In vitro production of llama (Lama glama) embryos by intracytoplasmic sperm injection: effect of chemical activation treatments and culture conditions.

Assisted reproductive technologies in the llama (Lama glama) are needed to provide alternative methods for the propagation, selection and genetic improvement; however, recovery of adequate quantity and quality of spermatozoa for conventional IVF is problematic. Therefore, an effort was made to adapt the intracytoplasmic sperm injection (ICSI) procedure for the in vitro production of llama embryos. The specific objectives of this study were: (1) to determine in vitro maturation rates of oocytes recovered by transvaginal ultrasound-guided oocyte aspiration (TUGA) or flank laparotomy; (2) to evaluate the effects of activation treatments following ICSI; (3) to evaluate the development of llama ICSI embryos in CR1aa medium or in an oviduct cell co-culture system. Llamas were superstimulated by double dominant follicle reduction followed by oFSH administered in daily descending doses over a 3-day interval. Oocytes were harvested by flank laparotomy or TUGA and matured in vitro for 30 h. Mature oocytes were subjected to ICSI followed by no chemical activation (Treatment A), ionomycin only (Treatment B) or ionomycin/DMAP activation (Treatment C). More oocytes were recovered by flank laparotomy procedure compared with TUGA (94% versus 61%, P<0.05) and a greater number of oocytes harvested by flank laparotomy reached the metaphase-II stage (77% versus 44%, P<0.05). After ICSI, the proportion of cleaved and 4-8-cell stages embryos was significantly greater when injected oocytes were activated with ionomycin/DMAP combination (63% and 38%, respectively, P<0.05). The co-culture of ICSI embryos with llama oviduct epithelial cells resulted in progression to morula (25%) and blastocyst (12%) stages; whereas, all embryos cultured in CR1aa medium arrested at the 8-16-cell developmental stage.

Banteng (Bos javanicus) embryos and pregnancies produced by interspecies nuclear transfer.

The banteng (Bos javanicus), a member of the bovidae family, is currently listed as threatened by the IUCN Red List and it is estimated the total world population is <10,000 animals. In exotic or endangered species, the lack of oocytes and recipients precludes the use of traditional somatic cell nuclear transfer (NT), and an approach such as interspecies NT may be the only alternative to produce embryos and offspring. A total of 348 enucleated domestic bovine oocytes were reconstructed with either male (Treatment A) or female (Treatment B) adult banteng fibroblasts and a total of 103 bovine oocytes were parthenogenically activated as a control (Treatment C). There was no significant difference in fusion rate (68 versus 77%) between Treatments A and B. Of fused couplets, those in Treatment A had greater (P < 0.05) cleavage (67 versus 51%) and blastocyst (28 versus 15%) rate than Treatment B. Of a total of 24 blastocysts transferred into 12 domestic cattle recipients from Treatment A, two pregnancies (17%) were established with heart beats detectable at 30 day by rectal ultrasonography. No pregnancies resulted from the transfer of 14 blastocysts from Treatment B. Both pregnancies were subsequently lost, one between 30 and 60 days and the second between 60 and 90 days of gestation. The bovine cytoplast supported mitotic cleavage of banteng karyoplasts, and was capable of reprogramming the nucleus to achieve blastocyst stage embryos and pregnancies in exotic bovids.

Fertilization of eggs of zebrafish, Danio rerio, by intracytoplasmic sperm injection.

To evaluate the potential for fertilization by sperm injection into fish eggs, sperm from zebrafish, Danio rerio, were microinjected directly into egg cytoplasm of two different zebrafish lines. To evaluate physiological changes of gametes on the possible performance of intracytoplasmic sperm injection (ICSI), four different combinations of injection conditions were conducted using activated or nonactivated gametes. From a total of 188 zebrafish eggs injected with sperm in all treatments, 31 (16%) developed to blastula, 28 (15%) developed to gastrula, 10 (5%) developed abnormally to larval stages, and another 3 (2%) developed normally and hatched. The highest fertilization rate (blastodisc formation) was achieved by injection of activated spermatozoa into nonactivated eggs (35%). Injections were most effective when performed within the first hour after egg collection. Flow cytometric analysis of the DNA content of the developing ICSI embryos revealed diploidy, and the use of a dominant pigment marker confirmed paternal inheritance. Our study indicates that injection of a single sperm cell into the cytoplasm of zebrafish eggs allows fertilization and subsequent development of normal larvae to hatching and beyond.

Comparing follicle stimulating hormone from two commercial sources for oocyte production from out-of-season dairy goats.

Until recently, two sources of follicle stimulating hormone (FSH-P; Schering-Plough; Kenilworth, NJ and Super-Ov; FSH-SOV; AUSA International, Tyler, TX) have been commercially available in the United States and routinely used for superovulation of ruminants. Because there have been no comparative follicle stimulating hormone studies on small ruminants, we determined the difference between the number of follicles induced and the number of oocytes that can subsequently be harvested from goats stimulated with either of these two follicle stimulating hormone products. Anestrous Saanen does were fitted with a progestin implant then randomly assigned to one of two ovarian stimulation groups. Starting 4 d after introducing the progestin implant, donors in treatment 1 were administered daily injections of FSH-P for 4 d. Does in treatment 2 were similarly treated but were administered FSH-SOV for 4 d. Follicle aspirations were performed by laparotomy in the morning of treatment d 8. In summary, no difference was detected between the two stimulatory agents for the number of follicles and quality of oocytes harvested from stimulated does, indicating that these two commercial FSH products could be used successfully for ovarian stimulation of anestrous dairy goats.

Production of goats by somatic cell nuclear transfer.

In this study, we demonstrate the production of transgenic goats by nuclear transfer of fetal somatic cells. Donor karyoplasts were obtained from a primary fetal somatic cell line derived from a 40-day transgenic female fetus produced by artificial insemination of a nontransgenic adult female with semen from a transgenic male. Live offspring were produced with two nuclear transfer procedures. In one protocol, oocytes at the arrested metaphase II stage were enucleated, electrofused with donor somatic cells, and simultaneously activated. In the second protocol, activated in vivo oocytes were enucleated at the telophase II stage, electrofused with donor somatic cells, and simultaneously activated a second time to induce genome reactivation. Three healthy identical female offspring were born. Genotypic analyses confirmed that all cloned offspring were derived from the donor cell line. Analysis of the milk of one of the transgenic cloned animals showed high-level production of human antithrombin III, similar to the parental transgenic line.

Transvaginal ultrasound-guided oocyte retrieval following FSH stimulation of domestic goats.

The objectives of this study were to evaluate different ovarian stimulation protocols on donor goats and to develop a safe, repeatable method for harvesting oocytes from FSH-treated does (Experiment I). Based on the preliminary findings of the first experiment, 32 crossbred does were used in a second experiment (Experiment II), 16 that had not been previously aspirated and 16 that had undergone one previous aspiration, were used to fine tune the procedure. Females were randomly subjected to 1 of the 2 ovarian stimulation protocols: Treatment (A) does were implanted with a norgestomet ear implant. Starting 10 d post-implantation, does were administered FSH daily for 4 d. Does in Treatment (B) were treated similarly to those in (A) but were implanted for only 3 d before starting the FSH injections and implants were not removed prior to aspiration. Using a 2 x 2 factorial arrangement, fresh does (n=16), not previously aspirated, were then further randomly assigned to either a laparoscopic aspiration procedure (LAP) or a transvaginal ultrasound-guided aspiration procedure (TUGA). The LAP procedure was performed using a fiber optics. For the TUGA, the doe was placed in dorsal recumbency, and a 5 MHz human transvaginal transducer, attached to the ultrasound unit, was positioned vaginally for oocyte aspiration. In summary, there was no significant difference among treatment groups for parameters evaluated, with the exception of methods for oocyte collection. The number of follicles detected and oocytes harvested using TUGA (9.5 and 4.3, respectively) was less than for females obtained by LAP (17.4 and 14.4, respectfully). The percentage of oocytes recovered from does subjected to the TUGA (68%), however, was similar to those subjected to the LAP (69%). Unlike donor does subjected to a repeated LAP, there was no evidence of adhesions in donor does from the repeated TUGA group. The TUGA approach to oocyte collection should not be overlooked in an effort to decrease the chances of adhesions in valuable donor goats.

In-vitro development of refrozen mouse embryos.

To evaluate the effects of sequential, repetitive freezing on their in-vitro development, mouse embryos at the eight- to 16-cell stage were subjected to one of five treatments. They were (i) cultured as unfrozen controls, (ii) frozen once and cultured, (iii) subjected to two consecutive freeze-thaw cycles, (iv) frozen and thawed, and then cultured for 18-30 h before being frozen a second time, and (v) frozen three times in succession without being cultured. To assess their functional survival after freezing and thawing, all embryos were cultured in vitro to the hatched blastocyst stage in Whitten's medium. In one experiment, hatched embryos that developed after one, two or three cycles of freezing and thawing were stained with Hoechst 33342 to determine their mean cell number. More embryos of the culture control group and the once-frozen group developed into hatching blastocysts than those of the refrozen groups. There was no difference in the second post-thaw rate of in-vitro development for embryos refrozen with the culture-refreeze or direct-refreeze procedure. Furthermore, there was no difference among in-vitro development rates for embryos frozen two or three times. However, among those embryos subjected to repeated cycles of freezing and thawing that did not survive, there was a considerable amount of damage to their zonae pellucidae. Furthermore, frozen mouse embryos had fewer cells per embryo at the time of hatching than the unfrozen embryos. Nevertheless, these results demonstrate that mouse embryos can survive even three successive freeze-thaw cycles yet still be capable of in-vitro development.

Developmental potential of rhesus monkey embryos produced by in vitro fertilization.

This study was an examination of the developmental potential of in vitro fertilization (IVF)-produced rhesus monkey embryos that were cultured in medium alone or cocultured with various cell types. End points were the quality and yield of embryos attaining the expanded or hatched blastocyst stage. A total of 96 IVF-produced embryos were cryopreserved and thawed, and 90 embryos were considered intact and suitable for culture. These embryos were placed into one of five treatment groups consisting of four different cell supports and medium alone. Two primary cultures (bovine oviductal cells [bOVID] and bovine cumulus cells [bCUM]) and two established cell lines (Vero cells and buffalo rat liver cells [BRL]) were utilized for coculture of embryos. Embryos were cultured for up to 14 days, and growth curves were established for all embryos that expanded and/or hatched. The developmental rate for embryos classified as viable varied substantially; in number of days to reach a given stage, early morulae ranged from Days 3 to 9 post-insemination, morulae from Days 4 to 9, blastocysts from Days 6 to 11, expanded blastocysts from Days 7 to 12, and hatched blastocysts from Days 9 to 15. On the basis of developmental curves, 30% of the embryos were arrested upon thawing or shortly after. Of the remaining embryos classified as viable, developmental efficiencies to the hatched blastocyst stage for the various treatments were 1) bOVID, 33%; 2) bCUM, 15%; 3) Vero cells, 9%; 4) BRL, 45%; and 5) medium alone, 8%.(ABSTRACT TRUNCATED AT 250 WORDS)

Birth of live calves after transfer of frozen-thawed bovine embryos fertilised in vitro.

Follicular oocytes were aspirated from bovine ovaries collected at a local abattoir. The cumulus-intact oocytes were matured, fertilised and subsequently cultured in vitro. Of 2297 oocytes exposed to in vitro procedures during a 30-day experimental period, 92 per cent matured, 83 per cent were fertilised, 73 per cent cleaved, 48 per cent developed to the morulae and 14 per cent developed to the expanded blastocyst stage. During this experimental period, 300 similar embryos fertilised in vitro were frozen at different post in vitro block developmental stages. After approximately one year of storage in liquid nitrogen, 98 of these embryos were thawed and cultured either for up to four hours or for two days in tissue culture medium-199. Culturing the embryos for up to four hours was not as successful for in vitro development as culturing for two days. Of the 40 embryos cultured for two days, 67 per cent of early blastocyst stage embryos developed to expanded blastocysts in vitro and 46 per cent of morula stage embryos developed to expanded blastocysts, whereas only 8 per cent of 16-cell stage embryos developed to expanded blastocysts. A 50 per cent pregnancy rate resulted when frozen-thawed embryos were co-cultured for two days before transfer compared with 20 per cent for frozen-thawed embryos cultured for up to four hours before transfer. Five calves were born after a normal gestation period with birthweights ranging from 37.3 to 54.5 kg.