Antifreeze protein from Anatolia polita (ApAFP914) improved outcome of vitrified in vitro sheep embryos

Embryo cryopreservation is an important tool to preserve endangered species. As a cryoprotectant for mouse oocytes, antifreeze protein from Anatolica polita (ApAFP914) has demonstrated utility. In the present study, the effects of controlled slow freezing and vitrification methods on the survival rate of sheep oocytes fertilized in vitro after freezing-thawing were compared. Different ApAFP914 concentrations were added to the vitrification liquid for exploring the effect of antifreeze protein on the warmed embryos. The results showed that the survival and hatching rates of in vitro derived embryos were significantly higher than that of the slow freezing method. Furthermore, among the cryopreserved embryos at different developmental stages, the survival and hatching rates of the expanded blastocyst were significantly higher than those of the blastocysts, early blastocysts and morula. The survival and the hatching rates of the fast-growing embryos were both significantly higher than that of the slow-growing embryos. Additionally, treatment of ApAFP914 (5–30 μg/mL) did not increase the freezing efficiency of the 6–6.5 d embryos. However, addition of 10 μg/mL of ApAFP914 significantly increased the hatching rate of slow-growing embryos. In conclusion, our study suggests that the vitrification is better than the slow freezing method for the conservation of in vitro sheep embryos, and supplementation of ApAFP914 (10 μg/mL) significantly increased the hatching rate of slow-growing embryos after cryopreservation.     

Open-pulled straw vitrification differentiates cryotolerance of in vitro cultured rabbit embryos at the eight-cell stage

The objective was to determine cryotolerance of in vitro cultured rabbit embryos to the open-pulled straw (OPS) method. Overall, 844 rabbit embryos at pronuclear, 2- to 4-cell, 8-cell, and morula/blastocyst stages were vitrified, and ≥ 1 mo later, were sequentially warmed, rehydrated, and subjected to continuous culture (n = 691) or embryo transfer (ET, n = 153). Embryos vitrified at the 8-cell stage or beyond had greater survival, expanded blastocyst and hatched blastocyst rates in vitro, and better term development than those vitrified at earlier stages. The 8-cell group had 70.1% expanded blastocysts, 63.7% hatched blastocysts, and 25.7% term development, as compared to 1.5-17.7%, 1.5-4.3% and 2.8-3.7% in the pronuclear, 2-cell and 4-cell embryos, respectively (P < 0.05). The expanded and hatched blastocyst rates in vitrified morula/blastocyst post-warming were higher than that in the 8-cell group; however, their term development after ET was similar (8-cell vs morula/blastocyst: 25.7 vs 19.4%, P > 0.05). Development after ET was comparable between vitrified-warmed embryos and fresh controls at 8-cell and morula/blastocyst stages (19.4-25.7 vs 13.7-26.6%, P > 0.05). For embryos at pronuclear or 2- to 4-cell stages, however, term rates were lower in the vitrified-warmed (2.8-3.7%) than in fresh controls (28.6-35.6%, P < 0.05). Therefore, cultured rabbit embryos at various developmental stages had differential crytolerance. Under the present experimental conditions, the 8-cell stage appeared to be the critical point for acquiring cryotolerance. We inferred that for this OPS cryopreservation protocol, rabbit embryos should be vitrified no earlier than the 8-cell stage, and stage-specific protocols may be needed to maximize embryo survival after vitrification and re-warming.     

The effect of equilibration time on survival and development rates of mouse pronuclear-stage embryos vitrified in solid surface (SSV) and convential straws: in vitro and in vivo evaluations

The objective of this study was to improve the efficiency of cryopreservation of pronuclear-stage (PN) mouse embryos. A novel vitrification technique (solid surface vitrification, SSV) was compared with a convential one in straws both for cryosurvival and obtaining progeny from cryopreserved PN mouse embryos. In the SSV method, 15-20 PN embryos were exposed to vitrification solutions for approximately 20 sec after equilibration, and then they were dropped in 2 microl drops onto a pre-cooled (-150 to -180 degrees C) metal surface. In the straws method, groups of 5-10 PN embryos were loaded in a single straw after equilibration. In experiment I, it was compared the effect of the vitrification solutions alone, without vitrification. No reduction was detected in survival, cleavage and blastocysts rates and the lowest development rate was obtained from hatched blastocyst for 20 min equilibration (24.5%). In experiment II, SSV method resulted in significantly higher survival and cleavage rates than that of in-straw vitrified 15-20 min group (87% vs. 60%, 83% vs. 67%, respectively; P < 0.05). There were no statistical differences among any of the blastocyts groups. However, there was a statistical difference in hatched blastocysts between 15 to 5, 10, and 20 min (P < 0.05). In experiment III, it was found no major effect among equilibration time periods in toxicity groups according to the mean cell number of blastocysts developed from PN embryos. But, there was a significant differences between 15 min SSV and 10 min in straw vitrified according to the mean cell number of blastocysts developed from PN embryos following vitrification (P < 0.05). The good results were obtained from 15 min equilibration group for SSV and 10 min equilibration group for straw vitrification. In the last experiment, embryo transfer after vitrification and toxicity was investigated. There were significant differences between SSV and straw just on the rate of pups born (30% and 20.5% respectively; P < 0.05). In conclusion, vitrification of PN mouse embryos by SSV can result in high rates of in vitro development to expanded and hatched blastocyst stage and in vivo development to live pups.     

Vitrification of Mouse Embryos at Various Stages by Open-Pulled Straw (OPS) Method

This study was performed to pursue the optimal condition for the cryopreservation of mouse morulae by a two-step OPS method and to investigate the feasibility of the optimal condition for vitrification of embryos at other developmental stages. First, the mouse morulae were vitrified in OPS using one-step procedure—that is, embryos were vitrified after direct exposure to EDFS30 (15% ethylene glycol (EG), 15% dimethyl sulfoxide (DMSO), Ficoll and sucrose), or two-step method—that is, embryos were first pretreated in 10%E+10%D (10% EG and 10% DMSO in mPBS) for 30 sec, then exposed to EDFS30 for 15 to 60 sec, respectively. After vitrification and warming, the embryos were morphologically evaluated and assessed by their development to blastocysts, expanded/hatched blastocysts, or to term after transfer. The result showed that all the vitrified-warmed morulae had similar blastocyst rate compared to that of control (91.7% vs. 100%), and the highest developmental rate to expanded blastocysts (100%) or hatched blastocysts (62.3%) was observed when the morulae were pretreated with 10%E+10%D for 0.5 min, exposed to EDFS30 for 25 sec before vitrification and warming in 0.5 M sucrose for 5 min. After transfer, the survival rate (33.1%) in vivo of the vitrified morulae was higher (P > 0.05) than that of the fresh embryos (24.6%). Secondly, embryos at different stages were cryopreserved and thawed following the above program. Most (93.4 to 100%) of the embryos recovered after vitrification were morphologically normal at all the developmental stages. The blastocyst rates of the vitrified one-cell (52.5 to 66.7%) and the two-cell (63.3 to 68.9%) embryos were lower (P < 0.05) than those of the vitrified four-cell embryos (81.7 to 86.4%), the eight-cell embryos (90.0 to 93.3%), morulae (96.7 to 100%), and the expanded blastocysts rate (98.3 to 100.0%) of the vitrified early blastocysts. The highest survival rate in vivo of vitrified embryos were from the early blastocysts (40.4%), which was similar to that of fresh embryos (48.6%). The data demonstrate that the optimal protocol for the cryopreservation of morulae was suitable for the four-cell embryos to early blastocyst stages and that the early blastocyst stage is the most feasible stage for mouse embryo cryopreservation under our experimental conditions.     

Vitrification of mouse embryos at various stages by open-pulled straw (OPS) method

This study was performed to pursue the optimal condition for the cryopreservation of mouse morulae by a two-step OPS method and to investigate the feasibility of the optimal condition for vitrification of embryos at other developmental stages. First, the mouse morulae were vitrified in OPS using one-step procedure-that is, embryos were vitrified after direct exposure to EDFS30 (15% ethylene glycol (EG), 15% dimethyl sulfoxide (DMSO), Ficoll and sucrose), or two-step method-that is, embryos were first pretreated in 10%E + 10%D (10% EG and 10% DMSO in mPBS) for 30 sec, then exposed to EDFS30 for 15 to 60 sec, respectively. After vitrification and warming, the embryos were morphologically evaluated and assessed by their development to blastocysts, expanded/hatched blastocysts, or to term after transfer. The result showed that all the vitrified-warmed morulae had similar blastocyst rate compared to that of control (91.7% vs. 100%), and the highest developmental rate to expanded blastocysts (100%) or hatched blastocysts (62.3%) was observed when the morulae were pretreated with 10%E + 10%D for 0.5 min, exposed to EDFS30for 25 sec before vitrification and warming in 0.5 M sucrose for 5 min. After transfer, the survival rate (33.1%) in vivo of the vitrified morulae was higher (P > 0.05) than that of the fresh embryos (24.6%). Secondly, embryos at different stages were cryopreserved and thawed following the above program. Most (93.4 to 100%) of the embryos recovered after vitrification were morphologically normal at all the developmental stages. The blastocyst rates of the vitrified one-cell (52.5 to 66.7%) and the two-cell (63.3 to 68.9%) embryos were lower (P < 0.05) than those of the vitrified four-cell embryos (81.7 to 86.4%), the eight-cell embryos (90.0 to 93.3%), morulae (96.7 to 100%), and the expanded blastocysts rate (98.3 to 100.0%) of the vitrified early blastocysts. The highest survival rate in vivo of vitrified embryos were from the early blastocysts (40.4%), which was similar to that of fresh embryos (48.6%). The data demonstrate that the optimal protocol for the cryopreservation of morulae was suitable for the four-cell embryos to early blastocyst stages and that the early blastocyst stage is the most feasible stage for mouse embryo cryopreservation under our experimental conditions.     

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.     

In vitro development and post-thaw survival of blastocysts derived from delipidated zygotes from domestic cats

The ability to cryopreserve in vitro-produced feline embryos was investigated. To improve the survival rate of cryopreserved embryos, first the developmental ability of in vitro fertilized feline zygotes (after removal of intracellular lipids) was determined, followed by the post-thaw survival of cryopreserved blastocysts derived from delipidated zygotes. More than 67% of the delipidated zygotes cleaved and 36% of them developed to the morula stage. The developmental ability of delipidated zygotes to the blastocyst stage (26%) was similar to that of sham-operated (30.5%) or control embryos (31.3%). Although the survival rate of delipidated blastocysts (81.8%) after freezing and thawing tended to be higher than that of control embryos without delipidation (60.6%), rates were not significantly different between the both groups. In conclusion, in vitro-produced feline blastocysts were successfully frozen, removal of the cytoplasmic lipid content in feline zygotes did not impair their in vitro developmental competence (up to the blastocyst stage), and reduction of cytoplasmic lipids by aspiration had no apparent effects on the survival of in vitro-derived blastocysts after cryopreservation.     

Production of transgenic mice from vitrified pronuclear-stage embryos.

Cryopreservation of pronuclear-stage embryos would be useful for transgenic technology and genome preservation purposes. We compared a novel vitrification technique (solid surface vitrification, SSV) with another vitrification method in straws for cryosurvival and to generate transgenic progeny from cryopreserved mouse zygotes following microinjection. The SSV solution consisted of 35% ethylene glycol (EG), 5% polyvinyl-pyrrolidone (PVP), and 0.4 M trehalose in M2 supplemented with 4 mg/ml BSA; the in straw vitrification solution was 7 M EG in M2 plus BSA. In experiment I, we compared the effect of the vitrification solutions alone, without cooling. No reduction was detected in survival and cleavage rates. In experiment II, SSV yielded a significantly higher percentage of morphologically normal zygotes (96%) that also cleaved at significantly higher rates (80%) when compared to that following "in straw" vitrification (68 and 66%, respectively). Cleavage rate in the non-vitrified control group (93%) was significantly higher than that of both vitrified groups. Following embryo transfer, there was no difference in the rate of pups obtained from the SSV, "in straw" vitrified, and control groups (97/457, 21%; 15/75, 20% and 56/209, 27%, respectively). In experiment III, SSV vitrified and fresh embryos were used for pronuclear DNA injection. Survival rate of vitrified embryos after microinjection was reduced compared to nonvitrified ones (64 vs. 72%, respectively; P < 0.05); however, development to two-cell stage was not different (76 vs. 72%, respectively). Following embryo transfer of vitrified vs. fresh microinjected embryos, in both cases 10% live pups were generated, including transgenic pups. The results demonstrated that the efficiency of generating transgenic pups from SSV vitrified pronuclear zygotes is comparable to that from fresh embryos.     

Vitrification of in vivo and in vitro produced ovine blastocysts.

Although cryopreservation of bovine embryo has made great progress in recent years, little achievement was obtained in ovine embryo freezing, especially in vitro produced embryos. However, a simple and efficient method for cryopreservation of sheep embryos will be important for application of ovine embryonic techniques such as in vitro fertilization, transgenic, cloning and etc. In this study ovine blastocysts, produced in vivo or in vitro, were cryopreserved by vitrification in EFS40 (40% ethylene glycol (EG), 18% ficoll and 0.5 M sucrose) or GFS40 (40% glycerol (GL), 18% ficoll and 0.5 Mol sucrose). In vitro produced, early blastocysts were directly plunged into liquid nitrogen (LN2) after preparation by one of the following procedures at 25 degrees C: (A) equilibration in EFS40 for 1 min; (B) equilibration in EFS40 for 2 min; (C) equilibration in EFS40 for 30 s following pretreatment in 10% EG for 5 min; (D) equilibration in EFS40 for 30 s following pretreatment in EFS20 for 2 min (E) equilibration in GFS30 for 30 s following pretreatment in 10% GL for 5 min. The survival rates observed after thawing and in vitro culture for 12 h were A 78.0% (39/50), B 50.0% (26/52), C 93.3% (70/75), D 92.0% (46/50) and E 68.0% (34/50). Survival rates were not significantly different for treatments C and D (p>0.05), but those for groups C and D were significantly higher than for A, B and E (p<0.05). After 24 h in vitro culture, hatched blastocyst rates were A 28.0% (14/50), B 21.1% (11/52), C 49.3% (37/75), D 48.0% (24/50), E 32.0% (16/50) and control 54.0% (27/50). The hatching rates for groups A, B and E were significantly lower than the control (p<0.05) in which early IVF blastocysts were cultured in fresh SOFaaBSA medium following treatment in PBS containing 0.3% BSA for 30 min, but for groups C and D it was similar to the control (p>0.05). The freezing procedures A, B and C were used to vitrify in vivo produced, early blastocysts recovered from superovulated ewes. The survival rates of frozen-thawed in vivo embryos were A 94.7% (72/76), B 75.0% (45/60) and C 96.4% (54/56) and for group B was significantly lower than for the other two treatment groups (p<0.05). Hatched blastocyst rates were A 46.0% (35/76), B 26.6% (16/60), C 51.8% (29/56) and the control 56.7% (34/60) in which early blastocysts from superovulation were cultured in fresh SOFaaBSA medium following treatment in PBS containing 0.3% BSA for 30 min. The hatching rate for treatment B was significantly lower than for the control (p<0.05) but did not differ between groups A, C and the control (p>0.05). Frozen-thawed embryos vitrified by procedure C were transferred into synchronous recipient ewes. Pregnancy and lambing rates were similar for embryos transferred fresh or frozen/thawed for both in vivo and in vitro produced embryos. These rates did not differ between in vivo and in vitro embryos transferred fresh (p>0.05). However, for frozen-thawed embryos, both rates were significantly lower for in vitro than for in vivo produced embryos (p<0.05).     

小鼠2—细胞胚胎单个卵裂球体外培养及其发育形成囊胚的玻璃化冷冻保存技术的研究（简报）

The present experiments were designed to study the effects of glucose, EDTA, glutamine on the in vitro development of single blastomeres from 2-cell embryos in mouse, and the efficiency of cryopreservation of blastocysts from single blastomers with different vitrification. Single blastomeres derived from female ICR x male BDF1 2-cell embryos were cultured in mKRB with or without glucose, EDTA and glutamine, respectively. The expanded blastocyst rates were significantly different between in mKRB with glucose and without glucose (34% vs 65%); The blastomeres were cultured in mKRB with EDTA and glutamine but glucose, the expanded blastocyst rate (90%) was significantly higher than other groups. The blastocysts derived from single blastomeres were vitrified in liquid nitrogen after equilibration in GFS40 for 0.5-2 min, the survival rate 24%-51%. The blastocysts were pretreated in mPBS with 10% glycerol for 5 min, followed by exposure to GFS40 at 25 degrees C for 0.5 min, then vitrified in liquid nitrogen(two-step method), the survival rate was 61%. However, the survival rates increased to 64% and 70% when the blastocysts were vitrified(one-step method) ater equilibration in EFS40 at 25 degrees C for 0.5-1 min.     

Vitrification of rat embryos at various developmental stages

The effect of developmental stage on the survival of cryopreserved rat embryos was examined. Wistar rat embryos at various developmental stages were vitrified by a 1-step method with EFS40, an ethylene glycol-based solution, or by a 2-step method with EFS20 and EFS40. After warming, the survival of the embryos was assessed by their morphology, their ability to develop to blastocysts (or expanded blastocysts for blastocysts) in culture, or their ability to develop to term after transfer. Most (91-100%) of the embryos recovered after vitrification were morphologically normal in all developmental stages. However, the developmental ability of 1-cell embryos was quite low; exposing them to EFS40 for just 0.5 min decreased the in vitro survival rate from 76 to 9%. The survival rates of 2-cell embryos and blastocysts, both in vitro and in vivo, were significantly higher with a 2-step vitrification process than with a 1-step vitrification process. Very high in vitro survival rates (94-100%) were obtained in 4- to 8-cell embryos and morulae in the 1-step method. Although survival rates in vivo of 4-cell (40%) and 8-cell (4%) embryos vitrified by the 1-step method were comparatively low, the values were similar to those obtained in non-vitrified fresh embryos. When morulae vitrified by the 1-step method were transferred to recipients, the in vivo survival rate (61%) was high, and not significantly different from that of fresh embryos (70%). These results show that rat embryos at the 2-cell to blastocyst stages can be vitrified with EFS40, and that the morula stage is the most feasible stage for embryo cryopreservation in this species.     

Birth of piglets after transfer of embryos cryopreserved by cytoskeletal stabilization and vitrification

Pig embryos suffer severe sensitivity to hypothermic conditions, which limits their ability to withstand conventional cryopreservation. Research has focused on high lipid content of pig embryos and its role in hypothermic sensitivity, while little research has been conducted on structural damage. Documenting cytoskeletal disruption provides information on embryonic sensitivity and cellular response to cryopreservation. The objectives of this study were to document microfilament (MF) alterations during swine embryo vitrification, to utilize an MF inhibitor during cryopreservation to stabilize MF, and to determine the developmental competence of cytoskeletal-stabilized and vitrified pig embryos. Vitrified morulae/early blastocysts displayed MF disruptions and lacked developmental competence after cryopreservation; hatched blastocysts displayed variable MF disruption and developmental competence. Cytochalasin-b did not improve morula/early blastocyst viability after vitrification; however, it significantly (P < 0.05) improved survival and development of expanded and hatched blastocysts. After embryo transfer, we achieved pregnancy rates of almost 60%, and litter sizes improved from 5 to 7.25 piglets per litter. This study shows that the pig embryo cytoskeleton can be affected by vitrification and that MF depolymerization prior to vitrification improves blastocyst developmental competence after cryopreservation. After transfer, vitrified embryos can produce live, healthy piglets that grow normally and when mature are of excellent fecundity.     

Successful vitrification of pronuclear-stage rabbit zygotes by minimum volume cooling procedure

Rabbit zygotes at the pronuclear-stage were cryopreserved by vitrification using a gel-loading tip (GL-tip), Cryoloop or Cryotop. In GL-tip and Cryoloop methods, zygotes were first exposed to 10% ethylene glycol (EG)+10% DMSO in TCM199+20% fetal bovine serum (FBS) for 2 min, and then equilibrated for 30 s in a vitrification solution composed of 20% EG+20% DMSO+0.6 M sucrose in TCM199+20% FBS. In Cryotop method, zygotes were first exposed to 7.5% EG+7.5% DMSO+20% FBS in TCM199 for 3 min, and then equilibrated for 1 min in a vitrification solution composed of 15% EG+15% DMSO+0.5 M sucrose+20% FBS in TCM199. In vitro culture of vitrified-warmed zygotes using GL-tip and Cryoloop resulted in low cleavage rates (2 and 5%, respectively) and no development into blastocysts. In contrast, zygotes vitrified-warmed using Cryotop exhibited higher proportions of cleavage (58%) and development into blastocysts (24%). When compacted morulae or early blastocysts were vitrified by these three procedures, 80-93% of them exhibited blastocoele expansion or zona hatching during the subsequent 48 h of culture. Use of Cryotop instead of GL-tip or Cryoloop for zygote vitrification, without changing conditions of solutions and periods for exposure, equilibration and post-warm dilution, resulted in cleavage and blastocyst development rates of 88 and 45%, respectively. A longer exposure time (10 min) of zygotes to 7.5% EG+7.5% DMSO+20% FBS in TCM199 resulted in higher proportions of zygotes cleaving (94%) and developing into blastocysts (51%) after Cryotop vitrification. Proportions of post-warm zygotes (10-min exposure group) and fresh control zygotes developing into newborn offspring were 36 and 53%, respectively. Pronuclear-stage rabbit zygotes were successfully cryopreserved by vitrification using the Cryotop method.     

Optimization of cryopreservation of buffalo (Bubalus bubalis) blastocysts produced by in vitro fertilization and somatic cell nuclear transfer

The objective of this study was to optimize cryopreservation conditions for buffalo in vitro produced (IVP) embryos. The in vitro fertilized (IVF) and somatic cell nuclear transferred (SCNT) blastocysts were vitrified with either 40% ethylene glycol (EG), 25% EG + 25% dimethylsulfoxide (DMSO), or 20% EG + 20% DMSO + 0.5 m sucrose, and the IVF blastocysts produced from abattoir-derived ovaries were also slow-frozen with either 10% EG or 0.05 m trehalose dehydrate + 1.8% EG + 0.4% BSA. Cryosurvival rates of blastocysts harvested on various days or at various developmental stages were also examined. In this study: (1) vitrification with 20% EG + 20% DMSO + 0.5 m sucrose had the best cryopreservation efficiency; (2) IVF and SCNT blastocysts had similar cryotolerance (P > 0.05); (3) after thawing, slow-frozen blastocysts reexpanded earlier than the vitrified blastocysts (P < 0.01); (4) cryosurvival rate of expanded blastocysts was higher than that of early blastocysts (P < 0.05); (5) cryosurvival rates of Days 5 to 7 blastocysts (Day 0 = day of IVF or SCNT) were higher than those of Days 8 to 9 blastocysts (P < 0.01); and (6) after embryo transfer, pregnancy rates for fresh and cryopreserved blastocysts were not different (P > 0.05). In conclusion, vitrification of Days 6 to 7 expanded blastocysts with 20% EG + 20% DMSO + 0.5 m sucrose was optimal for cryopreservation of buffalo IVP embryos.     

Ovicidal effects of vitrification solution and the vitrification-warming cycle and establishment of the proportion of toxic effects on nuclei and cytoplasm of mouse zygotes

The present study was conducted to compare the resistance of the nuclei with that of the cytoplasm of mouse zygotes to damage during the vitrification-warming cycle using the technique of pronuclear transplantation. Zygotes were collected from the oviduct of superovulated F1 female mice mated with males of the same strain. They were cryopreserved by the vitrification method. After being diluted with glycerol-sucrose PB1 solution, 86% of the recovered zygotes were morphologically normal and 80% of them developed to the two-cell stage in vitro, but the proportion of zygotes which developed to blastocysts was only 27%. When zygotes were exposed to VS1 solution in the same manner as above without cooling, 61% of them developed to blastocysts. In order to examine the source of injury during vitrification, the pronuclei of vitrified zygotes were transferred into enucleated fresh zygotes and vice versa. The developmental rate of blastocysts from vitrified zygotes that were enucleated and fused with pronuclei from fresh zygotes was significantly higher than that of zygotes reconstituted reversely. These findings suggest that nuclei are apparently damaged more than cytoplasm by the vitrification-warming cycle and the toxicity of VS1 solution.     

Changes in tri-methylation profile of lysines 4 and 27 of histone H3 in bovine blastocysts after cryopreservation

Pregnancy rates from cryopreserved embryos remain lower than non-cryopreserved counterparts, even though these embryos appear morphologically normal. How epigenetic events, such as histone modifications, are affected by cryopreservation of embryos remains unknown. The current study evaluated the effect of conventional freezing/thawing of in vitro produced bovine blastocyst embryos on histone modifications, H3K4me3 and H3K27me3. At day 7 of in vitro culture, blastocyst stage embryos were either frozen by conventional freezing method (−0.5 °C/min in 1.5 M ethylene glycol; F/T group) or remained in culture for an additional 18 h (Ctrl). Frozen embryos were stored in liquid N₂ for 14 days, thawed and placed in culture for 36 h for recovery. Control and re-expanded frozen-thawed blastocysts from both groups were fixed in 4% paraformaldehyde and stored in PBS +0.1% triton-X at 4 °C. Immunofluorescence, utilizing antibodies against H3K4me3 and H3K27me3, was conducted and staining intensity was analyzed as percentage of total DNA. Day 7 blastocyst development rate was 35.55% (352/990) with blastocyst recovery at 54.23% (77/142) 36 h post-thawing. Total cell numbers per blastocyst were not different amongst groups (117.8 ± 12.49 and 116.1 ± 14.69, F/T and Ctrl groups respectively). Global staining for the active mark, H3K4me3, was lower in F/T blastocysts compared to Ctrl (17.24 ± 2.80% vs. 34.95 ± 3.77%; P < 0.01). However, staining for the inhibitory mark, H3K27me3, was nearly 2-fold higher in F/T blastocysts (40.41 ± 3.83% vs. 21.29 ± 3.92%; P < 0.01). These results suggest that bovine blastocysts, subjected to conventional freezing methods, have altered histone modifications that may play a role in poor pregnancy rates.     

Nonequilibrium cryopreservation of rabbit embryos using a modified (sealed) open pulled straw procedure

The study was designed to evaluate the efficiency of a modified (sealed) open pulled straw (mOPS) method for cryopreserving rabbit embryos by vitrification or rapid freezing. An additional objective was to determine whether the mOPS method could cause the vitrification of a cryoprotectant solution generally used in rapid freezing procedures. Two consecutive experiments of in vitro and in vivo viability were performed. In Experiment 1, the in vitro viability of rabbit embryos at the morula, compacted morula, early blastocyst and blastocyst stages was assessed after exposure to a mixture of 25% glycerol and 25% ethylene glycol (25GLY:25EG: vitrification solution) or 4.5 M (approximately 25% EG) ethylene glycol and 0.25 M sucrose (25EG:SUC: rapid freezing solution). Embryos were loaded into standard straws or mOPS and plunged directly into liquid nitrogen. The mOPS consisted of standard straws that were heat-pulled, leaving a wide opening for the cotton plug and a narrow one for loading embryos by capillarity. The embryos were aspirated into the mOPS in a column positioned between two columns of cryoprotectant solution separated by air bubbles. The mOPS were then sealed with polyvinyl-alcohol (PVA) sealing powder. The vitrification 25GLY:25EG solution became vitrified both in standard straws and mOPS, whereas the rapid freezing 25EG:SUC solution crystallized in standard straws, but vitrified in mOPS. The total number of embryos cryopreserved was 1695. Embryos cryopreserved after exposure to each solution in mOPS showed higher rates (88.2%) of survival immediately after thawing and removal of the cryoprotectant than those cryopreserved in 0.25 ml standard straws (78.8%; P < 0.0001). After culture, the developmental stage of the cryopreserved embryos significantly affected the rates of development to the expanded blastocyst stage. Regardless of the cryoprotectant used, lower rates of in vitro development were obtained when the embryos were cryopreserved at the morula stage, and higher rates achieved using embryos at blastocyst stages. Based on the results of Experiment 1, the second experiment was performed on blastocysts using the mOPS method. Experiment 2 was designed to evaluate the in vivo viability of cryopreserved rabbit blastocysts loaded into mOPS after exposure to 25GLY:25EG or 25EG:SUC. Embryos cryopreserved in mOPS and 25GLY:25EG solution gave rise to rates of live offspring (51.7%) not significantly different to those achieved using fresh embryos (58.5%). In conclusion, the modified (sealed) OPS method allows vitrification of the cryoprotectant solution at a lower concentration of cryoprotectants than that generally used in vitrification procedures. Rabbit blastocysts cryopreserved using a 25GLY:25EG solution in mOPS showed a similar rate of in vivo development after thawing to that shown by fresh embryos.     

Cryopreservation of porcine embryos derived from in vitro-matured oocytes

This study describes a cryopreservation method for porcine in vitro-produced (IVP) embryos using as a model parthenogenetic embryos derived from in vitro-matured (IVM) oocytes. IVP embryos at the expanded blastocyst stage were cryopreserved by vitrification using the minimum volume cooling (MVC) method and exhibited an embryo survival rate of 41.2%. Survival was then significantly improved (83.3%, P < 0.05) by decreasing the amount of cytoplasmic lipid droplets (delipation) prior to vitrification. IVP embryos at the 4-cell stage also survived cryopreservation when vitrified after delipation (survival rate, 36.0%), whereas post-thaw survival of nondelipated embryos was quite low (9.7%). Furthermore, it was demonstrated that porcine IVP morulae can be cryopreserved by vitrification following delipation by a noninvasive method (survival rate, 82.5%). These results clearly confirm that porcine embryos derived from IVM oocytes can be effectively cryopreserved with high embryo survival using the MVC method in conjunction with delipation.