Embryo development rates after transfer of oocytes matured in vivo, in vitro, or within oviducts of mares

Objectives of the present study were to use oocyte transfer: 1) to compare the developmental ability of oocytes collected from ovaries of live mares with those collected from slaughterhouse ovaries; and 2) to compare the viability of oocytes matured in vivo, in vitro, or within the oviduct. Oocytes were collected by transvaginal, ultrasound-guided follicular aspiration (TVA) from live mares or from slicing slaughterhouse ovaries. Four groups of oocytes were transferred into the oviducts of recipients that were inseminated: 1) oocytes matured in vivo and collected by TVA from preovulatory follicles of estrous mares 32 to 36 h after administration of hCG; 2) immature oocytes collected from diestrous mares between 5 and 10 d after aspiration/ovulation by TVA and matured in vitro for 36 to 38 h; 3) immature oocytes collected from diestrous mares between 5 and 10 d after aspiration/ovulation by TVA and transferred into a recipient's oviduct <1 h after collection; and 4) im mature oocytes collected from slaughterhouse ovaries containing a corpus luteum and matured in vitro for 36 to 38 hours. Embryo development rates were higher (P < 0.001) for oocytes matured in vivo (82%) than for oocytes matured in vitro (9%) or within the oviduct (0%). However, neither the method of maturation nor the source of oocytes affected (P > 0.1) embryo development rates after the transfer of immature oocytes.     

Development to live young from bovine small oocytes after growth, maturation and fertilization in vitro

Bovine oocytes (90 to 99 microns in diameter) were isolated from early antral follicles (0.5 to 0.7 mm in diameter). Cumulus-oocyte complexes (COC) with pieces of parietal granulosa were embedded in collagen gels and cultured for 14 d. After in vitro growth culture, oocytes recovered from the collagen gels were further matured, fertilized and cultured in vitro, and then were transferred to recipient cows. After 14 d of growth culture, 37% of the oocytes (203/556) showed normal morphology in the collagen gels. The mean diameter of the oocytes was 110.1 +/- 6.0 microns, significantly larger (P < 0.01) than before growth culture (94.8 +/- 2.7 microns), and 77% were at the germinal vesicle stage while 23% had undergone germinal vesicle breakdown. After 24 h of maturation culture followed by insemination, 27% of in vitro-grown oocytes reached the second metaphase, and 42% of the oocytes were normally fertilized. After insemination, 18.2% of in vitro-grown oocytes cleaved and 3.7% developed to the blastocyst stage. Three blastocysts obtained from in vitro-produced 90- to 99-micron oocytes were transferred to 3 recipients. One recipient subsequently became pregnant and delivered a live calf on Day 277. These results demonstrated for the first time that 90 to 99-micron oocytes from early antral follicles can complete growth and acquire full developmental competence in vitro so that live young can be produced after maturation, fertilization, subsequent culture in vitro, and transfer to recipient cows.     

Pregnancies from vitrified equine oocytes collected from super-stimulated and non-stimulated mares

The objectives were to compare embryo development rates after transfer into inseminated recipients, vitrified thawed oocytes collected from super-stimulated versus non-stimulated mares. In vivo matured oocytes were collected by transvaginal, ultrasound guided follicular aspiration from super-stimulated and non-stimulated mares 24-26 h after administration of hCG. Oocytes were cultured for 2-4 h prior to vitrification. Cryoprotectants were loaded in three steps before oocytes were placed onto a 0.5-0.7 mm diameter nylon cryoloop and plunged directly into liquid nitrogen. Oocytes were thawed and the cryoprotectant was removed in three steps. After thawing, oocytes were cultured 10-12 h before transfer into inseminated recipients. Non-vitrified oocytes, cultured 14-16 h before transfer, were used as controls. More oocytes were collected from 23 non-stimulated mares (20 of 29 follicles), than 10 super-stimulated mares (18 of 88 follicles; P < 0.001). Of the 20 oocytes collected from non-stimulated mares, 12 were vitrified and 8 were transferred as controls. After thawing, 10 of the 12 oocytes were morphologically intact and transferred into recipients resulting in one embryonic vesicle on Day 16 (1 of 12 = 8%). Fourteen oocytes from super-stimulated mares were vitrified, and 4 were transferred as controls. After thawing, 9 of the 14 oocytes were morphologically intact and transferred into recipients resulting in two embryonic vesicles on Day 16 (2 of 14 = 14%). In control transfers, 7 of 8 oocytes from non-stimulated mares and 3 of 4 oocytes from super-stimulated mares resulted in embryonic vesicles on Day 16. The two pregnancies from vitrified oocytes resulted in healthy foals.     

Full-term development of bovine follicular oocytes matured in culture and fertilized in vitro

Follicular oocytes were cultured for 28h in vitro and 91% of the oocytes reached the the second metaphase in culture. The penetration rate after insemination in vitro using frozen-thawed spermatozoa was 81%. After cultivation for 48h in vitro, 18% of the in vitro fertilized oocytes developed to the three- to four-cell stages and 21% of these developed to the six- to eight-cell stages. Following in vivo culture in the rabbit oviduct, 18% of six- to eight-cell and 5% of three- to four-cell embryos developed to the blastocyst stage. To confirm the full developmental competence, 11 blastocysts were transferred to recipient cows, and six (55%) cows became pregnant or delivered calves.     

Heterogeneous nuclear-transferred-embryos reconstructed with camel (Camelus bactrianus) skin fibroblasts and enucleated ovine oocytes and their development H-M

This study reconstructed heterogeneous embryos using camel skin fibroblast cells as donor karyoplasts and ovine oocytes as recipient cytoplasts for investigating the developmental potential of the reconstructed embryos. Serum-starved adult camel skin fibroblast cells were used as donor somatic cells. Ovine oocytes matured in vitro were employed as recipient cytoplasts. The fusion of fibroblast cells into recipient cytoplasm was induced by electrofusion. The fused oocytes were activated by 5mM/ml inomycin with 2mM/ml 6-dimethylaminopurine (6-DMAP). The activated reconstructed embryos were co-cultured with ovine cumulus cells in synthetic oviduct fluid supplemented with amino acid (SOFaa) and 10% fetal calf serum (FCS) for 168h. A total of 300 enucleated ovine oocytes were available for xenonuclear embryo reconstruction. The results showed that 71% of the nuclear transfer couplets were successfully fused, 55% of the fused oocytes cleaved within 48h after activation, 82% of the cleaved oocytes developed to 2-16-cell embryo stages and 18% of the cleaved nuclear transfer zygotes developed to the morula stage. This study demonstrated that the xenonuclear transfer camel embryos can undergo the first embryonic division and subsequent development to morula stage in vitro.     

In vitro culture of sheep oocytes matured and fertilized in vitro

Sheep oocytes that matured and fertilized in vitro were cultured to evaluate their cleavage to the 8- to 16- cell stage and further development in five different media as follows: 1) CPMW (TCM199 + 20% ewe serum + 0.4% BSA), 2) Ham's F-10 + 10% ewe serum, 3) Brinster's pyruvate medium + 0.1% glucose (BPM-G), 4) co-culture with sheep oviduct epithelial cells in TCM199 + 10% fetal calf serum, and 5) co-culture with sheep granulosa cells in the same medium as 4. The culture duration was 4 or 7 d for 8- to 16-cell or further development. The proportions of 8- to 16-cell eggs were 1) 16% (8 49 ), 2) 25% (12 49 ), 3) 52% (58 112 ), 4) 63% (105 167 ) and 5) 45% (27 60 ). The co-culture with sheep oviduct cells resulted in a significantly (P < 0.05) higher rate of cleavage than the other media, except BPM-G. The proportion of noncompacted morula (35%, 24 68 ) was also significantly (P < 0.05) higher in the co-culture of sheep oviduct cells than the other media. The 8- to 16-cell eggs produced by BPM-G (n=38) and the co-culture with sheep oviduct cells (n=42) were transferred into the uterus of recipient ewes, but no elongated blastocysts were obtained 13 d later. On the other hand, 8 out of 55 one-cell eggs (15 to 18 h after in vitro insemination) transferred to the oviduct of recipient ewes were elongated blastocysts (24% of 34 recovered eggs). The data show that the co-culture of in vitro fertilized eggs with sheep oviduct epithelial cells could support development of 8- to 16-cell embryos or early morula, but their viability is still questionable.     

Birth of normal calves resulting from bovine oocytes matured, fertilized, and cultured with cumulus cells in vitro up to the blastocyst stage

Bovine oocytes matured in vitro were fertilized in high proportions (92% of matured oocytes) by sperm capacitated with Ca ionophore A23187. Eight percent of inseminated oocytes that were denuded 96 h after insemination developed to the morula stage when cultured for 6-120 h after insemination with cumulus cells from the original oocytes. Inseminated oocytes denuded 96 h after insemination developed to the blastocyst stage when cultured with or without cumulus cells or in the conditioned medium from 96 h to 168-216 h after insemination (9.0%, 8.1%, and 6.8% of inseminated oocytes respectively). Six frozen-thawed blastocysts were transferred nonsurgically to 3 recipients (2 embryos/recipient). Two of the 3 recipients became pregnant, with one delivering live twins at term. Seven fresh blastocysts were transferred nonsurgically to 6 recipients (1-2 embryos/recipient). Three of the 6 recipients became pregnant, with 2 delivering live calves.     

Cloning of bovine embryos by multiple nuclear transfer

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

In vitro maturation and transfer of equine oocytes after transport of ovaries at 12 or 22 degrees C

Transportation of equine ovaries would allow shipment of oocytes for research purposes or transfer after the death of a valuable mare. The objective of this study was to compare two temperatures for maintaining ovaries during a transport interval of 18-24 h. The goal was to obtain pregnancies after transport of ovaries, maturation of oocytes in vitro, and transfer of oocytes. Each shipment was composed of ovaries four to seven mares collected from an abattoir. From each mare, one ovary was packaged at approximately 12 degrees C, and the other was packaged at approximately 22 degrees C. Upon arrival at our laboratory, oocytes were collected and cultured for 24 h. For each transfer, between 9 and 15 oocytes from each group were placed into the oviducts of estrous mares through standing flank laparotomies. Recipients received human chorionic gonadotropin (hCG; 2000 IU, i.v.) 30-36 h before transfer (to synchronize ovulation). Recipients were inseminated 18-20 h before transfers with 2 x 10(9) progressively motile sperm. Uteri of recipients were examined with ultrasound to determine the number of developing embryos. On Day 16 ( ovulation = day 0), developing embryos were recovered by uterine lavage. Parentage verification was performed on recovered vesicles. Pregnancy rates were analyzed by Chi-square. The percentage of oocytes that developed into embryonic vesicles on Day 16 was not different between transport temperatures (22 degrees C, 13/73, 18% versus 12 degrees C, 11/73, 15%). In conclusion, pregnancies were obtained from in vitro matured oocytes that were recovered from ovaries transported for 18-24h at 12 or 22 degrees C.     

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)     

Oocyte transfer in mares with intrauterine or intraoviductal insemination using fresh, cooled, and frozen stallion semen

The objectives were to compare embryo development rates after oocyte transfer with: (1) intrauterine or intraoviductal inseminations of fresh semen versus intraoviductal insemination of frozen semen; (2) intraoviductal versus intrauterine inseminations of cooled semen. In Experiment I, oocytes were transferred into the oviduct, and recipients were inseminated into the uterus with 1 x 10(9) fresh spermatozoa, or into the oviduct with 2 x 10(5) fresh or frozen-thawed spermatozoa. In Experiment II, semen was cooled to 5 degrees C before intrauterine insemination with 2 x 10(9) spermatozoa or intraoviductal inseminations of 2 x 10(5) spermatozoa (deposited with the oocytes). In Experiment I, embryo development rates were similar (P>0.05) for intrauterine versus intraoviductal inseminations when fresh semen was used (8/14, 57% and 9/11, 82%, respectively). However, embryo development rates were lower (P<0.05) when frozen spermatozoa were placed within the oviduct (1/12, 8%). In Experiment II, embryo development rates were higher (P<0.05) when cooled semen was used for intrauterine (19/23, 83%) versus intraoviductal (4/16, 25%) inseminations. We concluded that intraoviductal insemination can be successfully performed using fresh spermatozoa. However, the use of cooled and frozen spermatozoa for intraoviductal inseminations was less successful, and needs further investigation.     

IN VITRO FERTILIZATION OF IN VITRO MATURED MINKE WHALE (BALAENOPTERA ACUTOROSTRATA) FOLLICULAR OOCYTES

In vitro fertilization of follicular oocytes harvested from ovaries and matured in vitro was attempted for 55 minke whales ( Balaenoptera acutorostrata ) captured for Japanese research purposes in the Antarctic Ocean during the period from November 1995 to March 1996. In Experiment 1, effects of culture duration (96 h or 120 h) on maturation of follicular oocytes and addition of caffeine (5 mM) and/or heparin (100 pg/ml) on sperm penetration and pro-nuclear formation were investigated. Spermatozoa recovered from the vasa deferentia of four mature males were diluted (5-fold) and frozen at - 80°C. The post-thawed and pooled spermatozoa were used for in vitro insemination. A higher ( P < 0.05) proportion of the oocytes cultured for 120 h (34.2% of 260) progressed beyond the second metaphase stage than of the oocytes cultured for 96 h (26.0% of 262). For the matured oocytes, higher rates of penetration ( P < 0.05) and pronuclear formation ( P < 0.01) were obtained in the oocytes cultured for 120 h (55.1% and 40.4%) than in those cultured for 96 h (32.4 % and 20.6%). Addition of caffeine and heparin did not show a significant effect. In Experiment 2, follicular oocytes matured for 120 h and then inseminated were cultured to examine the subsequent development in two culture systems (with and without co-cultured cumulus cells). Of 448 inseminated oocytes, cleaved embryos (2–16 cells) were observed with (5.8%) and without (4.9%) co-cultured systems. No cleavage was observed in 54 ova without insemination. These results indicate that in vitro fertilization of minke whale in vitro matured follicular oocytes with cryopreserved spermatozoa is possible, yielding cleaved embryos.     

Laparoscopic oviductal transfer of in vitro matured and in vitro fertilized bovine oocytes

The objective of this study was to obtain normal pregnancy following laparoscopic oviductal transfer of in vitro matured and fertilized bovine oocytes. Methods for in vitro maturation and in vitro fertilization were similar to those previously reported (1). Primary oocytes judged to be potentially viable were cultured for 26 h in modified TCM 199 supplemented with heat-treated fetal calf serum (20% v/v), 5mug/ml FSH (USDA-bFSH-B-1), and 1mug/ml estradiol 17-beta. Oocyte cumulus complexes were microscopically evaluated for maturation (first polar body formation) following a brief treatment with hyaluronidase. Mature oocytes were inseminated with heparin-treated spermatozoa and incubated at 39 degrees C under paraffin oil and moist 5% CO(2), 5% O(2), 90% N(2). In this work, 450 oocytes were recovered at slaughter from ovaries of 42 random cows of unknown reproductive status and 336 oocytes (74.7%) with compact cumulus were selected for culture. Of these, 322 (95.4%) matured in vitro. Of 218 inseminated oocytes, 198 (90.8%) were penetrated by sperm and 83 (38.1%) cleaved, with 102 (46.6%) of the embryos reaching four- to eight-cell stages. None of 40 oocytes not exposed to sperm and none of 30 oocytes inseminated with untreated sperm showed signs of activation. In a control experiment with hormones added, 105 of 115 (91.3%) oocytes matured in vitro and 20 of 105 (19.5%) cleaved following in vitro insemination. Laparoscopy was performed on four synchronized recipients under local anesthesia. A catheter containing three embryos in the two to four cell stages was passed through the operating channel of a direct viewing bronchoscope for deposition in the oviduct ipsilateral to the recipients developing corpus luteum while the fimbria and the mesovarium were manipulated with Semm's forceps. A normal term pregnancy confirmed in vitro fertilization and provides feasibility data for use of laparoscopic methodology developed in this work for testing viability of bovine oocytes and embryos. These results are encouraging for the application of in vitro maturation and in vitro fertilization for overcoming infertility in domestic and endangered species.     

Embryo technologies in the horse

Recent studies demonstrated that zwitterionic buffers could be used for satisfactory storage of equine embryos at 5 degrees C. The success of freezing embryos is dependent upon size and stage of development. Morulae and blastocysts <300 microm can be slowly cooled or vitrified with acceptable pregnancy rates after transfer. The majority of equine embryos are collected from single ovulating mares, as there is no commercially available product for superovulation in equine. However, pituitary extract, rich in FSH, can be used to increase embryo recovery three- to four-fold. Similar to human medicine, assisted reproductive techniques have been developed for the older, subfertile mare. Transfer of in vivo-matured oocytes from young, healthy mares into a recipient's oviduct results in a 70-80% pregnancy rate compared with a 30-40% pregnancy rate when the oocytes are from older, subfertile mares. This procedure can also be used to evaluate in vitro maturation systems. In vitro production of embryos is still quite difficult in the horse. However, intracytoplasmic sperm injection (ICSI) has been used to produce several foals. Cleavage rates of 60% and blastocyst rates of 30% have been reported after ICSI of in vitro-matured oocytes. Gamete intrafallopian tube transfer (GIFT) is a possible treatment for subfertile stallions. Transfer of in vivo-matured oocytes with 200,000 sperm into the oviduct of normal mares resulted in a pregnancy rate of 55-82%. Oocyte freezing is a technique that has proven difficult in most species. However, equine oocytes vitrified in a solution of ethylene glycol, DMSO, and Ficoll and loaded onto a cryoloop resulted in three pregnancies of 26 transfers and two live foals produced. Production of a cloned horse appears to be likely, as several cloned pregnancies have recently been produced.     

Influence of hardening of the zona pellucida on in vitro fertilization of bovine oocytes

The influence of hardening of the zona pellucida of in vivo matured bovine oocytes on fertilizability was investigated. For the study, 163 preovulatory and 73 postovulatory oocytes recovered from superovulated heifers were used. The preovulatory oocytes, before they were used for in vitro fertilization, consisted of: 1) those cultured in vitro for 4 to 6 h to permit final maturation and 2) those incubated in the rabbit oviduct for 4 to 5 h to permit final maturation and induce hardening of the zona pellucida. A few oocytes served as a control of nuclear maturity and the zona pellucida solubility. Preovulatory and postovulatory oocytes were both inseminated in vitro using frozen-thawed, heparin treated and swim-up separated spermatozoa. Significant differences (P<0.01) were established between fertilization rates of cultured preovulatory oocytes (68.8%) and those incubated in the rabbit oviducts (42.9%), or those recovered from bovine oviducts (40.7%). It can be concluded that hardening of the zona pellucida distinctly influences the fertilizability of oocytes. This factor should be taken into account when considering the source of oocytes or the kind of treatment to be used for in vitro fertilization.     

Maturation and fertilization of pig follicular oocytes cultured in pig amniotic fluid

Three experiments were conducted to assess the ability of pig amniotic fluid to support oocyte maturation and developmental competence. In Experiment 1, pig follicular oocytes were cultured in pig amniotic fluid (PAF) containing luteinizing hormone (LH) and estradiol-17beta for 28 to 48 h, during which time the maturational stages of the oocytes were observed. While the maturation rates to the second metaphase were high (62%) after 33 h of culture, the rates decreased (24 to 30%) when oocytes were cultured in PAF without LH. In Experiment 2, oocytes matured in PAF were inseminated in vitro with fresh semen from three boars. The spermatozoal penetration rate ranged from 42 to 100%, and 15 to 40% of the penetrated oocytes had both male and female pronuclei. In Experiment 3, oocytes were cultured for 46 to 47 h in PAF and transferred to the oviducts of inseminated gilts. Eighteen of 136 embryos recovered from the uteri 128 h after oocyte transfer developed to the morula and blastocyst stages. The embryos were transferred to a recipient, and two piglets were born (one live and one dead) of the resultant pregnancy. These results indicate that PAF can be used for maturation of pig follicular oocytes and that oocytes cultured in PAF have the developmental capacity to become piglets.     

Histone H1 kinase activity during in vitro fertilization of pig follicular oocytes matured in vitro

The present study was conducted to clarify the relationship between histone H1 kinase (H1K) activity and events associated with in vitro fertilization of pig follicular oocytes matured in vitro. Histone H1 kinase has been shown to be homologous with a maturation promoting factor (MPF). Cumulus-oocyte complexes obtained from prepubertal gilts were cultured for 46 h in a modified Waymouth's MB752/1 medium and were then inseminated in vitro with frozen-thawed and preincubated epididymal boar spermatozoa. At 4, 6, 8 and 10 h post insemination, the oocytes were stained with 10 microg/ml Hoechst-33342 and examined under a fluorescent microscope for the stage of fertilization, according to morphological changes of oocyte nuclear chromatin and the extent of sperm penetration. Sperm penetration was observed to occur within 4 h post insemination (20.5%), and the percentage of fertilized oocytes increased (P < 0.01) to 72.9% at 8 h post insemination. Pronuclear formation was observed from 6 h post insemination (3.3%) and the percentage increased (P < 0.01) to 46.8% at 10 h post insemination. In each examination period, H1K activities in unfertilized oocytes at metaphase-II remained unchanged (112.0 fmol/h/oocyte) and were higher (P < 0.01) than those in fertilized oocytes (30.1 fmol/h/oocyte). The H1K activity in fertilized oocytes such as oocytes emitting a second polar body, oocytes with an enlarging sperm head(s) and oocytes with multiple pronuclei did not differ significantly. These results suggest that MPF in pig oocytes is inactivated shortly after sperm penetration and is maintained at the basal level throughout pronuclear formation.     

Presence of granulosa cells during oocyte maturation improved in vitro development of IVM-IVF bovine oocytes that were collected by ultrasound-guided transvaginal aspiration

The effects of granulosa cells in maturation media on male pronuclear formation and in vitro development of in vitro-matured and fertilized (IVM-IVF) bovine oocytes were examined. In Experiment 1, cumulus-oocyte complexes (COCs) were aspirated from follicles of slaughterhouse ovaries and classified into 4 morphological categories according to the surrounding cumulus cells: Grade 1 (> 4 layers), Grade 2 (3 to 4 layers), Grade 3 (1 to 2 layers) and Grade 4 (denuded). Oocytes were co-cultured with or without granulosa cells (1 x 10(6) cells/ml) for 21 to 22 h. At 18 and 192 h after insemination, the abilities of oocytes to form a male pronucleus and develop up to the blastocyst stage in vitro were determined, respectively. The presence of granulosa cells during maturation did not affect (P < 0.05) the ability of oocytes in Grades 1 and 2 to form a male pronucleus and to develop to the blastocyst stage in Grades 1 and 4. However, the incidence of male pronuclear formation in Grades 3 and 4 and in vitro development to the blastocyst stage in Grades 2 and 3 was higher (P < 0.05) when COCs were cultured in the presence of granulosa cells than when cultured in the absence of granulosa cells. In Experiment 2, COCs collected by ultrasound-guided aspiration were co-cultured with or without granulosa cells, fertilized and cultured as described above. The incidence of blastocysts at 192 h after insemination was higher (P < 0.05) when COCs were cultured for maturation in the presence of granulosa cells (24%) than in the absence of granulosa cells (12%). These results demonstrate that supplementation of maturation medium with granulosa cells improves the quality of oocytes with relatively few cumulus cell layers, as determined by male pronuclear formation and in vitro development. We also conclude that this supplementation effectively improves the developmental ability of bovine IVM-IVF oocytes that were collected by ultrasound-guided transvaginal aspiration.     

Preincubation of cumulus-oocyte complexes before exposure to gonadotropins improves the developmental competence of porcine embryos matured and fertilized in vitro

The objectives of the present study were to examine whether delayed exposure of porcine cumulus-oocyte complexes (COCs) to gonadotropins affects the diameter of oocytes, the nuclear morphology of the germinal vesicle, the rate of germinal vesicle breakdown (GVBD), and the embryonic developmental rate of inseminated oocytes following maturation and fertilization in vitro (IVM/IVF). After preincubation (experimental) or no preincubation (control) in BSA-free NCSU23 medium containing 1096 porcine follicular fluid for 12 h, COCs were cultured for maturation in the same medium supplemented with gonadotropins for 20 h and then without those gonadotropins for 20 h. During the preincubation period, the nuclear morphology of the germinal vesicles became more homogeneous. Incidence of GVBD after 20 h of maturation culture was not different between the control and experimental group. When cultured in NCSU23 medium for 7 d following IVF, the incidence of embryos that developed to the blastocyst stage (23.1 +/- 3.1%) was higher in the experimental group than in the control group (8.7 +/- 1.2%). Blastocysts in the experimental group had a larger number of cells than control blastocysts. Following embryo transfer into the oviduct of recipient gilts, IVM/IVF embryos had elongated by Day 12 of gestation. These results indicate that preincubation of porcine COCs, before exposure to gonadotropins to induce the resumption of meiosis, increases the rate of development of IVM/IVF embryos to the blastocyst stage.     

Consequences of bovine oocyte maturation, fertilization or early embryo development in vitro versus in vivo: implications for blastocyst yield and blastocyst quality.

The aim of this study is to examine the effect of bovine oocyte maturation, fertilization or culture in vivo or in vitro on the proportion of oocytes reaching the blastocyst stage, and on blastocyst quality as measured by survival following vitrification. In Experiment 1, 4 groups of oocytes were used: (1) immature oocytes from 2-6 mm follicles; (2) immature oocytes from > 6 mm follicles; (3) immature oocytes recovered in vivo just before the LH surge; and (4) in vivo matured oocytes. Significantly more blastocysts developed from oocytes matured in vivo than those recovered just before the LH surge or than oocytes from 2-6 mm follicles. Results from > 6 mm follicles were intermediate. All blastocysts had low survival following vitrification. In Experiment 2, in vivo matured oocytes were either (1) fertilized in vitro or (2) fertilized in vivo by artificial insemination and the resulting presumptive zygotes recovered on day 1. Both groups were then cultured in vitro. In vivo fertilized oocytes had a significantly higher blastocyst yield than those fertilized in vitro. Blastocyst quality was similar between the groups. Both groups had low survival following vitrification. In Experiment 3a, presumptive zygotes produced by in vitro maturation (IVM)/fertilization (IVF) were cultured either in vitro in synthetic oviduct fluid, or in vivo in the ewe oviduct. In Experiment 3b, in vivo matured/in vivo fertilized zygotes were either surgically recovered on day 1 and cultured in vitro in synthetic oviduct fluid, or were nonsurgically recovered on day 7. There was no difference in blastocyst yields between groups of zygotes originating from the same source (in vivo or in vitro fertilization) irrespective of whether culture took place in vivo or in vitro. However, there was a dramatic effect on blastocyst quality with those blastocysts produced following in vivo culture surviving vitrification at significantly higher rates than their in vitro cultured counterparts. Collectively, these results indicate that the intrinsic quality of the oocyte is the main factor affecting blastocyst yields, while the conditions of embryo culture have a crucial role in determining blastocyst quality.