Effect of estrous cow serum during bovine embryo culture on blastocyst development and cryotolerance after slow freezing or vitrification

The present study investigated the effect of estrous cow serum (ECS) during culture of bovine embryos on blastocyst development and survival after cryopreservation by slow freezing or vitrification. Embryos were derived from in vitro maturation (IVM) and in vitro fertilization (IVF) of abbatoir-derived oocytes. At Day 3, embryos were cultured in three different media: Charles Ronsenkrans medium + amino acids (CR1aa; without bovine serum albumin (BSA)) + 5% estrous cow serum (CR1-ECS), CR1aa + 3 mg/mL BSA (CR1-BSA) or CR1aa + 5% ECS + 3 mg/mL BSA (CR1-ECS-BSA). At 7.5 d post-insemination (PI), blastocyst yield and quality were evaluated; blastocysts and expanded blastocysts from each media were cryopreserved by Open Pulled Straw (OPS) vitrification method or slow freezing (1.5 M ethylene glycol, EM). Total blastocyst yield did not differ among CR1-ECS, CR1-BSA and CR1-ECS-BSA (30.9, 33.1 and 32.9%, respectively, P < 0.05). Embryo survival (hatching rate) was higher in vitrified versus slow-frozen embryos (43% versus 12%, respectively, P < 0.01), and in embryos cultured in CR1-BSA (40.3%) compared with those cultured in serum-containing media (CR1-ECS, 21.5% and CR1-ECS-BSA, 19.8%; P < 0.01). In conclusion: (a) it was possible to produce in vitro bovine embryos in serum-free culture medium without affecting blastocyst yield and quality; (b) serum-free medium produced the best quality embryos (in terms of post-cryopreservation survival); and (c) vitrification yielded the highest post-cryopreservation survival rates, regardless of the presence of serum in the culture medium.     

Development, chromosomal composition, and cell allocation of bovine cloned blastocyst derived from chemically assisted enucleation and cultured in conditioned media

Treatment of in vitro matured bovine oocytes with colcemid results in a membrane protrusion that contains maternal chromosomes, which can be easily removed by aspiration. Four experiments were designed to evaluate the overall and temporal effects of conditioned medium (CM) by bovine cumulus cells on development of nuclear transfer (NT) bovine embryos and to examine the chromosomal composition and allocation of inner cell mass (ICM) and trophectoderm (TE) of the subsequent blastocysts. The nuclear transfer embryos were cultured in various CR1aa media conditioned by preculture with bovine cumulus cells. Development to the blastocyst stage in BSA-containing CM (BCM) and serum-containing CM (SCM) were similar to co-culture group (24-30%). The 24 hr-conditioned BCM yielded higher blastocyst development than 48 and 72 hr-conditioned BCM. Temporary exposure of embryos to BCM and SCM followed by CR1aa was also studied. Morula and blastocyst development were not different among the groups cultured in BCM for 72, 96, and 168 hr, but were significantly higher (P < 0.01) than groups exposed to BCM for 24 and 48 hr, respectively. Blastocyst development in SCM for 24 hr (29%), 96 hr (25%), and 168 hr (27%) were much higher (P < 0.05) than those in SCM for 48 hr (12%) and 72 hr (10%). The analyses of chromosomal composition of the resulting blastocysts indicate approximately 80% of the blastocysts cultured in CR1aa with co-culture or groups initially exposed to BCM for 24 hr followed by culture in CR1aa were diploid. However, the incidence of diploidy were only 36-60% in SCM-cultured groups and groups cultured in BCM beyond 48 hr. Conditioned media did not affect the allocation of ICM and TE in the blastocyst. No difference was found in the ratio of inner cell mass to total cells in co-culture, BCM or SCM groups (0.424, 0.441, and 0.473, respectively). In conclusion, bovine cumulus cell-CM and CR1aa with co-culture supported comparable development and blastocyst ICM:total cell ratio of bovine NT embryos. However, CM affected the blastocyst chromosomal composition and induced higher mixploidy.     

Succinate and malate improve development of hamster eight-cell embryos in vitro: Confirmation of viability by embryo transfer

The in vitro development of hamster preimplantation embryos is supported by non-glucose energy substrates. To investigate the importance of embryonic metabolism, influence of succinate and malate on the development of hamster 8-cell embryos to blastocysts was examined using a chemically defined protein-free modified hamster embryo culture medium-2 (HECM-2m). There was a dose-dependent influence of succinate on blastocyst development; 0.5 mM succinate was optimal (85.1% ± 3.9 vs. 54.5% ± 3.5). In succinate-supplemented HECM-2m, blastocyst development was reduced by omission of lactate (68.5% ± 7.2), but not pyruvate (85.8% ± 6.2) or glutamine (84.1% ± 2.1). Succinate along with either glutamine or lactate or pyruvate poorly supported blastocyst development (28%–58%). Malate also stimulated blastocyst development; 0.01 mM malate was optimal (86.3% ± 2.8). Supplementation of both succinate and malate to HECM-2m supported maximal (100%) blastocyst development, which was inhibited 4-fold by the addition of glucose/phosphate. The mean cell numbers (MCN) of blastocysts cultured in succinate-supplemented HECM-2m was higher (28.3 ± 1.1) than it was for those cultured in the absence of glutamine or pyruvate (range 20–24). The MCN was the highest (33.4 ± 1.6) for blastocysts cultured in succinate-malate-supplemented HECM-2m followed by those in succinate (28.3 ± 1.1) or malate (24.7 ± 0.5) supplemented HECM-2m. Embryo transfer experiments showed that 29.8% (±4.5) of transferred blastocysts cultured in succinate-malate-supplemented HECM-2m produced live births, similar (P > 0.1) to the control transfers of freshly recovered 8-cells (33.5% ± 2.0) or blastocysts (28.9% ± 3.0). These data show that supplementation of succinate and malate to HECM-2m supports 100% development of hamster 8-cell embryos to high quality viable blastocysts and that non-glucose oxidizable energy substrates are the most preferred components in hamster embryo culture medium. Mol. Reprod. Dev. 47:440–447, 1997. © 1997 Wiley-Liss, Inc.     

Effects of amino acids and α-amanitin on bovine embryo development in a simple protein-Free medium

Five experiments, utilizing 3741 embryos produced in vitro, were designed to test the effects of Eagle's nonessential amino acids, and combinations of Eagle's essential amino acids and the RNA polymerase inhibitor α-amanitin on the development of preimplantation bovine embryos in a modified protein-free KSOM medium. Embryos were cultured in 5% O₂:5% CO₂:90% N₂ at 39°C for the first 40–44 hr in modified KSOM, and embryos with ≥4 cells were cultured in modified KSOM-PVA with different amino acids in experiments 1–4, and with the addition of α-amanitin in experiment 5. In experiment 1, addition of 0.5× of the essential amino acids, with different concentrations of nonessential amino acids significantly increased hatching of blastocysts and decreased blastocyst degeneration, but increasing the nonessential amino acids from 1× to 5×, did not stimulate embryo development. In experiments 2–4, increasing only the glycine concentration, or adding each of the 12 essential amino acids singly or several in combination to the medium containing nonessential amino acids, did not significantly improve embryo development. Taurine (0.4 mM) in the modified KSOM medium reduced blastocyst degeneration. In experiment 5, α-amanitin (20 μM) completely inhibited further embryo development when it was added at several stages from 4-cell embryos to morulae. The study with protein-free KSOM plus amino acids provided a completely defined simple medium for culturing bovine embryos, with evidence that continuous mRNA activity and presumed protein synthesis was obligatory to meet the complex and continuous requirements for proteins by the developing blastocyst. Mol. Reprod. Dev. 46:278–285, 1997. © 1997 Wiley-Liss, Inc.     

Optimization of culture medium for cloned bovine embryos and its influence on pregnancy and delivery outcome

This study was conducted to establish an effective culture system for supporting in vitro development of cloned bovine embryos and to evaluate whether improved development in the optimal culture system could contribute to enhancing pregnancy and delivery outcomes after transfer. Enucleated oocytes at the metaphase II stage were reconstructed with serum-starved ear fibroblasts and cloned embryos were subsequently cultured for 168 h in vitro. In Experiment 1, cloned embryos were cultured in either modified Charles Rosenkrans 2 amino acid medium (mCR2aa) or modified synthetic oviduct fluid medium (mSOF). More (P < 0.05) 2-cell embryos (78% versus 92%), morulae (51% versus 69%) and blastocysts (2% versus 39%) were obtained after culture in mSOF than after culture in mCR2aa. In Experiment 2, cloned embryos were successively cultured in mSOF supplemented with various macromolecules during different periods of culture. A successive culture of oocytes in BSA-containing medium for 72 h and then in FBS-containing medium for the next 96 h yielded a higher rate of blastocyst formation (49% versus 25-36%) than other combinations (BSA to BSA or PVA to PVA, BSA or FBS). This macromolecule supplementation also significantly increased the number of total blastomeres (117.3 cells/blastocyst) and inner cell mass cells (ICM, 49.7 cells/blastocyst), and the ratio of ICM cells to trophoblast cells (TB, 0.98). In Experiment 3, a total of 85 blastocysts obtained from each 2-step culture were transferred individually to recipient cows at the end of the culture period and 32 pregnancies (38%) were diagnosed on Day 60 after transfer. However, no (P > 0.05) significant differences due to culture were apparent in the pregnancy outcome. Although six calves were produced using the 2-step culture regime of either BSA-BSA or PVA-FBS, no calves were produced using the successive culture of BSA then FBS, which optimized preimplantation development. In conclusion, mSOF has more potential to support the development of clone embryos than mCR2aa, and successive supplementation of BSA and FBS to mSOF further promotes blastocyst formation. However, enhanced development in vitro might not directly contribute to improving pregnancy outcomes.     

The differential requirement of albumin and sodium citrate on the development of in vitro produced bovine embryos

In vitro culture for bovine embryos is largely not optimal. Our study was to determine the components necessary for early embryo development. In experiment 1, IVF embryos were cultured for two days in CR1aa medium containing sodium citrate and BSA from two sources (Sigma vs. ICPbio), subsequently for additional five days with cumulus monolayer in 10% FBS CR1aa. We found that supplementation with both Sigma-BSA and sodium citrate significantly increased total blastocyst (BL) development compared with the ICPbio-BSA groups (37% vs. 19-21%), and enhanced the total number of high quality (C1 BL, IETS standard) blastocysts (26% vs. 11-17%) (P < 0.05). In experiment 2 with serum free and/or somatic free culture, we found that CR1aa culture can support a comparable embryo development with a supplement of Sigma BSA. The addition of sodium citrate did not increase blastocyst development in either the Sigma-BSA or the ICPbio-BSA groups. An inferior blastocyst development occurring in ICPbio-BSA culture (1-3%) could be rescued by culture in CRlaa supplemented with 10% FBS (29%), more importantly, by culture in CR1aa with a replacement of Sigma BSA (24%) (P <0.05). C1 blastocysts rescued by FBS and Sigma BSA in ICPbio-BSA culture possessed indistinguishable morphology to embryos developed in a Sigma-BSA, FBS and somatic co-culture system, showing similar cell number/blastocyst (129-180, P > 0.05). Our study found a beneficial effect of sodium citrate and BSA on the in vitro development of bovine IVF embryos during co-culture. We also determined that differential embryotrophic factor(s) contained in BSA and serum, probably not sodium citrate, is necessary for promoting competent morula and blastocyst development in cattle.     

Effect of amino acids and α-amanitin on the development of rabbit embryos in modified protein-free KSOM with HEPES

Four experiments were conducted to test the effects of Eagle's non-essential amino acids (NEAA) and essential amino acids (EAA), glycine, and the RNA polymerase inhibitor α-amanitin, on the development of preimplantation rabbit embryos in modified protein-free KSOM medium. Embryos were distributed randomly into different treatments and cultured in 5% O₂:5% CO₂:90% N₂. In experiment 1, 100% of the embryos became blastocysts in the medium with Eagle's IX NEAA and 0.5X EAA, but 100% stopped development at the morula stage in KSOM without amino acids. These morulae failed to develop further when transferred to amino acid supplemented medium after 72 hr of culture. Glycine alone in modified KSOM (experiment 2) was ineffective in supporting development of 8–16-cell stage embryos past the morula stage. In experiment 3, the addition of IX NEAA and 0.5X EAA at 0, 12, 24, 36, and 48 hr of culture resulted, respectively, in 57, 65, 65, 44, and 14% blastocysts on Day 3 (P<0.05) and 86, 77, 77, 78, and 69% on Day 5 (P<0.05). Omission of Eagle's amino acids until 48 hr clearly delayed embryo development. In experiment 4, when α-amanitin (20 μM) was added to the medium containing Eagle's amino acids after 0, 12, 24, 36, and 48 hr of culture most embryos cleaved only once or twice after adding the α-amanitin. Without the inhibitor, 94% of the zygotes developed into blastocysts. These results indicate that modified KSOM or KSOM plus glycine could not support rabbit embryo development past the morula stage, but this block was overcome by adding Eagle's amino acids. An exogenous source of amino acids was not critical for embryo development during the first 24 hr of culture, but was required after that for development to equal controls. Addition of α-amanitin at multiple pre-blastocyst stages limited further embryo development to one or two cleavage divisions, with no blastocyst development. © 1996 Wiley-Liss, Inc.     

Pyruvate prevents peroxide‐induced injury of in vitro preimplantation bovine embryos

The impact of oxidative stress on the in vitro development of bovine embryos in synthetic oviduct fluid medium (mSOF) was assessed by using H₂O₂ as a stress inducer. In a preliminary experiment, a chemiluminescent method was used to measure the antioxidative capacity of the mSOF culture medium. Pyruvate was the mSOF component displaying the highest H₂O₂ degrading ability. Essential and nonessential amino acids also significantly reduced the H₂O₂ concentration, whereas lactate and glutamine were ineffective. The effect on further development of a short exposure of zygotes, 9–16‐cell stage embryos and blastocysts to 0 M; 10⁻⁷ M ; 10⁻⁶ M, and 10⁻⁵ M H₂O₂ in pyruvate‐free mSOF was evaluated. Developmental rates of the H₂O₂‐treated zygotes to the 5–8‐cell or blastocyst stages and survival of H₂O₂‐treated blastocysts were reduced in a dose‐dependent manner whereas the 9–16‐cell embryos were unaffected by those treatments. Blastocysts treated with H₂O₂ also tended to have lower numbers of bisbenzimide‐stained nuclei and showed increased nuclear fragmentation. Including pyruvate in the mSOF culture medium during a 10⁻⁵ M H₂O₂ pulse highly reduced the H₂O₂ concentration as measured by chemiluminescence and improved zygote and blastocyst development, but failed to prevent blastocyst nuclei degradation. These experiments suggest that bovine embryos show developmental change in sensitivity to exogenous H₂O₂, the 9–16‐cell embryos being more resistant than zygotes and blastocysts and that H₂O₂ and its toxic effects can be attenuated by including pyruvate in the medium. Mol. Reprod. Dev. 52:149–157, 1999. © 1999 Wiley‐Liss, Inc.     

Improved development of DNA-injected bovine embryos co-cultured with mouse embryonic fibroblast cells

The in vitro development of DNA-injected bovine zygotes, produced in vitro, was compared when cultured with or without mouse embryonic fibroblasts (MEF). The in vivo viability of the embryos produced in these in vitro culture systems was assessed by single or double transfer to recipients taken to term. For these experiments, in vitro fertilized oocytes were not injected (Experiment 1) or were injected with pBL1 gene (Experiment 2) and then cultured for 2 days in CR1aa medium supplemented with 3 mg/ml BSA at 38.5 degrees C in a humidified atmosphere of 5% CO(2) in air. Embryos that developed to the 4- to 8-cell stage at the end of this period were randomly assigned to the two cultured systems and cultured for a further 5 days in groups of 10 to 15 embryos in 0.75 ml medium. These two culture systems were CR1aa medium alone or co-culture with MEF in CR1aa medium supplemented with 10% fetal bovine serum (FBS). Every 48 h, 0.5 ml of the medium was replaced with fresh CR1aa medium and at Day 5 of culture, both media were supplemented by the addition of 5.56 mM glucose and 1x GMS-X supplement solutions. Results were assessed as morphological development of the embryos and data were analyzed by Chi-square test or Student's t-test.The development rate of in vitro fertilization (IVF)-derived embryos co-cultured with MEF (24.4%, 49/201) was significantly higher than those cultured alone (14.4%, 28/194; P<0.05) in Experiment 1. There was a similar difference between the treatments in the proportions of embryos which reached the hatching stage or hatched (10.9%, 22/201 vs. 4.1%, 8/194, respectively; P<0.05). DNA-injected embryos co-cultured with MEF (13.7%, 28/205) showed a higher developmental rate than that of the embryos cultured without MEF (6.7%, 13/193; P<0.05) in Experiment 2. Following the transfer to recipients of one or two DNA-injected blastocysts, the pregnancy rates for two culture systems were similar (MEF co-culture 27.4%, 23/84; CR1aa culture 24. 2%, 16/66). However, the numbers of calves born alive from these pregnancies were higher on the MEF co-culture group (82.6%, 19/23) than the CR1aa culture group (56.2%, 9/16). It was concluded that in vitro embryo development to the blastocyst stage and subsequent in vivo development to term of DNA-injected bovine embryos was improved in comparison to culture in CR1aa alone when the last 5 days of in vitro culture were in a MEF co-culture system.     

Effect of supplementation of different growth factors in embryo culture medium with a small number of bovine embryos on in vitro embryo development and quality

When embryos are cultured individually or in small groups, blastocyst yield efficiency and quality are usually reduced. The aim of this work was to investigate the effect of supplementation of the embryo culture medium (CM) with several growth factors (GFs) on embryo development and apoptosis rate when a reduced number of embryos were in vitro cultured. Two experimental studies (ES) were carried out. In ES 1, five treatments were tested to study the effect of GF on embryo development: Control (∼30 to 50 embryos cultured in 500 μl of CM); Control 5 (Five embryos cultured in 50 μl microdrops of CM), without addition of GF in either of the two control groups; epidermal GF (EGF); IGF-I; and transforming GF-α (TGF-α) (Five embryos were cultured in 50 μl microdrops of CM with 10 ng/ml EGF, 10 ng/ml IGF-I or 10 ng/ml TGF-α, respectively). In ES 2, following the results obtained in ES 1, four different treatments were tested to study their effect on embryo development and quality (number of cells per blastocyst and apoptotic rate): Control; Control 5; EGF, all three similar to ES 1; EGF + IGF-I group (five embryos cultured in 50 μl microdrops of CM with 10 ng/ml EGF and 10 ng/ml IGF-I). In both ESs, it was observed that a higher proportion of embryos cultured in larger groups achieved blastocyst stage than embryos cultured in reduced groups (22.6% v. 14.0%, 12.6% and 5.3% for Control v. Control 5, IGF-I, TGF-α groups in ES 1, and 24.9% v. 17.1% and 19.0% for Control v. Control 5 and EGF in ES 2, respectively; P < 0.05), with the exception of embryos cultured in medium supplemented with EGF (18.5%) or with EGF + IGF-I (23.5%), in ES 1 and ES 2, respectively. With regard to blastocyst quality, embryos cultured in reduced groups and supplemented with EGF, alone or combined with IGF-I, presented lower apoptosis rates than embryos cultured in reduced groups without GF supplementation (11.6% and 10.5% v. 21.9% for EGF, EGF + IGF-I and Control 5 groups, respectively; P < 0.05). The experimental group did not affect the total number of cells per blastocyst. In conclusion, this study showed that supplementation of the CM with EGF and IGF could partially avoid the deleterious effect of in vitro culture of small groups of bovine embryos, increasing blastocyst rates and decreasing apoptosis rates of these blastocysts.     

Lysophosphatidic acid accelerates development of porcine embryos by activating formation of the blastocoel

Culture media modifications, including the addition of various factors, are important for the in vitro production of oocytes and embryos. In this study, we investigated the effects of lysophosphatidic acid (LPA) on porcine embryo development. Porcine parthenogenetic embryos were cultured with 0, 0.1, 1, and 10 μM LPA for 7 days, or cultured in basic medium until Day 4 and then treated with LPA from Days 4 to 7. No difference in the in vitro development of embryos cultured with LPA for 7 days was observed. Conversely, rates of blastocyst and over‐expanded blastocyst formation were higher in the 0.1 and 1 µM LPA‐treated versus the other groups of embryos treated from Days 4 to 7. Moreover, formation of early blastocysts occurred earlier and embryo size was larger in LPA‐treated compared to control embryos. Expression of Connexin 43 and gap junction and cell adhesion‐related genes (GJC1 and CDH1, respectively) was also higher in LPA‐treated compared to control embryos. Despite no difference in the blastocyst total cell number between groups, the apoptotic index was lower in the LPA‐treated group than in the control group; indeed, BCL2L1 (B‐cell lymphoma 2‐like protein 1) expression increased while BAK (Bcl‐2 homologous antagonist killer) decreased in the LPA‐treated group. Thus, addition of LPA to the medium from Days 4 to 7 of culture improves blastocyst formation and aids the development of preimplantation embryos.     

Oxygen consumption and energy metabolism of the early mouse embryo

Oxygen consumption of preimplantation and early postimplantation mouse embryos has been measured using a novel noninvasive ultramicrofluorescence technique, based on an oil-soluble, nontoxic quaternary benzoid compound pyrene, whose fluorescence is quenched in the presence of oxygen. Pyruvate and glucose consumption, lactate production, and glycogen formation from glucose were also measured. Preimplantation mouse embryos of the strain CBA/Ca × C57BL/6 were cultured in groups of 10–30 in 2 μl of modified M2 medium containing 1 mmol l⁻¹ glucose, 0 mmol l⁻¹ lactate, and 0.33 mmol l⁻¹ pyruvate, for between 4–6 hr. Day 6.5 and 7.5 embryos were cultured singly in 40 μl M2 medium for between 2–3 hr. Oxygen consumption was detected at all stages of development, including, for the first time, in the early postimplantation embryo. Consumption remained relatively constant from zygote to morula stages before increasing in the blastocyst and day 6.5–7.5 stages. When expressed as QO₂ (μl/mg dry weight/hr), oxygen consumption was relatively constant from the one-cell to morula stages before increasing sharply at the blastocyst stage and declining to preblastocyst levels on days 6.5 and 7.5. Pyruvate was consumed during preimplantation stages, with glucose uptake undetectable until the blastocyst stage. Glucose was the main substrate consumed by the 6.5 and 7.5 day embryo. The proportions of glucose accounted for by lactate appearance were 81%, 86%, and 119% at blastocyst, day 6.5, and day 7.5 stages, respectively. The equivalent figures for glucose incorporated into glycogen were 10.36%, 0.21%, and 0.19%, respectively. The data are consistent with a switch from a metabolism dependent on aerobic respiration during early preimplantation stages to one dependent on both oxidative phosphorylation and aerobic glycolysis at the blastocyst stage, a pattern which is maintained on days 6.5 and 7.5. Our technique for measuring oxygen consumption may have diagnostic potential for selecting viable embryos for transfer following assisted conception techniques in man and domestic animals. © 1996 Wiley-Liss, Inc.     

Progesterone enhances in vitro development of bovine embryos

Increased pregnancy rates in cattle given progesterone (P₄) prior to 5 d after breeding have recently been reported. The objective was to determine if this increase in pregnancy rate could be attributed to a direct positive effect of P₄ on the developing embryo. In Experiment 1, 280 bovine oocytes were inseminated in vitro and at Day 3 (insemination = Day 0), good quality 8 cell embryos (n = 206) were randomly allocated to be cultured in either CR1aa+serum with 0 or ∼15 ng/mL (n = 102 and n = 104, respectively). In Experiment 2, 881 bovine oocytes were used; on Day 3, good quality 8 cell embryos (n = 511) were randomly allocated to either the control (CR1aa+FCS, n = 168), vehicle (CR1aa + FCS + ethanol, n = 170), or P₄ treatment (CR1aa + FCS + ∼15 ng/mL P₄ in ethanol, n = 173). On Day 7, in both experiments, there were increased numbers of blastocysts developing in the P₄ group (Experiment 1, 59% and Experiment 2, 71%) compared to the vehicle (Experiment 2, 53%) or control (40 and 62% in Experiments 1 and 2, respectively). The addition of P₄ (8%) stimulated the rate of embryo development (early blastocysts or more advanced stages on Day 6) compared to vehicle (3%) and control (0%) and the P₄ group had more hatched or hatching blastocysts (33%) on Day 9 compared to the control or vehicle group (21 or 22%). Additionally, the P₄ group had greater embryo diameter and significantly more Grade 1 blastocysts on Day 7. In conclusion, P₄ had a direct, positive effect on developing bovine embryos cultured in vitro.     

Development of preimplantation embryos of the golden hamster in a defined culture medium

Eight-cell embryos were recovered from mated golden hamsters that had been superovulated with pregnant mare's serum gonadotropin (PMSG) and human chorionic gonadotropin (hCG). Embryos were cultured for 24 or 32 h in a defined medium (modified Tyrode's solution) designed for fertilization of hamster oocytes in vitro. This medium was supplemented in some experiments with amino acids (glutamine, phenylalanine, methionine and isoleucine) and with vitamins (Eagle's Minimum Essential Medium vitamin supplement). At the end of the culture period, the numbers of embryos developing to the blastocyst stage were recorded. In other experiments, the effects of varying the osmotic pressure (225, 250, 275 and 300 m0smol/kg) and the pH (6.8 and 7.4) of the culture medium on blastocyst formation were examined. A difference was found between the ability of early 8-cell embryos (approx. 54 h post-egg activation) and late 8-cell embryos (approx. 62 h post-egg activation) to develop in culture. In the unsupplemented culture medium, only 2% of early 8-cell embryos developed to the blastocyst stage compared with 22% of late 8-cell embryos. A marked effect of the four amino acids on development was found. In the presence of amino acids 36% of early 8-cell embryos developed into blastocysts (18-fold increase). The amino acids also increased the percentage of late 8-cell embryos that developed into blastocysts from 22% to 66%. These data suggest that an important metabolic change may occur in hamster embryos during a critical period at the 8-cell stage of development. No additional effect on development was observed when vitamins were included in the culture medium. No significant effect of either osmotic pressure of pH of the culture medium on development was found. When blastocysts formed from cultured 8-cell embryos were transferred surgically to pseudopregnant hamsters, about 25% developed into normal-looking fetuses and 5 normal-looking young were born, 4 of which have survived. These results represent an approach towards achieving complete preimplantation development of hamster embryos in vitro.     

Offspring from Mouse Embryos Developed Using a Simple Incubator-Free Culture System with a Deoxidizing Agent

To culture preimplantation embryos in vitro, water-jacketed CO₂ incubators are used widely for maintaining an optimal culture environment in terms of gas phase, temperature and humidity. We investigated the possibility of mouse embryo culture in a plastic bag kept at 37°C. Zygotes derived from in vitro fertilization or collected from naturally mated B6D2F1 female mice were put in a drop of medium on a plastic culture dish and then placed in a commercially available plastic bag. When these were placed in an oven under air at 37°C for 96 h, the rate of blastocyst development and the cell numbers of embryos decreased. However, when the concentration of O₂ was reduced to 5% using a deoxidizing agent and a small oxygen meter, most zygotes developed into blastocysts. These blastocysts were judged normal according to their cell number, Oct3/4 and Cdx2 gene expression levels, the apoptosis rate and the potential for full-term development after embryo transfer to pseudopregnant recipients. Furthermore, using this system, normal offspring were obtained simply by keeping the bag on a warming plate. This culture method was applied successfully to both hybrid and inbred strains. In addition, because the developing embryos could be observed through the transparent wall of the bag, it was possible to capture time-lapse images of live embryos until the blastocyst stage without needing an expensive microscope-based incubation chamber. These results suggest that mouse zygotes are more resilient to their environment than generally believed. This method might prove useful in economical culture systems or for the international shipment of embryos.     

Production of calves by transfer of nuclei from cultured somatic cells obtained from Japanese black bulls

We investigated the possibility of producing calves from transferable bovine embryos obtained by nuclear transfer using somatic cell-derived cell lines. Muscle cells obtained from 2 Japanese Black bulls were dispersed in Hank's solution supplemented with collagenase Type-I. The separated muscle cells were cultured in Dulbecco's Modified Eagle's medium (D-MEM) supplemented with 10% fetal bovine serum (FBS) at 39 degrees C in an atmosphere of 5% CO2 in air. Cells were passaged at least 4 times, and for 5 d prior to nuclear transfer they (donor cells: karyoplasts) were cultured in D-MEM supplemented with 0.5% FBS (to induce quiescence) or 10% FBS. Recipient oocytes were produced by in vitro culture of bovine oocytes that were obtained at a slaughterhouse and then enucleated in modified phosphate buffered saline supplemented with cytochalasin B. Embryos were reconstructed by 3 protocols using karyoplasts cultured in the medium with 0.5% FBS. 1) Group A: recipient oocytes (cytoplasts; n = 157) were treated with Ca ionophore A 23187, ethanol and cycloheximide, and then a karyoplast was fused to an activated cytoplast. 2) Group B: karyoplasts were transferred to cytoplasts (n = 117), and the couplets were treated with electric stimulation and then Ca ionophore A 23187 and cycloheximide. 3) Group C: cytoplasts (n = 104) were cultured for a further 12 h before fusion, and then the couplets were treated with electric stimulation and cycloheximide. 4) Group D: in addition to the above 3 groups, karyoplasts cultured in the medium with 10% FBS were transferred to recipient cytoplasts (n = 137) and treated as in Protocol 2. Reconstructed embryos were cultured in modified CR1aa for 8 d, and the development of embryos was assessed. In total 73 blastocysts were obtained, and the frequency of development to the blastocyst stage in Group A (2.5%) was lower than that of Groups B, C and D (20.5, 18.3 and 19.0%, respectively; P < 0.01). Of these the sex of 21 blastocysts was determined by rapid Y-chromosome detection assay, and all were male, suggesting that nuclear replacement had been achieved successfully. When 26 blastocysts were transferred to 20 recipient cows, 8 of them became pregnant; 4 cows subsequently aborted about 60 d after embryo transfer while the remaining 4 cows calved. These results indicate that reconstructed embryos obtained by nuclear transfer of muscle cell-derived cell lines can develop to the blastocyst stage, and some are sufficiently competent to develop to term. Particularly important was the finding that special culture protocols for somatic cells prior to nuclear transfer were not necessary in our system.