Short-term exposure of two-cell hamster embryos to collection media is detrimental to viability

Improved Oocyte Isolation and Embryonic Development of Outbred Deer Mice

In this study, we improved the protocol for isolating cumulus-oocyte complexes (COCs) from the outbred deer mice by using only one hormone (instead of the widely used combination of two hormones) with reduced dose. Moreover, we identified that significantly more metaphase II (MII) oocytes could be obtained by supplementing epidermal growth factor (EGF) and leukemia inhibition factor (LIF) into the previously established medium for in vitro maturation (IVM) of the COCs. Furthermore, we overcame the major challenge of two-cell block during embryonic development of deer mice after either in vitro fertilization (IVF) or parthenogenetic activation (PA) of the MII oocytes, by culturing the two-cell stage embryos on the feeder layer of inactivated mouse embryonic fibroblasts (MEFs) in the medium of mouse embryonic stem cells. Collectively, this work represents a major step forward in using deer mice as an outbred animal model for biomedical research on reproduction and early embryonic development.

Effective cryopreservation of golden Syrian hamster embryos by open pulled straw vitrification

Golden Syrian hamster embryos are difficult to cryopreserve due to their high sensitivity to cryoprotectants and in vitro handling. The objective of this study is to develop a robust open pulled straw (OPS) vitrification technique for cryopreserving hamster embryos at various developmental stages. We first systematically tested the concentrations of cryoprotectants and the exposure times of two-cell embryos to various vitrification solutions. We identified pretreatment of two-cell embryos with 10% (v/v) ethylene glycol (EG) + 10% (v/v) dimethylsulfoxide (DMSO) for 30 s followed by exposure in the vitrification solution, EDFS30 (containing 15% EG + 15% DMSO), for 30 s before plunging into liquid nitrogen (two-step exposure method) as the optimal OPS vitrification protocol. We then investigated the resourcefulness of this protocol for vitrifying hamster embryos at different developmental stages. The results showed that high blastocyst rates from embryos vitrified at two-cell, four-cell, eight-cell, or morula stage (62%, 78%, 80%, or 72%, respectively), but not those verified at pronuclear (0%) or blastocyst stage (24%; P < 0.05), were achieved by this protocol. When embryos vitrified at the two-cell stage were recovered and then directly transferred to recipient females, 29% of them developed to term, a development rate not significantly different (P > 0.05) from the 40% birth rate of the unvitrified controls. In conclusion, we have developed an effective two-step OPS vitrification protocol for hamster embryos.

Development block of golden hamster ICSI embryos is associated with decreased expression of HDAC1, HSPA1A and MYC

We have investigated the mechanism for embryo development block in vitro and to improve the development rate of golden hamster embryos in vitro. Intracytoplasmic sperm injection (ICSI) technique was used to produce golden hamster ICSI embryos. The changes in the histone acetylation and the expression of histone deacetylase and related genes were analyzed by immunocytochemical staining and real-time PCR both in golden hamster in vivo embryos and in ICSI embryos. Aged oocytes significantly increased the oocyte spontaneous activation rate. In vitro cultured ICSI embryos suffered from severe development block in M199TE medium. Expression of histone deacetylase 1 (HDAC1) was significantly decreased in the nuclei of the arrested ICSI 2-cell embryos, and its nuclear and cytoplasmic expression pattern was also markedly altered. The acetylation level of H4K5, however, was not significantly changed between golden hamster in vivo embryos and ICSI embryos. HSPA1A and MYC, the marker genes for zygotic genome activation (ZGA), were transcriptionally decreased in arrested ICSI 2-cell embryos. Transcription of HDAC1 was also downregulated in these embryos, whereas the mRNA expression of the proapoptotic gene, BAX, was not changed. These results indicate that the golden hamster ICSI embryo development block during ZGA is associated with decreased nuclear expression and altered expression of HDAC1. HSPA1A, MYC, and HDAC1 mRNA levels, which decrease, resulting in ZGA failure.

Biological pH buffers in IVF: help or hindrance to success

PURPOSE

Minimizing environmental stress helps maintain cellular homeostasis and is a crucial component in optimizing embryo development in vitro and resulting ART success. One stressor of particular interest is pH. Biologic buffers, such as HEPES and MOPS, are valuable tools for stabilizing pH. The objective of this manuscript is to summarize efficacy and impact of various pH buffers used during IVF lab procedures

METHODS

Keyword searches were performed using Pubmed and Medline and relevant literature reviewed.

RESULTS

Various pH buffers have been used with varying degrees of success for gamete and embryo processing in a variety of animal species, as well as in human.

CONCLUSION

Though biologic buffers off a means to improve pH stability, not all buffers may be appropriate for use with gametes and embryos. Specific buffers may have undesired effects, and these may be buffer, species, cell type or concentration dependent. Continued research is needed to further refine and improve the use of biologic buffers for use in human ART.

Optimizing the culture environment in the IVF laboratory: impact of pH and buffer capacity on gamete and embryo quality

Supplying and maintaining appropriate culture conditions is critical to minimize stress imposed upon gametes and embryos and to optimize the in-vitro environment. One parameter that requires close scrutiny in this endeavour is pH. Though embryos have a limited ability to regulate their internal pH (pH(i)), oocytes lack robust mechanisms. Thus, careful attention to external pH (pH(e)) of culture media is imperative in IVF. Ability to withstand deviations in hydrogen ion concentration varies depending on culture conditions, as well as laboratory procedures. Cryopreserved--thaw--thawed embryos, as well as denuded oocytes, are especially susceptible to perturbations in pH(e). Therefore, proper setting, monitoring and stabilizing of pH(e) during IVF laboratory procedures is a crucial component of a rigorous quality control programme. Here, importance of both pH(i) and pH(e) in respect to gamete and embryo quality are discussed. Furthermore, factors influencing selection of pH(e), as well as emerging methods to stabilize pH(e) in the IVF laboratory are detailed.

New pH-buffering system for media utilized during gamete and embryo manipulations for assisted reproduction

Maintenance of stable pH is important for optimizing gamete and embryo culture. One method to stabilize pH entails using zwitterionic buffers in IVF handling media used outside the laboratory incubator. Current handling media utilize single buffers, such as MOPS or HEPES. However, the use of a single buffer limits the ability to adjust the range of buffering capacity. Furthermore, changes in temperature alter buffering of these compounds. Therefore, traditional IVF handling media utilizing a single buffer may not provide ideal pH buffering. This study reports that combining multiple buffers, such as HEPES, MOPS and DIPSO, into a single medium in various ratios gives the ability to shift the effective buffering range to cover a specific pH. Additionally, by combining various buffers, it is possible to expand pH buffering over a range of temperatures, while simultaneously reducing the absolute concentration of individual buffers, thereby reducing or alleviating toxicity concerns. This report verifies that DIPSO, MOPS and HEPES, and their combinations, support embryo development. Therefore, utilization of bi- and tri-buffered media, containing a mixture of HEPES, MOPS or DIPSO, offers advantages compared with media containing HEPES or MOPS alone, and may be used for procedures such as oocyte retrieval, intracytoplasmic sperm injection, embryo transfer and cryopreservation.

The effect of different zwitterionic buffers and PBS used for out-of-incubator procedures during standard in vitro embryo production on development, morphology and gene expression of bovine embryos

The effect of the zwitterionic buffers HEPES, TES and MOPS and of PBS used for out-of-incubator procedures during standard in vitro embryo production on bovine oocytes and embryo development, morphology and on the expression patterns of eight selected genes: Fgf-4, Lama1, Ube2a, Gsta4, Il6, Sod1, Prss11 and Hspb1, was evaluated. All buffers were prepared at a concentration of 10 mM in TALP medium, with the exception of PBS. The total time of oocyte/embryo exposure to each buffer was approximately 41 min. The cleavage rates and number of embryos that developed to > or =8 cells at day 4 were no different among the buffers tested, however, more blastocysts developed at day 7, 8 and 9 in HEPES and MOPS treatments than in PBS and TES (P<0.05). No difference between buffers in total and apoptotic cell number was found. Except for Hspb1 and Ube2a genes, the levels of expression of the six remaining transcripts were higher in in vivo than in in vitro embryos irrespective of buffer used (P<0.05). In addition, higher expression of Hspb1 and lower expression of Ube2a and Lama1 were observed in PBS and TES than in MOPS and HEPES treatments (P<0.05). Expression of Fgf-4 and Gsta4 in the in vitro embryos was lower in PBS than in the remaining three buffers (P<0.05) and the level of expression of the Il6 gene was not affected by any buffer tested but was lower in in vitro than in in vivo derived embryos. Expression of both Sod1 and Prss11 genes in MOPS were at the level of the in vivo embryos. These results showed that the choice of buffer and short exposure time of approximately 41 min, affects mRNA expression of in vitro produced bovine embryos.

Comparison of glucose metabolism in in vivo- and in vitro-matured tammar wallaby oocytes and its relationship to developmental potential following intracytoplasmic sperm injection

Although marsupial oocytes undergo nuclear maturation in vitro, there is, at present, no indication of their developmental potential, largely owing to the lack of in vitro fertilisation and related technologies for marsupials. Glucose metabolism has proven a useful indicator of oocyte cytoplasmic maturation and developmental potential in several eutherian species. Therefore, the aims of the present study were to compare: (1) the rates of glycolysis and glucose oxidation in immature, in vitro-matured and in vivo-matured tammar wallaby oocytes; and (2) the metabolic rate of individual oocytes with their ability to form pronuclei after intracytoplasmic sperm injection. The rates of glycolysis measured in immature (2.18 pmol oocyte–1 h–1), in vitro-matured (0.93 pmol oocyte–1 h–1) and in vivo-matured tammar wallaby oocytes (0.54 pmol oocyte–1 h–1) were within a similar range to values obtained in eutherian species. However, unlike the trend observed in eutherian oocytes, the glycolytic rate was significantly higher in immature oocytes compared with either in vivo- or in vitro-matured oocytes (P < 0.001) and significantly higher in in vitro-matured oocytes compared with in vivo-matured oocytes (P < 0.001). No relationship was identified between glucose metabolism and the developmental capacity of oocytes after intracytoplasmic sperm injection when assessed after 17–19 h. Oocytes that became fertilised (two pronuclei) or activated (one or more pronucleus) were not distinguished from others by their metabolic rates. Longer culture after intracytoplasmic sperm injection (e.g. blastocyst stage) may show oocyte glucose metabolism to be predictive of developmental potential; however, culture to the single-cell stage did not reveal any significant differences in normally developing embryos.

Quality and age of companion felid embryos modulate enhanced development by group culture

For some species, embryos cultured with conspecific companions may have enhanced in vitro development compared with singletons. The objective of this study was to determine the effect of quality and age of companion embryos on single felid embryos produced by in vitro maturation or in vitro fertilization. Test oocytes (intermediate quality) were inseminated and incubated alone or with 10 embryos derived from oocytes with a high, intermediate, or low glucose uptake. The effect of relative age of companion embryos on test embryo development was also examined by insemination and incubation of test oocytes alone or with 10 conspecific embryos that were older, younger, or the same age. Test embryos coincubated with better- or equal-quality companions had better development and more cells per embryo (mean +/- SEM number, 74.9 +/- 16.9 and 40.6 +/- 8.8, respectively, Day 7; P < 0.05) than test embryos coincubated with lesser-quality companions (5.1 +/- 1.4) or alone (8.4 +/- 3.7). Intermediate-quality embryos incubated with older companions had more cells per embryo (88.3 +/- 17.0; P < 0.01) than those incubated with synchronous (49.3 +/- 12.1) or younger (29.4 +/- 6.1) embryos. The cell number of solitary embryos (9.8 +/- 3.1) was less (P < 0.05) than that of every group of test embryos incubated with companions, regardless of age. In vitro development of solitary cat embryos is improved by culture with excellent-quality conspecific companions, particularly companions of an advanced age.

Paternal exposure to cyclophosphamide dysregulates the gene activation program in rat preimplantation embryos

Although there has been progress in determining the mechanisms by which maternal toxicant exposure affects progeny, there is little information on the actions of drugs administered to the father. We investigated the effects of pre-conceptional paternal exposure to cyclophosphamide, an anti-cancer agent, on embryonic gene activation in the rat. The male pronucleus was formed earlier in embryos sired by cyclophosphamide-treated male rats than in those sired by controls; early male pronucleus formation was followed by alterations in the gene activation program. BrUTP incorporation into RNA and Sp1 transcription factor immunostaining were increased and spread over both cytoplasmic and nuclear compartments in 2-cell embryos sired by cyclophosphamide-treated males compared to controls. Total RNA synthesis was constant in 1-8 cell embryos sired by drug-treated fathers, while in control embryos RNA synthesis increased four-fold to peak at the 4-cell stage. In 2-cell embryos sired by drug-treated males, the relative abundance of candidate imprinted genes was elevated significantly above control; a peak in the expression of these genes was not observed until the 8-cell stage in control embryos. Thus, paternal drug exposure temporally and spatially dysregulated rat zygotic gene activation, altering the developmental clock.

Penetration of concanavalin-A-treated Chinese hamster oocytes by golden hamster spermatozoa in vitro, and chromosome analysis of hybrid 1-cell zygotes

Pretreatment of zona-free Chinese hamster (CH) oocytes with three kinds of lectin--concanavalin A (Con-A), phytohaemagglutinin-P (PHA) and wheat germ agglutinin (WGA)--was attempted in order to improve penetration by golden hamster (GH) spermatozoa in vitro. Con-A had no significant effect on penetration at 2 micrograms/ml, adequately facilitated oocyte-sperm fusion at 4 micrograms/ml, and caused excessive sperm binding and resultant severe polyspermy at 10 micrograms/ml. Neither PHA nor WGA had positive effects on sperm penetration at any concentrations (2-10 micrograms/ml) examined. Using the Con-A (4 micrograms/ml) pretreatment, high rates of interspecific fertilisation and subsequent chromosome analysis of hybrid 1-cell zygotes were achieved. Among 258 CH oocytes used, 212 (82.2%) were fertilised and 153 (72.2% of fertilised ova) developed to the first cleavage metaphase. Eventually, 132 CH-derived chromosome complements and 153 GH-derived ones were successfully karyoanalysed. Incidences of aneuploidy and structural anomaly were 3.1% and 2.3% in CH complements, and 1.4% and 6.5% in GH complements, respectively. These incidences were not significantly different from those obtained by intraspecific in vivo fertilisation, suggesting that our interspecific in vitro fertilisation system does not cause chromosome aberrations.

Characterization of developmental arrest in early bovine embryos cultured in vitro

The susceptibility of early bovine embryos to developmental arrest ("blocking") in vitro was examined. Embryos, obtained from superovulated donors, were cultured in vitro in Ham's F10 culture medium or in vivo in sheep oviducts. Treatments were terminated on Day 7 post-donor estrus (estrus = day 0), and the embryos were evaluated for development. Experiment 1 tested whether the 8- to 16-cell block was reversible. One- to two-cell embryos were cultured in vitro to the 8-cell stage (2 d), then in vivo for 3 d; controls were cultured in vitro or in vivo for 5 d. Forty-two percent (19/45) of in vivo controls developed normally; none (0/55; 0%) of the in vitro controls cleaved past the 9- to 16-cell stage. Only 4% (2/48) of the embryos cultured to eight cells in vitro developed normally after culture in sheep oviducts, indicating that the block was irreversible. Irreversibility was not caused by overt cell death, since 33/33 (100%) of blocked embryos responded positively to fluorescein diacetate vital staining. Experiment 2 tested the effect of in vitro exposure at specific cell stages on subsequent in vivo development. Embryos at the 1- to 2-, 3- to 4-, 5- to 8- and 9- to 16-cell stages were assigned randomly to one of the following treatments: in vivo culture; in vitro culture; or 24 h in vitro culture, followed by in vivo culture. Subsequent in vivo development was affected by 24 h of in vitro culture (P<0.05) only in 3- to 4-cell embryos (11/41, 27% vs 22/41, 54% for in vivo controls). We conclude that 1) the block is a manifestation of in vitro exposure during the four- to eight-cell stage, and 2) the block, while irreversible, is not the result of overt embryonic death.

Co-culture of two-cell rat embryos on cell monolayers

Monolayers of 2 different populations of uterine cells and of fetal fibroblasts were evaluated for the support of rat embryo development in vitro. Compared to controls, cultures performed in Earle's buffered saline solution (EBSS) alone, the cleavage rate of 2-cell embryos to the 4-cell stage was significantly increased when the embryos were cocultured for 24 h with mixed uterine stromal and myometrial cells (70.7 vs. 56.0%; P less than 0.01). Coculture of 2-cell embryos with either uterine epithelial-stromal or stromal-myometrial cells in medium TC 199 (M199) for 24 h significantly increased the cleavage rate to the 4-cell stage compared to controls in the same medium (respectively, 78.3 and 77.6 vs. 49.9%; P less than 0.01). The development was not improved when fibroblasts were used as feeder cells. After 48 h, the proportion of 4-cell embryos showing cellular fragmentation was significantly decreased in the presence of either epithelial-stromal or stromal-myometrial cells in M199 compared to controls (respectively, 18.4 and 20.0 vs. 43.8%; P less than 0.01). Coculture in EBSS or with fibroblasts failed to prevent embryo degeneration. In one coculture with stromal-epithelial cells in M199, 6/11 embryos proceeded beyond the 4-cell stage, two of them reaching the 8-cell stage. No embryo developed beyond that stage in our study. Although considerable efforts remain necessary to achieve further growth, these results suggest that coculture offers promise as a means of supporting the in vitro development of rat embryos.

Factors limiting reproductive efficiency in selected laboratory animals

The mouse, rat, hamster, and rabbit have had remarkable success in surviving in the wild, which attests to their high reproductive capability. In fact, Parkes refers to mice conceiving at each postpartum estrus having the potential for 13 litters per year. Paufler et al. used GnRH to repeatedly cause ovulation in 27 rabbits a few days after parturition, resulting in an average pregnancy rate of 71.5%, 7.0 young born, 5.8 young weaned, and 50 young per doe per year. All four species produce an excess of spermatozoa relative to the requirements for fertilization. The rabbit is suitable for semen collection, artificial insemination, and most of the techniques one might wish to model for reproductive studies in both males and females. A major limitation to reproduction in these species is that reproductive capacity fails long before the finite oocyte population formed prenatally is depleted. The uterus of the aged female appears to be the major cause of reproductive failure, as fertilized eggs replaced in such a uterus usually soon deteriorate. With in vitro techniques, much is still to be learned about harvesting, maturing and fertilizing oocytes and identifying those most likely to result in formation of a healthy neonate.

Cold culture of different stage mouse embryos in bicarbonated and bicarbonate-free media

Mouse embryos of different stages of development were cultured to expanded blastocysts following storage (1 to 8 d) at 4 degrees C in the presence or absence of HCO(3)(-). The effect of oxygen tension on the cold storage of one- and two-cell mouse embryos at 4 degrees C was evaluated by 37 degrees C culture and transfer to pseudopregnant recipients. Survival at 4 degrees C of early, one- to four-cell mouse embryos was improved with HCO(3)(-) in the medium. The presence of HCO(3)(-) was not of benefit for morulae or blastocyst survival following cold storage. Reducing the oxygen atmosphere from 20 to 5% O(2) improved survival of one-cell mouse embryos stored at 4 degrees C. The survival of two- and four-cell embryos, morulae and blastocysts at 4 degrees C was similar in 90% N(2), 5% CO(2) and 5% CO(2) in air, but it was significantly poorer in air alone. The collapse of morulae and blastocysts during cold storage up to 5 d was reduced with HCO(3)(-) in the storage medium. Blastocysts stored for 6 d at 4 degrees C failed to survive following immediate transfer to pseudopregnant recipients. Blastocyst survival was improved compared to controls (direct transfer of unstored blastocysts to recipients) when cultured for 36 h at 37 degrees C following 6 d of cold storage. This result suggests that cold-stored mouse blastocysts may require a metabolic period of readjustment to survive following transfer to synchronized recipients.

Development of golden hamster embryos through the two-cell block in chemically defined medium

The effect of increasing the embryo:medium volume ratio on overcoming the hamster two-cell block was examined. Two-cell golden hamster embryos from each superovulated female were cultured in microdrops (estimated at 0.75 microliter) or 100 microliter macrodrops of chemically defined medium (modified Tyrode's solution [TLP] plus glutamine, isoleucine, methionine, phenylalanine, and taurine). In 11 trials (i.e., with embryos from 11 donors), 28.6% of 269 embryos developed to the four-cell stage in microdrops, whereas only 2 (0.7%) embryos developed in the macrodrops. When two microdrops were used to culture the two-cell embryos from each donor (n = 8), 17.8% of 304 embryos developed to four cells. Increasing the embryo:medium volume ratio further by culturing all of the embryos from each donor (n = 10) in single microdrops resulted in 53.1% of 397 embryos developing to four cells. Conditioning of the culture medium by these embryos could not be demonstrated. Increasing the embryo:medium volume ratio may protect against loss of some intracellular component essential for growth of early-stage hamster embryos. Alternatively, increasing this ratio may permit embryos to reduce the concentration of a substance detrimental to their growth. This work represents the first report of cleavage of hamster two-cell embryos in vitro. These findings are a significant step towards our goal of obtaining complete preimplantation developmental of hamster embryos in vitro and may be helpful for solving the in vitro developmental blocks in embryos from other species.

Quick freezing of rat embryos

Quick freezing of rat morulae and blastocysts was attempted after they were dehydrated at room temperature. Combined solutions of 2.8 M glycerol and 0.125, 0.25, 0.50 and 1.0 M sucrose in phosphate buffered saline + 20% steer serum were compared. Survival rates (expanding blastocysts 15 h after thawing) were 42.1, 79.4, 87.5 and 16.7%, respectively (P<0.01). Freezing procedures consisted of either a direct plunge into liquid nitrogen (48.8%), holding for 5 min in the neck of a liquid nitrogen container or holding the samples for 60 min at -30 degrees C before insertion into liquid nitrogen. The direct plunge method resulted in a lower survival rate than either the 5- or the 60-min treatments (48.8% vs 76.9% and 77.6%, respectively). After thawing, dilution at room temperature in sucrose solutions of 0.25, 0.50 and 1.0 M gave survival rates of 80.0, 90.6 and 69.4%, respectively (NS). If diluted directly in PBS + 20% steer serum, 86.8% of embryos survived at +37 degrees C vs 0% at 0 degrees C (P<0.01).

Successful pregnancies from the transfer of pronucleate embryos in an outpatient in vitro fertilization program

Twenty-nine infertile women were given clomiphene citrate (100 mg/day, days 3 to 7), human menopausal gonadotropin (150 IU/day, days 7 to 12 or 13), and human chorionic gonadotropin (2000 IU) for the induction of ovulation. Eggs were collected by laparoscopy and preincubated for 6 hours before being cultured with spermatozoa for fertilization. Approximately 16 to 18 hours after insemination, the eggs that showed two pronuclei were transferred to the patient's uterus. As confirmed by the ultrasonic appearance of a gestational sac, six women who received pronucleate embryos became pregnant, and three pregnancies resulted in normal full-term deliveries. These results confirm that, unlike requirements for most laboratory and farm animals, the requirements of synchrony between the preimplantation human uterus and developing embryos are not very stringent. In vitro fertilization treatment procedures can thus be made simpler by the transfer of embryos at the pronucleate stage.