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.     

The ovine uterus as a host for in vitro-produced bovine embryos

A series of experiments were conducted to determine whether bovine blastocysts would develop beyond the blastocyst stage in the ovine uterine environment. In Experiment 1, in vitro matured, fertilized and cultured (IVM/IVF/IVC) expanded bovine blastocysts were transferred into uteri of ewes on Day 7 or 9 of the estrous cycle and collected on Day 14 or 15 to determine if the bovine blastocysts would elongate and form an embryonic disk. Springtime trials with ewes that were synchronized with a medroxyprogesterone acetate (MAP) sponge resulted in a 78% blastocyst recovery rate, and 68% of the recovered spherical or elongated embryos had embryonic disks. In Experiment 2, transfer of 4-cell bovine embryos to the oviducts of ewes at Day 3 resulted in a lower recovery (47 vs 80%) than the transfer of blastocysts at Day 7 when embryos were recovered at Day 14. However, the percentage of embryos containing embryonic disks was higher for embryos transferred at the 4-cell stage (71%) than for embryos transferred as blastocysts (50%). In Experiment 3, IVF embryos from super-ovulated cows or Day 8 in vitro produced embryos transferred to cows were collected at Day 14 and were found to be similar in size to those produced by transfer to ewes in Experiment 2. In Experiment 4, the transfer of bovine blastocysts to ewes did not prolong the ovine estrous cycle. In Experiment 5, extension of the ovine estrous cycle by administration of a MAP releasing intravaginal device allowed bovine embryos to elongate extensively and to become filamentous. In Experiment 6, uterine flushings on Day 14 or Day 16 contained elevated levels of interferon-tau when bovine blastocyst were transferred on Day 7. Transfer of bovine embryos to the reproductive tract of a ewe allows some embryos to develop normally to advanced perimplantation stages and may be a useful tool for studying critical stages of embryo development and the developmental capacity of experimental embryos.     

Cloned piglets born after nuclear transplantation of embryonic blastomeres into porcine oocytes matured in vivo

Nuclear transplantation in the pig is more difficult than in other domestic animals and only one embryonic nuclear transplantation (NT) pig has been born to date. In this study, reconstituted porcine embryos were produced by electrofusion of blastomeres from in vivo four-cell embryos to enucleated in vivo or in vitro matured (IVM) oocytes. Nuclear transfer using cumulus cells as nuclear donors was also conducted. When blastomeres were used as donors, the electrofusion rate was significantly higher in oocytes matured in vivo (91.5%) than in those matured in vitro (66.1%) (p < 0.01). After fusion, the NT embryos reconstituted from in vivo matured oocytes developed to blastocysts at a rate of 10.3% after culture in rabbit oviducts for up to 5 days, while only 5.9% of the NT embryos reconstructed from in vitro matured oocytes developed to blastocyst stage. Electrofusion rate of cumulus cell nuclei with enucleated IVM oocytes was lower (47.6%) and only 1.5% (2/136) of the reconstituted eggs developed in vitro to morula stage, and 1.9% developed to blastocysts when cultured in the ligated rabbit oviducts. Transfer of 94 embryos reconstructed by blastomere NT with in vivo matured oocytes to five synchronous recipients resulted in the birth of two cloned piglets. No piglet was born following transfer to two recipients of embryos (n = 39) derived from NT with in vitro matured oocytes. The results demonstrate that in vivo matured oocytes are better recipients than those matured in vitro for pig cloning.     

Low concentrations of MEM vitamins during in vitro maturation of porcine oocytes improves subsequent parthenogenetic development

To investigate the effects of water-soluble vitamin supplementation for IVM/IVC of porcine oocytes and evaluate maturation and developmental capacity in vitro, porcine cumulus oocyte complexes (COCs) was matured in NCSU-23-based medium with water-soluble vitamins for 44 h and then cultured in PZM-3 for 7 days following activation. The COCs were allocated into five treatment groups and matured in various concentrations of MEM vitamins (control, 0.05, 0.1, 0.2, 0.4, and 1x). Metaphase II plates of the cumulus-free oocytes were observed following Hoechest 33258 staining. The COCs were allocated into four treatment groups, matured in various concentrations of MEM vitamins (control, 0.05, 0.1, 0.2, and 0.4x) and cultured in PZM-3 following activation. Also, COCS were matured without MEM vitamins and cultured in PZM-3 with various concentrations (control, 0.1, 0.4, 1.0, and 2.0 x) of MEM vitamins. Furthermore, 2 x 2 factorial (IVM/IVC) experiments were performed in IVM medium with or without 0.05 x MEM vitamins and IVC medium with or without 0.4x MEM vitamins to examine the in vitro development of parthenogenetic embryos. Maturation rates of COCs treated with MEM vitamins did not differ significantly among groups. However, compared to the control group, oocytes matured with the addition of 0.05 x MEM vitamins developed to blastocysts at a higher percentage (P<0.05) following activation and culture in PZM-3 without MEM vitamins. Total cell number of blastocysts was significantly higher in the 0.05 x group. Addition of 0.4x MEM vitamins decreased (P<0.05) cleavage and blastocyst developmental rates compared with 0.05 x MEM vitamins-treated group. In contrast, addition of vitamins to PZM-3 medium for in vitro culture of activated porcine oocytes did not affect development. In conclusion, addition of a low concentration of MEM vitamins to IVM medium for porcine oocytes enhanced subsequent development and improved embryo quality.     

Culture of in vitro produced bovine zygotes in vitro vs in vivo: implications for early embryo development and quality

The objectives of this study were to examine the effect of culture system on bovine blastocyst formation rates and quality. Presumptive IVM/IVF bovine zygotes were cultured either in vitro in synthetic oviduct fluid (SOF, 25 embryos/25 microL in 5% CO2, 5% O2, 90% N2 at 39 degrees C) or in vivo in the ewe oviduct (approximately 100 embryos per oviduct). The recovery rate after in vivo culture was 53% (813/1,530). The blastocyst rate on Day 7 was significantly higher for the in vitro system (28%, 362/1,278 vs 17%, 37/813; P< 0.0001). However, after culture in vitro for a further 24 h, there was no difference in Day 8 yields (36%, 457/1,278 vs 32%, 258/813, for in vitro and in vivo culture, respectively). There was no difference in blastocyst cell number between treatments (Day 7: 96 vs 103; Day 8: 78 vs 85 for in vitro and in vivo culture, respectively). Irrespective of culture system, Day 7 blastocysts had a significantly higher cell number than those appearing on Day 8. There was no difference in pregnancy rate at Day 35 after fresh transfer of a single Day 7 blastocyst (37.5%, 21/56 vs 45.3%/, 24/53 for in vitro and in vivo culture, respectively). After cryopreservation by freezing in 10% glycerol, VS3a vitrification or solid surface vitrification, the survival of in vitro cultured embryos was significantly lower than survival of embryos cultured in the ewe oviduct or those produced by superovulation of donors. In conclusion, these findings demonstrate that while bovine zygotes cultured in vitro are capable of rates of development similar to those of their in vivo cultured counterparts (in terms of Day 8 blastocyst yield, cell number and early pregnancy rate), there are significant differences in embryo cryosurvival. This suggests that current in vitro culture systems need to be improved to optimize embryo quality and pregnancy rates.     

Effect of morphological properties of transferred embryonic stages on tubal migration Implications for in vivo culture in the bovine oviduct

In cattle, there is no practical method, which allows tubal transfer of pre-implantation embryos for routine in vivo culture as it has been established in sheep. The aim of our study was to perform tubal transfer by transvaginal endoscopy in synchronized heifers, in order to expose embryos at various embryonic stages to the physiological mechanisms of migration in the non-ligated oviducts. Various embryonic stages were transferred by transvaginal endoscopy into the oviducts of temporary recipients and were recovered on Day 7. The transfer of embryos in hyaluronate containing medium ("Hyaluronan"), zygotes stripped of cumulus ("Denuded Zygotes"), embryos embedded in cumulus ("Zygotes with Cumulus"), matured oocytes with capacitated spermatozoa ("GIFT") or embryos embedded in Na alginate ("Alginate") led to increasing recovery rates (13, 30, 56, 63 and 71%, respectively). However, the developmental rate on Day 7 was adversely affected (16, 11, 8, 16 and 8%), whereas the blastocyst rate on Day 8 showed more balanced results (17, 14, 18, 21 and 11%). Our data demonstrate that the structural properties of transferred embryos affect tubal migration and are crucial for subsequent in vivo culture. Embryos enclosed in cumulus cells or alginate synchronize more successfully with the oviductal transport systems than denuded stages or embryos in hyaluronate containing medium.     

Development and viability of bovine preplacentation embryos treated with swainsonine in vitro.

This study investigated the effects of swainsonine (a locoweed toxin) on bovine preplacentation embryo development using in vitro procedures. We examined and confirmed the viability and developmental potential of swainsonine-treated embryos by transfer to synchronized recipient heifers. Oocytes (n = 6338) were aspirated from ovaries collected from the abattoir and subjected to in vitro maturation (IVM), in vitro fertilization (IVF) and in vitro culture (IVC). Swainsonine was added to IVM, IVF, IVC media spatially and IVM/IVF/IVC continuously, at 0 ng/ml (TRTI, control), 200 ng/ml (TRT2), 400 ng/ml (TRT3), and 800 ng/ml (TRT4). Embryo development was evaluated with respect to oocyte cleavage rate and the rates of morula and blastocyst formation. There was no difference (P > 0.05) among treatments. The average number of nuclei per blastocyst at Day 7.5 of culture (Day 0 = IVF) was 85.9 +/- 4.3 (n = 47) and 89.3 +/- 4.4 (n = 44) for swainsonine-treated embryos (800 ng/ml) and control embryos, respectively. Pregnancy rate as determined by ultrasonography on day 35 to 40 post embryo transfer was 43.8% and 38.3% for swainsonine-treated (800 ng/ml) and control embryos, respectively. Nine (9.4%) healthy calves were delivered from heifers receiving swainsonine-exposed and nine (9.6%) from control embryos. No difference (P > 0.05) was detected in number of calves developing from TRT and control embryos. We conclude that swainsonine does not have an adverse effect on the development and viability of preplacentation bovine embryos.     

Effects of oxygen tension on the development and quality of porcine in vitro fertilized embryos

The present study was conducted to examine the effect of oxygen tension during in vitro culture (IVC) of porcine oocytes/embryos on their development and quality using two different culture systems. Porcine cumulus oocyte complexes (COCs) were matured (IVM) and fertilized (IVF) in vitro, and subsequently cultured for 6 days in a simple and economical portable incubator or a standard CO(2) incubator. While the same temperature (38.5 degrees C) and CO(2) concentration (5%) were used in the both systems, the portable incubator was operated in a negative air pressure (- 300 mmHg) to create an O(2) level at 8-10% (low O(2) concentration), or in a positive air pressure (high O(2) concentration). To compare the two culture systems, IVM and IVF of COCs and subsequent IVC of in vitro produced (IVP) embryos were carried out in the portable incubator with a low O(2) concentration (Group I) or in the standard incubator with a high O(2) concentration (Group II). To assess the effect of O(2) concentration on IVC of IVP embryos, some oocytes that had been cultured in the standard incubator for IVM and IVF were subsequently cultured in the portable incubator with a low O(2) concentration (Group III) or a high O(2) concentration (Group IV). The occurrence of DNA fragmentation in the blastocysts produced under different culture conditions was examined by TUNEL staining to assess embryo quality. The rates of oocytes that reached MII and were penetrated by spermatozoa following IVF did not differ between the two incubation systems. In contrast, the proportions of development to blastocysts and the mean cell number of blastocysts in Group I were higher than those in Group II and Group IV. The index of DNA-fragmented nucleus in the blastocysts of Group I was significantly lower than that in the blastocysts of Group II. Therefore, low oxygen tension during IVM, IVF and IVC enhanced the subsequent development of IVP embryos to the blastocyst stage and improved their quality.     

The effect of oxygen tension on porcine embryonic development is dependent on embryo type

Reducing oxygen concentration from atmospheric levels during in vitro culture generally, but not invariably, improves embryonic development across a range of species. Since the few published reports of such an action in the pig are contradictory--perhaps a consequence of the derivation of the embryos prior to culture--a study was performed to examine the effect of O2 tension during culture on three different types of porcine embryos, namely: in vivo flushed embryos, and in vitro matured oocytes either fertilized in vitro or parthenogenetically activated. In vivo embryos (n=208) were flushed at the 2-8 cell stage. Cumulus oocyte complexes (COCs) destined for IVF or parthenogenetic activation were derived from 2 to 6 mm, post-pubertal ovarian follicles and matured for 48 h in TCM-199. Parthenogenones were generated by activating denuded oocytes (n=573) with 10 mM calcium ionophore, followed by 2 mM DMAP prior to culture. The IVF embryos (n=971) were produced by fertilizing COCs (day 0) with fresh ejaculated semen in modified tris-based medium for 6 h before cumulus removal. All embryos were cultured in BECM-3 containing 12 mg/mL fatty-acid-free BSA up to day 4, followed by BECM-3 supplemented with 10% calf serum until day 7. The gas environment for IVM/IVF was 5% CO2 in air, while that for IVC was either 5% CO2 in air or 5% O2, 5% CO2 and 90% N2. Low O2 tension increased both day 7 blastocyst rates (high versus low O2, respectively; 9.3+/-2.9%: 26/280; 23.9+/-4.2%: 71/293; P<0.001) and total cell numbers (39.3+/-2.9, n=24 versus 61.2+/-7.7, n=61; P=0.01) of parthenogenetically activated embryos. In contrast, such a treatment neither affected blastocyst rates (89.3+/-6.9 versus 87.8+/-7.5) nor cell numbers (87.4+/-4.5 versus 87.7+/-4.8) of in vivo flushed embryos. The effect of reduced O2 concentration on IVF embryos was intermediate, since only cell numbers were improved (69.8+/-3.5, range=17-204, n=49; 88.5+/-5.8, range=28-216; n=66; P<0.01), equivalent to that recorded in in vivo flushed embryos. However, blastocyst rates were unaffected (10.7+/-1.4%: 51/486; 12.9+/-2.2%: 67/485). The effect, when present, of reducing O2 concentration from 20 to 5% was beneficial for pig in vitro embryonic development. The responses are apparently dependent on firstly, the manner by which the embryonic cell cycle is activated and secondly, the derivation of the tissue prior to placement into culture, if the observed resilience of in vivo embryos is independent of treatment duration.     

Nuclear maturation and development of IVM/IVF canine embryos in synthetic oviductal fluid or in co-culture with buffalo rat liver cells

In vitro embryo production in the domestic bitch can provide valuable insights for conservation of endangered canids. In the present study, canine oocytes underwent in vitro maturation (IVM) in simple or complex media, with production of in vitro matured and fertilized (IVM/IVF) canine embryos. Cumulus–oocyte complexes (COCs) were harvested from ovaries by slicing and subjected to IVM in four media (SOF, TCM 199, Ham-F10, and DMEM/F12). After culture for 48 h, oocytes were stained and examined for nuclear maturation. There were no significant differences in the mean (±S.D.) percentage of nuclear maturation (metaphase II) of oocytes cultured in SOF (18.6 ± 7.6%), TCM 199 (18.3 ± 4.5%), Ham-F10 (13.9 ± 8.2%), or DMEM/F12 (11.9 ± 4.2%). For assessment of embryo development, oocytes were matured for 48 h in synthetic oviductal fluid (SOF), fertilized with frozen-thawed sperm, and presumptive zygotes were cultured for 7 d, either in SOF or as co-cultures with BRL cells in TCM 199. Percentages of IVM/IVF oocytes that developed to the 2-cell, 3–4-cell, and 5–7-cell stages were higher (P < 0.05) following culture in SOF versus BRL cell co-cultures (33.6 ± 1.2% vs 13.7 ± 1.2%, 24.7 ± 0.5% vs 8.7 ± 1.1%, and 15.1 ± 2.2% vs 4.3 ± 1.3%, respectively). However, none of the embryos developed beyond the 8–16-cell stage. In conclusion, simple or complex media successfully induced resumption of meiosis and nuclear maturation of canine oocytes. Furthermore, SOF supported in vitro development of IVM/IVF canine embryos to the 8–16-cell stage.     

Effect of exogenous glutathione on the in vitro fertilization of bovine oocytes

Increased amounts of reactive oxygen species (ROS) during in vitro culture may cause cytotoxic damage to gametes and embryos. The main purpose of this study was to investigate the effect of glutathione (GSH), a ROS scavenger, supplemented during IVF of bovine oocytes on embryo development using spermatozoa from different bulls. The following experiments were performed: 1) matured COCs were fertilized in the absence or presence of 1 mM GSH using semen from 4 bulls (Bulls A, B, C and D); 2) matured COCs were fertilized in the absence or presence of 1 mM GSH using semen from Bull C to examine sperm penetration, pronuclear formation and apposition; 3) COCs were fertilized with in the presence of either 0, 0.1, 1.0 or 10 mM GSH to examine the effect of GSH concentration using sperm from Bull C; 4) concentrations of GSH were measured both in the medium and in the oocytes during IVF. Glutathione at 1 mM in IVF medium affected the blastocyst formation, but not the cleavage rate. The effect on blastocyst formation was bull dependent: semen from Bull B and D had a negative, that from Bull C a positive and the one from Bull A no effect. The positive effect of Bull C semen increased the rate of blastocyst formation from 20.1 to 27.3% in control and GSH-treated samples, respectively. The increased rate was due to more zygotes reaching the 8-cell or greater stage by Day 4 after IVF. There was no change in the fertilization or cleavage rates. The GSH was still stable after 18 h incubation in IVF medium, and there was a dose-dependent increase in the GSH concentration in the oocytes. It is concluded that the effect of GSH during IVF on the proportion of blastocysts is dependent on both bull and GSH concentration.     

Influences of zinc on fertilisation and development of bovine oocytes in vitro.

The effects of zinc (as ZnCl2) on in vitro production of bovine embryos (IVMFC) and components of the procedure, that is in vitro oocyte maturation (IVM), fertilisation (IVF) and embryo development in culture (IVC), and the effect of added zinc on sperm motility were studied. Immature cumulus oocyte complexes (COCs) were aspirated from ovarian follicles (2-5 mm diameter) at slaughter, and matured, fertilised and cultured in chemically defined conditions. The presence of zinc (10, 100 or 1000 micrograms added per millilitre) throughout IVMFC inhibited fertilisation. After addition of 10 micrograms zinc per millilitre separately to media for IVM and IVF, fertilisation was inhibited only when zinc was present for IVM. When present for IVF, 80% of oocytes selected for IVM reached 2- to 4-cell stages by 46 h after insemination whereas 67% of control oocytes (inseminated without added zinc) cleaved. Higher zinc concentrations (100 and 1000 micrograms added per millilitre) for IVF inhibited fertilisation. Sperm motility was reduced with addition of 10 micrograms per millilitre of zinc for sperm preparation (i.e. capacitation interval). Addition of 1.0 microgram zinc per millilitre to media used through IVMFC, or to the IVC medium alone, resulted in inhibition of development after 2- to 4-cell stages. When added to IVM or to both IVM and IVF media 1.0 microgram/ml of zinc compromised development to the morula stage and beyond. Maturing bovine oocytes may be more sensitive to 1.0 microgram ml of zinc in vitro than in vivo because a concentration of 3.0 micrograms/ml has been reported for bovine follicular fluid. Fertilisation was not adversely affected by 10 micrograms/ml of zinc; however, higher concentrations were inhibitory.     

Development of in vitro matured,in vitro fertilized domestic cat embryos following cryopreservation,culture and transfer

The ability of embryos to successfully survive cryopreservation is dependent on both morphological and developmental characteristics. Domestic cat oocytes matured in vitro exhibit alterations in nuclear and cytoplasmic maturation that may affect developmental competence, particularly after cryopreservation. In Experiment 1, we evaluated the developmental competence of in vitro produced (IVM/IVF) cat embryos after cryopreservation on Days 2, 4 or 5 of IVC. In Experiment 2, in vivo viability was examined by transfer of cryopreserved embryos into recipient queens. Oocytes recovered from minced ovaries were cultured in TCM-199 with hCG/eCG and EGF at 38 degrees C in 5% O(2), 5% CO(2), 90% N(2) for 24h. In Experiment 1, after IVM/IVF, on Day 2 (n=56), Day 4 (n=48) and Day 5 (n=42) of IVC, embryos were equilibrated for 10 min at 22 degrees C in HEPES (15m M) Tyrode's (HeTy) with 1.4M propylene glycol (PG), 0.125 M sucrose (S), 10% dextran and 10% FBS, loaded into 0.25 ml straws, cooled at 2.0 degrees C/min to -6.0 degrees C and held for 10 min. After seeding, cooling resumed at 0.3 degrees C/min to -30 degrees C and after a 10 min hold, straws were plunged into liquid nitrogen (LN(2)). Straws were thawed in air for 2 min and cryoprotectant was removed by a five-step rinse consisting of 3 min each in HeTY with 0.95 M PG/0.25 M S; 0.95 M PG/0.125 M S; 0.45 M PG/0.125 M S; 0 PG/0.125 M S; 0 PG/0.0625 M S. Contemporary IVM/IVF embryos were used as nonfrozen controls (Day 2, n=14; Day 4, n=26; Day 5, n=35). After 8 days of IVC, the number of embryos developing to blastocysts was recorded and blastocyst cell numbers were counted after staining with Hoechst 33342. In Experiment 1, developmental stage did not affect the survival rate after thawing (Day 2=79%, Day 4=90%, Day 5=98%) and was not different from that of controls (Day 2=89%, Day 4=88%, Day 5=96%). Blastocyst development was similar among days both after cryopreservation (Day 2=59%, Day 4=54%, Day 5=63%) and in controls (Day 2=55%, Day 4=54%, Day 5=58%). Mean (+/-S.D.) cell number of blastocysts was slightly lower (NS) in cryopreserved embryos (Day 2=152+/-19, Day 4=124+/-20, Day 5=121+/-24) than in controls (Day 2=141+/-25, Day 4=169+/-21, Day 5=172+/-19). In Experiment 2, embryos frozen on Day 2 (n=68), Day 4 (n=49) or Day 5 (n=73) were thawed and cultured for 3, 1, or 0 days before transfer by laparotomy to 5 (mean=12.6+/-2.4), 4 (mean=12.2+/-3.7) and 6 (mean=12.0+/-1.6) recipients, respectively. Four recipients were pregnant on Day 21; two from embryos frozen on Day 4 and two from Day 5. Two live kittens were born at 66 days, a third kitten died during parturition at 64 days and a fourth pregnancy aborted by Day 45. In summary, we have shown that a controlled rate cryopreservation technique can be successfully applied to cat embryos produced by IVM/IVF. In vitro development to the blastocyst stage was not affected by the age of embryos at cryopreservation. The births of live kittens after ET of cryopreserved embryos is additional validation of progress toward applying assisted reproductive technology to preservation of endangered felids.     

Quality controls for bovine viral diarrhea virus-free IVF embryos

Introduction of bovine viral diarrhea virus (BVDV) with cumulus-oocyte-complexes (COCs) from the abattoir is a concern in the production of bovine embryos in vitro. Further, International Embryo Transfer Society (IETS) guidelines for washing and trypsin treatment of in-vivo-derived bovine embryos ensure freedom from a variety of pathogens, but these procedures appear to be less effective when applied to IVF embryos. In this study, COCs were exposed to virus prior to IVM, IVF and IVC. Then, virus isolations from cumulus cells and washed or trypsin-treated nonfertile and degenerated ova were evaluated as quality controls for IVF embryo production. The effect of BVDV on rates of cleavage and development was also examined. All media were analyzed prior to the study for anti-BVDV antibody. Two approximately equal groups of COCs from abattoir-origin ovaries were washed and incubated for 1 h in minimum essential medium (MEM) with 10% equine serum. One group was incubated in 10(7) cell culture infective doses (50% endpoint) of BVDV for 1 h, while the other was incubated without virus. Subsequently, the groups were processed separately with cumulus cells, which were present throughout IVM, IVF and IVC. Cleavage was evaluated at 4 d and development to morulae and blastocysts at 7 d of IVC. After IVC, groups of nonfertile and degenerated ova or morulae and blastocysts were washed or trypsin-treated, sonicated and assayed for virus. Cumulus cells collected at 4 and 7 d were also assayed for virus. Anti-BVDV antibody was found in serum used in IVM and IVC but not in other media. A total of 1,656 unexposed COCs was used to produce 1,284 cleaved embryos (78%), 960 embryos > or = 5 cells (58%), and 194 morulae and blastocysts (12%). A total of 1,820 virus-exposed COCs was used to produce 1,350 cleaved embryos (74%), 987 embryos > or = 5 cells (54%), and 161 morulae and blastocysts (9%). Rates of cleavage (P = 0.021), cleavage to > or = 5 cells (P = 0.026) and development to morula and blastocyst (P = 0.005) were lower in the virus-exposed group (Chi-square test for heterogeneity). No virus was isolated from any samples from the unexposed group. For the exposed group, virus was always isolated from 4- and 7-d cumulus cells, from all washed nonfertile and degenerated ova (n = 40) and morulae and blastocysts (n = 57) and from all trypsin-treated nonfertile and degenerated ova (n = 80) and morulae and blastocysts (n = 91). Thus, virus persisted in the system despite the presence of neutralizing antibody in IVM and IVC media, and both washing and trypsin treatment were ineffective for removal of the virus. Presence of virus in 4- and 7-d cumulus cells as well as in nonfertile and degenerated ova were good indicators of virus being associated with morulae and blastocysts.     

Nuclear transfer in cattle: Effect of nuclear donor cells,cytoplast age,co-culture,and embryo transfer

There are many factors affecting the efficiency of nuclear transfer technology. Some are evaluated here using our novel approach by enucleating oocytes at 20–22 hr after in vitro maturation (IVM), culturing the enucleated oocytes (cytoplasts) for 8–10 hr or 18–20 hr to gain activation competence and then conducting nuclear transfer. In the first experiment, we demonstrated that cumulus cell (CC) monolayer can support some cloned embryos to develop into morulae or blastocysts. Co-culture with CC and bovine oviduct epithelial cell (BOEC) monolayers resulted in no differences (P 0.05) in supporting the development of cloned embryos (Experiment 2). When in vitro matured oocytes were enucleated at 22 hr after IVM followed by nuclear transfer 18–20 hr later, cleavage and morula or blastocyst development of the cloned embryos were similar to those resulting from the enucleated oocytes which had been matured in vivo (Experiment 3). Frozen embryos as nuclear donor cells worked equally well as fresh embryos for cloning in embryo development which was superior to IVF embryos (Experiment 4). However, fresh embryos resulted in a higher proportion (P < 0.05) of blastomere recovery than did frozen or IVF ambryos. Finally, embryo transfer of cloned embryos from our procedure produced a viable calf, demonstrating the commercial value of this novel approach of the technology. © 1993 Wiley-Liss, Inc.     

Efficient in vitro production of cat embryos in modified synthetic oviduct fluid medium: effects of season and ovarian status.

The effects of season (January-March = I; April-June = II; July-September = III; October-December = IV) and ovarian status (freshly ovulated, follicular, luteal, intermediate, or inactive) on the efficiency of the in vitro production of domestic cat embryos were evaluated. Ovaries and testes from cats with access to daylight were collected at local veterinary clinics. A total of 6843 cumulus-oocyte complexes (COCs) were recovered from 363 pairs of ovaries, matured in TCM 199 supplemented with BSA and gonadotropins (IVM), fertilized with epididymal sperm in a medium based on Tyrode albumin lactate pyruvate (IVF), and cultured in synthetic oviduct fluid (SOF) medium supplemented with 10% estrous cow serum (ECS) and essential and nonessential amino acids. The proportion of freshly ovulated, follicular, or luteal ovaries was higher (P < 0.05) in seasons II (64.4%) and III (60.5%) than in seasons I (42.0%) and IV (30.6%). The average number of COCs recovered per donor was not influenced by season. After IVM/IVF, cleavage rates (Day 2) were significantly higher (P < 0.05) in seasons II (mean +/- SEM: 53.1% +/- 1.9%) and III (54.6% +/- 2.8%) than in seasons I (48.4% +/- 1.4%) and IV (44.9% +/- 3.0%). Blastocyst rates on Day 6 were similar in seasons I (25.3% +/- 1.3%), II (28.2% +/- 1.5%), and III (29.6% +/- 2.3%) but were significantly lower (P < 0.01) in season IV (18.6% +/- 2.4%). The corresponding blastocyst rates on Day 8 were 28.9% +/- 1.3%, 33.7% +/- 1.6%, 37.9% +/- 2.3%, and 23.6% +/- 2.6%. In addition, we found a significant effect (P < 0.05) of ovary type; luteal, follicular, and intermediate ovaries yielding a higher proportion of developmentally competent oocytes than did freshly ovulated and inactive ovaries. These data show that the culture system used in our study supports development of IVM/IVF cat oocytes to blastocysts at a higher rate than those obtained with other methods. Although embryos could be produced throughout the year, the efficiency was significantly affected by season and ovary type.     

Bovine somatic cell nuclear transfer using recipient oocytes recovered by ovum pick-up: effect of maternal lineage of oocyte donors.

The efficiency of bovine nuclear transfer using recipient oocytes recovered by ultrasound-guided follicle aspiration (ovum pick-up [OPU]) was investigated. Oocyte donors were selected from 2 distinct maternal lineages (A and B) differing in 11 nucleotide positions of the mitochondrial DNA control region. A total of 1342 cumulus-oocyte complexes (COCs) were recovered. The numbers of total COCs and class I/II COCs recovered from donors of lineage A were higher (P < 0.001) than those obtained from lineage B. Follicle aspiration once per week yielded a higher (P < 0.001) total number of COCs per session than aspiration twice per week, whereas the reproduction status of donors (heifer vs. cow) had no effect on OPU results. Of the 1342 oocytes recovered, 733 (55%) were successfully matured in vitro and used for nuclear transfer. Fusion was achieved in 550 (75%) karyoplast-cytoplast complexes (KCCs), resulting in 277 (50%) cleaved embryos on Day 3. On Day 7 of culture, 84 transferable embryos (15% based on fused KCCs) were obtained. After 38 transfers (10 single, 22 double, and 6 triple transfers), 9 recipients (8 double and 1 triple transfer) were diagnosed as pregnant on Day 28, corresponding to a pregnancy rate of 24%. The proportion of transferable embryos on Day 7 was significantly (P < 0.05) influenced by maternal lineage of oocyte donors and by the frequency of follicle aspiration. Our study demonstrates the feasibility of generating nuclear transfer embryos with defined cytoplasmic background. These will be valuable tools to experimentally dissect the effects of nuclear and cytoplasmic components on embryonic, fetal, and postnatal development.     

Effect of 17beta-estradiol on the in vitro maturation of bovine oocytes

Although 1 microg/ml of 17beta-estradiol (E2) is often used in routine in vitro maturation (IVM) and in vitro fertilization (IVF), its effect remains controversial. The objective of our study was to investigate the effects of E2 on bovine oocyte IVM and subsequent embryo development, using a defined medium. Bovine cumulus oocyte complexes (COCs), aspirated from 2 to 8 mm follicles of slaughterhouse ovaries, were matured in TCM199 in the presence of 1 microg/ml E2 with or without 0.05 IU/ml recombinant hFSH. Cultures without E2, FSH or both served as controls. COCs were matured for 22 h at 39 degrees C in a humidified atmosphere of 5% CO2 in air. To investigate the effect of E2 with and without FSH on nuclear maturation, COCs were fixed after maturation and the nuclear stage was assessed following DAPI staining. Similarly, denuded oocytes (DO) were matured in the presence of E2 and the nuclear stage assessed after 22 h. To investigate the effect of E2 with and without FSH during IVM on subsequent embryo development, in vitro matured COCs were fertilized in vitro and after removal of the cumulus cells, the presumed zygotes were cocultured on BRL monolayer for 11 days. At Day 4, the number of cleaved embryos, and at Days 9 and 11, the number of blastocysts, were assessed. Addition of 1 microg/ml E2 to TCM199 significantly decreased the percentage of Metaphase II (MII) compared to control (56.3 and 74.0%, respectively), and increased the percentage of nuclear aberrations compared to control (13.3 and 2.1%, respectively). The negative effect of E2 on nuclear maturation was stronger when DO were matured; 25.1 and 60.0% of the oocytes reached MII stage for the E2 and control groups, respectively. When COCs were matured in TCM199 supplemented with FSH, the addition of 1 microg/ml E2 did not influence the proportion of MII oocytes, although a higher percentage of nuclear aberrations as compared to control was observed. Presence of E2 during IVM also decreased the blastocyst rate (14.4 and 10.0% for control and E2 groups, respectively). However, when FSH was present, the addition of E2 had no effect on the cleavage rate and blastocyst formation (20.3 and 21.7% for control and E2 groups, respectively). In conclusion, supplementation of 1 microg/ml E2 to a serum free maturation medium negatively affects bovine oocyte nuclear maturation and subsequent embryo development. Although these effects are attenuated in the presence of FSH, we strongly suggest omission of E2 in routine maturation protocols of bovine oocytes.     

Effect of follicle-stimulating hormone on nuclear and cytoplasmic maturation of sow oocytes in vitro

A series of experiments were conducted to evaluate the effects of FSH supplementation during IVM on porcine oocyte nuclear maturation, and subsequent fertilization, cleavage and embryo development. Cumulus-oocyte complexes (COCs) were cultured 40 h without FSH (control), 40 h with FSH (FSH 0-40 h), or 20 h with FSH followed by a 20-h culture period without FSH (FSH 0-20 h). Nuclear stage of oocytes was assessed at intervals from 12 to 40 h of IVM. Furthermore, oocytes were in vitro fertilized, fixed and stained to determine normally fertilized and polyspermic oocytes. Additionally, COCs were matured with FSH, fertilized and zygotes cultured in NCSU-23. The percentage of cleaved embryos and blastocysts were determined and the number of nuclei was counted. The presence of FSH during the first 20 h of IVM retarded germinal vesicle breakdown. After 40 h of culture 84, 67 and 58% MII oocytes were observed in the FSH 0-20 h, FSH 0-40 h and control groups, respectively. After IVF, penetration rates were similar at 27, 26 and 29%, while the proportion of polyspermic oocytes was 7, 19 and 11% of penetrated oocytes for control, FSH 0-40 and FSH 0-20 h groups, respectively. Cleavage and blastocyst rates differed among treatments (21, 29 and 38%, and 7, 15 and 20% for control, FSH 0-40 and FSH 0-20 h groups, respectively). No differences in blastocyst cell number were found among groups. Blastocyst rates, based on number of cleaved embryos, were 51 and 52% for the FSH 0-40 and FSH 0-20 h groups, which differed significantly from the control group (31%). The results indicate that FSH has a stimulatory effect on nuclear and cytoplasmic maturation of sow oocytes. Addition of FSH for the first 20 h of culture was most beneficial, based on cleavage and blastocyst development rates.     

In vitro production of embryos in swine.

In recent years, progress has been achieved in the production of pig embryos through IVM and IVF techniques. Cytoplasmic maturation of oocytes has been improved by modifications to IVM procedures. However, the historical problem of polyspermic penetration still remains a major issue to be solved. Recent studies indicate that the type of IVF medium and certain modifications to that medium can reduce polyspermy. Efforts should be directed to increase the developmental competence and quality of embryos. At present, many embryo culture (EC) media are available that can overcome the historical 4-cell block and support development of early in vivo derived embryos to the blastocyst stage. In contrast, blastocyst development of in vitro produced embryos in these culture media varies significantly. Furthermore, morphology and cell numbers in in vitro produced blastocysts are inferior to their in vivo counterparts. However, several modifications to EC techniques have improved embryo quality and developmental competence. Testing embryo viability through surgical transfer to recipient animals has resulted in acceptable pregnancy rates with moderate litter sizes. Although reliable in vitro systems are available for the generation of pig embryos, the problem of polyspermy and poor embryo development hamper their large-scale implementation. Further research efforts should be directed to improve oocyte/embryo quality and the methods to minimize polyspermy through development of novel IVM, IVF, and EC techniques.