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.     

Preliminary characterization of pyruvate uptake by one-cell ovine embryos

Pyruvate uptake was measured by a noninvasive method on a total of 59 individual one-cell ovine embryos. Uptake was measured over a 4-h period in Whitten's medium containing 1.0 mM glucose and either 0.0 mM, 0.33 mM, 0.67 mM or 1.0 mM sodium pyruvate. Glucose uptake was also assessed to determine the effect of altering pyruvate concentration on glucose uptake. Embryos incubated in medium containing 1.0 mM or 0.67 mM pyruvate showed average uptake values of 20.36 and 5.00 pmoles per embryo per 4 h, respectively. In contrast, when pyruvate concentrations were 0.0 mM and 0.33 mM, the embryos released an average of 24.60 and 10.40 pmoles pyruvate per embryo per 4 h. Uptake or release of pyruvate was found to vary linearly with concentration level. Increasing pyruvate concentration resulted in a significant decrease in glucose uptake.     

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.     

In vitro analysis of glucose metabolism and embryonic growth in postimplantation rat embryos

The glucose metabolism and embryonic development of rat embryos during organogenesis was studied using embryo culture. Glucose uptake and embryonic growth and differentiation of 10.5-day explants (embryos + membranes) were limited by the decreasing glucose concentration, but not the increasing concentration of metabolites, in the culture media during the second 24 h of a 48 h culture. No such limitations were found on the embryonic development of 9.5-day explants during a 48 h culture although glucose uptake was slightly reduced at very low concentrations of glucose. From the head-fold stage to the 25-somite stage of development, glucose uptake was characteristic of the stage of development of the embryo and not the time it had been in culture. Embryonic growth of 9.5-day explants was similar to that previously observed in vivo. Glucose uptake by 9.5-day explants was dependent on the surface area of the yolk sac and was independent of the glucose concentration in the culture media (within the range of 9.4 to 2.5 mM). The proportion of glucose converted to lactate was 100% during the first 42h of culture then fell to about 50% during the final 6h. The protein contents of both the extraembryonic membranes and the embryo were dependent on the glucose uptake.     

Glucose, glutamine and inorganic phosphate in early development of the pig embryo in vitro

Pig embryos at the 1- or 2-cell stage (before the 'block' to development in vitro) were cultured in 8 different media derived from Krebs'-Ringer-bicarbonate medium. A 2 x 2 x 2 factorial arrangement was used for the treatments, with glucose, glutamine and phosphate being the major effects tested. Embryos were obtained from sows approximately 44-48 h after the observation of oestrus, with the majority being at the 1-cell stage. Embryos from each female were randomly assigned to each treatment. After in-vitro culture, all embryos were scored for the stage of development attained and stained to determine final cell number. Significant effects were evident due to female, glucose, glutamine, a phosphate x glucose interaction and a glutamine x glucose interaction. None of the media components tested was inhibitory to embryo development. The greatest development (45-60% morula or blastocyst) was achieved with glucose and glutamine (both alone and in combination) in the media, demonstrating that an amino acid can serve as the sole energy source for complete preimplantation embryonic development in vitro.     

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.     

The roles of pyruvate, lactate and glucose during preimplantation development of embryos from F1 hybrid mice in vitro.

Embryos of certain inbred mouse strains, and their F1 hybrids, are able to develop from the 1-cell to blastocyst stage in simple chemically defined media containing lactate (L), pyruvate (P) and glucose (G). The individual roles of these substrates in supporting complete preimplantation development in vitro was examined with 1-cell F2 embryos from B6CBF1 hybrid mice. Embryos collected between 26 and 27 h post hCG were cultured in medium containing L, P, LP or LPG. After 50 h in culture, the proportions developing to the morula stage were 1%, 83%, 94% and 100%, respectively. In combination, lactate and pyruvate appeared to act synergistically and both the rate and level of development to the morula stage were unaffected by the absence of glucose. After a further 46 h in culture, only the embryos grown in the presence of glucose developed into blastocysts. In LP medium, embryos arrested at the compacted morula stage late on day 3 of development. As culture continued in the absence of glucose, embryos decompacted (approximately 82 h post hCG) and subsequently degenerated. Exposure to medium containing glucose for the first, second or third 24 h period in culture was sufficient to support the morula-to-blastocyst transition. Glucose still supported this transition when embryos were transferred to LPG medium 3 h after the completion of compaction (76 h post hCG), but was ineffective 6 h later (82 h post hCG) once decompaction had commenced. We conclude that lactate and pyruvate together are able to support normal development of 1-cell F2 embryos to the morula stage in vitro, but that glucose is an essential component of the culture medium for development to the blastocyst stage.     

Successful development of viable blastocysts from enhanced green fluorescent protein transgene-microinjected mouse embryos: comparison of culture media

To improve efficiency of transgenesis, we compared M16 and CZB embryo culture media, supporting development to blastocysts of FVB/N mouse pronuclear-eggs, microinjected with enhanced green fluorescent protein (EGFP) transgene. When EGFP-injected-eggs were cultured (120 hr), blastocyst development was significantly (P < 0.03) higher in M16 medium (72.5 +/- 2.4%) than that in CZB (13.2 +/- 4.3%) or CZBG (CZB with 5.6 mM glucose at 48 hr culture) (62.1 +/- 3.7%) media. Blastocyst development of noninjected embryos was higher in M16 (92.0 +/- 2.6%) and CZBG (83.9 +/- 3.9%) media than in CZB (31.9 +/- 2.8%) medium (P < 0.0001). However, percentages of morulae at 72 hr were comparable in all treatments. Developed blastocysts were better in M16 than in CZB or CZBG media. Consistent with this, mean cell number per blastocyst, developed from injected embryos, was significantly (P < 0.002) higher in M16 medium (79.6), than those in CZB (31.3) or CZBG media (60.7); similar with noninjected embryos. Cell allocation to trophectoderm (TE) and inner cell mass (ICM), i.e., TE:ICM ratio, for injected blastocysts in M16 (3.0) was less than (P < 0.05) those in CZB (4.2) and CZBG (4.4) media; similar with noninjected blastocysts. Moreover, blastocysts, developed in M16 and CZBG media, hatched, attached, and exhibited trophoblast outgrowth; 18% of them showed EGFP-expression. Importantly, blastocysts from M16 medium produced live transgenic "green" pups (11%) following embryo transfer. Taken together, our results indicate that supplementation of glucose, at 48 hr of culture (CZBG), is required for morula to blastocyst transition; M16 medium, containing glucose from the beginning of culture, is superior to CZB or CZBG for supporting development of biologically viable blastocysts from EGFP-transgene-injected mouse embryos.     

Two-cell block to development of cultured hamster embryos is caused by phosphate and glucose

The failure of hamster 2-cell embryos to develop in vitro (2-cell block) was examined with experiments in which concentrations of glucose and phosphate in the culture medium were varied. Embryos were cultured in a protein-free modified Tyrode's solution that normally contains 5.0 mM glucose and 0.35 mM sodium dihydrogen phosphate. In the presence of 0.35 mM phosphate but without glucose, 23% of 2-cell embryos reached the 4-cell stage or further after culture for 1 day and 27% after 2 days. Glucose inhibited embryo development even at 0.1 mM (4% development to greater than or equal to 4-cells after culture for 2 days); there was no dose-related inhibition above this glucose concentration. In a second experiment, phosphate levels were varied in the absence of glucose. Phosphate was highly inhibitory to development, with 97% of 2-cell embryos reaching the 4-cell stage or further after culture for 1 day in the absence of phosphate compared to 9-21% in the presence of 0.1-1.05 mM phosphate. After culture for 2 days, 26% of embryos reached the 8-cell stage or further when phosphate was absent compared to 0% development to 8-cells with 0.1 mM phosphate or higher. In a factorial experiment, phosphate blocked development when glucose was present or absent, whereas glucose did not block embryo development in the absence of phosphate. However, 2-deoxyglucose (a non-metabolizable analogue of glucose) inhibited embryo development in the absence of phosphate. These data show that the in vitro block to development of hamster 2-cell embryos is caused at least in part by glucose and/or phosphate. Deletion of these compounds from the culture medium eliminates the 2-cell block to development in virtually all embryos, and approximately 25-75% of embryos develop to the 8-cell or morula stages in vitro. The observations provide a possible explanation for the 2-cell and 4-cell blocks that occur in conventional culture media: stimulation of glycolysis by glucose and/or phosphate may result in inefficient adenosine triphosphate (ATP) production. The data indicate marked dissimilarities in the regulation of in vitro development of early cleavage stage hamster embryos compared with embryos of inbred mice, since the latter have an inactive glycolytic pathway prior to the 8-cell stage of development and will grow from 1-cell to blastocyst with both phosphate and glucose in the culture medium.     

In vitro development and nutrient uptake by embryos derived from oocytes of pre‐pubertal and adult cows

The present study compared the developmental potential and uptake of nutrients by embryos from pre‐pubertal and adult cows. Oocytes retrieved from ovaries of 5 to 7 month old calves and adult cows were matured and fertilized in vitro. Embryos were cultured in SOFaa to the blastocyst stage (7 days post‐insemination). At successive stages of development, rates of glucose and pyruvate uptake were measured non‐invasively by microfluorescence for individual embryos. Fertilization was equivalent in embryos from pre‐pubertal and adult cows (P > 0.05), however development to blastocyst was significantly lower in embryos from pre‐pubertal cows (9.8% versus 33.7%, respectively; P < 0.05). Total blastocyst cell number was not different between pre‐pubertal and adult material (P > 0.05). Glucose uptake was exponential (pre‐pubertal, r = 0.82; adult, r = 0.82; P < 0.05), with an increase in uptake beyond the 8‐ to 16‐cell stage. Glucose uptake was significantly lower in embryos from pre‐pubertal cows at the 2‐ to 4‐cell stages (1.5 versus 3.0 pmoles/embryo/hr; P < 0.05), but was equivalent to the adult cow at all other stages of development (P > 0.05). Pyruvate uptake was low until the blastocyst stage. Pyruvate uptake by embryos from pre‐pubertal cows was significantly different to adult cows at the 1‐cell stage (2.7 versus 4.6 pmoles/embryo/hr, respectively; P < 0.05) and 2‐ to 4‐cell stages (4.9 versus 3.6 pmoles/embryo/hr, respectively; P < 0.05). Pyruvate uptake was equivalent in the two groups in the later stages of development (P > 0.05). Perturbations in the uptake of nutrients by embryos from pre‐pubertal cows were most likely due to the presence of a high proportion of developmentally incompetent embryos. Further, embryos from pre‐pubertal cows that did develop to the blastocyst were as viable as blastocysts from adult cows with respect to nutrient uptakes and total cell number. Mol. Reprod. Dev. 54:49–56, 1999. © 1999 Wiley‐Liss, Inc.     

Glycolysis and glucose uptake in intact outer segments isolated from bovine retinal rods

Glucose transport across the plasma membrane of isolated bovine rod outer segments (ROS) was measured by uptake of 14C-labeled 3-O-methylglucose and 2-deoxyglucose and was inferred from deenergization of ROS with 2-deoxyglucose. Glucose transport was mediated by a facilitated diffusion glucose transporter that equilibrated external and internal free hexose concentrations. Glucose transport in ROS displayed two components as judged from kinetic analysis of hexose equilibration and as judged from inhibition by cytochalasin B and phloretin. Transport under exchange conditions was considerably faster as compared with net hexose uptake, similar to that observed for the erythrocyte glucose transporter. Sensitivity to cytochalasin B and affinity to 3-O-methylglucose were similar to those observed for the hepatocyte glucose transporter. The cytochalasin-insensitive component appears unique to ROS and did not reflect leakage transport as judged from a comparison with L-glucose uptake. Glucose transport feeds glycolysis localized to ROS. We suggest that a major role for glycolysis in ROS is phosphorylation of GDP to GTP via pyruvate kinase and PEP, while phosphorylation of ADP to ATP can use the creatine kinase/phosphocreatine pathway as well.     

Implication of glucose 6 phosphate isomerase (EC 5.3.1.9) activity in blocking segmentation of the mouse ovum at the 2 cell stage in vitro

The mouse embryo, when grown in media containing glucose, synthesizes and accumulates glycogen. In certain strains, glucose could be responsible for the 2 cell block; it can be replaced for a short time by glutamine, but with an increase in embryo degeneration. We have tested the hypothesis according to which the problems of glycogen accumulation and the developmental arrest could be due to a metabolic lock involving glucose 6 phosphate isomerase (EC 5.3.1.9). Fructose is located immediately downstream from this metabolic lock. We have exactly replaced the glucose in Whittingham M16 culture medium by fructose: Medium F.M. With this culture medium, Swiss one cell embryos, which normally block in M16 medium (greater than 90%), do not block any longer at the 2 cell stage (11.6%). They can be cultured for 4 days with high rates of blastocyst formation (53.6%). Embryo degeneration (23.6%) is lower than that observed in CZB (31%), and not different from our control degeneration in vivo. Moreover fructose seems to be adequate all through the culture period as there is no need for further addition of metabolites, to obtain blastocysts, as observed for CZB. This demonstrates that a lock at the Glucose phosphate isomerase level is responsible for glycogen accumulation and the 2 cell block in the mouse embryo in vitro.     

Energy metabolism in preimplantation bovine embryos derived in vitro or in vivo

This study was an investigation of metabolism during bovine preimplantation development from the oocyte up to the hatched blastocyst derived in vitro or in vivo. Metabolism was determined by estimating the consumption of radiolabeled glucose, pyruvate, or lactate during a 4-h incubation period in a closed noninvasive system with NaOH as trap for the continuous collection of CO(2). The postincubation medium was analyzed for the presence of lactate. Embryonic metabolism from the matured oocyte to the 12-cell stage was more or less constant, with pyruvate being the preferred substrate. The first marked increase in oxidation of glucose occurred between the 12- and 16-cell stage. Compaction of morula and blastocyst expansion was accompanied by significant increases in oxidation of all three energy substrates. The incorporation of glucose increased steadily 15-fold from the 1-cell to the blastocyst stage. In general, the pattern of metabolism was similar between the embryos derived in vitro and in vivo but with some distinct differences. The most apparent feature of glucose metabolism by in vitro-produced embryos was a 2-fold higher rate of aerobic glycolysis as compared to that in their in vivo counterparts. In vitro-matured oocytes produced measurable amounts of lactate, whereas in vivo-matured oocytes exhibited a significantly lower metabolic activity and did not produce any lactate. When in vivo-collected embryos were preexposed to culture conditions, lactate production increased significantly and at the hatched blastocyst stage matched that of their in vitro counterparts. In vitro-produced embryos up to the 8-cell stage oxidized significantly higher amounts of lactate and had a lower ratio of pyruvate-to-lactate oxidation than the in vivo-obtained embryos. The results of this study show that under our culture conditions, important differences exist at the biochemical level between bovine embryos produced in vitro and those generated in vivo that may well affect the developmental capacity.     

Concentrations of nutrients in mouse oviduct fluid and their effects on embryo development and metabolism in vitro

An ultramicrofluorometric technique was used to analyse the nutrient composition of mouse oviduct fluid. The concentrations of pyruvate, glucose and lactate in the vicinity of the cumulus mass were 0.37, 3.40 and 4.79 mM respectively. In the absence of cumulus cells, the concentration of pyruvate was significantly reduced, to 0.14 mM, while the concentration of glucose was significantly increased to 5.19 mM. Glutamine, which may help to overcome the '2-cell block' in mouse embryos in culture, was present at a concentration of 0.20 mM. A modified medium (MTF) in which the concentration of nutrients was similar to that in mouse oviduct fluid was prepared and its effects on embryo development and metabolism in vitro were compared with that of a conventional embryo culture medium (M16). The percentage of zygotes forming blastocysts in vitro by Day 5 was similar in both media (82% in M16, 79% in MTF). Rates of development, as assessed by cell number, were also comparable. However, the proportion of glucose consumed which was converted to lactate increased dramatically following culture; from 44% in fresh blastocysts, to 73% and 91% in blastocysts derived from 8-cell embryos cultured for 24 h in media MTF and M16 respectively.     

Embryo metabolism during the expansion of the bovine blastocyst

Embryo metabolism was evaluated during re‐expansion of in vitro produced bovine blastocysts collapsed with cytochalasin D (CCD) and incubated in the presence and absence of ouabain, a specific inhibitor of the Na⁺, K⁺ pump. Day 8 expanded blastocysts were treated for 2 to 4 hr with 20 μg/ml CCD. Four conditions were tested: untreated embryos and embryos collapsed with CCD and allowed to re‐expand for 4 hr in the presence of 0 M, 1 nM, or 1 μM ouabain. Incubation of collapsed embryos for 4 hr in the presence of 1 nM or 1 μM ouabain significantly inhibited blastocyst re‐expansion. Glucose, pyruvate, and amino lactate uptake/release were not significantly affected by ouabain treatment and did not correlate with the degree of blastocyst re‐expansion. Few variations in the uptake/release of amino acids by the embryos were observed. Ouabain treatment significantly decreased oxygen uptake which directly correlated with the degree of blastocyst re‐expansion. For embryos allowed to re‐expand in the presence or absence of ouabain, a direct correlation was observed between the uptake of oxygen and of glucose. One mM cyanide or 2,4 dinitrophenol inhibited blastocyst re‐expansion although 0.01 and 0.1 mM were ineffective. This study indicates a role for oxidative metabolism in providing the energy necessary for blastocoel expansion in the bovine. Nevertheless, blastocyst expansion is relatively insensitive to inhibition of oxidative phosphorylation indicating the ability of the bovine blastocyst to adapt to hypoxic conditions. Mol. Reprod. Dev. 53:171–178, 1999. © 1999 Wiley‐Liss, Inc.     

Effects of metabolic inhibitors on mouse preimplantation embryo development and the energy metabolism of isolated inner cell masses

The effects of two metabolic inhibitors, methyl palmoxirate (MP) and amino-oxyacetate (AOA), on mouse preimplantation embryo development and cell number, and inner cell mass (ICM) cell metabolism have been examined. Two-cell embryos were cultured in media supplemented with either MP, which inhibits fatty acid oxidation, or AOA, which inhibits the transamination of glutamate into α-ketoglutarate. Embryos were scored for development daily. On day 5, expanded blastocysts were differentially labeled with fluorochromes to visualize TE and ICM cell nuclei, or the ICMs isolated by immunosurgery and their energy metabolism determined using microfluorometric methods. Embryos exposed to the two inhibitors developed into fully expanded blastocysts, although cell numbers of both the TE and ICM cells were significantly reduced compared to controls. The uptake of glucose in the presence of 1 mM MP or AOA did not differ from the controls, but less glucose was accountable for by lactate production. MP significantly reduced lactate production. In the presence of 4 mM AOA, the amount of glucose oxidized and the amount of lactate formed by ICMs were significantly reduced. The results indicate that the fuels used by isolated mouse ICMs vary in response to substrate availability and that fatty acids may be a potential energy source. © 1996 Wiley-Liss, Inc.     

CULTURE OF MATURE ECOTYLEDONOUS EMBRYOS OF PHASEOLUS VULGARIS AND THE NUTRITIONAL ROLE OF COTYLEDONS

Embryos of Phaseolus vulgaris L. were excised from seeds and cultured with cotyledons removed to determine the actions of various cultural conditions upon embryo development. Four media were tested, but ecotyledonized embryos did not grow as rapidly on any of them as did embryos with intact cotyledons on agar-water media. Comparisons of growth of ecotyledonized embryos with embryos bearing fractions of cotyledons indicated ecotyledonized embryos cultured on nutrient media grew about as well as embryos bearing cotyledons from which 97% of the volume had been removed surgically. The final weight of ecotyledonized embryos was greater when detached cotyledons were placed near them and was even greater when extracts of detached and incubated cotyledons were employed in the nutrient medium. Benzyladenine, kinetin, gibberellic acid, indole-acetic acid, presence of sucrose, and light or dark culture failed to enhance the ability of incubated cotyledons to stimulate growth of embryos.     

Assessment of embryo viability prior to transfer by the noninvasive measurement of glucose uptake

An ultramicrofluorometric technique was used to measure the uptake of glucose by single mouse blastocysts prior to transferring them into the uterus of pseudopregnant foster mothers. Of 50 blastocysts whose glucose uptake was measured prior to embryo transfer, 25 gave rise to male and 13 to female offspring. Twelve embryos failed to develop. The mean glucose uptake of these 12 embryos was significantly below that of those which developed successfully. Female embryos took up slightly more glucose than male embryos.     

A culture system for the development of the preimplantation rat embryo

We describe a system for the culture of 1-cell rat embryos through to the blastocyst stage, using co-culture on specific feeder cell layers and particular defined media. We show that the use of rat uterine epithelial cells as a feeder layer, together with either M16M, CZB or HECM-1 media at 38.5 degrees C can improve the in vitro development of cultured rat embryos. There was considerable variation in the culture conditions, which were optimal for each strain of rat tested. We show that the 4 to 8-cell embryos are viable after reimplantation and that the second 4 to 8-cell block in the rat can be overcome using HECM-1 in a co-culture system, thus enabling the in vitro culture of rat embryos up to the blastocyst stage.     

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.