Bovine oocyte vitrification: effect of ethylene glycol concentrations and meiotic stages

Success in oocyte cryopreservation is limited and several factors as cryoprotectant type or concentration and stage of oocyte meiotic maturation are involved. The aim of the present study was to evaluate the effect of maturation stage and ethylene glycol (EG) concentration on survival of bovine oocytes after vitrification. In experiment 1, kinetics of oocyte in vitro maturation (IVM) was evaluated. Germinal vesicle (GV), germinal vesicle breakdown (GVBD), metaphase I (MI), and metaphase II (MII) oocytes were found predominantly at 0, 0–10, 10–14, and 18–24 h of IVM, respectively. In experiment 2, in vitro embryo development after in vitro fertilization (IVF) of oocytes exposed to equilibrium (ES) and vitrification solution VS-1 (EG 30%), or VS-2 (EG 40%) at 0, 12 or 18 h of IVM was evaluated. Only blastocyst rate from oocytes vitrified in SV-2 after 18 h of IVM was different from control oocytes. Hatched blastocyst rates from oocytes vitrified in VS-1 after 12 and 18 h, and SV-2 after 18 h of IVM were different from unvitrified oocytes. In experiment 3, embryo development was examined after IVF of oocytes vitrified using VS-1 or VS-2 at 0, 12 or 18 h of IVM. Rates of blastocyst development after vitrification of oocytes in VS-1 at each time interval were similar. However, after vitrification in VS-2, blastocyst rates were less at 18 h than 0 h. Both cleavage rates and blastocyst rates were significantly less in all vitrification groups when compared to control group and only control oocytes hatched. In conclusion, both EG concentration and stage of meiotic maturation affect the developmental potential of oocytes after vitrification.     

Cryopreservation of immature and in vitro matured porcine oocytes by solid surface vitrification

Cryopreservation of normal, lipid-containing porcine oocytes has had limited practical success. This study used solid surface vitrification (SSV) of immature germinal vesicle (GV) and mature meiosis II (MII) porcine oocytes and evaluated the effects of pretreatment with cytochalasin B, cryoprotectant type (dimethylsulfoxide (DMSO), ethylene glycol (EG), or both), and warming method (two-step versus single-step). Oocyte survival (post-thaw) was assessed by morphological appearance, staining (3',6'-diacetyl fluorescein), nuclear maturation, and developmental capacity (after in vitro fertilization). Both GV and MII oocytes were successfully vitrified; following cryopreservation in EG, more than 60% of GV and MII stage porcine oocytes remained intact (no significant improvement with cytochalasin B pretreatment). Oocytes (GV stage) vitrified in DMSO had lower (P<0.05) nuclear maturation rates (31%) than those vitrified in EG (51%) or EG+DMSO (53%). Survival was better with two-step versus single-step dilution. Despite high survival rates, rates of cleavage (20-26%) and blastocyst formation (3-9%) were significantly lower than for non-vitrified controls (60 and 20%). In conclusion, SSV was a very simple, rapid, procedure that allowed normal, lipid-containing, GV or MII porcine oocytes to be fertilized and develop to the blastocyst stage in vitro.     

Developmental competence of in vitro-fertilized porcine oocytes after in vitro maturation and solid surface vitrification: effect of cryopreservation on oocyte antioxidative system and cell cycle stage

The susceptibility of in vitro matured (IVM) porcine oocytes to be fertilized in vitro after vitrification was investigated. IVM oocytes were cryopreserved by solid surface vitrification (SSV) or treated with cryoprotectants (toxicity control, TC). Control oocytes were not treated or vitrified. Live oocytes in the three groups were in vitro fertilized (IVF) and then cultured (IVC) for 6 days. In vitro maturation and IVC were performed under 5% or 20% O(2) tension. The percentage of live oocytes in the SSV group was lower than those in the control and TC groups. Fertilization rates after SSV were significantly lower than in the control group. Significantly fewer penetrated oocytes formed male pronuclei in the SSV group than in the control and TC groups. Cleavage rates were significantly lower in the SSV group than in the control and TC groups. Blastocyst formation rates in the control and TC groups were similar, whereas only a single embryo developed to the blastocyst stage from 113 oocytes after vitrification. Blastocyst formation rates in the control group and in the TC group were significantly higher under 5% O(2) IVC than under 20% O(2) IVC. Oxygen tension during IVM had no effect on embryo development. The glutathione (GSH) content of vitrified oocytes was significantly lower than in the controls. In contrast, the H(2)O(2) level was higher in vitrified oocytes than in control oocytes. Vitrification caused parthenogenetic activation in 44.9% of unfertilized oocytes. This significant increase in parthenogenetic activation along with significantly dropped GSH level in vitrified oocytes may explain the decreased ability of the SSV group to form male pronuclei. These factors might have contributed to the poor developmental competence of vitrified oocytes.     

Nuclear maturation and embryo development of porcine oocytes vitrified by cryotop: Effect of different stages of in vitro maturation

The present study was designed to evaluate the viability, meiotic competence and subsequent development of porcine oocytes vitrified using the cryotop method at different stages of in vitro maturation (IVM). Cumulus–oocyte complexes (COCs) were cultured in IVM medium supplemented with 1 mM dibutyryl cAMP (dbcAMP) for 22 h and then for an additional 22 h without dbcAMP in the medium. Germinal vesicle (GV), germinal vesicle breakdown (GVBD), metaphase I (MI), anaphase I/telophase I (AI/TI) and metaphase II (MII) were found to occur predominantly at 0–22, 26, 32, 38 and 44 h of IVM, respectively. Oocytes were exposed to cryoprotectant (CPA) or vitrified after different durations of IVM (0, 22, 26, 32, 38 and 44 h). After CPA exposure and vitrification, surviving oocytes that were treated before completion of the 44 h maturation period were placed back into IVM medium for the remaining maturation period, and matured oocytes were incubated for 2 h. CPA treatment did not affect the viability of oocytes matured for 26, 32, 38 or 44 h, but significantly decreased survival rate of oocytes matured for 0 or 22 h. CPA treatment had no effect on the ability of surviving oocytes to develop to the MII stage regardless of the stage during IVM; however, blastocyst formation following PA was severely lower (P < 0.05) than that in the control. At 2 h post-warming, the survival rates of oocytes vitrified at 26, 32, 38 and 44 h of IVM were similar but were higher (P < 0.05) than those of oocytes vitrified at 0 or 22 h of IVM. The MII rates of surviving oocytes vitrified at 0 and 38 h of IVM did not differ from the control and were higher (P < 0.05) than those of oocytes vitrified at 22, 26 or 32 h of IVM. After parthenogenetic activation (PA), both cleavage and blastocyst rates of vitrified oocytes matured for 22, 26, 32, 38 and 44 h did not differ, but all were lower (P < 0.05) than those matured 0 h. In conclusion, our data indicate that survival, nuclear maturation and subsequent development of porcine oocytes may be affected by their stage of maturation at the time of vitrification; a higher percentage of blastocyst formation can be obtained from GV oocytes vitrified before the onset of maturation.     

Ultra-structural changes and developmental potential of porcine oocytes following vitrification

This study evaluated the effects of exposure and/or vitrification of porcine metaphase II (MII) oocytes on their in vitro viability and ultra-structural changes with two experiments. Experiment 1 examined the effect of vitrified oocytes on microtubule localization, mitochondrial morphology, chromosome organization and the developmental rate in IVF control and vitrified oocytes. Oocytes matured for 44 h were subjected to IVF (IVF control). Oocytes matured for 42 h were exposed to cryoprotectants (CPA control), followed by 2h culture, and subjected to IVF. Oocytes vitrified at 42 h post-maturation were warmed, cultured for 2h, and subjected to IVF (vitrified). Experiment 2 evaluated the effect of oocytes freezing on development of ICSI with and without activation and parthenotes. Fresh and vitrified oocytes were subjected to ICSI with and without electrical activation. Cleavage and blastocyst rates were significantly (P<0.05) lower in vitrified IVF, parthenote and ICSI embryos than those in fresh counterparts. Between ICSI embryos from fresh oocytes and vitrified oocytes, the rates of blastocyst were significantly higher (P<0.05) in activated group than the group without activation. Significant differences (P<0.05) were observed in normal spindle configuration of vitrified (43.5%) compared to control (81.0%) oocytes, but no significant difference was observed between CPA exposed and control groups. In conclusion, porcine oocytes at MII stage are very sensitive to vitrification with altered microtubule localization and mitochondrial organization thus resulting in impaired fertilization and embryo development.     

Effect of meiotic stages and maturation protocols on bovine oocyte's resistance to cryopreservation

We investigated the effect of meiotic stages and two maturation protocols on bovine oocyte's resistance to cryopreservation. Oocytes at germinal vesicle breakdown (GVBD) and metaphase II (MII) stage as well as oocytes matured for 22 h in media supplemented with FSH or LH were vitrified by the open pulled straw method. After warming, oocytes underwent additional 16 h (GVBD group) or 2 h (MII group) maturation. Then they were subjected to in vitro fertilization and culture. Some oocytes that matured in the medium supplemented with LH were subjected to parthenogenetic activation after vitrification to determine their developmental potential in absence of fertilization. Survival of oocytes after vitrifying/warming was determined after 22 h in fertilization medium. Cleavage and blastocyst formation rates were used to assess their developmental competence. In both experiments, a portion of unvitrified MII oocytes were subjected to in vitro fertilization and culture as control groups. In Experiment 1, similar cleavage rates were obtained for both GVBD and MII oocytes (53.56 versus 58.01%, P > 0.05). However, significantly higher proportion of cleaved embryos from vitrified MII oocytes developed into blastocysts than those from vitrified GVBD oocytes (1.06 versus 8.37%, respectively, P < 0.01). In Experiment 2, vitrified MII oocytes matured in medium supplemented with LH were superior to vitrified MII oocytes matured in FSH supplementation not only in cleavage rates (61.13 versus 50.33%), but in blastocyst formation rates (11.79 versus 5.19%, P < 0.01) as well. Cleavage and blastocyst formation rates of parthenogenetically activated oocytes were similar to those that were fertilized. Nevertheless, the vitrifying/ warming process significantly compromised the oocytes' developmental capacity since the vitrified oocytes showed significant reduction in both cleavage and blastocyst rates compared to those of not vitrified controls in both experiments (P < 0.01). We showed that oocytes at different maturation stages respond to cryopreservation differently and MII stage oocytes have better resistance to cryopreservation than GVBD stage oocytes. The maturation protocols also influence oocyte's ability to survive cryopreservation. Poor developmental potential after vitrification seem to have resulted from the cryodamage to the oocyte itself. These results suggested the importance of maturation on the developmental competence of cryopreserved oocytes.     

Live piglets derived from in vitro-produced zygotes vitrified at the pronuclear stage

We report the successful cryopreservation of in vitro-produced porcine zygotes. Follicular oocytes from prepubertal gilts were matured (IVM), fertilized (IVF), and cultured (IVC) in vitro. At 10 or 23 h after IVF, the oocytes were centrifuged to visualize pronuclei. Zygotes with two or three pronuclei were used for solid surface vitrification (SSV). Survival of vitrified-warmed zygotes was determined by their morphology. To assess their developmental competence, vitrified (SSV), cryoprotectant-treated (CPA), and untreated (control) zygotes were subjected to IVC for 6 days. Survival and developmental competence did not differ between control and CPA zygotes. The proportion of live zygotes after SSV and warming (93.4%) was similar to that in the controls (100%). Cleavage and blastocyst formation rates of SSV zygotes after vitrification (71.7% and 15.8%, respectively) were significantly lower than those of controls (86.3% and 24.5%, respectively; ANOVA P<0.05). Blastocyst cell numbers of SSV and control embryos were similar (41.2+/-3.4 and 41.6+/-3.3, respectively). There was no difference in developmental ability between zygotes cryopreserved at an early (10 h after IVF) or late (23 h after IVF) pronuclear stage. Storage in liquid nitrogen had no effect on the in vitro developmental competence of vitrified zygotes beyond the reduction induced by the vitrification itself. When the embryo culture medium was supplemented with 1 muM glutathione, the rate of development of cryopreserved zygotes to the blastocyst stage did not differ significantly from that of control glutathione-treated zygotes (18.6% and 22.1%, respectively). To test their ability to develop to term, vitrified zygotes were transferred to five recipients, resulting in three pregnancies and the production of a total of 17 piglets. These data demonstrate that IVM-IVF porcine zygotes can be cryopreserved at the pronuclear stage effectively without micromanipulation-derived delipation, preserving their full developmental competence to term.     

Bovine oocyte vitrification using the Cryotop method: Effect of cumulus cells and vitrification protocol on survival and subsequent development

The ability to successfully cryopreserve mammalian oocytes has numerous practical, economical and ethical benefits, which may positively impact animal breeding programs and assisted conception in humans. However, oocyte survival and development following vitrification remains poor. The aim of the present study was (1) to evaluate the effect of the presence of cumulus cells on the outcome of vitrification of immature (GV) or mature (MII) bovine oocytes, (2) to compare empirical and theoretical vitrification protocols, and (3) to assess the effect of adding ice blockers to vitrification media on survival and development competence of bovine oocytes following vitrification using the Cryotop method. In Experiment 1, cumulus-enclosed and partially-denuded GV and MII oocytes were vitrified in 15% EG + 15% Me₂SO + 0.5 M sucrose in two steps. In Experiment 2, GV oocytes were vitrified either as above or using theoretical modeling based on permeability and osmotic tolerance characteristics in 30% EG + 11.4% trehalose in three steps or 40% EG + 11.4% trehalose in four steps. In Experiment 3, GV oocytes were vitrified in media supplemented or not with 1 of 2 ice blockers (21st Century Medicine, Fontana, CA) 1% X-1000, 1% Z-1000 or both in three steps. In Experiment 1, the survival, cleavage and blastocyst rate of cumulus-enclosed oocytes was significantly higher than those of partially-denuded oocytes when vitrified at the GV stage (93.8% vs. 81.3%, 65.8% vs. 47.3%, 11.3% vs. 4.0%, respectively, P < 0.05). However, no significant effect of cumulus cover was detected between the two groups when vitrified at MII (93.0% vs. 91.8%, 35.2% vs. 36.8%, 5.0% vs. 4.4%, respectively). Furthermore, cumulus-enclosed oocytes vitrified at the GV stage exhibited significantly higher developmental competence than those vitrified at the MII stage (P < 0.05). In Experiment 2, there were no significant differences in the survival, cleavage and blastocyst rate among three protocols (86.0% vs. 92.8% vs. 91.2%, 44.8% vs. 54.4% vs. 45.6%, 5.0% vs. 5.4% vs. 4.0%, respectively). However, cleavage and blastocyst rate were significantly lower (P < 0.05) than non-vitrified control oocytes. In Experiment 3, the presence of ice blockers did not alter the cleavage rate or blastocyst development (P > 0.05). In conclusion, cumulus-enclosed GV bovine oocytes survived vitrification and subsequently developed at higher rates than MII oocytes using Cryotop method and conventional IVF procedure. Theoretical analysis of permeability characteristics and tolerance limits could not explain the low developmental competence of vitrified oocytes.     

Vitrification of immature and in vitro matured pig oocytes: study of distribution of chromosomes, microtubules, and actin microfilaments

Studies were conducted to compare viability of immature and mature porcine oocytes vitrified in ethylene glycol (EG) using open-pulled straws (OPS). Oocytes that had been allowed to mature for 12 h (germinal vesicle group; GV) and 40 h (metaphase II group; MII) were divided into three treatments: (1) control; (2) treated with cytochalasin B and exposed to EG; and (3) treated with cytochalasin B and vitrified by stepwise exposure to EG in OPS. After warming, a sample of oocytes was fixed and evaluated by specific fluorescent probes before visualization using confocal microscopy. The remaining oocytes were fertilized and cleavage rate was recorded. Exposure of GV oocytes to EG or vitrification had a dramatic effect on spindle and chromosome configurations and no cleavage was obtained after in vitro fertilization. When MII oocytes were exposed to EG or were vitrified, 18 and 11% of oocytes, respectively, maintained the spindle structure and either EG exposure or vitrification resulted in substantial disruption in microfilament organization. The cleavage rates of mature oocytes after being exposed to EG or after vitrification were similar (14 and 13%, respectively) but were significantly less than that of control oocytes (69%). These results indicate that porcine oocytes at different meiotic stages respond differently to cryopreservation and MII porcine oocytes had better resistance to cryopreservation than GV stage oocytes.     

In vitro maturation,fertilization and development of domestic cat oocytes recovered from ovaries collected at three stages of the reproductive cycle

This study was conducted to examine the effect of the donor cat's reproductive cycle stage on in vitro maturation (IVM), in vitro fertilization (IVF), and in vitro development of oocytes recovered from ovaries that were collected and stored at 35 degrees C for a short period (1-6 h). Based on the presence or absence of follicles and corpora lutea, the ovarian pairs collected were classified into inactive, follicular, or luteal stages. Nuclear status of 161 cumulus-oocyte complexes (COCs) were examined immediately after recovery; 91.3% of the oocytes were found to be at the immature germinal vesicle (GV) stage, and 3.7% of the oocytes were at metaphase II (MII) stage. The percentage of the oocytes at the GV stage was significantly lower in the follicular stage than in the inactive stage (P < 0.01). Of the oocytes from the follicular stage, 9.1% were at MII stage. After culture for 24 h, however, the proportions of oocytes that reached metaphase I and MII were not different among the reproductive cycle stages of the ovaries collected (P > 0.05). After co-incubation with sperm, 63.1% of oocytes were fertilized, but there were no significant differences among the reproductive cycle stages of the ovaries with respect to the proportions of normal and polyspermic fertilization. However, the number of oocytes reaching cleavage stage and development to the morula and blastocyst stages from follicular stage ovaries were significantly lower (P < 0.05) than those obtained from inactive and luteal stage ovaries. These results indicate that the reproductive cycle stage of donor cat ovaries, stored at 35 degrees C, has no apparent effects on the frequencies of maturation and fertilization of oocytes, but influences developmental competence of the oocytes following IVM or IVF.     

Immature cat oocyte vitrification in open pulled straws (OPSs) using a cryoprotectant mixture

Cryopreservation of gametes is an important tool in assisted reproduction programs to optimise captive breeding programmes of selected felid species. In this study the vitrification was evaluated in order to cryopreserve the immature domestic cat oocytes by assessing the survival of cumulus-oocyte complexes (COC), and the development competence after IVM and IVF by fresh cat epididymal sperms. From a total of 892 COC obtained from queens after ovariectomy were divided into two groups: Experiment 1 for viability evaluation (150 vitrified and 100 control COC) and Experiment 2 for assessing the developmental competence (414 vitrified and 228 control COC). The viability was evaluated by double staining with carboxyfluorescein and Trypan blue, while the developmental competence was evaluated by in vitro maturation (IVM), in vitro fertilisation (IVF) by fresh epididymal spermatozoa and in vitro culture (IVC). The vitrification was performed in OPS into sucrose medium (1 M sucrose in HSOF + 6% BSA) containing dimethyl sulfoxide (DMSO) (16.5% final concentration) and ethylene glycol (EG) (16.5% final concentration) as cryoprotectants. Percentage of non-viable COC was significantly higher in Experimental 1 vs Control 1 (11% vs 54.5%; P < 0.01), while cleavage rate were significantly lower for vitrified oocytes (Experimental 2) than control 2 (18.6% vs 48.2%; P < 0.01). Blastocyst rate on day 8 was higher for control oocytes than vitrified counterparts (4.3% vs 20.6% P < 0.01). This vitrification protocol ensured a development to blastocyst stage and it is the first report of development of vitrified GV COC.     

Meiotic arrest maintained by cAMP during the initiation of maturation enhances meiotic potential and developmental competence and reduces polyspermy of IVM/IVF porcine oocytes

We investigated effects of invasive adenylate cyclase (iAC), 3-isobutyl-1-methylxanthine (IBMX) and dibutyryl cyclic AMP (dbcAMP) on porcine oocyte in vitro maturation (IVM), in vitro fertilisation (IVF) and subsequent embryonic development. Porcine oocytes were collected in Hepes-buffered NCSU-37 supplemented with or without 0.1 microg/ml iAC and 0.5 mM IBMX. IVM was performed in a modified NCSU-37 supplemented with or without 1 mM dbcAMP for 22 h and then without dbcAMP for an additional 24 h. After IVF, oocytes were cultured in vitro for 6 days. After 12 h of IVM, no difference in nuclear status was observed irrespective of supplementation with these chemicals during collection and IVM. At 22 h, most (95%) of the oocytes cultured with dbcAMP remained at the germinal vesicle (GV) stage, whereas 44.3% of the oocytes cultured without dbcAMP underwent GV breakdown. At 36 h, oocytes cultured with dbcAMP had progressed to prometaphase I or metaphase I (MI) (32.6% and 49.3%, respectively), whereas non-treated oocytes had progressed further to anaphase I, telophase I or metaphase II (MII) (13.6%, 14.3% and 38.0%, respectively). At 46 h, the rate of matured oocytes at MII was higher in oocytes cultured with dbcAMP (81%) than without dbcAMP (57%), while the proportion of oocytes arrested at MI was lower when cultured with dbcAMP (15%) than without dbcAMP (31%). The rate of monospermic fertilisation was higher when oocytes were cultured with dbcAMP (21%) than without dbcAMP (9%), with no difference in total penetration rates (58% and 52%, respectively). The blastocyst rate was higher in oocytes cultured with dbcAMP (32%) than without dbcAMP (19%). These results suggest that a change in intracellular level of cAMP during oocyte collection does not affect maturational and developmental competence of porcine oocytes and that synchronisation of meiotic maturation using dbcAMP enhances the meiotic potential of oocytes by promoting the MI to MII transition and results in high developmental competence by monospermic fertilisation.     

Cumulus cells during in vitro fertilization and oocyte vitrification in sheep: Remove,maintain or add?

The objective was to evaluate the developmental competence of immature and matured ovine oocytes after removing, maintaining or adding cumulus cells (CC) associated to vitrification by Cryotop method. Three experiments were performed involving 3,144 oocytes. In Experiment 1, CC were removed from immature, matured or fertilized oocytes subjected to in vitro embryo production. In Experiment 2, oocytes were vitrified either in MI or MII stage with or without CC, while a control group with CC remained unvitrified. In Experiment 3, oocytes partially denuded from CC were vitrified either in MI or MII stage, and a co-culture of fresh CC was added or not soon after warming to complete in vitro maturation (IVM) and in vitro fertilization (IVF), or IVF, respectively, while a control group remained unvitrified. In Experiment 1, the cleavage rate, development rate on Day 6 and blastocyst rate on Day 8 were improved when CC were maintained until the end of IVF (P < 0.05). In Experiment 2, vitrification of oocytes with enclosed CC showed a tendency to increase cleavage (P = 0.06) and improved blastocyst rate (P < 0.05). In Experiment 3, adding CC as co-culture after vitrification-warming tended to improve cleavage rate (P = 0.06) and increased hatching rate (P < 0.05). Regarding oocyte stage, vitrification of in vitro matured oocytes resulted in greater developmental competence than immature stages (P < 0.05). In conclusion, CC seems to have a relevant role for in vitro embryo development in either fresh or vitrified oocytes.     

Effects of cryopreservation on the developmental competence, ultrastructure and cytoskeletal structure of porcine oocytes

The purpose of this study was to determine ultrastructural and cytoskeletal changes that result from vitrification of porcine germinal vesicle- (GV-) and meiosis II- (MII-) stage oocytes. To investigate the effects of vitrification on developmental competence, oocytes were divided into three groups: fresh GV-oocytes (control), vitrified GV-oocytes, and vitrified MII-oocytes. In both GV- and MII-oocytes, vitrification resulted in a high proportion with normal morphology (92.4 vs. 94.2%, P > 0.05), while vitrified GV-oocytes yielded a higher survival rate than did vitrified MII-oocytes (56.8 vs. 41.9%, P < 0.05). In vitrified GV-oocytes, 12 of 154 oocytes underwent cleavage after fertilization in vitro, and 6 of these developed to the 8-cell stage, 3 developed to the 16-cell stage, and 3 developed into morulae. No cleavage was obtained from vitrified MII-oocytes. For ultrastructural analysis of oocytes, fresh and vitrified-warmed GV- and MII-oocytes were randomly selected for transmission electron microscopy (TEM). Results showed that vitrification caused various degrees of cryodamage in GV-oocytes. Cumulus cells of some oocytes were separated from the cumulus-oocyte complex (COC), and the zona pellucida adjacent to cumulus cells was fractured. The gap junctions between cumulus cells were ruptured, and many microvilli were disrupted or disappeared. Only homogeneous lipid droplets were observed. After vitrification, cortical granules still lined the oolemma of MII-oocytes. Only morphologically irregular, nonhomogeneous lipid droplets surrounding large vacuoles were found. To examine cytoskeletal structures, fresh and vitrified-warmed MII-oocytes were analyzed by laser-scanning confocal microscopy (LSCM); vitrified-warmed GV-oocytes were cultured for 42-44 hr before LSCM. Of 58 control oocytes, 79.5% displayed normal spindles with chromosomes aligned along the equatorial plate. In vitrified oocytes the percentage with normal spindle organization was decreased significantly in both vitrified GV-oocytes and MII-oocytes (10.1 and 12.9%, respectively, P < 0.05). The proportion of oocytes with normal distribution of F-actin was lower for vitrified GV- and MII-oocytes than for controls (16.9 and 37.2% vs. 72.3%). Results of this experiment suggest that irreversible damage to the cytoskeleton of porcine GV- and MII-oocytes after vitrification could be an important factor affecting developmental competence.     

In vitro maturation and fertilization of porcine oocytes after a 48 h culture in roscovitine, an inhibitor of p34cdc2/cyclin B kinase

Maintaining oocytes at the germinal vesicle (GV) stage in vitro may permit enhanced acquisition of the developmental competence. The objective of the current study was to evaluate the nuclear and cytoplasmic maturation in vitro of porcine oocytes after pretreatment with S-roscovitine (ROS). Cumulus oocyte complexes (COC) were treated with 50 microM ROS for 48 h and then matured for various lengths of time in a conventional step-wise in vitro maturation (IVM) system by using dibutyryl cyclic AMP. The COC that were matured in the same system for 44 h without pretreatment with ROS were used as the control group. At various periods after the start of IVM, oocytes were assessed for the meiotic stages and subjected to in vitro fertilization (IVF) with fresh spermatozoa. The ROS treatment inhibited GV breakdown of 94.4% oocytes, with the majority arrested at the GV-I stage (67.4%). Maximum maturation rate to the metaphase-II stage after ROS treatment was achieved by 44 h of IVM (92.1%) and no differences were observed with control oocytes (95.0%). Penetration rate was correlated to the maturation rate. The duration of IVM had no effects on polyspermy and male pronuclear (MPN) formation rates at 8 h post insemination (hpi), whereas both rates increased at 22 hpi. Direct comparison with controls assessed at 22 hpi confirmed a lesser MPN formation in ROS-treated oocytes (73.7% compared with 53.6%). Glutathione (GSH) concentrations were less in oocytes treated with ROS than in control oocytes (5 compared with 7.7 pmol/oocyte) as well as blastocyst rate (22.0% compared with 38.1%, respectively). These results demonstrate that cytoplasmic maturation in porcine oocytes pretreated with ROS for 48 h did not equal that of control oocytes in the current IVM system.     

In vitro fertilization and development of frozen-thawed bovine oocytes.

Bovine oocytes were vitrified (V-oocytes) or frozen slowly (S-oocytes) at the germinal vesicle (GV) stage or after maturation in vitro (IVM) and their survival assessed morphologically and also by in vitro fertilization (IVF) and culture. The morphological survival of S-oocytes was 30.7% after freezing at the GV stage and 53.3% after IVM. The corresponding survival rates of V-oocytes were significantly lower, viz. 14.6 and 14.0%, respectively. The fertilization rate of S-oocytes frozen after IVM (51.0%) was lower than that of unfrozen controls (75.8%), but higher than after other treatments. Development continued in 16.0% of the fertilized S-oocytes, compared to 39.4% of control IVF zygotes and 1.6% developed into morulae or blastocysts (4.5% in controls). Only 0.8% of frozen-thawed GV stage oocytes and 4.6% of post-IVM V-oocytes cleaved after IVF and none formed morulae or blastocysts. Transfer of four embryos (two morulae and two blastocysts) derived from post-IVM S-oocytes into a recipient heifer resulted in pregnancy and the birth of twin calves.     

Production of good-quality porcine blastocysts by in vitro fertilization of follicular oocytes vitrified at the germinal vesicle stage

We investigated survival, meiotic competence, cytoplasmic maturation, in vitro fertilization, and development of immature porcine (Sus scrofa) oocytes cryopreserved by a modified solid surface vitrification protocol. Cumulus-oocyte complexes (COCs) collected from follicles 3 to 6 mm in diameter in abattoir-derived ovaries of prepubertal gilts were either vitrified (Vitrified group), subjected to cryoprotectant treatment (CPA group), or used without any treatment (Control group). Oocyte viability was assayed by staining with fluorescein diacetate. Live oocytes were matured in vitro and their meiotic progression investigated by nuclear staining. In a series of experiments, the glutathione (GSH) content of in vitro-matured oocytes and viability of cumulus cells were assayed simultaneously. The in vitro-matured oocytes were also fertilized and cultured in vitro to assess their ability to be fertilized and to develop to the blastocyst stage, respectively. The proportion of viable oocytes in the Vitrified group was significantly lower than that in the CPA and Control groups (27.7%, 90.4%, and 100%, respectively). Among the three groups, there were no differences in meiotic competence, cumulus viability, and GSH levels at the end of in vitro maturation. Fertilization parameters (i.e., rates of male pronucleus formation, monospermy, and second polar body extrusion) were also similar among groups. However, comparison of the developmental abilities of oocytes in the Vitrified, CPA, and Control groups revealed that the Vitrified group had a significantly reduced ability to undergo first cleavage (34.4%, 63.3%, and 69.0%) and to develop to the blastocyst stage (5.1%, 25.5%, and 34.6%). The mean total cell numbers in blastocysts after 6 d of culture were not significantly different among the Vitrified, CPA, and Control groups (40.3, 42.8, and 43.4). In conclusion, despite low survival rates and impaired development in the Vitrified group, meiotic competence, cytoplasmic maturation, and subsequent fertilization characteristics of surviving germinal vesicle oocytes were unaffected by vitrification, and high-quality blastocysts were produced from vitrified immature oocytes.     

Germinal stage vitrification is superior to MII stage vitrification in prepubertal mouse oocytes

This study investigated if in vitro maturation (IVM) before or after vitrification would be more successful for prepubertal oocytes. To mimic prepubertal conditions in an experimental setup, oocytes were collected from healthy 14, 21 and 28day old Swiss albino mice. The germinal vesicle (GV) stage oocytes and in vitro matured MII oocytes were subjected to vitrification-warming. Both structural (meiotic spindle morphology, mitochondrial integrity, cortical granules) and functional (sperm zona binding, fertilization) characteristics were assessed in oocytes after warming. This study demonstrated that IVM was more detrimental to prepubertal oocytes than to young adults. Further, vitrification of the IVM oocytes resulted in an increase in the number of abnormal meiotic spindles, a change in the cortical distribution pattern, a reduction in sperm zona binding and the fertilization rate. Importantly, oocyte integrity was better when prepubertal oocytes were vitrified before, rather than after, IVM. The above observations support GV stage vitrification for prepubertal oocytes requiring fertility preservation. Understanding the mechanisms behind the differing outcomes for oocytes from immature females will help in refining current protocol, thereby retaining the oocytes' maximum structural and functional integrity Further investigation is necessary to determine whether human prepubertal oocytes also behave in a similar way. It is to be noted here, with great emphasis, that a major limitation of this study is that the oocytes’ abilities were tested only until fertilisation, as a consequence of which the study cannot reveal the developmental potentials of the embryos beyond fertilisation.     

Bovine oocytes treated prior to in vitro maturation with a combination of butyrolactone I and roscovitine at low doses maintain a normal developmental capacity.

Butyrolactone I (BL-I) and Roscovitine (ROS), two specific and potent inhibitors of M-phase promoting factor (MPF) kinase activity, were used to block germinal vesicle breakdown (GVBD) of cattle oocytes. A concentration 6.25 microM BL-I and 12.5 microM ROS blocked over 93.3 +/- 2.5% of oocytes in germinal vesicle (GV) stage during a 24-hr culture period. Following a second 24-hr culture step in maturation medium (IVM) almost all (91.5 +/- 3.0%) inhibited oocytes resumed meiosis and reached the metaphase II (MII) stage. The MII kinetics was different for inhibited and control oocytes. Fifty percent MII was reached at 13-14 hr in BL-I + ROS treated oocytes, compared to 18 hr in control oocytes. Therefore, control oocytes were fertilised (IVF) after 22 hr IVM and inhibited oocytes after 16 or 22 hr IVM. After IVF, percentage of grade 1 freezable embryos on day 7 (D + 7) as well as percentage of blastocyst formation on D + 8 in the group of BL-I + ROS treated oocytes fertilised after 16 hr IVM were higher (P < 0.05) compared with the other experimental group fertilised after 22 hr IVM but not different in comparison with the control. Survival to freezing and thawing of grade 1 embryos frozen on D + 7 was employed as viability criteria and was similar in all groups. Thus, the presence of BL-I + ROS in the prematuration medium of bovine oocytes determines a reversible meiotic block, without compromising their subsequent developmental competence.     

In vitro fertilization of ovine oocytes vitrified by solid surface vitrification at germinal vesicle stage

Cryopreservation of immature oocytes at germinal vesicle (GV) stage would provide a readily available source of oocytes for use in research and allow experiments to be performed irrespective of seasonality or other constraints. This study was designed to evaluate the recovery, viability, maturation status, fertilization events and subsequent development of ovine oocytes vitrified at GV stage using solid surface vitrification (SSV). Cumulus oocyte complexes (COCs) obtained from mature ewes were randomly divided into three groups (1) SSV (oocytes were vitrified using SSV), (2) EXP (oocytes were exposed to vitrification and warming solutions without vitrification) or (3) Untreated (control). Following vitrification and warming, viable oocytes were matured in vitro for 24h. After that, nuclear maturation was evaluated using orcein staining. Matured oocytes were fertilized and cultured in vitro for 7days. Following SSV, 75.7% 143/189 oocytes were recovered. Of those oocytes recovered 74.8%, 107/143 were morphologically normal (viable). Frequencies of in vitro maturation were significantly (P<0.01) decreased in SSV and EXP groups as compared to control. In vitro fertilization rates were significantly (P<0.01) decreased in SSV (39.3%) group as compared to EXP (56.4%) and control (64.7%) groups. Cleavage at 48h post insemination (pi) and development to the blastocyst stage on day 7 pi were significantly (P<0.001) decreased in SSV oocytes as compared to EXP and control groups. In conclusion, immature ovine oocytes vitrified using SSV as a simple and rapid procedure can survive and subsequently be matured, fertilized and cultured in vitro up to the blastocyst stage, although the frequency of development is low.