Evaluation of developmental competence of vitrified-warmed early cleavage stage embryos and their application for chimeric mouse production.

The developmental competence of in vitro cultured embryos vitrified-warmed at an early cleavage stage (2- or 4, 8-cell stage) was examined by both direct transfer into recipient animals and after in vitro manipulation for chimeric mice production using embryonic stem (ES) cells. Vitrified-warmed embryos transferred at the morulae and blastocyst stages showed fetus development comparable to control embryos, although blastocyst development of vitrified-warmed embryos was significantly slower than that of controls. When vitrified-warmed early cleavage stage embryos were used for chimeric mouse production using ES cells, 1 to 10% of the injected or aggregated embryos developed into chimeric neonates and germ-line chimeric mice were obtained from all ES cell lines. This study indicates that embryos developed in vitro from vitrified-warmed embryos have equivalent competence with unvitrified embryos irrespective of stage of vitrification and that these vitrified-warmed embryos maintain adequate viability even after in vitro manipulation such as aggregation and microinjection with ES cells.     

Birth of large calves that developed from in vitro-derived bovine embryos

High birth weights were observed in calves that developed from bovine embryos produced by in vitro maturation (IVM) and in vitro fertilization (IVF) procedures. After IVM and IVF, embryos were either co-cultured in vitro with oviductal epithelial cells or transferred into the sheep oviduct for development to the blastocyst stage. Blastocysts were transferred to the reproductive tracts of recipient heifers and cows for development to term. Birth weights and gestation periods were compared between calves that developed from in vitro-derived embryos and calves born after artificial insemination (AI) of cows in the herd from which recipient females were selected. Gestation periods were not different among the groups (P > 0.05), but calves that developed from IVM/IVF-derived embryos co-cultured in vitro were larger at birth than calves born from IVM/IVF-derived embryos that developed into blastocysts in the sheep oviduct and calves born from AI (P < 0.001). Dystocia and calf mortality were associated with large calf size at birth. These data were collected from an experiment designed for other purposes, and confounding variables and small sample size could have influenced the observed differences in birth weights. Nevertheless, the extreme birth weights of some calves suggest that abnormal prenatal growth occurs in some IVM/IVF-derived bovine embryos and that conditions for co-culture to the blastocyst stage may exacerbate the problem.     

In vitro embryo development and blastocyst hatching rates following vitrification of river buffalo embryos produced from oocytes recovered from slaughterhouse ovaries or live animals by ovum pick-up

The present study was undertaken to determine whether the source of oocytes (ovum pick up versus slaughterhouse ovaries) affected in vitro embryo production and embryo survival (as measured by blastocyst hatching rates) following vitrification in buffaloes (Bubalus bubalis). Oocytes recovered from live buffaloes (n=6) by ovum pick up (OPU) and by manual aspiration from slaughterhouse ovaries were in vitro matured, fertilized and cultured to blastocyst stage under same culture conditions. Vitrification of blastocysts was carried out in two steps at 24 degrees C. Embryos were equilibrated in 10% EG+10% DMSO+0.3 M sucrose in base medium for 4 min. Subsequently, the embryos were transferred into 25% EG+25% DMSO+0.3 M sucrose in base medium for 45 s and then the embryos were loaded into straws and immersed in liquid nitrogen. Following warming, blastocysts were cultured in vitro for 48 h to assess hatching. Oocytes derived from live animals by OPU resulted in a significantly higher blastocyst yield then those derived from slaughterhouse ovaries (30.6+/-4.3 versus 18.5+/-1.8). Blastocyst hatching rates following vitrification of buffalo embryos produced from the oocytes collected from live animals by OPU was significantly higher than the oocytes collected from slaughterhouse ovaries (52.8+/-4.2 versus 40.2+/-4.4). In conclusion, the present study showed that source of oocytes (OPU versus slaughterhouse ovaries) affects the in vitro embryo development and blastocyst hatching rates following vitrification of embryos in buffaloes.     

Pregnancies following transfer of equine embryos cryopreserved by vitrification

The objective of this study was to investigate the in vitro and in vivo developmental abilities of equine embryos cryopreserved by vitrification. Twenty-eight embryos were recovered from Native pony and Thoroughbred mares at Days 5 to 7 by nonsurgical uterine flushing (detection of ovulation=Day 0). The vitrification solution contained 40% ethylene glycol, 18% Ficoll, and 0.3 M sucrose in PBS. The embryos were placed for 1 to 2 min in vitrification solution (Group 1) or following exposure to 20% ethylene glycol in PBS for 10 to 20 min (Groups 2 and 3). Single embryos were loaded in 0.25-ml straws, cooled for 1 min in liquid nitrogen vapor and immersed in liquid nitrogen. Straws were warmed in water (20 degrees C, 20 sec), and the contents were expelled with 0.5 M sucrose in PBS. Then the sucrose was diluted in 1-step (Groups 1 and 2) or 4-steps (Group 3). Embryos (n=21) were cultured for 120 h in TCM199 supplemented with 10% fetal bovine serum at 37 degrees C in 5% CO(2) in air and evaluated morphologically. Development to the hatching or hatched blastocyst stage was obtained in 0 7 , 4 7 and 4 7 embryos in Groups 1, 2 and 3, respectively. An additional 7 embryos were vitrified-warmed according to the treatment of Group 2 (4 embryos) and Group 3 (3 embryos). Five embryos were selected after in vitro culture for 4 h and were transferred nonsurgically into the uterine horn of Day-4 recipient mares. Transfer of 2 embryos (both Day-6 blastocysts: Group-2 treatment) resulted in pregnancies with a viable fetus at Day-60 of the gestation period.     

Vitrification of in vitro produced bovine embryos: in vitro and in vivo evaluations

The efficacy of different vitrification solutions to cryopreserve in vitro produced bovine blastocysts was evaluated based upon in vitro development of embryos in culture and on in vivo development of embryos transferred into recipients. In the first experiment, ethylene glycol + glycerol (Eg + Gly) + different sucrose concentrations were evaluated. There were no significant differences in development rates among solutions. As for hatching, the Eg + Gly + 0.1 M sucrose group had a greater rate as compared with Eg + Gly + 0 M sucrose and Eg + Gly + 0.5 M sucrose groups in the evaluations of Day 6, Day 7 and Day 6 + Day 7 embryos; and, Eg + Gly + 0.3 M sucrose group had a greater rate as compared with the Eg + Gly + 0 M sucrose and Eg + Gly + 0.5 M sucrose groups in evaluations of Day 6 and Day 6 + Day 7 embryos. There were no significant differences in development and hatching rates between Day 6 and 7 in in vitro produced bovine embryos within each treatment group. There were significant differences in nuclei number after vitrification between Eg + Gly + 0.1 M and Eg + Gly + 0 M sucrose groups and the Eg + Gly + 0.5 M sucrose group. Pregnancy after 60 days of transfer and calving rates showed a difference between in vivo produced embryos freshly transferred and in vitro produced embryos vitrified with Eg + Gly + 0.3 M. There were no significant differences in gestation length and sex ratio between treatments. As for birth weight, there were significant differences between fresh in vivo produced embryos and all treatments of in vitro produced embryos. There were significant differences in dystocial parturition between in vivo produced embryos and all treatments with in vitro produced embryos. These results demonstrate that vitrification can be used successfully in the cryopreservation of in vitro produced bovine embryos, and that it might be considered for use in commercial programs.     

Successful in vitro and in vivo development of in vitro fertilized two- to four-cell cat embryos following cryopreservation, culture and transfer

In vitro and in vivo survival of in vitro-derived 2- to 4-cell cat embryos following cryopreservation was examined. Prefreeze 1- vs 2-step cryoprotectant exposure (Experiment 1) and warming method (Experiment 2) on zona pellucida damage and development in vitro were compared. To determine viability in vivo, frozen/thawed embryos were cultured in vitro to the morula/early blastocyst stage and transferred to synchronous recipients (Experiment 3). At 24 to 26 h after IVF, embryos were cryopreserved in 1.4 M propanediol (Pr) + 0.125 M sucrose (Su) by cooling at 0.3 degrees C/min from -6 degrees C to -30 degrees C and storing in liquid nitrogen. Autologous embryos were cultured in vitro for 7 d. After warming for 5 sec in air and 10 sec at 37 degrees C in water (Experiments 1 to 3), or at room temperature air (22 degrees C; Experiment 2), the cryoprotectant was removed and embryos were cultured in vitro for 6 d (Experiments 1 and 2). Development was assessed after staining by counting cell numbers/embryo and determining the percentages at the 2- to 4-cell (nonsurvivor), pre (5 to 15), early (16 to 32), mid (33 to 50), late (>50) morula or blastocyst stages. Post-thaw development to late morula/blastocyst after 1-step exposure (68%, 15 min Pr + Su) was higher (P< 0.05) than that after 2-step exposure (36%, 15 min Pr and 15 min Pr + Su). Both warming methods produced similar percentages of embryos with damaged zonae (13 to 15%) and equivalent development to morula/blastocyst (64 to 69%). Development in vitro to early morula/blastocyst of frozen embryos with intact zonae was similar to that of nonfrozen embryos. Following cryopreservation, most 2- to 4-cell cat embryos retained their capability for in vitro development to morula/blastocyst, and in vivo viability was demonstrated by the birth of 3 live kittens to 2 of 4 recipients following the transfer of 58 embryos.     

Transfer of fresh and cryopreserved IVP bovine embryos: normal calving, birth weight and gestation lengths

In vitro and in vivo developmental competence of fresh and cryopreserved in vitro produced (IVP) bovine embryos was evaluated up to birth. Three experiments were done. The objective in the first experiment was to develop an optimal vitrification procedure for IVP bovine embryos by determining effects of exposure time (2, 5, 10, 20 min) and temperature (4, 22, 27 degrees C) in cryoprotective agents prior to vitrification on their post-thaw viability. The best combination was used in Experiments 2 and 3. In the second experiment, the importance of post-thaw morphologic selection on pregnancy rates was determined by transferring either selected or unselected single embryos. In the third experiment, pregnancy initiation, maintenance and calving results of vitrified embryos were compared with fresh and conventionally frozen embryos. Fetal losses, birth weights, gestation lengths and frequency of dystocia in the third experiment were monitored. The interaction of exposure time and temperature on both post-thaw re-expansion and hatching rates was significant (P < 0.01). Five minute exposure at 27 degrees C was optimal. In the second experiment, post-thaw selected vitrified embryos had higher pregnancy rates than unselected embryos (P < 0.05). In the third experiment, the pregnancy rate of vitrified embryos did not differ from that of fresh embryos (P > 0.05). However, pregnancy rate of conventionally frozen embryos was lower than that of fresh or vitrified embryos (P < 0.05). Of 92 calves born, 53 were male and 39 were female. Birth weights and dystocia scores of single-born calves did not differ between sexes (P > 0.05). Twin-born calves were lighter than single-born calves (P < 0.05). Overall, the data demonstrate that the transfer of vitrified IVP bovine embryos can result in healthy, apparently normal calves similar to those derived from transfer of fresh and conventionally frozen IVP bovine embryos.     

The placenta as a contributor to production of large calves.

Unusually high birth weights frequently occur in calves born from cultured bovine embryos. The mechanism(s) through which in vitro manipulations during early cleavage are translated to enhanced fetal growth is (are) incompletely understood. Accelerated growth is primarily prenatal, and the placenta of an in vitro-derived conceptus could account for abnormal fetal growth. Results from a systematic comparison of placental morphology and function in bovine concepti produced in vitro versus in vivo are discussed.     

Cryopreservation of in vitro matured buffalo (Bubalus bubalis) oocytes by minimum volumes vitrification methods

The aim of this study was to evaluate the efficiency of the solid surface vitrification (SSV) and the cryoloop vitrification (CLV) methods to cryopreserve in vitro matured buffalo oocytes. Another objective of the work was to investigate whether the presence of cumulus cells affects the efficiency of oocyte vitrification in this species. In the SSV method, oocytes were vitrified in a solution of 35% ethylene glycol, 5% polyvinyl-pyrrolidone and 0.4% trehalose and they were warmed in a 0.3M trehalose solution. In the CLV method, oocytes were vitrified in 16.5% ethylene glycol and 16.5% dimethyl sulfoxide and warmed in decreasing concentrations of sucrose. The oocytes that survived vitrification were fertilized and cultured in vitro up to the blastocyst stage. Although high survival rates were recorded in all groups, when the oocytes were vitrified by the CLV method in the absence of cumulus cells, the survival rate was significantly (P<0.05) lower. However, the CLV gave a significantly higher cleavage rate compared to the SSV with the denuded oocytes (45% versus 26%, respectively; P<0.05), whereas no differences were found between methods with the cumulus-enclosed oocytes (14% versus 15%, respectively). Blastocysts were produced for the first time from in vitro matured oocytes that were vitrified-warmed in buffalo. Nevertheless, vitrification significantly decreased blastocyst yield, regardless of both the method employed and the presence or absence of cumulus cells.     

Vitrification of bovine IVF blastocysts in an ethylene glycol/sucrose solution and heat-stable plant-extracted proteins

The use of heat-stable plant proteins in an ethylene glycol-based solution for the vitrification of in vitro-derived embryos was examined. Day 7, 8 and 9 bovine in vitro matured, fertilized and cultured (IVMFC), full and expanded blastocysts were vitrified in solutions composed of 40% ethylene glycol (EG) plus 0.3 M sucrose supplemented with 20% Ficoll and 0.3% BSA (VF-1), 25 mg/ml heat-stable plant proteins (HSPP; VF-2), or with no supplement (VF-3). In Experiment 1, embryos were expelled from the straw after thawing, and EG was diluted from embryos with 0.5 M sucrose. There were no differences in post-thaw embryo survival rates or in hatching/hatched rates after 24 h of culture between the VF-1, VF-2 and VF-3 solutions (40.1, 54.1 and 50.8% and 10.7, 16.4 and 17.5%, respectively). Transfer of 12 frozen/thawed embryos to 6 recipients (2 recipients per treatment) resulted in 2 pregnancies from the VF-2 group and 1 pregnancy from the VF-3 group. In Experiment 2, EG was diluted from embryos after thawing within the straw with 0.5 M sucrose. There were no differences in post-thaw survival or hatching/hatched rates after 24 h of culture (19.0, 13.6 and 23.8% and 9.5, 9.0 and 14.4% for VF-1, VF-2 and VF-3, respectively). Transfer of 6 frozen/thawed embryos to 3 recipients (1 recipient per treatment) resulted in no pregnancies. The post-thaw histology of Day 7, 8 and 9 IVMFC blastocysts showed typical ultrastructure with well preserved cell-to-cell contacts. There were no major differences in the fine structure of blastocysts regardless of treatment. The use of HSPP at a concentration of 25 mg/ml in the vitrification medium did not affect the post-thaw embryo survival over that of no protein supplementation. The presence of macro molecules in a 40% EG/sucrose vitrification solution also did not improve post-thaw viability of IVMFC-derived blastocysts.     

小鼠不同阶段胚胎玻璃化冷冻保存的比较研究

The cryopreservation of different embryo stages collected from ICR, C57BL/6 and F1 of DBA*C57BL/6 was carried out by using vitrification method. The morphology, in vitro development and birth rates of these embryos were compared after frozen-thawed. The results showed that more than 75% of the morphology from 2-cell embryos to morula stages from different strains was normal, the normal morphology rates of 8-cell embryos being the highest, while those of blastulas being the lowest. The in vitro development rates became higher as the embryos developed. The morphology of in vivo and in vitro fertilized frozen 2-cell embryos showed no difference, but the development rate of in vivo fertilized frozen 2-cell embryos was significantly higher than that of in vitro ones. Embryos that underwent 3 times frozen-thawing remained normal morphology. The pregnant rate and birth rate of frozen 2-cell embryos after embryo transfer were 64% and 40% respectively, but lower than those of fresh 2-cell embryo transfer.     

Nonelectrophoretic PCR-sexing of bovine embryos in a commercial environment

Techniques for sex determination of bovine embryos have evolved from karyotyping of older preimplantation embryos some 25 years ago to the current variety of widely used polymerase chain reaction (PCR) protocols. Although highly accurate, most PCR protocols for sex determination have included an electrophoresis step. The present work is a retrospective study utilizing a unique PCR protocol to sex bovine embryos without use of electrophoresis in a commercial embryo transfer program. Both in vivo and in vitro-derived embryos were produced by conventional techniques and biopsied between 7 and 8 days of age with a steel blade attached to a mechanical micromanipulator. Males constituted 49.0% of 3964 in vivo and 53.0% of 1181 in vitro-derived embryos subjected to PCR. Based on ultrasound fetal sexing and on calvings, the accuracy of sex determination was 98.7% for male embryos and 94.4% for females, with no samples producing an undetermined outcome. Pregnancy rates following transfer of biopsied Grade 1 embryos were lower than control, intact embryos as follows: 8, 6 and 16% points for in vivo, in vitro and in vivo frozen embryos, respectively. Pregnancy rates were similar for all stages of in vivo-derived embryos, whereas the pregnancy rate was significantly lower for in vitro-derived morulae compared to all stages of blastocysts. The sex ratio was significantly skewed in favor of females among in vitro-derived morulae, and in favor of males among in vitro expanded blastocysts. The sex ratio of in vivo expanded blastocysts was significantly skewed in favor of female embryos. No seasonal variation in either pregnancy rate or sex ratio was detected. There was no evidence that DNA contamination influenced the PCR assay during the duration of the study. The assay was sensitive to single blastomeres from male embryos, whereas it was not sensitive to Percoll-centrifuged or accessory sperm cells.     

Nuclear transplantation in the bovine embryo: assessment of donor nuclei and recipient oocyte

Blastomeres from 2- to 32-cell bovine embryos were transferred to enucleated oocytes matured either in vivo or in vitro by micromanipulation and electrofusion. The percentage of donor cells fusing with the recipient oocytes was dependent on relative cell size or stage of development. Therefore, when smaller donor karyoplasts (17- to 32-cell vs. 2- to 8-cell) were transferred, the rate of fusion was significantly less (p less than 0.01). After fusion, nuclear transfer embryos were cultured either in vitro or in vivo (in a ligated ovine oviduct). Nuclear transfer embryos cultured in vitro developed to the 4- to 6-cell stage after 72 h (4-cell, 71%; 8-cell, 33%, 16-cell, 33%; p less than 0.30), whereas nuclear transfer embryos cultured in vivo developed to the morula or blastocyst stage (2- to 8-cell, 11.7%; 9- to 16-cell, 16.0%; 17- to 32-cell, 8.3%; p greater than 0.30) after 4 or 5 days. Freshly ovulated oocytes (collected 36 h after the onset of estrus), when used as recipients, resulted in morula/blastocyst-stage embryos more often than in vitro-matured oocytes or in vivo-matured oocytes collected 48 h after the onset of estrus (20% vs. 7.8% and 6.7%, respectively; p less than 0.02). After in vivo culture, nuclear transfer embryos were mounted and fixed or transferred nonsurgically to the uteri of 6- to 8-day postestrus heifers. Seven pregnancies resulted from the transfer of 19 embryos into 13 heifers; 2 heifers completed pregnancy with the birth of live calves.(ABSTRACT TRUNCATED AT 250 WORDS)     

小鼠不同阶段胚胎玻璃化冷冻保存的比较研究

采用玻璃化冷冻法对ICR、C57BL/6、DBA~*C57BL/6杂交F1代三种品系小鼠的不同阶段胚胎进行冷冻保存,比较胚胎解冻后形态良好率、体外发育率和移植后的出生率,结果表明解冻后各品系小鼠胚胎从2细胞到桑椹胚形态良好率在75%以上,其中8细胞胚胎形态良好率在83%以上,而囊胚的形态良好率仅在40%左右。解冻后胚胎体外培养的发育率随胚胎发育阶段的提高而提高,桑椹胚的发育达93%以上。体外受精2细胞冷冻胚与体内受精2细胞冷冻胚比较,二者形态良好率差异无显著意义(74%∶75%),但体内受精冷冻胚的发育率明显高于体外受精冷冻胚(76%:40%,p<0.01);胚胎经过三次反复冻融后形态良好率无显著差别;冷冻2细胞胚移植后的受孕率与仔鼠出生率分别达64%和40%,但均低于新鲜2细胞胚。     

Production of transgenic mice following deoxyribonucleic acid microinjection and embryo freezing

Experiments with mouse embryos were designed to assess the feasibility of freezing embryos after DNA microinjection. One-cell pronuclear stage mouse embryos were microinjected with cloned deoxyribonucleic acid (DNA) and cultured in vitro to the late eight-cell stage. Microinjected and matched control embryos were frozen and stored in liquid nitrogen. Following thawing, embryos were cultured for 8 h and transferred to recipient females. In a separate set of experiments, embryos were transferred to recipients immediately following DNA microinjection. Control (uninjected) embryos developed to the late eight-cell stage significantly better than surviving microinjected embryos. Of the embryos thawed, 76% of the microinjected and 60% of the control embryos survived to be transferred to recipients. Progeny were obtained with similar survival rates from both groups following embryo transfer with transgenic mice identified among the progeny from microinjected embryos. Mouse embryos can be microinjected with DNA, cultured in vitro, frozen, thawed, transferred to recipients and transgenic progeny can be obtained.     

Cryopreservation of goat oocytes and in vivo derived 2- to 4-cell embryos using the cryoloop (CLV) and solid-surface vitrification (SSV) methods

This study evaluated the efficiency and toxicity of two cryopreservation methods, solid-surface vitrification (SSV) and cryoloop vitrification (CLV), on in vitro matured oocytes and in vivo derived early stage goat embryos. In the SSV method, oocytes were vitrified in a solution of 35% ethylene glycol (EG), 5% polyvinyl-pyrrolidone (PVP), and 0.4% trehalose. Microdrops containing the oocytes were cryopreserved by dropping them on a cold metal surface that was partially immersed in liquid nitrogen. In the cryoloop method, oocytes were transferred onto a film of the CLV solution (20% DMSO, 20% EG, 10mg/ml Ficoll and 0.65 M sucrose) suspended in the cryoloop. The cryoloop was then plunged into the liquid nitrogen. In vivo derived embryos were vitrified using the same procedures. The SSV microdrops were warmed in a solution of 0.3M trehalose and those vitrified with CLV were warmed with incubation in 0.25 and 0.125 M sucrose. Oocytes and embryos vitrified by the SSV method had a significantly lower survival rate than the control (60 and 39% versus 100%, respectively; P<0.05), while the survival rate of CLV oocytes and embryos (89 and 88%, respectively) did not differ from controls. Cleavage and blastocyst rates of the surviving vitrified oocytes (parthenogenetically activated) and embryos (cultured for 9 days) were not significantly different (P>0.05) from the control nor did they differ between vitrification methods. Embryos vitrified with the CLV method gave rise to blastocysts (2/15). Our data demonstrated that the two vitrification methods employed resulted in acceptable levels of survival and cleavage of goat oocytes and embryos.     

Blastocyst viability and generation of transgenic cattle following freezing of in vitro produced, DNA-injected embryos

This study examined whether the viability, determined in vitro, of DNA-injected bovine embryos produced in vitro was affected by freezing, and if the frozen embryos developed to term following transfer to recipients. In vitro fertilized zygotes were injected with the pBL1 gene and then co-cultured with mouse embryonic fibroblasts (MEF) in CR1aa medium. Embryos were prepared for cryopreservation by exposure to a 10% (v/v) glycerol solution, loaded into 0.25 ml straws and then frozen by conventional slow freezing. Thawing was by rapid warming in water (37 degrees C) and embryos were rehydrated in PBS diluents of 6%, 3% and 0% (v/v) glycerol supplemented with 0.25 M sucrose and 0.5% (w/v) BSA. In Experiment 1, blastocysts that developed from DNA-injected embryos were individually classified into three morphological groups and three stages of development prior to freezing. DNA-injected blastocysts of excellent quality at freezing showed a higher survival rate (78.8+/-10.6%) after thawing than those of good (60. 9+/-16.4%) or fair (12.5+/-5.9%) quality (P<0.05). Post-thaw survival rate, judged in vitro, increased with more advanced stage of blastocyst development at freezing (early 48.8+/-15.9%, mid 52. 1+/-12.6% and expanded 71.2+/-1.1; P<0.05). In Experiment 2, the frozen/thawed embryos were transferred to recipients to examine in vivo viability. Following transfer of one or two embryos per recipient, pregnancy rates at 60 days of gestation were 13.6% (13/96) for frozen embryos and 26.5% (43/162) for fresh embryos (P<0. 05). Of the 12 live calves born from the frozen/thawed embryos, two males (18.3%) were transgenic. None of the live-born calves derived from fresh embryos exhibited the transgene. One of transgenic bulls did not produce transgenic sperm. Three out of 23 calves (13.0%) produced from cows inseminated with semen of the other bull were transgenic, suggesting that this animal was a germ-line mosaic. These studies indicated that the viability of in vitro produced, DNA-injected bovine blastocysts was affected by freezing and by both the quality and stage of development of the embryo prior to freezing. The generation of transgenic cattle demonstrates that it is feasible to freeze DNA-injected, in vitro produced embryos.     

Abnormal offspring following in vitro production of bovine preimplantation embryos: a field study

Data on 944 calves from 2228 in vitro-produced (IVP) bovine preimplantation embryos were compared with data on 2787 AI calves born in the same herds in 1995. Bovine preimplantation embryos were produced in vitro following ovum pick up (OPU) from donor cows and pregnant heifers in an open nucleus breeding program. After 7 d of in vitro culture on a BRL cell monolayer in the presence of 10% FCS, frozen-thawed expanded blastocysts and fresh morulae to expanded blastocysts were transferred into recipient heifers and cows at 119 contracted farms throughout the Netherlands. The pregnancy rate, as confirmed by palpation per rectum between 90 and 150 d after transfer was 43.5% for both fresh and frozen embryos. Data on IVP and AI calves were registered by the farmers. The percentage of calves with a congenital malformation and the percentage of male calves were related to the total number of calves born. Gestation length, birth weight (measured by a balance), perinatal mortality and ease of calving were analyzed in a subdataset (699 IVP and 2543 AI calves, respectively) by a comparative analysis of variance (ANOVA). The ANOVA model included herd, month of calving, sire nested within AI or IVP, parity and breed of the inseminated cow/embryo recipient, sex of calf, type of calf (AI or IVP) and two-way interactions between type of calf and sex, parity and breed. The percentage of calves with congenital malformations was 3.2% and 0.7% for IVP and AI calves, respectively. An increased incidence of hydro-allantois and abnormal spinal cords and limbs was observed in IVP calves. The percentage of male calves was significantly different between IVP and AI, 55.5% and 48.9%, respectively (Chi-square, 1 degree of freedom, P < 0.05). On the average, IVP calves showed a significant increase of birth weight by 10% (4-5 kg), a 3-d longer gestation period, 2.4% more perinatal mortality and a more difficult calving process compared to AI calves (P < 0.05). From these results it is concluded that calves produced by IVP deviate significantly from calves produced by AI.     

In vitro embryo production in buffalo (Bubalus bubalis) using sexed sperm and oocytes from ovum pick up

The objective was to explore the use of sexed sperm and OPU-derived oocytes in an IVP system to produce sex-preselected bubaline embryos. Oocytes were recovered from 20 fertile Murrah and Nili-Ravi buffalo cows by repeated (twice weekly) ultrasound-guided transvaginal ovum pick up (OPU), or by aspiration of abbatoir-derived bubaline ovaries, and subjected to IVF, using frozen-thawed sexed or unsexed bubaline semen. On average, 4.6 oocytes were retrieved per buffalo per session (70.9% were Grades A or B). Following IVF with sexed sperm, oocytes derived from OPU had similar developmental competence as those from abattoir-derived ovaries, in terms of cleavage rate (57.6 vs. 50.4%, P=0.357) and blastocyst development rate (16.0 vs. 23.9%, P=0.237). Furthermore, using frozen-thawed sexed versus unsexed semen did not affect rates of cleavage (50.5 vs. 50.9%, P=0.978) or blastocyst development (15.3 vs. 19.1%, P=0.291) after IVF using OPU-derived oocytes. Of the embryos produced in an OPU-IVP system, 9 of 34 sexed fresh embryos (26.5%) and 5 of 43 sexed frozen embryos (11.6%) transferred to recipients established pregnancies, whereas 7 of 26 unsexed fresh embryos (26.9%) and 6 out of 39 unsexed frozen embryos (15.4%) transferred to recipients established pregnancies. Eleven sex-preselected buffalo calves (10 females and one male) and 10 sexed buffalo calves (six females and four males) were born following embryo transfer. In the present study, OPU, sperm sexing technology, IVP, and embryo transfer, were used to produce sex-preselected buffalo calves. This study provided proof of concept for further research and wider field application of these technologies in buffalo.     

Genetic and environmental determinants of interferon-tau secretion by in vivo- and in vitro-derived bovine blastocysts

Several experiments were conducted to assess the effects of genotype and various culture media on interferon-tau secretion by in vitro-derived bovine blastocysts and to compare these values with interferon released by blastocysts flushed from superovulated cows. In experiment 1, oocytes were inseminated with semen from three different bulls. While paternal genotype had no effect on cleavage rate, the size or hatching ability of blastocysts, it was a significant determinant of the embryo's ability to develop to the blastocyst stage and of subsequent interferon-tau secretion. In the second experiment, embryos were cultured in synthetic oviductal fluid containing either polyvinyl alcohol, bovine serum albumin or fetal bovine serum. While there was no effect of supplement on the percentage of embryos developing to the blastocyst stage, blastocysts which formed in medium with polyvinyl alcohol had significantly fewer cells, were older at blastocyst formation and produced significantly more interferon-tau. In the third experiment, embryos were cultured to the blastocyst stage in either TCM199 alone or in co-culture with buffalo rat liver, bovine oviductal or bovine uterine epithelial cells. Culture with oviductal or buffalo rat liver cells increased blastocyst cell number, although secretion of interferon-tau was not affected. In the final experiment, bovine blastocysts were flushed from superovulated cows on Day 7 following insemination. Overall, secretion of interferon-tau by in vivo-produced blastocysts did not differ from that of age-matched blastocysts produced in vitro.