Effect of donor stimulation, frozen semen and heparin treatment on the efficiency of in vitro embryo production in goats

Investigations on in vitro embryo production in goats in comparison with other domestic species, especially cattle, have been the subject of few reports despite their usefulness for both basic research and commercial application. The objectives of this study were to compare the efficiency of IVP in goats using immature follicular oocytes recovered from FSH-primed and control goats. After IVM, oocytes were fertilized with fresh or frozen-thawed semen capacitated with or without heparin. Mature oocytes were fertilized in vitro with fresh and frozen-thawed sperm of a single buck. Sperm preparation included swim-up separation and heparin treatment (50 micrograms/ml of sperm suspension for 45 min) before spermatozoa were added to oocytes in TALP-IVF. After IVF, the zygotes were cultured for 24h and cleaved embryos were further cultured with goat oviduct epithelial cells or transferred to synchronized recipients. Mean number of oocytes recovered from FSH-primed goats (24.5 +/- 8.6) was significantly higher (P < 0.01; t test) in comparison to control does (14.7 +/- 4.7). Irrespective of fresh or frozen semen, no differences were observed in blastocyst yield when sperm was treated with heparin. However, the highest cleavage rate (99/126; 79.4%) as well as blastocyst yield (47/126; 37.3%) was obtained after IVF with fresh sperm capacitated without heparin. Contrary to fresh sperm, heparin treatment of frozen-thawed sperm significantly improved (P < 0.01) embryo cleavage. No differences between in vivo developmental competence of embryos related to sperm origin were found after transferring into recipients. Overall, more than 60% of the recipients became pregnant and 20% of all transferred embryos survived delivering 13 healthy kids. Our caprine IVP system allows obtaining embryos with developmental competence comparable to bovine IVP.     

Pregnancy rate and birth rate of calves from a large-scale IVF program using reverse-sorted semen in Bos indicus, Bos indicus-taurus, and Bos taurus cattle

Obtaining sexed sperm from previously frozen doses (reverse-sorted semen [RSS]) provides an important advantage because of the possibility of using the semen of bulls with desired genetic attributes that have died or have become infertile but from whom frozen semen is available. We report the efficiency of RSS on the pregnancy rate and birth rate of calves in a large-scale program using ovum pick-up and in vitro embryo production (IVEP) from Bos indicus, Bos indicus-taurus, and Bos taurus cattle. From 645 ovum pick-up procedures (Holstein, Gir, and Nelore), 9438 viable oocytes were recovered. A dose of frozen semen (Holstein, Nelore, Brahman, Gir, and Braford) was thawed, and the sperm were sex-sorted and cooled for use in IVF. Additionally, IVF with sperm from three Holstein bulls with freeze-thawed, sex-sorted (RSS) or sex-sorted, freeze-thawed (control) was tested. A total of 2729 embryos were produced, exhibiting a mean blastocyst rate of 29%. Heifers and cows selected for adequate body condition, estrus, and health received 2404 embryos, and 60 days later, a 41% average pregnancy rate was observed. A total of 966 calves were born, and 910 were of a predetermined sex, with an average of 94% accuracy in determining the sex. Despite the lower blastocyst rate with freeze-thawed, sex-sorted semen compared with sex-sorted semen, (P < 0.05), the pregnancy rate (bull I, 45% vs. 40%; II, 35% vs. 50%; and III, 47% vs. 48% for RSS and control, respectively; P > 0.05) and sex-sorted efficiency (bull I, 93% vs. 98%; II, 96% vs. 94%; and III, 96% vs. 97% for RSS and control, respectively; P > 0.05) were similar for each of the three bulls regardless of the sperm type used in the IVF. The sexing of previously frozen semen, associated with IVEP, produces viable embryos with a pregnancy rate of up to 40%, and calves of the desired sex are born even if the paternal bull has acquired some infertility, died, or is located a long distance from the sexing laboratory. Furthermore, these data show the feasibility of the process even when used in a large-scale IVEP program.     

Can bovine in vitro-matured oocytes selectively process X- or Y-sorted sperm differentially?

It has been reported that the mammalian female could have a preconceptual influence on the sex of her offspring, and it has been hypothesized that this influence could go some way toward accounting for the reported lower fertility following insemination with sex-sorted sperm. To test whether in vitro matured oocytes are able to select X- or Y-bearing spermatozoa following in vitro fertilization (IVF), we fertilized in vitro 1788 oocytes with X-sorted semen, Y-sorted semen, a mix of X- and Y-sorted semen, and unsorted semen from the same bull, and cultured until Day 9. Fertility was assessed by recording cleavage rate at 48 h postinsemination (hpi) and blastocyst development until Day 9. Embryos were sexed at the two- to four-cell stage and the blastocyst stage. The proportion of zygotes cleaving at 48 hpi was not different between X- and Y-sorted groups and the mix of X- and Y-sorted semen group; however, all were significantly lower than the unsorted group (P < 0.001). Blastocyst yield on Day 6 was significantly higher (P < or = 0.01) in the control group compared with the rest of the groups. Cumulative blastocyst yields on Days 7, 8, and 9 were also significantly higher (P < or = 0.01) in the unsorted group compared with the sorted groups. The proportion of female and male two- to four-cell embryos obtained following IVF with X- and Y-sorted sperm was 88% and 89%, respectively and the sex ratio at the two- to four-cell stage was not different following IVF with unsorted or sorted/recombined sperm (56.9% males vs. 57% males, respectively). At the blastocyst stage, similar percentages were obtained. In conclusion, the differences in cleavage and blastocyst development using sorted versus unsorted sperm are not due to the oocyte preferentially selecting sperm of one sex over another, but are more likely due to spermatic damage caused by the sorting procedure.     

In vitro fertilization with flow-cytometrically-sorted bovine sperm

An attractive feature of IVF is that fewer sexed sperm are needed than for artificial insemination. However, sperm sexed by flow cytometry/cell sorting are probably pre-capacitated, necessitating modifications to standard IVF systems for optimal success. With current procedures, the percentages of oocytes fertilized with sorted and unsorted frozen bovine sperm are similar, and events during the first cell cycle are timed similarly for sorted and unsorted sperm. However, in most cases, blastocyst production with sorted sperm was approximately 70% of controls produced with unsorted sperm. In some early studies, there appeared to be an unexplained delay of about half a day in blastocyst development. Nevertheless, some dozens of apparently normal calves, pre-sexed with 90% accuracy, have resulted from frozen embryos produced via IVF with sexed sperm. IVF also has proven useful as a bioassay for improving sperm-sorting procedures such as determining potential detrimental effects of laser power. It is likely that use of IVF in cattle breeding programs will increase considerably when sexed, frozen sperm become commercially available.     

Birth of twins after in vitro fertilization with flow-cytometric sorted buffalo (Bubalus bubalis) sperm

Flow-cytometric sorting of mammalian sperm for production of offspring with the desired sex is one of the most important new biotechnologies available for livestock industry. The objectives of this study were: (i) to sort the sperm into X- and Y-enriched populations and (ii) use the sorted sperm for in vitro fertilization (IVF) to produce sex-preselected embryo and offspring. The results revealed that the accuracy of sorted X- and Y-sperm was 94% and 89%, respectively. There was a decrease in blastocyst development rate in IVF with sorted sperm comparing to unsorted sperm, but the percentage of blastocysts on D6-D8 was not statistically different. Transplantation of the presumed X-embryos derived from IVF into a recipient resulted in the birth of female twins. These results indicated the feasibility of sperm sorting by flow cytometry and in vitro production of sex-preselected embryos and offspring in buffalo.     

Superovulation and embryo transfer in Holstein cattle using sexed sperm

The use of sexed bull sperm in multiple ovulation and embryo transfer (MOET) programs for Holsteins was evaluated for (1) heifers housed at a commercial embryo transfer (ET) facility (Experiments 1 and 2), and (2) heifers and cows on dairy farms (Experiment 3). In Experiment 1, superstimulated heifers were inseminated with 5 × 10⁶ sexed (X-sorted; n = 5) or unsexed (n = 5) frozen-thawed sperm from one bull at 12 and 24 h after estrus detection. No difference was observed in the rates of transferable embryos (53.4% vs 68.1%), degenerate embryos (24.8% vs 26.6%) and unfertilized ova (21.8% vs 5.3%) between sexed and unsexed sperm, respectively, except for the percent of female transferable embryos diagnosed by embryo sexing (100% vs 49.3%, P < 0.0001). In Experiment 2, donors were inseminated twice with 5 × 10⁶ sexed unfrozen sperm (n = 10) or sexed frozen-thawed sperm (n = 9). Embryo production rates for both treatments were similar to that observed on a commercial ET facility using unsexed sperm. Pregnancy rates for frozen-thawed embryos were similar for sexed and unsexed sperm (70.4% vs 72.4%, respectively). In Experiment 3, 99 flushes were conducted using sexed frozen-thawed sperm from nine bulls but an overall statistical analysis was not completed because the use of bulls was not balanced. However, for one bull with balanced usage, the rate of transferable embryos was higher in heifers than in cows (P < 0.05) inseminated twice with 5 × 10⁶ sperm/dose (10 × 10⁶ total). We concluded that the use of sexed frozen-thawed sperm (≥90% X-sperm biased and 10 × 10⁶ total sperm) may be economically viable for commercial MOET programs in Holstein heifers.     

Bovine and buffalo in vitro embryo production using oocytes derived from abattoir ovaries or collected by transvaginal follicle aspiration

This study was undertaken in order to evaluate the effect of oocyte source (live animals and abattoir ovaries) on subsequent embryo development in buffalo (Bubalus bubalis). Cow ovaries were also collected as oocyte donors for in vitro embryo production (IVEP).Three hundred thirty-eight oocytes were recovered by ovum pick up (OPU, Group A) from 8 pluriparous buffalo cows, while 1127 and 1457 oocytes were aspirated, respectively, from buffalo (Group B) and bovine (Group C) slaughterhouse ovaries. Cumulus enclosed oocytes (COCs) suitable for IVEP were in vitro matured (IVM), fertilized (IVF) and cultured (IVC) to the tight morula (Tm) and blastocyst (Bl) stage.Within buffalo species Group A had a higher Bl yield (29.7 % versus 19.9%; P<0.05) and a lower proportion of embryos arrested at Tm stage (11.1% versus 22.3%; P<0.05) than Group B.Within slaughterhouse groups cattle oocytes had a higher cleavage rate (83.9% versus 64.8%; P<0.05) and yielded 49.2% more blastocysts than buffalo. However, when data are related to the total number of cleaved oocytes, only 13.7% more blastocysts were produced in cattle than in buffalo.In conclusion, in buffalo species the source of oocytes significantly affected post-fertilization embryo development, as demonstrated by the higher Bl yields derived from OPU-derived oocytes.A higher overall IVEP efficiency, mainly related to the higher cleavage rate, was recorded in cattle compared with buffalo when ovaries from an abattoir were used as oocyte donors.     

Pregnancy rates in cattle with cryopreserved sexed sperm: effects of sperm numbers per inseminate and site of sperm deposition

In six field trials, doses between 1.0 and 6.0 x 10(6) total sexed, frozen-thawed sperm were inseminated into the uterine body or bilaterally into the uterine horns of heifers and nursing Angus cows 12 or 24h after observed estrus. Except for one comparison in one trial in which uterine body insemination was slightly superior (P<0.05) to uterine horn insemination, there was no significant (P>0.1) difference between sites of semen deposition. Additionally, except for one small study with limited numbers, there was essentially no difference in pregnancy rates in the range between 1.5 and 6 x 10(6) sexed, frozen-thawed sperm per inseminate. Pregnancy rates with smaller doses of sexed sperm averaged about 75% of controls of 20 x 10(6) total frozen-thawed, unsexed sperm. While 1.0 x 10(6) sexed, frozen-thawed sperm per insemination dose resulted in decreased pregnancy rates compared to larger doses, the lesser fertility with sexed sperm could not be compensated by increasing sperm numbers in the range of 1.5-6 x 10(6) sperm per dose. Pregnancy rates with 2 x 10(6) sexed, frozen-thawed sperm per dose were not markedly less than control pregnancy rates with 20 x 10(6) frozen-thawed unsexed sperm/dose in well-managed herds.     

Improved in vitro development of OPU-derived bovine (Bos taurus) embryos by group culture with agarose-embedded helper embryos

The average number of oocytes collected by ovum pick up (OPU) from Bos taurus cattle is <8 per live donor. The objective was to determine whether development of small numbers of cattle embryos (produced by OPU and IVF), was enhanced by including “helper” embryos, produced from abbatoir-derived oocytes and embedded in agarose. Oocytes were from abbatoir-derived ovaries (Experiments 1 and 2) or OPU of elite donors (Experiment 3). In Experiment 1, cleaved embryos (2–8 cells), were randomly allocated. Controls were groups of 1, 3, 5, 10, and 20 cleaved embryos cultured in 50 μL serum-free SOF, whereas treatments were groups of 1, 3, and 5 embryos freely cultured along with helpers in groups of either 9, 7 or 5 embedded in agarose per droplet. Therefore, there were 10 cleaved embryos per droplet in combinations of 1 + 9, 3 + 7 or 5 + 5 (free + helper), respectively. There was an increase in the progression to blastocyst for 1–5 embryos per droplet, compared to 10 and 20 (6.6–24.2% vs. 39.2–43.3%, P < 0.05). For the tested free embryos, those cultured with helpers had increased blastocyst development over their control counterparts (39.3–49.5% vs. 6.6–24.2%, P < 0.05). When the number of embryos per droplet was 10 or 20, blastocyst percentage was similar (39.2–49.5%, P > 0.05). In Experiment 2, addition of an agarose chip to the culture medium did not significantly affect development to the blastocyst stage. In Experiment 3, after fertilizing OPU oocytes with sorted X-sperm, a group of three cleaved embryos were cultured in a droplet with either seven helpers (3 + 7) or alone (3 + 0). Blastocyst development of OPU oocytes in the 3 + 7 group was 37.1%, higher than that in the 3 + 0 group (11.8%, P < 0.05). In conclusion, limited numbers of OPU/IVF oocytes had competent development when cultured with helpers (embedded in agarose to provide physical separation).     

Improved in vitro development of OPU-derived bovine (Bos taurus) embryos by group culture with agarose-embedded helper embryos

The average number of oocytes collected by ovum pick up (OPU) from Bos taurus cattle is <8 per live donor. The objective was to determine whether development of small numbers of cattle embryos (produced by OPU and IVF), was enhanced by including “helper” embryos, produced from abbatoir-derived oocytes and embedded in agarose. Oocytes were from abbatoir-derived ovaries (Experiments 1 and 2) or OPU of elite donors (Experiment 3). In Experiment 1, cleaved embryos (2–8 cells), were randomly allocated. Controls were groups of 1, 3, 5, 10, and 20 cleaved embryos cultured in 50 μL serum-free SOF, whereas treatments were groups of 1, 3, and 5 embryos freely cultured along with helpers in groups of either 9, 7 or 5 embedded in agarose per droplet. Therefore, there were 10 cleaved embryos per droplet in combinations of 1 + 9, 3 + 7 or 5 + 5 (free + helper), respectively. There was an increase in the progression to blastocyst for 1–5 embryos per droplet, compared to 10 and 20 (6.6–24.2% vs. 39.2–43.3%, P < 0.05). For the tested free embryos, those cultured with helpers had increased blastocyst development over their control counterparts (39.3–49.5% vs. 6.6–24.2%, P < 0.05). When the number of embryos per droplet was 10 or 20, blastocyst percentage was similar (39.2–49.5%, P > 0.05). In Experiment 2, addition of an agarose chip to the culture medium did not significantly affect development to the blastocyst stage. In Experiment 3, after fertilizing OPU oocytes with sorted X-sperm, a group of three cleaved embryos were cultured in a droplet with either seven helpers (3 + 7) or alone (3 + 0). Blastocyst development of OPU oocytes in the 3 + 7 group was 37.1%, higher than that in the 3 + 0 group (11.8%, P < 0.05). In conclusion, limited numbers of OPU/IVF oocytes had competent development when cultured with helpers (embedded in agarose to provide physical separation).     

In vitro and in vivo survival of frozen-thawed bovine oocytes after IVF,nuclear transfer,and parthenogenetic activation

Cryopreservation of bovine oocytes would be beneficial both for nuclear transfer and for preservation efforts. The overall objective of this study was to evaluate the viability as well as the cryodamage to the nucleus vs. cytoplasm of bovine oocytes following freezing-thawing of oocytes at immature (GV) and matured (MII) stages using in vitro fertilization (IVF), parthenogenetic activation, or nuclear transfer assays. Oocytes were collected from slaughterhouse ovaries. Oocytes at the GV, MII, or MII but enucleated (MIIe) stages were cryopreserved in 5% (v/v) ethylene glycol; 6% (v/v) 1,2-propanediol; and 0.1-M sucrose in PBS supplemented with 20% (v/v) fetal bovine serum. Frozen-thawed oocytes were subjected to IVF, parthenogenetic activation, or nuclear transfer assays. Significantly fewer GV oocytes survived (i.e., remained morphologically intact during freezing-thawing) than did MII oocytes (47% vs. 84%). Subsequent development of the surviving frozen-thawed GV and MII oocytes was not different (58% and 60% cleavage development; 7% and 12% blastocyst development at Day 9, respectively, P > 0.05). Parthenogenetic activation of frozen-thawed oocytes resulted in significantly lower rates of blastocyst development for the GV than the MII oocyte groups (1% vs. 14%). Nuclear transfer with cytoplasts derived from frozen-thawed GV, MII, MIIe, and fresh-MII control oocytes resulted in 5%, 16%, 14%, and 17% blastocyst development, respectively. However, results of preliminary embryo transfer trials showed that fewer pregnancies were produced from cloned embryos derived from frozen oocytes or cytoplasts (9%, n = 11 embryos) than from fresh ones (19%, n = 21 embryos). Transfer of embryos derived by IVF from cryopreserved GV and MII oocytes also resulted in term development of calves. Our results showed that both GV and MII oocytes could survive freezing and were capable of developing into offspring following IVF or nuclear transfer. However, blastocyst development of frozen-thawed oocytes remains poorer than that of fresh oocytes, and our nuclear transfer assay suggests that this poorer development was likely caused by cryodamage to the oocyte cytoplasm as well as to the nucleus. Mol. Reprod. Dev. 51:281–286, 1998. © 1998 Wiley-Liss, Inc.     

Long term effect of Ovum Pick-up in buffalo species

The aim of this study was to evaluate the effect of an Ovum Pick-up (OPU) treatment carried out for 9 months in buffalo (Bubalus bubalis) species. Eight pluriparous non-lactating buffalo cows underwent OPU for 9 months. Recovered cumulus enclosed oocytes (COCs) were classified and COCs suitable for in vitro embryo production (IVEP) were in vitro matured (IVM), fertilized (IVF) and cultured (IVC) to the blastocyst (Bl) stage. Animals were monitored for a total period of 270 days, but at the summer solstice, follicular turnover decreased and at the 68-day of the trial, we decided to increase the OPU sampling interval from 3-4 to 7 days. It was therefore possible to distinguish two phases: a first phase (18 sessions), during which OPU was carried out twice weekly and a second phase (16 sessions) during which OPU sessions were performed weekly. This reduction did not modify the percentage of good quality COCs, while the incidence of grade D COCs decreased (P<0.01). Furthermore, embryo production was higher in the second phase, either if embryos were calculated on the total recovered COCs (8.3% vs. 21.4%; P<0.01) and on grade A+B COCs (13.0% vs. 32.1%; P<0.01), that supposedly should have given similar blastocyst yield. During the total period of the trial it was possible to distinguish a first period of 6 months (34 sessions) characterized by blastocyst production (0.36 blastocyst/buffalo/session), followed by an unproductive period of 3 months (12 sessions), during which embryos were not produced. During the first 6 months a higher (P<0.01) number of follicles (5.06 vs. 3.71), small follicles (3.38 vs. 2.07), total COCs (2.58 vs. 1.56) and good quality (A+B) COCs (1.51 vs. 0.94) per subject/session were recorded compared to the last 3 months. No Blastocyst were produced during the second period, even if the percentage of grade A+B COCs was similar to that recorded during the first period. In conclusion, buffalo cows submitted to repeated OPU sampling for a 9-month period, showed a decline of follicle recruitment and oocyte collection after the first two months of samplings. After 6-month of samplings, in spite of the quality grade of the collected oocytes, we found a drop in their developmental competence.     

In vitro production of cattle × buffalo hybrid embryos using cattle oocytes and African buffalo (Syncerus caffer caffer) epididymal sperm

Interspecies hybridization of bovids occurs between domestic cattle and at least three other species; American bison (Bison bison), yak (Bos grunniens) and banteng (Bos banteng). Birth of a cattle × buffalo (Bubalus bubalis) hybrid has reportedly occurred in Russia and in China, but these reports were not authenticated. Such hybrids could be important in improving livestock production and management of diseases that impede production in tropical Africa. This study investigated hybridization between cattle and its closest African wild bovid relative, the African buffalo (Syncerus caffer caffer). In an attempt to produce cattle × buffalo hybrid embryos in vitro, matured cattle oocytes were subjected to a standard in vitro fertilization (IVF) procedure with either homologous cattle (n = 1166 oocytes) or heterologous African buffalo (n = 1202 oocytes) frozen-thawed epididymal sperm. After IVF, 67.2% of the oocytes inseminated with the homologous cattle sperm cleaved. In contrast, fertilization with buffalo sperm resulted in only a 4.6% cleavage rate. The cleavage intervals were also slower in hybrid embryos than in the IVF-derived cattle embryos. Of the cleaved homologous cattle embryos 52.2% progressed to the morula stage compared with 12.7% for the buffalo hybrid embryos. No hybrid embryos developed beyond the early morula stage, while 40.1% of the cleaved cattle × cattle embryos developed to the blastocyst stage. Transfer of buffalo hybrid IVF embryos to domestic cattle surrogates resulted in no pregnancies at 60 days post-transfer. This study indicates that interspecies fertilization of cattle oocytes with African buffalo epididymal sperm can occur in vitro, and that a barrier to hybridization occurs in the early stages of embryonic development. Chromosomal disparity is likely the cause of the fertilization abnormalities, abnormal development and subsequent arrest impairing the formation of hybrid embryos beyond the early morula stage. Transfer of the buffalo hybrid embryos did not rescue the embryos from development arrest.     

Production efficiency of Japanese black calves by transfer of bovine embryos produced in vitro

The objective of this study was to examine the production efficiency of Japanese Black beef calves after transfer of bovine embryos derived from an in vitro procedure. In vitro-produced (IVP) embryos were obtained from in vitro maturation and fertilization and in vitro development by co-culture with cumulus cells until 7 or 8 days after insemination. In vivo-developed (IVD) embryos from superovulated Japanese Black heifers and cows 7 days after artificial insemination were used as a control group. Bovine embryos were transferred nonsurgically to recipient cows on Day 7 +/- 1 of the estrous cycle. Pregnancy was diagnosed by palpation per rectum at Day 60 to 70 after estrus. Pregnancy, abortion, perinatal accident and birth rates were examined according to the origin of embryos (IVP or IVD), the number of transferred embryos (single or twin) and the storage status (fresh or frozen-thawed). In Experiment 1, production efficiency by twin transfer of fresh IVP embryos was examined. Higher pregnancy rates (52 1% vs 42 9%, P < 0.05) and birth rates (47.0% vs. 33.0%, P < 0.05) were obtained by twin transfer than by single transfer of fresh IVP embryos. Thus, the twin transfer of fresh IVP embryos was effective for production of calves, although the birth rates for single and twin transfers of fresh IVD embryos were still higher (55.5% and 76.1%, P < 0.05). But the abortion and perinatal accident rates for twin transfer of fresh IVP embryos were also significantly greater than those for single and twin transfer of fresh IVD embryos (P < 0.05). In Experiment 2, production efficiency by twin transfer of frozen-thawed IVP embryos was examined. Either single or twin transfer of frozen-thawed IVP embryos resulted in a similar pregnancy rate (41.3% vs. 46.7%, P > 0.05) and birth rate (34.1% vs. 41.1%, P>0.05). Thus, in combination with frozen-thawed IVP embryos, the twin transfer did not enhance production efficiency. In conclusion, Japanese Black beef calves could effectively produce calves by twin transfer to Holstein recipients when using fresh IVP embryos, and by single transfer when using frozen-thawed IVP embryos.     

Large-scale in vitro embryo production and pregnancy rates from Bos taurus, Bos indicus, and indicus-taurus dairy cows using sexed sperm

Herein we describe a large-scale commercial program for in vitro production of embryos from dairy Bos taurus, Bos indicus, and indicus-taurus donors, using sexed sperm. From 5,407 OPU, we compared the number of recovered oocytes (n = 90,086), viable oocytes (n = 64,826), and embryos produced in vitro from Gir (Bos indicus, n = 617), Holstein (Bos taurus, n = 180), 1/4 Holstein × 3/4 Gir (n = 44), and 1/2 Holstein-Gir (n = 37) crossbred cows, and the pregnancy rate of recipient cows. Viable oocytes were in vitro matured (24 h at 38.8 °C, 5% CO₂ in air) and fertilized by incubating them for 18 to 20 h with frozen-thawed sexed sperm (X-chromosome bearing) from Gir (n = 8) or Holstein (n = 7) sires (2 × 10⁶ sperm/dose). Embryos were cultured in similar conditions of temperature and atmosphere as for IVM, with variable intervals of culture (between Days 2 and 5) completed in a portable incubator. All embryos were transferred fresh, after 24 to 72 h of transportation (up to 2,000 km). On average, 16.7 ± 6.3 oocytes (mean ± SEM) were obtained per OPU procedure and 72.0% were considered viable. Total and viable oocytes per OPU procedure were 17.1 ± 4.5 and 12.1 ± 3.9 for Gir cows, 11.4 ± 3.9 and 8.0 ± 2.7 for Holstein cows, 20.4 ± 5.8 and 16.8 ± 5.0 for 1/4 Holstein × 3/4 Gir, and 31.4 ± 5.6 and 24.3 ± 4.7 for 1/2 Holstein-Gir crossbred females (P < 0.01). The mean number of embryos produced by OPU/IVF and the pregnancy rates were 3.2 (12,243/ 3,778) and 40% for Gir cows, 2.1 (2,426/1,138) and 36% for Holstein cows, 3.9 (1,033/267) and 37% for 1/4 Holstein × 3/4 Gir, and 5.5 (1,222/224), and 37% for 1/2 Holstein-Gir. In conclusion, we compared oocyte yield from two levels of indicus-taurus breeds and demonstrated the efficiency of sexed sperm for in vitro embryo production. Culturing embryos during long distance transportation was successful, with potential for international movement of embryos.     

Bovine nuclear transfer using fresh cumulus cell nuclei and in vivo- or in vitro-matured cytoplasts

We examined the effects of the source of recipient oocytes and timing of fusion and activation on the development competence of bovine nuclear transferred (NT) embryos derived from fresh cumulus cells isolated immediately after collection by ovum pickup (OPU). As recipient cytoplasts, we used in vivo-matured oocytes collected from hormone-treated heifers by OPU, or in vitro-matured oocytes from slaughterhouse-derived ovaries. NT embryos were chemically activated immediately (simultaneous fusion and activation, FA) or 2 h (delayed activation, DA) after fusion. When in vitro-matured oocytes were used as recipient cytoplasts, the development rate to the blastocyst stage of NT embryos produced by the DA method (23%) tended to be higher than those by the FA method (15%), but the difference was not significant. NT embryos derived from in vivo-matured cytoplasts have a high blastocyst yield (46%). Pregnancy rate at day 35 did not differ with the timing of fusion and activation (FA vs. DA; 50% vs. 44%) or oocyte source (in vivo- vs. in vitro-matured; 50% vs. 44%). Subsequently, the high fetal losses (88% of pregnancies) were observed with in vitro-matured cytoplasts, whereas no abortions were observed in NT fetuses from in vivo-matured cytoplasts. A total of three embryos derived from fresh cumulus cells developed to term. However, all three cloned calves were stillborn. These results indicate that improvement of development competence after NT is possible by using in vivo-matured oocytes as recipient cytoplasts in bovine NT.     

Relationship between in vitro fertilisation of ewe oocytes and the fertility of ewes following cervical artificial insemination with frozen-thawed ram semen

No laboratory test exists that can reliably predict differences among rams in field fertility after artificial insemination (AI) with frozen-thawed semen. In vitro fertilisation (IVF) has been proposed as a method of predicting these differences. The objectives of this study were to evaluate whether IVF system could discriminate among rams of different fertility in vivo after AI using frozen-thawed semen. Also, to examine effects of lowering sperm concentration on discrimination power between rams used for IVF. The aim of Experiment 1 was to evaluate the effect of altering the sperm concentration from 2 x 10(6) to 0.03125 x 10(6) spermatozoa/mL on subsequent cleavage rate and blastocyst rate in vitro. In Experiment 2, six rams (three High and three Low in vivo fertility; average pregnancy rates of 37.6% and 21.8%, respectively) were compared for their fertilising ability in IVF. Spermatozoa from each of the six rams were added to ewe oocytes using a concentration of either 2 x 10(6) or 0.0625 x 10(6)/mL. There were six replicates with 25 oocytes per well and two wells per ram per replicate. Cleavage rate was monitored at 48 h post-insemination (p.i.) and blastocyst rate determined on Days 6-8 p.i. In Experiment 1, cleavage rate increased with increasing sperm concentration and blastocyst rate was not affected by sperm concentration on any day. When the six rams were tested using 2 x 10(6) spermatozoa/mL, no significant differences were found between High and Low fertility groups for cleavage rate or blastocyst rate on Days 6, 7, or 8 p.i. (P>0.05). When the experiment was repeated using 0.0625 x 10(6) spermatozoa/mL, no differences were found between High and Low group rams for blastocyst rate on any of Days 6, 7 or 8 p.i. (P>0.05). However, there was a significant difference between High and Low fertility rams for percentage of oocytes cleaved (16.4, S.E. 2.02%; P<0.01) and the correlation between fertility in vivo and cleavage rate in vitro was significant (P=0.013). Replicate of IVF was a source of significant variation for both cleavage rate and blastocyst rate and conditions need to be further controlled. However, we suggest that using a low concentration of spermatozoa (0.0625 x 10(6)/mL) for IVF may be a useful method for predicting field fertility of frozen-thawed ram semen.     

In vivo and in vitro embryo production in goats

Assisted reproductive technologies (ART) such as artificial insemination (AI) and multiple ovulation and embryo transfer (MOET) have been used to increase reproductive efficiency and accelerate genetic gain. The principal limitations of MOET are due to variable female response to hormonal treatment, fertilization failures and premature regression of Corpora luteum. The in vitro production (IVP) of embryos offers the possibility of overcoming MOET limitations. The method of IVP of embryos involves three main steps: in vitro maturation of oocytes (IVM), in vitro fertilization of oocytes (IVF) with capacitated sperm and in vitro culture (IVC) of embryos up to blastocyst stage. Recovering oocytes from live selected females by laparoscopic ovum pick-up (LOPU) and breeding prepubertal females by juvenile in vitro embryo technology (JIVET) will allow a greater production of valuable goats. Also, IVP of goat embryos will provide an excellent source of embryos for basic research on development biology and for commercial applications of transgenic and cloning technologies. Different protocols of IVP of embryos have been used in goats. However oocyte quality is the main factor for embryos reaching blastocyst stage from IVM/IVF/IVC oocytes. One of the principal determinant factors in the results of blastocyst development is the age of the oocyte donor females. In goats, oocytes from prepubertal and adult females do not show differences in in vitro maturation and in vitro fertilization; however the percentage of oocytes reaching blastocyst stage ranges from 12 to 36% with oocytes from prepubertal and adult goats, respectively.     

In vitro fertilization and subsequent development of porcine oocytes using cryopreserved and liquid-stored spermatozoa from various boars

We had previously developed a porcine IVF system using a chemically defined medium, i.e., porcine gamete medium supplemented with theophylline, adenosine, and cysteine (PGMtac). In the present study, we investigated the utility of this IVF system using different types of semen: (1) cryopreserved ejaculated (n = 8); (2) cryopreserved epididymal (n = 4); and (3) liquid-stored ejaculated (n = 5). Cryopreserved spermatozoa were prepared by three methods. In vitro-matured porcine oocytes were fertilized for 20 h in PGMtac using each type of semen, and the presumptive zygotes were cultured in porcine zygote medium (PZM)-4 for 5 days. In the case of frozen-thawed spermatozoa, the number of spermatozoa per penetrated oocyte (1.1-1.7), rate of blastocyst formation (26-56%), and total number of cells per blastocyst (34-49) differed (P < 0.05) among freezing methods. However, blastocysts were produced using all types of cryopreserved spermatozoa (14-75%). When spermatozoa were liquid-stored for 1-14 days after semen collection, the rate of sperm penetration (P < 0.05) decreased as storage time increased, although there was no significant reduction in sperm motility during storage. In all groups, semen that had been stored within 10 days after collection enabled blastocyst production in vitro (20-48%). In conclusion, this IVF system, which uses a chemically defined medium, had widespread utility with both frozen-thawed and liquid-stored spermatozoa.     

Caprine blastocyst development after in vitro fertilization with spermatozoa frozen in different extenders

The feasibility of using frozen-thawed semen in caprine IVF outside the breeding season was investigated. Electroejaculated spermatozoa from a Nubian buck were washed twice and then frozen in skim milk- or in egg yolk-based extenders. Goat oocytes were matured and inseminated by frozen-thawed spermatozoa selected by swim-up. In vitro fertilization was performed in a modified defined medium (mDM), altered experimentally, for 24 h. Embryos were cultured in 50 microL of c-SOF + NEA for 9 d. The percentages of oocytes exposed to heparin-capacitated spermatozoa, (previously cryopreserved in skim milk-based extender) that cleaved, reached morula, blastocyst and expanded blastocyst stages were 82.8, 57.1, 35.7 and 30.0%, respectively. Without heparin treatment the rates for cleavage, morula, blastocyst and expanded blastocyst stages were 44.3, 31.4, 18.6 and 8.6%, respectively. Therefore, heparin treatment was included in sperm capacitation. Use of spermatozoa with BSA in the IVF medium yielded no cleavage. Although extenders containing 8 to 20% egg yolk enabled good sperm motility after cryopreservation, in vitro fertilizing ability was compromised under our conditions. By contrast, semen commercially processed in season in an egg yolk-based diluent remained effective for IVF. The highest proportion of blastocysts resulted from the use of spermatozoa diluted in a skim milk extender, heparin capacitation, and insemination in medium containing lamb serum.