSO solution affected the fusion of nuclear transfer, and that a higher fusion rate was obtained when fresh MGE cells were exposed to PEG/DMSO solution at pH 8.0 for 5 min. In Experiment 2, the proportion of fused oocytes with fresh PEG/DMSO-treated cells (70 +/- 6%) was significantly higher than that with non-treated cells (50 +/- 13%, p < 0.05). The same tendency was observed when frozen-thawed cells as donor nuclei were used (48 +/- 6% vs. 34 +/- 12%, p < 0.05). In addition, PEG/DMSO treatment has neither harmful nor beneficial effects on the cleavage and development of the blastocyst stage of reconstructed embryos (p > 0.05). The fusion and cleavage rates of frozen-thawed cells were significantly lower than those of fresh cells (p < 0.05). After 10 blastocysts, derived from fresh PEG/DMSO-treated cells, were transferred to five recipient heifers, one live female calf was obtained. Experiment 3 showed that PEG/DMSO treatment reduced the viability of both fresh and frozen-thawed MGE cells (p < 0.05). We conclude that the PEG/DMSO treatment of fresh MGE cells, as well as the frozen-thawed cells, before electrofusion has a positive effect on the fusion of nuclear transfer without decreasing the in vitro development of reconstructed embryos.     

Characteristics of the cell membrane fluidity, actin fibers, and mitochondrial dysfunctions of frozen-thawed two-cell mouse embryos

Physical and chemical alterations caused by the freezing and thawing and their effects on survivals/developments in vitro were investigated. Of a total of 452 two-cell mouse embryos, the overall survival rate of the frozen-thawed embryos was 76.1% (344/452). The blastocyst formation of the frozen-thawed embryos was 32.6% (44/136) compared to 74.5% (117/157) in the fresh embryos (P<0.05). The total number of cells in a blastocyst also decreased from 96.0 +/- 19.0 (n=26) in the fresh embryos to 42.0 +/- 11 .34 (n=30) in the frozen-thawed embryos (P<0.05). Fluorescence recovery after photobleaching (FRAP) measurement revealed about 5-fold decrease in the cell membrane fluidity with a characteristic time constant (tau) of 1.46 +/- 0.13 sec (n=5) in the frozen-thawed embryos as opposed to 0.28 +/- 0.04 sec (n=5) in the fresh embryos (P<0.05). The relative amount of H(2)O(2) in an embryo as quantified by the fluorescence intensity of 2',7'-dichlorofluorescein (DCF) showed 62.8 +/- 23.5 (n=24) and 34.2 +/- 14.5 (n=20) in the frozen-thawed embryos and in the fresh embryos, respectively (P<0.05). The distribution of actin filaments in the frozen-thawed embryos revealed an uneven distribution, particularly discontinuities at the "actin band," which contrasted to an even distribution shown in the fresh embryos. Mitochondrial staining by Rhodamine 123 showed that there was no significant difference between the two treatments in the number and in the distribution of viable mitochondria, but a marked aggregation was seen in the arrested embryos. No Annexin V binding was detected in two-cell or four-cell embryos while the binding was positive in the arrested embryos. The mitochondrial membrane potential measured by a membrane potential-sensitive fluorescent probe 5,5',6,6'-tetrachloro-1,1',3,3'-tetraethylbenzimidazol- carbocyanine iodide (JC-1) revealed a marked depolarization in the frozen-thawed embryos. Finally, terminal deoxynucleotidyl transferase (TdT)-mediated dUTP-digoxigenin nick end-labeling (TUNEL) was employed to quantify the DNA fragmentation. In 75.0% cells of blastocysts (n=24) in the frozen-thawed embryos, the DNA fragmentation was detected as opposed to 37.0% in the fresh embryos (n=20) (P<0.05). Taken together, it is proposed that during the cryopreservation, two-cell mouse embryos are subjected to physical and chemical alterations, including destruction of the cell membrane integrity, redistribution of actin fibers, mitochondrial depolarizations, and increased reactive oxygen species (ROS) productions, which then may trigger the apoptotic cascade leading to a decrease in the survival rate and in the developmental rate of the embryos.     

Viability of frozen-thawed mouse blastocysts with different number of dead cells

Dead cells in frozen-thawed mouse blastocysts were detected by the DAPI-fluorescence test, and the relationship between the number of dead cells in the embryos and their in vitro development was examined. Morphologically good embryos had significantly fewer dead cells and gave a higher percentage of embryos that developed in vitro than the fair and poor embryos. Viability of the good embryos was reduced as the number of dead cells increased (P<0.001). Embryos with more than 5 dead cells had a very low viability of 7.1%. Embryos which showed re-expansion of the blastocoele after the removal of DMSO had significantly fewer (P<0.001) dead cells than those which remained contracted. The percentage of the re-expanded and contracted embryos that developed in vitro was 97.5 and 51.8%, respectively. These results indicate that number of dead cells influenced the in vitro development of frozen-thawed mouse blastocysts.     

Effect of lecithin on in vitro and in vivo survival of in vitro produced bovine blastocysts after cryopreservation

The use of soybean lecithin in an glycerol-based solution for slow freezing of in vitro matured, fertilized and cultured (IVMFC) bovine embryos was examined. Embryos were developed in vitro in INRA Menezo's B2 medium supplemented with 10% fetal calf serum (FCS) on Vero cells monolayers. Day 7 blastocysts were frozen in a two-step protocol consisting of exposure to 5% glycerol and 9% glycerol containing 0.2 M sucrose in F1 medium + 20% FCS. Soybean lecithin was either added or not to the freezing solutions at a final concentration of 0.1% (w/v). In Experiment 1, blastocysts were equilibrated in cryoprotectant solutions without cooling. Cryoprotectant was diluted from embryos with 0.5 M and 0.2 M sucrose. The percentages of fully expanded and hatched blastocysts treated with or without lecithin after 24 and 48 h in culture were not significantly different (100 versus 100% and 93.3 versus 100%, respectively). In Experiment 2, the in vitro survival of frozen-thawed IVMFC blastocysts was compared when cryoprotectant solutions were either supplemented or not with lecithin. No significant effect of lecithin was found on the ability of frozen-thawed blastocysts to re-expand after 48 h in culture (65.6 and 54.2%, respectively). However, the post-thaw hatching rate of embryos cryopreserved in the presence of 0.1% lecithin was significantly higher after 72 h in culture (52 and 31.8%, respectively). In Experiment 3, the ability of frozen-thawed IVMFC blastocysts to establish pregnancy following single embryo transfer was determined. Transfers of 58 and 66 frozen-thawed embryos cryopreserved with or without lecithin resulted in 6 and 10 (10.3 and 15.1%, respectively) confirmed pregnancies at Day 60. Addition of lecithin to cryoprotectants did not improve the in vivo development rate of cryopreserved IVMFC bovine blastocysts.     

The effect of partial weaning on the rebreeding performance of primiparous Hereford heifers

One or two 6–7 or 9–10 day old blastocysts were transferred to 39 pure-bred or cross-bred Charolais heifer recipients.The embryos were collected after slaughter of the donors. An insemination catheter (Cassou gun) was used to transfer the blastocysts through the cervix into the uterus. Placement was approximately 5cm beyond the body of the uterus.Pregnancy was determined by slaughter of the recipients on the 45th day of gestation. Nineteen of the 39 recipients were pregnant. The survival rate of embryos transferred was as follows: 6–7 day old embryos: 7 out of 23 (30.4%); 9–10 day old embryos: 18 out of 36 (50%). All embryos: 25 out of 59 (42.3%). The difference between the 6–7 day old embryos and the 9–10 day old embryos was not significant. Twelve of the 20 recipients receiving a bilateral transfer were pregnant, and 6 were carrying twins. This is a satisfactory technique for use in field conditions for the transfer of bovine blastocysts.     

Pregnancies after in-vitro fertilization of cow follicular oocytes, their incubation in rabbit oviduct and their transfer to the cow uterus

Cow embryos fertilized in vitro (1-8-cell) (n = 113) were transferred surgically to the ligated oviduct of pseudopregnant female rabbits (31 +/- 4 h after 75 i.u. hCG). Rabbits were killed 99 +/- 5 h later and 67 embryos were recovered: 45 (67%) had cleaved at least once, 15 had reached the morula stage and 2 blastocysts were obtained. Transfer of cleaved embryos (2-8-cell) led to a high recovery rate (84%) compared to 39% for one-cell embryos. Of the embryos incubated for more than 99 h in the rabbit oviduct, 41% were at the morula stage. Embryos incubated in vivo (n = 21) (8-cell to blastocyst) were transferred to the uterus of 14 synchronized recipient heifers by a surgical (N = 5) or a non-surgical (N = 9) procedure: 6 pregnancies resulted (4 from the non-surgical procedures). In addition, 27 (2-8-cell) cow embryos developed in vitro were transferred to the oviduct of synchronized heifers by a paralumbar surgical approach on a standing animal, but no pregnancies resulted. It is therefore concluded that (1) the rabbit oviduct can be used to obtain cow eggs at an embryonic stage sufficiently advanced to permit transfer to the uterus of a synchronized recipient; and (2) the pregnancy rate after in-vitro fertilization and incubation in the rabbit oviduct are similar to results with fertilization in vivo.     

Embryo survival and recipient pregnancy rates after transfer of fresh or vitrified,in vivo or in vitro produced ovine blastocysts

The aim of this study was to assess the effect of production system and of cryopreservation of ovine embryos on their viability when transferred to recipients. The experimental design was an unbalanced 2 x 2 factorial design of two embryo production systems (in vivo versus in vitro) and two embryo preservation conditions prior to transfer (transferred fresh versus transferred after vitrification/warming). For the production of blastocysts in vivo, crossbred donor ewes (n=30) were synchronised using a 13-day intravaginal progestagen pessary. Ewes received 1500 IU equine chorionic gonadotropin (eCG) 2 days before pessary withdrawal, and were mated 2 days after pessary withdrawal and embryos were recovered surgically (6 days after mating). Blastocysts were produced in vitro (IVP) using standard techniques. Recipients (n=95) were synchronised using a progestagen pessary and received 500 IU eCG at pessary removal and were randomly assigned to receive (two per recipient) in vivo fresh (n=10), in vivo vitrified (n=10), in vitro fresh (n=35) or in vitro vitrified (n=40) blastocysts. Recipients were slaughtered at day 42 of gestation and foetuses recovered. Pregnancy and embryo survival rates were recorded and analysed using CATMOD procedures. Foetal weights and crown-rump lengths were recorded and analysed using generalised linear model (GLM) procedures. There were no statistically significant interactions between the effects of embryo production system and preservation status at transfer on pregnancy rate and embryo survival. The pregnancy rate following transfer of fresh IVP blastocysts was lower (P<0.07) than that of in vivo embryos (54.3% versus 90.0%, respectively). Vitrification resulted in a decrease in pregnancy rate, the effect being more pronounced in the case of IVP embryos (54.3-5.0%, P<0.001) compared with in vivo embryos (90.0-50.0%), although the absolute change was similar (49.3% versus 40.0%). Transfer of fresh IVP blastocysts resulted in a higher proportion of single (78.9% versus 33.3%) and lower proportion of twin (21.1% versus 66.7%) pregnancies than those produced in vivo. This was reflected in a significant difference in embryo survival rate (fresh: 32.8% versus 75.0%, P<0.01; vitrified: 2.5% versus 35.0%, P<0.001, for IVP and in vivo blastocysts, respectively). Similarly, all pregnancies resulting from the transfer of vitrified/warmed IVP blastocysts were single pregnancies, while 40% of those from vitrified/warmed in vivo blastocysts were twin pregnancies; this was reflected in an embryo survival rate of 35.0% versus 75.0%, respectively. There was a significant effect (P=0.0184) of litter size on foetal weight but not on foetal length (P=0.3304). Foetuses derived from the fresh transfer of IVP blastocysts were heavier (6.4+/-0.2g versus 5.8+/-0.2g, respectively, P<0.05) and longer (5.2+/-0.1cm versus 4.8+/-0.1cm, respectively, P<0.01) than those derived from fresh in vivo blastocysts. There was no difference in these parameters as a consequence of vitrification of IVP embryos. However, in vivo blastocysts subjected to vitrification resulted in heavier (6.6+/-0.3g versus 5.8+/-0.2g, respectively, P=0.055) and longer (5.2+/-0.1cm versus 4.8+/-0.1cm, respectively, P<0.05) foetuses than their counterparts transferred fresh.     

In vitro development up to hatching of bovine in vitro-matured and fertilized oocytes with or without support from somatic cells

To verify the importance of somatic cells upon in vitro embryo development, in vitro-matured (IVM) and -fertilized (IVF) bovine oocytes were cultured in TCM 199 supplemented with estrous cow serum (10% v/v) and 0.25 mM sodium pyruvate (ECSTCM) under the following treatments: 1) ECSTCM alone; 2) together with bovine oviduct epithelial cells (BOEC); 3) with cumulus cells (CC); 4) in fresh BOEC conditioned ECSTCM; or 5) in frozen-thawed BOEC conditioned ECSTCM. Culturing zygotes encased in cumulus cells significantly reduced the cleavage rate (P<0.05). There was no difference between culture systems in the proportions of embryo development through the 8-cell stage (P=0.42) up to the morula/blastocyst stages (P=0.50) at Day 7 post insemination. However, co-culture with BOEC yielded the highest percentage (21.2% of zygotes; P<0.05) of quality Grade-1 and Grade-2 embryos with the number of blastomeres per embryo (114.4) comparable to that of 7-day-old in vivo-developed embryos of similar grades (102.5), and higher (P<0.05) than those of the other treatments. The ratio of blastocysts to total morulae/blastocysts obtained from frozen-thawed conditioned medium was lower (P<0.05) than that from ECSTCM or after co-culture with BOEC at Day 7 post insemination. On average, 7.5 to 17.5% of the zygotes developed to blastocyst, expanded blastocyst and hatched blastocyst stages by Day 10 post insemination, depending upon the culture system. The difference between treatments, however, was not significant (P=0.68). The results indicate that chronological development up to hatching of bovine IVM-IVF embryos is not favored by somatic cells; however, the presence of viable oviduct epithelial cells in culture significantly improves the quality of 7-day-old embryos.     

Production of cloned calves following nuclear transfer with cultured adult mural granulosa cells

Adult somatic cell nuclear transfer was used to determine the totipotent potential of cultured mural granulosa cells, obtained from a Friesian dairy cow of high genetic merit. Nuclei were exposed to oocyte cytoplasm for prolonged periods by electrically fusing quiescent cultured cells to enucleated metaphase II cytoplasts 4-6 h before activation (fusion before activation [FBA] treatment). Additionally, some first-generation morulae were recloned by fusing blastomeres to S-phase cytoplasts. A significantly higher proportion of fused embryos developed in vitro to grade 1-2 blastocysts on Day 7 with FBA (27.5 +/- 2.5%) than with recloning (13.0 +/- 3.6%; p < 0. 05). After the transfer of 100 blastocysts from the FBA treatment, survival rates on Days 60, 100, 180, and term were 45%, 21%, 17%, and 10%, respectively. Ten heifer calves were delivered by elective cesarean section; all have survived. After the transfer of 16 recloned blastocysts, embryo survival on Day 60 was 38%; however, no fetuses survived to Day 100. DNA analyses confirmed that the calves are all genetically identical to the donor cow. It is suggested that the losses throughout gestation may in part be due to placental dysfunction at specific stages. The next advance in this technology will be to introduce specific genetic modifications of biomedical or agricultural interest.     

The effect of vitamins during maturation of caprine oocytes on subsequent developmental potential in vitro

Only a small proportion of goat oocytes selected for in vitro oocyte maturation (IVM) can successfully complete cytoplasmic maturation and support embryonic development. To produce goat blastocysts more efficiently in vitro, it is necessary to identify factors required during oocyte maturation. The objective of this study was to determine the role of vitamins during maturation of caprine oocytes in semi-defined medium on subsequent developmental capacity in vitro. Cumulus oocyte complexes (COCs) collected from a local abattoir were matured in synthetic oviductal fluid (SOF) medium supplemented with BSA, LH, FSH, and EGF in the presence or absence of MEM vitamins for 24 h. The COCs were co-incubated with frozen-thawed sperm in Bracket and Oliphant fertilization medium for 18-22 h. Embryos were cultured in G1.2 medium for 72 h followed by culture in G2.2 medium for an additional 72 h. Addition of vitamins significantly increased (P<0.05) overall blastocyst development (16.4+/-1.2% versus 12.3+/-1.1%), and tended to increase (P<0.06) the percentage of cleaved embryos (61.4+/-3.0% versus 52.7+/-2.6%). Addition of MEM vitamins to SOF maturation medium significantly increased (P<0.05) mean blastocyst cell number compared with control medium (107.7+/-6.0 versus 85.1+/-6.3). Hatched blastocysts tended to have increased (P<0.06) cell numbers in the vitamin-treated group (150.5+/-8.4 versus 123.4+/-8.8). These results suggest that addition of vitamins during oocyte maturation is beneficial for subsequent blastocyst development and viability.     

Developmental ability of bovine embryos after nuclear transfer based on the nuclear source: in vivo versus in vitro

Bovine nuclear transfer embryos reconsitituted from in vitro-matured recipient oocyte cytoplasm and different sources of donor nuclei (in vivo, in vitro-produced or frozen-thawed) were evaluated for their ability to develop in vitro. Their cleavage rate and blastocyst formation are compared with those of control IVF embryos derived from the same batches of in vitro-matured oocytes that were used for nuclear transfer and were co-cultured under the same conditions on bovine oviducal epithelial cell monolayers for 7 d. Using fresh donor morulae as the source of nuclei resulted in 30.2% blastocyst formation (150 497 ), which was similar to that of control IVM-IVF embryos (33.8% blastocysts, 222 657 ). When IVF embryos were used as the source of nuclei for cloning, a slightly lower blastocyst formation rate (22.6%, 41 181 ) was obtained but not significantly different from that using fresh donor morulae. Nuclear transfer embryos derived from vitrified donor embryos showed poor development in vitro (7.1%, 11 154 ). No difference in morphology or cell number was observed after 7 d of co-culture between blastocysts derived from nuclear transfer or control IVF embryos. The viability of 34 in vitro-developed nuclear transfer blastocysts was tested in vivo and resulted in the birth of 11 live calves (32.3%).     

Non-surgical embryo transfer in cattle embryo-recipient interactions

Results from 2286 non-surgical embryo transfers were analyzed to find relationships between embryo factors and recipient factors that affect pregnancy. Pregnancy rates from morulae (44%) and advanced morulae (53%) were reduced (P < .05) when compared to early blastocysts (65%), blastocysts (65%), blastocysts (66%) and advanced blastocysts (64%). Pregnancy rates from good quality Grade 1 embryos (64%) were higher (P < .05) than from Grade 2 (45%) or Grade 3 (33%) embryos. Pregnancy rates related to synchronization of estrus between donor and recipients are: -36 hrs. (before donor) (59%), -24 hrs. (61%), -12 hrs. (68%), 0 hr. (59%), +12 hrs. (61%), +24 hrs. (58%) and +36 hrs. (41%). Differences in pregnancy rate were significant for -12 hrs. (P < .01) and +36 hrs. (P < .01) recipients. Overall pregnancy rates in recipients on day 5 (48%), 5 1/2 (50%) and 6 (53%) were reduced (P < .02) when compared to day 6 1/2 (62%), 7 (63%), and 7 1/2 (66%) and 8 (62%). Pregnancy rates within each embryo stage of development were not related to synchronization with the donor cow (-36 hrs. to +36 hrs.) or the day of the recipient cycle (day 5 to 8).