Arief Boediono

Viability of bovine blastocysts obtained after 7, 8 or 9 days of culture in vitro following vitrification and one-step rehydration.

This study examined morphological appearance, viability and hatching rates in relation to the total cell number following vitrification of in vitro produced bovine blastocysts and expanded blastocysts. In Experiment 1, embryos obtained after 7, 8 or 9 d of culture were pooled and equilibrated in either 10% ethylene glycol (EG) or 10% EG plus 0.3M trehalose in Dulbeccos phosphate buffered saline (DPBS) supplemented with 10% calf serum and 0.6% BSA for 5 min each, at room temperature, and then vitrified together in precooled vitrification solutions consisting of 40% EG (Treatment 1), 40% EG plus 0.3M trehalose (Treatment 2), 40% EG plus 0.3M trehalose and 20% polyvinylpyrrolidone (PVP, Treatment 3) in DPBS. The embryo viability and hatching rates of Treatment 1 (19 and 3%) differed significantly (P < 0.05) from those of Treatment 2 (56 and 31%) and Treatment 3 (70 and 43%). There was a significant difference (P < 0.05) in embryo viability between Treatment 2 (31%) and Treatment 3 (43%). In Experiment 2, Day 7, 8 and 9 embryos were vitrified separately, with higher viability and hatching rates in Experiment 1 than in Experiment 2. The viabilities of Day 7 (87%), 8 (71%) and 9 (46%) embryos differed significantly (P < 0.05). Again, there were significant differences (P < 0.01) among the hatching rates of Day 7 (75%), 8 (38%) and 9 (9%) embryos. The total cell number of hatched blastocysts was then determined by differential fluorochrome staining. The total cell number of Day 7, 8 and 9 embryos differed significantly (P < 0.05).

Offspring born from chimeras reconstructed from parthenogenetic and in vitro fertilized bovine embryos

Chimeric embryos were produced by aggregation of parthenogenetic (Japanese Red breed) and in vitro fertilized (Holstein breed) bovine embryos at the Yamaguchi Research Station in Japan and by aggregation of parthenogenetic (Red Angus breed) and in vitro fertilized (Holstein breed) embryos at the St. Gabriel Research Station in Louisiana. After embryo reconstruction, live offspring were produced at each station from transplanting these embryos. The objective of this joint study was to evaluate the developmental capacity of reconstructed parthenogenetic and in vitro fertilized bovine embryos. In experiment I, chimeric embryos were constructed: by aggregation of four 8‐cell (demi‐embryo) parthenogenetic and four 8‐cell stage (demi‐embryo) IVF‐derived blastomeres (method 1) and by aggregation of a whole parthenogenetic embryo (8‐cell stage) and a whole IVF‐derived embryo (8‐cell stage) (method 2). Similarly in experiment II, chimeric embryos were constructed by aggregating IVF‐derived blastomeres with parthenogenetic blsatomeres. In this experiment, three categories of chimeric embryos with different parthenogenetic IVF‐derived blastomere ratios (2:6; 4:4, and 6:2) were constructed from 8‐cell stage bovine embryos. In experiment III, chimeric embryos composed of four 8‐cell parthenogenetic and two 4‐cell IVF‐derived blastomeres or eight 16‐cell parthenogenetic and four 8‐cell IVF‐derived blastomeres were constructed. Parthenogenetic demi‐embryos were aggregated with sexed (male) IVF demi‐embryos to produce chimeric blastocysts (experiment IV). In the blastocyst stage, hatching and hatched embryos were karyotyped. In experiment V, chimeric embryos that developed to blastocysts (zona‐free) were cryopreserved in ethylene glycol (EG) plus trehalose (T) with different concentrations of polyvinylpyrrolidone (PVP; 5%, 7.5%, and 10%). In experiment I, the aggregation rate of the reconstructed demi‐embryos cultured in vitro without agar embedding was significantly lower than with agar embedding (53% for 0% agar, 93% for 1% agar, and 95% for 1.2% agar, respectively). The aggregation was also lower when the aggregation resulted from a whole parthenogenetic and IVF‐derived embryos cultured without agar than when cultured with agar (70% for 0% agar, 94% for 1% agar, and 93% for 1.2% agar, respectively). The development rate to blastocysts, however, was not different among the treatments. In experiment II, the developmental rates to the morula and blastocyst stages were 81%, 89%, and 28% for the chimeric embryos with parthenogenetic:IVF blastomere ratios of 2:6, 4:4, and 6:2, respectively. In experiment III, the developmental rate to the morula and blastocyst stages was 60% and 65% for the two 4‐cell and four 8‐cell chimeric embryos compared with 10% for intact 8‐cell parthenogenetic embryos and 15% for intact 16‐cell parthenogenetic embryos. To verify participation of parthenogenetic and the cells derived from the male IVF embryos in blastocyst formation, 51 embryos (hatching and hatched) were karyotyped, resulting in 27 embryos having both XX and XY chromosome plates in the same sample, 14 embryos with XY and 10 embryos with XX. The viability and the percentage of zona‐free chimeric embryos at 24 hr following cryopreservation in EG plus T with 10% PVP were significantly greater than those cryopreserved without PVP (89% vs. 56%). Pregnancies were diagnosed in both stations after the transfer of chimeric blastocysts. Twin male (stillbirths) and single chimeric calves were delivered at the Yamaguchi station, with each having both XX and XY chromosomes detected. Three pregnancies resulted from the transferred 40 chimeric embryos at the Louisiana station. Two pregnancies were lost prior to 4 months and one phenotypically‐ chimeric viable male calf was born. We conclude that the IVF‐derived blastomeres were able to stimulate the development of bovine parthenogenetic blastomeres and that the chimeric parthenogenetic bovine embryos were developmentally competent. Mol. Reprod. Dev. 53:159–170, 1999.

Comparison of hybrid and purebred in vitro-derived cattle embryos during in vitro culture

Frozen-thawed spermatozoa collected from a beef bull (Japanese Black) were used for in vitro fertilization (IVF) of matured oocytes obtained from dairy (Holstein) and beef (Japanese Black) females. Embryos were examined for fertilization, cleavage rate, interval between insemination and blastocyst production (experiment I), total cell number per embryo and sex ratio during blastocyst formation (experiment II), and blastocyst production rate of zygotes that developed to 2-, 4-, and 8-cell stages at 48h post-fertilization (experiment III). Fertilized oocytes were cultured in vitro on a cumulus cell co-culture system. The fertilization and cleavage rate of oocytes groups were similar, however, the blastocyst production rate was greater (P<0.05) in hybrid than from purebred embryos (27% versus 20%). Development of blastocysts produced from hybrid embryos developed at a faster rate than blastocysts produced from the straightbred embryos. In hybrid embryos, blastocyst production was significantly greater on day 7 (56%) and gradually decreased from 20% on day 8 to 17% on day 9. In contrast, blastocyst production rate from the purebred embryos was lower on day 7 (17%), increasing on day 8 to 59% and then decreased on day 9 to 24%. The total number of cells per embryo and sex ratio of in vitro-produced blastocysts were not different between hybrid and purebred embryos. The number of blastocysts obtained from embryos at the 8-cell stage of development by 48h post-fertilization (94%) was greater (P<0.01) than the number of zygotes producing blastocysts that had developed to the 4-cell stage (4%) and the 2-cell stage (2%) during the same interval. These results show that the blastocyst production rate and developmental rate to the blastocyst stage were different between hybrid and purebred embryos, and that almost all of the in vitro-produced blastocysts were obtained from zygotes that had developed to the 8-cell stage 48h post-fertilization.

The effect of sperm-oocyte incubation time on in vitro embryo development using sperm from a tetraparental chimeric bull

The present study was designed as 5 x 4 factorial to investigate the effects of using sperm from 5 bulls, and varied sperm-oocyte incubation times (5, 10, 15 and 20 h) on the fertilization, cleavage rates and blastocyst formation on an in vitro bovine embryo production system. The bulls included a tetraparental Chimera, its sires (Japanese Black and Limousin), its maternal grand-sires (Japanese Brown and Holstein). The proportion of polyspermy, 2-pronuclei formation, fertilization, cleavage and development to blastocyst were affected (P < 0.001) by the duration of sperm-oocyte incubation, as well as by the interaction between bulls and their corresponding sperm-oocyte incubation time. Blastocyst rate observed after 5 h in oocytes inseminated with Chimera, Japanese Black and Limousin were higher (p < 0.05) than those observed at 20 h incubation. The proportion of blastocysts from oocytes inseminated with Japanese Black observed at 10 h of incubation did not differ from that of Chimera, but both were higher (p < 0.05) than those observed for the Limousin, Japanese Brown and Holstein sires. The present study showed that there was an effect by the duration of sperm-oocyte incubation on in vitro embryo development. The optimal time of sperm-oocyte incubation for the Chimera was similar to that of its sires (Japanese Black and Limousin) but differed from its maternal grand-sires (Japanese Brown and Holstein). The fertilization rates for the sperm from the Holstein bull increased up to 15 h suggesting that this might be the only bull that would benefit from a long incubation period for insemination.

Pregnancy rate and survival in culture of in vitro fertilized bovine embryos frozen in various cryoprotectants and thawed using a one-step system.

Bovine oocytes surrounded with compact cumulus cells were cultured for 20 to 22 hours (38.5 degrees C, 5% CO(2)) in modified TCM-199 medium supplemented with 5% superovulated cow serum (SCS) and inseminated by in vitro capacitated spermatozoa. Day 7 to 8 embryos were equilibrated for 10 minutes in 1.3 M methyl cellosolve (MC), 1.1 M diethylene glycol (DEG), 1.8 M ethylene glycol (EG), 1.6 M propylene glycol (PG) and 1.1 M 1, 3-butylene glycol (BG) solutions. They were then loaded into 0.25-ml straws, placed into an alcohol bath freezer at 0 degrees C, cooled from 0 degrees C to -6 degrees C at -1 degrees C/minute, seeded, held for 10 minutes, and cooled again at -0.3 degrees C or -0.5 degrees C/minute to -30 degrees C. Straws were then plunged and stored in liquid nitrogen. After thawing in 30 degrees C water, the embryos were rehydrated in TCM-199 medium and then cultured for 48 hours in TCM-199 plus 5% SCS. Embryos were considered viable if they progressed to later developmental stages with good morphology. Some of the embryos frozen in each cryoprotectant were thawed and transferred nonsurgically without removing the cryoprotectant. Hatched embryos survived freezing and one-step dilution as follows: EG (50.0%), MC (53.6%), DEG (56.9%), PG (58.0%) and BG (11.5%). The survival rate of embryos cooled at -0.3 degrees C vs -0.5 degrees C/minute was not significantly different (P>0.05), however, blastocysts hatched most often (P<0.01) in vitro when cooled at a rate of -0.3 degrees C/minute (64.6%, 31/48) than at -0.5 degrees C/minute (22.6%, 12/53). Pregnancy rates resulting from embryos frozen in the different cryoprotectants were as follows: MC (48%, 10/21); DEG (30%, 3/10); EG (74%, 20/27); and PG (40%, 4/10). These results indicate that MC, DEG, EG and PG have utility as cryoprotectants for the freezing and thawing of IVF bovine embryos.

VIABILITY OF FROZEN-THAWED BOVINE IVM/IVF EMBRYOS IN RELATION TO AGING USING VARIOUS CRYOPROTECTANTS

Bovine IVF embryos developed on Days 7, 8 and 9 were equilibrated with 1.6 M propylene glycol (PG), 1.8 M ethylene glycol (EG), 1.1 M diethylene glycol (DEG) or 1.3 M ethylene glycol monomethyl ether (EME) for 10 to 20 min in modified phosphate buffered saline. (mPBS) supplemented with 10% superovulated cow serum. The embryos were loaded into 0.25-ml plastic straws and were placed directly into a 0 degrees C alcohol bath chamber and held for 2 min. They were cooled from 0 degrees C to -5.5 degrees C at 1 degrees C/min and then seeded, followed by a 10-min holding period at -5.5 degrees C. The straws were then cooled to -30 degrees C at 0.3 degrees C/min before plunging into liquid nitrogen. Embryos were thawed and placed directly into the culture medium and washed 3 times. The survival rates of the Day-9 embryos based on reappearance of blastocoele, expansion, and hatching after 48 h of post-thaw culture were significantly lower (P<0.01) than those of the Day-7 and 8 embryos, in all of the cryoprotectants tested. On the other hand, while the reappearance of blastocoele and expansion of blastocysts after 48 h of post-thaw culture were not significantly different among each cryoprotectant, the percentage of hatching blastocysts were significantly different between DEG and EME (P<0.05), between DEG and EG (P<0.01) and between PG and EG (P<0.05). These findings demonstrate that the age of the embryo (Day 7 and 8) is very important for the successful freezing of IVF bovine embryos. Also, as to the hatching rates, EME and EG are superior as cryoprotectants than the other 2 cryoprotectants tested.

Fertility of sperm from a tetraparental Chimeric bull

The purpose of the present study was to examine the ability of a tetraparental Chimera in producing IVF embryos. Cumulus oocytes complexes (COCs) were matured in vitro for 22 h. Frozen-thawed sperm of a Chimera (CH), as well as Japanese Black (JB), Limousin (L), Japanese Brown (JBr), Holstein (H) bulls were used for IVF. The chromosome preparations were made from peripheral lymphocytes. Based on chromosome analysis the Chimera had apparently normal chromosomes (29 acrocentric pairs, one large sub metacentric X chromosome and one small sub metacentric Y chromosome). The proportion of acrosome reacted spermatozoa after 1 h incubation was higher (P < 0.01) with the Chimera (CH) than with the Holstein and in Japanese Brown bulls, but did not differ from Japanese Black and Limousin bull sperm (79.0%, 71.2%, 72.5%, 57.8% and 57.0% for CH, JB, L, JBr and H sperm, respectively). Fertilization rates observed after 5 h of sperm-oocyte incubation with Chimera (O-CH) sperm were higher (P < 0.05) than with Japanese Brown (O-JBr) and (P < 0.01) than with Holstein (O-H) sperm, but did not differ from Japanese Black (O-JB) and Limousin (O-L) sperm (36/44, 81.8%; 28/35, 80.0%; 25/36, 69.4%; 19/43, 44.2% and 6/33, 18.2% for O-CH, O-JB, O-L, O-JBr and O-H, respectively). The cleavage rates of IVM oocytes inseminated with Chimera sperm were also higher (P < 0.001) than in Holstein, (P < 0.01) Japanese Brown and (P < 0.05) Limousin, but did not differ from Japanese Black sperm (181/239, 75.7%; 123/171, 71.9%; 108/186, 58.1%; 80/196, 40.8% and 30/186, 16.1% for O-CH, O-JB, O-L, O-JBr and O-H, respectively). The blastocyst rates of IVM oocytes inseminated with sperm were higher (P < 0.05) than in Limousin, Japanese Brown and Holstein, but did not differ from Japanese Black (69/181, 38.1%; 48/123, 39.0%; 27/108, 25.0%; 7/30, 23.3% and 16/80, 17.8% for O-CH, O-JB, O-L, O-JBr and O-H, respectively). Three findings suggested the sperm from this tetraparental Chimeric bull were able to be used for producing bovine IVF embryos.

Production of chimeric calves by aggregation of in vitro fertilized bovine embryos without zonae pellucidae

Abstract Bovine embryos produced by in vitro maturation (IVM), fertilization (IVF) and culture (IVC) were used to produce aggregation chimeras. An aggregated chimera was produced by combining bovine IVF embryos (Holstein × Japanese Black and Japanese Brown × Limousin breeds) which were cultured in vitro without the zonae pellucidae. Forty-eight hours after IVF, embryos at the 8 cell-stage were used to produce aggregation chimeras. In Experiment I, the zonae pellucidae was removed by a microsurgical method using a microblade or by treatment with 0.25% pronase. Holstein × Japanese Black embryos were aggregated with Japanese Brown × Limousin embryos after zonae removal by hand manipulation in culture medium. In Experiment II, the viability of the aggregated embryos developing into blastocysts was examined by measuring the extent of development. The number of aggregated embryos and embryos developed into blastocysts was 34 (91.9%) and 24 (70.6%), respectively, when the zonae pellucidae was removed by the microsurgical method; and 12 (92.3%) and 6 (50.0%), respectively, when the zonae pellucidae was removed using the 0.25% pronase treatment. The size of the aggregated embryos was significantly different from that of the normal embryos when cultured in vitro until Day 10, but not different thereafter. Five aggregated embryos were transferred nonsurgically to the recipients, resulting in 1 pregnancy and the birth of 2 chimeric calves. Skin color was used as evidence of chimerism.

Selected single blastocyst transfers maintained pregnancy outcome and eliminated multiple pregnancies

BackgroundTransfer of more than one embryo followingin vitro fertilization/intracytoplasmic sperm injection cycles have increased pregnancy rate at the cost of increasing the incidence of triplets and twins. It has been proposed that prolonged culture to the blastocyst stage would automatically result in the selection of good quality embryos for transfer and minimize the incidence of triplets and twins.Methods and ResultsThe objectives of the present retrospective analysis were to examine the pregnancy outcome, multiple pregnancy and related data following: (i) single blastocyst transfer (BT) and double BT; (ii) single BT in patients belonging to different age groups; and (iii) good, fair or poor quality of BT. A total of 260 BT were carried out between August 1998 and July 2002 and they are included in the current study. Sixty of the 260 BT patients received a single BT, and 41 of them received selected single good quality BT (SSBT). The implantation rate has no significant difference between following single BT (53.3%) and double BT (42.8%). No multiple pregnancy occurred following single BT, while significantly higher (P < 0.05) multiple pregnancy rate was observed following a double BT (45.8%). The clinical pregnancy and implantation rates following a single BT were similar (P > 0.05) in patients belonging to < 30 years (62.5%), 30–34 years (57.9%) and 35–39 years old (35.8%).ConclusionSelected single good quality BT maintained pregnancy and avoided multiple pregnancies. It is recommended for patients with a risk for high-order multiple pregnancy.

Microphthalmia‐associated transcription factor mutations are associated with white‐spotted coat color in swamp buffalo

Summary A candidate gene analysis of the microphthalmia‐associated transcription factor (MITF) gene was used in an attempt to identify the genetic basis for a white‐spotted coat color phenotype in the Asian swamp buffalo (Bubalus bubalis carabanensis). Ninety‐three buffaloes—32 solid, 38 spotted and 23 white individuals—were Sanger‐sequenced for all MITF exons as well as highly conserved intronic and flanking regions. MITF cDNA representing skin and iris tissue from six spotted, nine solid and one white buffaloes was also Sanger‐sequenced to confirm detected mutations. Two independent loss‐of‐function mutations, a premature stop codon (c.328C>T, p.Arg110*) and a donor splice‐site mutation (c.840+2T>A, p.Glu281_Leu282Ins8), both of which cause white‐spotted coat color in swamp buffaloes, were identified. The nonsense mutation leads to a premature stop codon in exon 3, and likely removal of the resulting mRNA via nonsense‐mediated decay pathway, whereas the donor splice‐site mutation leads to aberrant splicing of exon 8 that encodes part of a highly conserved region of MITF. The resulting insertion of eight amino acid residues is expected to perturb the leucine zipper part in the basic helix‐loop‐helix leucine zipper (bHLH‐Zip) domain and will most likely influence dimerization and DNA binding capacity. Electrophoretic mobility shift assay was performed using mutant and wild‐type MITF proteins and showed that the mutant MITF protein resulting from the splice‐site mutation decreased in vitro DNA binding capacity compared to wild‐type MITF. White‐spotted buffalo bulls are sacrificed in funeral ceremonies in Tana Toraja, Indonesia, because they are considered holy, and our results show that genetic variation causes a tie to the cultural use of these buffaloes.