Nutrient uptake and utilization can be used to select viable day 7 bovine blastocysts after cryopreservation

The ability of individual bovine blastocysts to survive freezing and thawing procedures was assessed by measuring glucose and pyruvate uptake and lactate production immediately before and after cryopreservation. Using glucose and pyruvate uptake and lactate production it was not possible to determine, prior to freezing, which blastocysts would be viable after thawing. However, in the 5 hr immediately after thawing, those blastocysts which expanded their blastocoel had significantly greater glucose and pyruvate uptake and lactate production (P < 0.01) than those embryos which failed to develop after a 14 hr overnight incubation. Interestingly, after thawing, two distinct populations of blastocysts existed with respect to glucose uptake and lactate production, indicating that it is possible to identify those blastocysts immediately after thawing which will reexpand. In contrast, there was a considerable degree of overlap in pyruvate uptakes between the viable and nonviable groups of embryos, indicating that this parameter could not be used to select viable embryos after thawing. There was an increase in the calculated oxidation of carbohydrates after thawing, consistent with a partial uncoupling of the inner mitochondrial membrane. In conclusion, glucose uptake and lactate production can be used to select prospectively viable blastocysts immediately after thawing, indicating that glycolysis is a major energy-generating pathway for the embryo at this time. © 1996 Wiley-Liss, Inc.     

The role of glucose and pyruvate transport in regulating nutrient utilization by preimplantation mouse embryos

Preimplantation mouse embryos utilize pyruvate preferentially during the early cleavage stages before switching to glucose at around the time of compaction. This switch in substrate preference has been studied using a non-invasive ultramicrofluorometric analytical technique on single mouse embryos. On the basis of transport kinetic studies and inhibition by phloretin, cytochalasin B and sugar analogues, a component of glucose uptake by mouse blastocysts was found to be mediated by facilitated diffusion. The Jmax and Kt of this facilitated component were 3.53 pmol embryo-1 h-1 and 0.14 mM, respectively. At physiological concentrations of glucose, the facilitated component accounts for around 75% of glucose uptake. Glucose uptake by blastocysts was found to be insensitive to insulin, added at a range of concentrations. There was no evidence for glucose active transport. The carrier-mediated component of glucose entry was detectable from the 2-cell stage onwards. Pyruvate uptake was also mediated by a carrier throughout development. In the absence of glucose in the incubation medium, the characteristic decline in pyruvate uptake does not occur. The data are consistent with a role for embryonic cell transport in regulating glucose utilization prior to compaction, but do not exclude the involvement of metabolic factors, such as the allosteric regulation of the enzymes hexokinase and phosphofructokinase.     

Assessment of metabolism of equine morulae and blastocysts

Nutrient uptakes and metabolite production by equine morula and blastocyst stage embryos were determined by non-invasive microfluorometry. Equine morula took up equal amounts of both pyruvate and glucose. However, at the early blastocyst there was a small increase in glucose uptake and, by the expanded blastocyst stage, glucose was the predominant nutrient. Expanded blastocysts took up five times more glucose than pyruvate. Expanded blastocysts exhibited an exponential increase in glucose uptake and lactate production with respect to both diameter and surface area. As less than 50% of the glucose was accounted for by lactate production, the equine blastocyst appears to have a significant capacity to oxidize glucose. Embryos with a higher morphological grade consumed more nutrients than those with a poorer morphology. However, there was a large range in nutrient consumption within the highest grade blastocysts. This suggests that nutrient uptake may be useful as a viability marker of equine blastocysts.     

Cryopreservation of mouse embryos affects later embryonic development possibly through reduced expression of the glucose transporter GLUT1

In order to study the effects of cryopreservation on later embryonic development, two-cell mouse embryos were frozen, thawed, and then allowed to develop into blastocysts. The percentage of cryopreserved embryos which developed into blastocysts was significantly lower than that of fresh two-cell embryos. The amount of glucose incorporation in terms of ³H-2-deoxyglucose uptake in blastocysts developed in vivo, and in vitro from fresh or frozen-thawed two-cell embryos, was 473 ± 108, 105 ± 75, and 43.0 ± 28.3 fmol per embryo per hour, respectively. Quantification of glucose transporter GLUT1 in these embryos by Western blotting was reflective of the degree of glucose incorporation. The implantation rate of blastocysts developed in vitro from frozen-thawed two-cell embryos (22.0%) was significantly lower than that developed in vivo (41.1%). These data suggest that cryopreservation may have later consequences on embryonic development through a mechanism that involves altered GLUT1 expression. Mol. Reprod. Dev. 48:496–500, 1997.© 1997 Wiley-Liss, Inc.     

Substrate utilization in porcine embryos cultured in NCSU23 and G1.2/G2.2 sequential culture media

Embryo metabolism is an indicator of viability and, therefore, efficiency of the culture medium. Currently, little is known regarding porcine embryo metabolism. The objective of our study was to evaluate glucose and pyruvate uptake and lactate production in porcine embryos cultured in two different media systems. Oocytes were matured and fertilized according to standard protocols. Embryos were allocated randomly into two culture treatments, NCSU23 medium or G1.2/G2.2 sequential culture media 6-8 h post-insemination (hpi). Embryo substrate utilization was measured at the two-cell (24-30 hpi), 8-cell (80 hpi), morula (120 hpi), and blastocyst (144 hpi) stages using ultramicrofluorimetry. Glucose uptake was higher (P < 0.05) in two-cell embryos cultured in G1.2 than in NCSU23 medium (4.54 +/- 0.71, 2.16 +/- 0.87 pmol/embryo/h, respectively). Embryos cultured in G1.2/G2.2 produced significantly more lactate than those in NCSU23 at the eight-cell stage (9.41 +/- 0.71, 4.42 +/- 0.95 pmol/embryo/hr, respectively) as well as the morula stage (11.03 +/- 2.31, 6.29 +/- 0.77 pmol/embryo/hr, respectively). Pyruvate uptake was higher (P < 0.05) in morula cultured in G1.2/G2.2 versus NCSU23 (22.59 +/- 3.92, 11.29 +/- 1.57 pmol/embryo/h, respectively). Lactate production was greater (P < 0.05) in blastocysts cultured in G1.2/G2.2 (38.13 +/- 15.94 pmol/embryo/h) than blastocysts cultured in NCSU23 (8.46 +/- 2.38 pmol/embryo/h). Pyruvate uptake was also greater in blastocysts cultured in G1.2/G2.2 (24.3 +/- 11.04) than those in NCSU23 (11.30 +/- 2.70). When cultured in NCSU23 medium, two- and eight-cell embryos utilized less glucose than morulae and blastocysts, and two-cell embryos produced less lactate than blastocysts (P < 0.05). In G1.2/G2.2 media, two-cells took up less pyruvate than morulae or blastocysts, while blastocysts produced more lactate and utilized more glucose than two-cell, eight-cell and morula stage embryos (P < 0.05). As in other species, glycolysis appears to be the primary metabolic pathway in post-compaction stage porcine embryos. Culture medium composition affects not only substrate uptake, but also metabolic pathways by which these substrates are utilized in porcine embryos at several developmental stages.     

Developmental kinetics of in vitro produced bovine embryos: the effect of sex, glucose and exposure to time-lapse environment

In this study, a simple time-lapse video recording system was used to compare developmental kinetics of female and male bovine embryos produced in vitro. Following embryo sex determination, the timing of each cleavage up to the 4-cell stage was compared between the sexes from the videotapes after culture in the presence and absence of glucose. In the second experiment, the consequences of exposure to a time-lapse video recording (TL) environment were studied by culturing embryos further until day 7 in an incubator, followed by collection and sex determination of morulae and blastocysts. In the absence of glucose, female embryos cleaved earlier than male ones. In the presence of glucose, however, male embryos cleaved earlier than female ones. There was no difference in the number of morulae/blastocysts in the absence of glucose, but in the presence of glucose more male than female embryos reached the morula and blastocyst stage. Exposure to the TL environment itself also had a sex-related effect, being more detrimental to male than female embryos. The difference in the number of functional X chromosomes between the sexes during early preimplantation development could explain these findings. In females, an increased capacity for oxygen radical detoxification through the pentose phosphate pathway could result in a reduced cleavage rate. Furthermore, glucose may influence the expression of enzymes located on the X chromosome. According to these results, a simple time-lapse video recording system is suitable for investigating embryo developmental kinetics and perhaps for the selection of embryos with the greatest developmental potential.     

Metabolism and cell allocation during parthenogenetic preimplantation mouse development

Diploid parthenogenetic postimplantation mouse embryos, containing two maternal genomes, are characterized by poor development of extraembryonic membranes derived from the trophectoderm and primitive endoderm of the blastocyst. This is thought to be caused by a deficiency of expression of paternally derived imprinted genes. Here we have compared the inner cell mass, from which the primitive endoderm and fetal lineages are derived, and the trophectoderm, which forms a major component of the placenta, in parthenogenetic and fertilized preimplantation embryos. We have also studied the metabolism from the 1-cell to the blastocyst stage. Cell numbers were reduced in the ICM and TE of parthenogenetic blastocysts compared to fertilized blastocysts. This was thought to be due to the increased levels of cell death observed in these lineages. Pyruvate and glucose uptake by parthenogenetic embryos was similar to that by fertilized embryos throughout preimplantation development. However, at the expanded blastocyst stage glucose uptake by parthenogenetic embryos was significantly higher than by fertilized embryos. The implications of the actions of imprinted genes and of X-inactivation is discussed. © 1996 Wiley-Liss, Inc.     

Effect of conventional controlled-rate freezing and vitrification on morphology and metabolism of bovine blastocysts produced in vitro

This study compares the effects of conventional controlled-rate freezing and vitrification on the morphology and metabolism of in vitro-produced bovine blastocysts. Day 7 expanded blastocysts cultured in synthetic oviduct fluid with 5% fetal calf serum were frozen in 1.36 M glycerol, 0.25 M sucrose or vitrified in 25% glycerol, 25% ethylene glycol. Cell alterations and in vitro development were evaluated immediately after thawing or after 72 h. The effect of cryopreservation on inner cell mass and trophectoderm (TE) cell number as well as glucose, pyruvate, and oxygen uptakes, and lactate release by blastocysts were evaluated. Immediately after thawing, blastocysts showed equivalent cell membrane permeabilization after both cryopreservation procedures, while alterations in nuclear staining were more frequent in vitrified embryos. After culture, similar survival and hatching rates were observed. Both procedures decreased cell number immediately after thawing and after 72 h. However, the number of TE cells was lower in frozen embryos than in vitrified ones. In relation to this, frozen blastocysts showed a decrease in glucose, pyruvate, and oxygen uptake, although those parameters were not altered in vitrified embryos. An increased glycolytic activity was also observed in frozen embryos, indicating a stress response to this procedure.     

Glutamine uptake and utilization by preimplantation mouse embryos in CZB medium

At least 71% of CF1 x B6SJLF1/J embryos developed from the 1-cell stage to the blastocyst stage in an optimum glutamine concentration of 1 mM, as long as glucose was present after the first 48 h of culture. Blastocysts raised under these conditions had significantly more cells than did blastocysts raised in CZB medium alone (glutamine present, glucose absent). Embryos raised in vivo accumulated 170-200 fmol glutamine/embryo/h at the unfertilized egg and 1-cell stages with a decline to 145 fmol/embryo/h at the 2-cell stage, followed by sharp increases to 400 and 850 fmol/embryo/h at the 8-cell and blastocyst stages. The presence or absence of glucose in the labelling medium had no effect on glutamine uptake by these embryos. Embryos raised in vitro accumulated 2-3 times more glutamine at stages comparable to those of embryos raised in vivo. In all cases in which 1-cell to blastocyst development in vitro was successful, glucose was present in the culture medium and the incremental uptake of glutamine between the 8-cell stage and the blastocyst stage was approximately 2-fold. This was also the increment for in-vivo raised embryos. When glucose was not present after the first 48 h, the 8-cell to blastocyst glutamine increment was not significant, and development into blastocysts was reduced. The results also show that glutamine can be used as an energy source for the generation of CO2 through the TCA cycle by all stages of preimplantation mouse development, whether raised in vivo or in vitro from the 1-cell stage. Two-cell embryos raised in vivo converted as much as 70% of the glutamine uptake into CO2, consistent with an important role for glutamine in the very earliest stages of preimplantation development. Cultured blastocysts appeared to convert less glutamine and the presence of glucose in the culture medium seemed to inhibit this conversion.     

Mouse embryos used as a bioassay to determine control of marsupial embryonic diapause

Mouse blastocysts appear to be under direct inhibition from the uterine environment, whereas no evidence of direct inhibition during diapause in the tammar wallaby has been observed. Normally developing (day 4) and quiescent mouse blastocysts were incubated for up to 12 hr in media supplemented with BSA, wallaby plasma, wallaby day 0 (day of removal of pouch young; RPY), day 5, or day 10 endometrial exudates at a concentration of 2 mg/ml of protein, and analyzed for rates of carbohydrate metabolism using fluorescence and radioisotopes. Rates of glucose uptake and lactate production by day 4 blastocysts increase after incubation with day 10 and day 5 wallaby exudates compared with rates by blastocysts incubated in BSA. Pyruvate uptake increased after 8 hr irrespective of incubation media, except for embryos incubated in day 0 exudate, which maintained levels significantly lower than BSA-incubated embryos. Quiescent mouse embryos displayed a high ATP/ADP ratio during diapause (1.06 +/- 0.24) which decreased after 4 hr incubation in all media (0.42 +/- 0.05; P < 0.01) but embryos incubated in day 0 exudate media remained at a significantly higher level than embryos incubated in BSA. These results indicate that quiescent tammar endometrial exudate is not capable of initiating diapause in mouse embryos at the concentration used, but is able to slow the rate of reactivation of quiescent blastocysts. Importantly, reactivated wallaby exudate increases mouse blastocyst glucose metabolism and lactate production. It is possible that the quiescent tammar endometrial environment has an inhibitory factor necessary to maintain diapause in the tammar blastocyst.     

Characterization and regulation of monocarboxylate cotransporters Slc16a7 and Slc16a3 in preimplantation mouse embryos

Concurrent with compaction, preimplantation mouse embryos switch from the high pyruvate consumption that prevailed during cleavage stages to glucose consumption against a constant background of pyruvate uptake. However, zygotes exposed to and subsequently deprived of glucose can form blastocysts by increasing pyruvate uptake. This metabolic switch requires cleavage-stage exposure to glucose and is one aspect of metabolic differentiation that normally occurs in vivo. Monocarboxylates, such as pyruvate and lactate, are transported across membranes via the SLC16 family of H(+)-monocarboxylate cotransporter (MCT) proteins. Thus, the increase in pyruvate uptake in embryos developing without glucose must involve changes in activity and localization of MCT. In mouse embryos, continued expression of Slc16a1 (MCT1) requires glucose supply. Messenger RNA for Slc17a7 (MCT2) and Slc16a3 (MCT4) has been detected in mouse preimplantation embryos; however, protein function, localization, and regulation of expression at the basis of these net pyruvate uptake changes remain unclear. The expression and localization of SLC16A7 and SLC16A3 have therefore been examined to clarify their respective roles in embryos derived from the reproductive tract and cultured under varied conditions. SLC16A3 appears localized to the plasma membrane until the morula stage and also maintains a nuclear distribution throughout preimplantation development. However, continued Slc16a3 mRNA expression is dependent on prior exposure to glucose. SLC16A7 localizes to apical cortical regions with punctate, vesicular expression throughout blastomeres, partially colocalizing in peroxisomes with peroxisomal catalase (CAT). In contrast to SLC16A3 and SLC16A1, SLC16A7 and CAT demonstrate upregulation in the absence of glucose. These striking differences between the two isoforms in expression localization and regulation suggest unique roles for each in monocarboxylate transport and pH regulation during preimplantation development, and implicate peroxisomal SLC16A7 as an important redox regulator in the absence of glucose.     

Glucose and glutamine metabolism in pre-attachment cattle embryos in relation to sex and stage of development

Individual Day-7 embryos (morulae to expanded blastocysts) were incubated with radiolabelled substrates and karyotyped to determine the sex. In Exp. 1, embryos were incubated for 3 h with D-[1-14C]glucose, as a measure of the activity of the pentose-phosphate pathway (PPP) and D-[5-3H]glucose, as a measure of total glucose metabolism. The labelled products 14CO2 and 3H2O were collected throughout the measurement period. Total glucose metabolism in male embryos was twice that in female embryos and increased between the morula and expanded-blastocyst stages. Relative to total glucose metabolism, PPP activity was four times greater in female than in male embryos. In Exp. 2, embryos were cultured with D-[1-14C]glucose, and L-[3,4-3H(N)]glutamine (a measure of Krebs cycle activity) in the presence of brilliant cresyl blue, a stimulator of the PPP. Glutamine metabolism increased from the morula to expanded-blastocyst stages. Relative to the metabolism of glutamine, the activity of the PPP was one-third greater in female than in male embryos.     

An unusual subcellular localization of GLUT1 and link with metabolism in oocytes and preimplantation mouse embryos

Although mouse oocytes and cleavage-stage embryos prefer pyruvate and lactate for metabolic fuels, they do take up and metabolize glucose. Indeed, presentation of glucose during the cleavage stages is required for subsequent blastocyst formation, which normally relies on uptake and metabolism of large amounts of glucose. Expression of the facilitative glucose transporter GLUT1 was examined using immunohistochemistry and Western blotting, and in polyspermic oocytes, metabolism of glucose was measured and compared with that of pyruvate and glutamine. GLUT1 was observed in all oocytes and embryos, and membrane and vesicular staining was present. Additionally, however, in polyspermic oocytes, the most intense staining was in the pronuclei, and this nuclear staining persisted in cleaving normal embryos. Furthermore, GLUT1 expression appeared to be up-regulated both in nuclei and plasma membranes following culture of oocytes in the absence of glucose. In polyspermic oocytes, the metabolism of glucose, but not of pyruvate or glutamine, was directly proportional to the number of pronuclei formed. After compaction, nuclear staining diminished, and GLUT1 localized to basolateral membranes of the outer cells and trophectoderm. In blastocysts, a weak but uniform staining of inner-cell-mass plasma membranes was apparent. The results are discussed in terms of potential roles for GLUT1 in pronuclei of oocytes and zygotes, nuclei of cleavage-stage embryos, and a transepithelial transport function for GLUT1, probably coupled with GLUT3, in compacted embryos and blastocysts.     

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.     

Hyperglycemia-induced apoptosis affects sex ratio of bovine and murine preimplantation embryos

The effect of glucose in the medium used during in vitro culture on both cell death by apoptosis and the sex ratio of bovine blastocysts derived from in vitro-matured and in vitro-fertilized oocytes was evaluated. Oocytes were matured, inseminated, and cultured in vitro in mSOF medium with 10% FCS with or without glucose supplementation. Exposure to high concentrations of glucose (10, 20, and 30 mM) during bovine embryo development in vitro from zygote to blastocyst resulted in a decrease in the number of cells per embryo and an increase in the frequency of apoptotic cells. A significantly higher proportion of females was found among those embryos that developed under hyperglycemic conditions in vitro. Moreover, both murine and bovine blastocysts incubated for 6 hr in 20 mM glucose had a significantly higher number of apoptotic cells in comparison to control. In this study, we also determined whether blastocyst production of the X-linked inhibitor of apoptosis protein (XIAP) differs between the sexes. Our results show that female bovine blastocysts produce significantly higher amounts of XIAP mRNA than males and this could be crucial in explaining the higher proportion of female blastocysts observed following in vitro culture under hyperglycemic conditions which induce apoptosis. Moreover, a higher proportion of female murine blastocysts cultured under hyperglycemic conditions were implanted in the uterus (65.3 of implantations from embryos cultured with 20 mM of glucose are females vs. 49% in control). This mechanism provides an explanation for the significant reduction of male children born to diabetic mothers.     

Glycine and Na+ transport in preimplantation mouse embryos

The dependence of glycine uptake on glycine and Na+ concentrations was determined and compared in 2-cell embryos and blastocysts. In both, uptake was by a combination of a Na+-independent non-saturable route and a Na+-dependent saturable system with Km values of 62 microM and 274 microM for 2-cell embryos and blastocysts respectively. Na+-dependent saturable uptake by embryos of both stages had a Hill coefficient of 2 for Na+, indicating co-transport of 2 Na+ with each glycine molecule. These results suggest that glycine enters 2-cell embryos by the gly-system, and blastocysts by a similarly Na+-dependent system with characteristics resembling the A-system.     

Energy metabolism in late preimplantation rat embryos

The consumption of pyruvate and glucose, and the production of lactate, by single preimplantation embryos, was measured using a noninvasive technique. Embryos were cultured in 300-500-nl microdrops, for 8-12 h at a time, from Day 4 to Day 6 after mating, when they developed from the 8-cell stage to expanded blastocyst. Pyruvate was the predominant substrate at the 8-cell/morula stage; glucose uptake exceeded that of pyruvate after the onset of blastocoel formation. Lactate production increased in parallel with glucose consumption. For most stages, approximately 100% of the glucose uptake was accountable for by lactate production and in some cases an additional source of lactate must be postulated. Culture in vitro had little effect on lactate production, although a lower level of metabolism was observed compared with fresh blastocysts. Rat embryos were capable of developing to blastocysts in the absence of glucose, when lactate production was greatly reduced.     

Effects of paternal heat stress on the in vivo development of preimplantation embryos in the mouse

The objective of this study was to examine the effect of paternal heat stress on the in vivo development of preimplantation embryos in the mouse. Synchronised B6CBF1 female mice were mated either to a control male mouse or to one that had been exposed at 7, 21 or 35 days previously, for 24 h to an ambient temperature of 36+/-0.3 degrees C and 66+/-5.6% relative humidity. Embryos were collected from the oviducts of mice at 14-16 h, 34-39 h or 61-65 h after mating or from the uterus at 85-90 h after mating and their developmental status was evaluated morphologically. The number of cells within blastocysts was also determined using bisbenzimide-propidium iodide staining. Paternal heat stress 7 days before mating reduced the proportion of embryos developing from 4-cell (4-C) to morulae (M), hatched blastocysts, total blastocysts and the number of inner cell mass (ICM) and trophectoderm (TE) cells in the blastocyst. Paternal heat stress 21 days prior to mating reduced the proportion of 2-C and 4-C to M embryos with no embryos developing to blastocysts. There were also increases in the number of 1-C and abnormal embryos recorded at this time. Paternal heat stress 35 days before mating decreased the proportion of 2-C embryos, expanded blastocysts and ICM and TE cells in the blastocyst. These results support previous work demonstrating that both the sperm in the epididymis and germ cells in the testis are susceptible to damage by environmental heat stress, with spermatocytes being the most vulnerable. This study also demonstrates that subtle effects on the male such as a short exposure to elevated environmental temperatures can translate to quite profound paternal impacts on early embryo development.