Glucose and phosphate inhibit respiration and oxidative metabolism in cultured hamster eight-cell embryos: evidence for the "crabtree effect"

The development of hamster eight-cell embryos is inhibited by glucose in culture medium containing inorganic phosphate (Pi). This is hypothetically attributed to the "Crabtree effect," in which enhanced glycolysis inhibits respiratory activity and oxidative metabolism. To examine this hypothesis, oxygen consumption of hamster eight-cell embryos was measured using a microelectrode. A two- to three-fold decrease in oxygen consumption was observed in embryos cultured with glucose and Pi. Oxidizable substrates and intermediates of the Krebs cycle supported embryo development only in the absence of glucose and Pi; Krebs cycle inhibitors (fluoroacetate and arsenite) arrested embryo development. Under anaerobic conditions, pyruvate and lactate did not support embryo development. Inhibition of both respiration and oxidative activity in cultured hamster embryos by glucose and Pi is consistent with the existence of a Crabtree effect and indicates that the metabolic properties of preimplantation embryonic cells differ markedly from those of most somatic cells and resemble some cancer cells.     

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.     

Determination of pentose phosphate and Embden-Meyerhof pathway activities in bovine embryos

Quantitative determination was made of the activity of pentose phosphate pathway (PPP) and Embden-Meyerhof pathway (EMP) in individual bovine embryos from the six-cell to the hatched blastocyst stage. Embryos were collected from superovulated cross-bred heifers and classified into good and poor categories. A single embryo in 1 ul of medium was mixed with 2 ul of medium containing 3 to 30 nCi radiolabeled glucose previously placed on a detached lid of the 1.5-ml polypropylene microcentrifugé vial. The lid was then fitted to its vial which had been loaded in advance with 1.5 ml of 0.1 N NaOH. Vials were then incubated at 37 degrees C for 3 h. At the end of the incubation period, a 1.5-ml NaOH trap was inverted and placed into a 20-ml scintillation vial containing 10 ml of aqueous counting solution and counted in a liquid scintillation spectrophotometer. The PPP activity in good-quality embryos was greatest at the six-cell stage and decreased with increasing embryo development. The EMP activity showed the reverse trend. Poor- quality embryos had a lower glucose metabolism and higher PPP activity. Similar measurements were made on embryos following 24 h of culture, and total glucose metabolism and percentage of PPP activity were increased. In conclusion, these data suggest that in good quality bovine embryos total glucose utilization is low until 16-cell stage, with PPP being the predominant pathway. Total glucose utilization increases significantly at the morula stage; EMP activity increases with increasing embryo development; and PPP activity increases significantly in poor quality embryos and in embryos 24 h in culture.     

WHOLE-EMBRYO CULTURE AND THE STUDY OF MAMMALIAN EMBRYOS DURING ORGANOGENESIS

1. Simple and reliable methods are now available for growing rat and mouse embryos in culture at all stages of organogenesis. Primitive-streak embryos can be maintained for up to 5 days in culture while they develop to early foetal stages. Older embryos are maintained for progressively shorter periods and the most advanced stage that can be supported is equivalent to the rat foetus of 15 days' gestation. 2. The rates of protein synthesis and differentiation of the younger embryos in vitro are similar, and of head-fold embryos identical, to those in vivo. After the formation of the limb buds growth is slower, with protein synthesis more retarded than differentiation, resulting in embryos or foetuses that are well formed but smaller than in vivo. This slowing of growth of the older embryos in culture is probably caused by the lack of a functional allantoic placenta. 3. The embryos of some other species, including the guinea-pig, hamster, rabbit and opossum have also been maintained in culture during organogenesis but the results are not yet as good as those for rats and mice. 4. Maximum growth of rat embryos explanted with the visceral yolk sac intact is obtained in undiluted homologous serum, though adequate growth for many studies can be maintained in mixtures of serum with chemically defined tissue-culture media. The best results are obtained in serum prepared from blood centrifuged before clotting has occurred (I.C. serum) and heat-inactivated. The importance of a high concentration of serum in the culture medium may be related to the mechanisms for uptake, transport and digestion of macromolecules by the rodent yolk sac. 5. There is no convincing evidence for a changing rate of oxygen consumption during organogenesis but there is strong evidence for changes in energy metabolism. At the beginning of organogenesis, the embryo shows a high rate of anaerobic glycolysis and of pentose-shunt activity. During the following days these decline while activity of the Krebs' cycle and electron-transport system increases. Anoxia, or exposure of the embryo to carbon monoxide, increases glycolysis and reduces growth rate. 6. The earliest stages of the formation of the heart and blood circulation can be closely observed in culture. The heart rate of the 111/2-day rat embryo is about 160 beats per minute at 38°C, and falls by about 7% per degree for lower temperatures. Several drugs that are cardioactive in the adult also affect the frequency of the heartbeat in the embryo, and the pattern of response suggests that the adrenergic receptors in the embryo develop before the cholinergic receptors. Experiments in which embryo and yolk sac were cultured separately, as well as together, have indicated that haemopoiesis can occur in the embryo only after a migration of stem cells from the yolk sac. 7. Microsurgery has been successfully applied to embryos in culture in studies on morphogenetic movements, heart development, axial rotation, limb-bud regeneration and placenta formation. Biochemical studies of normal morphogenesis have been few, but one has shown a high rate of hyaluronate synthesis by the embryo which may be related to the maintenance and expansion of extracellular spaces and the formation of the neural folds. 8. Embryos are particularly sensitive to teratogenic agents during organogenesis. Teratogens that have been studied on whole embryos in culture include trypan blue, antisera, hyperthermia, anaesthetics, and abnormal concentrations of vitamins, oxygen and glucose. Many of the malformations induced have been similar to those obtained after administration of the same agents in vivo and have demonstrated a direct teratogenic effect on the embryo independent of the maternal metabolism. It is suggested that culture methods may provide a valuable additional screening procedure for new drugs and other potentially embryopathic agents.     

Effects of human diabetic serum on the in vitro development of early somite rat embryos

High levels of glucose, beta-hydroxybutyrate (B-HOB), and acetoacetate are known to have embryotoxic and teratogenic effects on rat embryos in culture, especially when added concomitantly to the culture medium. We studied the effects of human serum from different types of diabetes mellitus on the in vitro development of 10 1/2-day-old rat embryos cultured for 48 hours. We used serum from type I diabetes with and without ketoacidosis and type II diabetes either untreated or treated with insulin or with daonil. Type I diabetes without ketoacidosis increased the rate of malformations to 27% vs. 11% in controls. Serum from type I diabetes with ketoacidosis further increased the malformation rate to 44%. The rate of malformations induced by serum of type II diabetes was dependent on the treatment. It was relatively low among embryos cultured on serum from untreated (16%) or treated with daonil (19%) and rose to 27% among embryos cultured on serum from type II diabetes treated with insulin. No significant correlation was found between the rate of malformations and the concentrations of glucose, B-HOB, acetoacetate, and HbA1c in all diabetic sera except serum from type I diabetes with ketoacidosis. We may therefore conclude that for most types of diabetes in humans, neither the high blood glucose concentrations nor the high levels of ketone bodies seem to be the main reason for the high rate of malformations. However, we used cultured rat embryos, and the effects on the human embryo may be different. The results of studies on various experimental animal models in diabetes teratogenicity seem to have only partial relevance to the human situation.     

A diabetes-like environment increases malformation rate and diminishes prostaglandin E(2) in rat embryos: reversal by administration of vitamin E and folic acid

BACKGROUND: Offspring of women with diabetes are at increased risk for congenital malformations and disturbed growth compared with infants from nondiabetic pregnancies. The precise biological process behind these effects is not yet completely clarified. Previous studies have suggested that diabetic embryopathy is associated with increased level of oxidative stress and disturbed arachidonic acid metabolism. The aim of the present study was to investigate whether a diabetes-like environment both in vivo and in vitro increases embryonic levels of isoprostanes and alters embryonic prostaglandin E(2) (PGE(2)) concentration. Furthermore, we studied whether vitamin E and folic acid treatment rectify such alterations. METHODS: Embryos from diabetic and nondiabetic rats at gestational days (GDs) 10 and 11 were used. In the in vitro experiments, we used whole embryo culture, which mimics pregnancy. GD 9 embryos from nondiabetic rats were cultured for either 24 hr (corresponding to GD 10) or 48 hr (corresponding to GD 11) and exposed to 10 or 30 mM glucose concentration with or without folic acid. RESULTS: Embryos from diabetic rats and embryos cultured in a high glucose concentration showed increased malformation rates. Dietary treatment with vitamin E in vivo and supplementation of folic acid in the culture medium with 30 mM glucose in vitro decreased the malformation rate, decreased embryonic isoprostane levels, and increased PGE(2) concentration. CONCLUSIONS: Diabetes-induced oxidative stress and disturbance of PGE(2) production may contribute to the embryonic dysmorphogenesis in the offspring of diabetic rodents and, thereby, may also have a role in human diabetic embryopathy.     

Differential effect of hexoses on hamster embryo development in culture

The effects of glucose, fructose, and galactose on hamster embryo development in the absence of phosphate were studied in culture. One- and two-cell embryos were cultured to the blastocyst stage in HECM-9 medium without hexose or in medium with increasing concentrations of hexoses. Embryo development, cell number, and cell allocation were assessed in blastocysts. Blastocyst viability was determined by transfer to pseudopregnant recipients. Although 0.25 mM fructose increased mean cell number, low glucose concentrations had no stimulatory effect on development to blastocyst. Both galactose and 5.0 mM glucose were detrimental to embryos. Addition of 0.5 mM glucose increased implantation and fetal viability as compared with controls. Compared with 0.5 mM glucose, treatment with 0.25 mM fructose gave similar implantation and fetal viability, whereas 5.0 mM glucose tended to decrease implantation and significantly decreased fetal development. These data demonstrate that morphology is a poor indicator of embryo viability and that exposure of preimplantation embryos to glucose or fructose is important for embryo viability post-transfer. Although no difference in blastocyst viability was detected between embryos cultured with 0.25 mM fructose and those cultured with 0.5 mM glucose, increased cell numbers obtained with fructose suggest that fructose may be more appropriate than glucose for inclusion in culture medium.     

Developmental competence and metabolism of bovine embryos cultured in semi-defined and defined culture media.

Development of in vitro-produced bovine embryos was studied in 3 two-step culture media: synthetic oviduct fluid (SOF), Gardner's G1/G2, and control (hamster embryo culture medium with 11 amino acids [HECM-6] followed by tissue culture medium 199 + 10% bovine calf serum). Modifications were made to reduce or eliminate protein. Glycolysis and Krebs cycle activity of morulae and blastocysts developed from selected immature oocytes were measured. There were no differences in development to the morula and blastocyst stages between SOF, G1/G2, or control (41%, 36%, and 46%, respectively), although more blastocysts developed in control medium than in G1/G2 (46%, 30%, respectively). Reducing or removing BSA during the initial culture period did not significantly reduce development to blastocyst (31%, 33%, respectively), although development was reduced in SOF with BSA removed from the final culture period (19%). There were no differences in development to the blastocyst stage between SOF, SOF with BSA removed during the initial culture period, and control (44%, 32%, 49%, respectively), but development was reduced in chemically defined protein-free medium throughout the culture period (21%). Krebs cycle activity did not differ between treatments; however, glycolysis was highest in the control embryos and lowest in embryos cultured in protein-free medium. Embryos that developed in the presence of serum appeared dark and granular and had elevated glycolytic rates compared to embryos developed in completely defined medium. This study shows that both metabolism and blastocyst development of embryos are altered by different culture media, implying a functional linkage between these two indicators of successful embryogenesis.     

Expression pattern of glucose metabolism genes in relation to development rate of buffalo (Bubalus bubalis) oocytes and in vitro–produced embryos

The expression pattern of glucose metabolism genes (hexokinase, phosphofructokinase, glucose-6-phosphate dehydrogenase [G6PDH], lactate dehydrogenase [LDH], and pyruvate dehydrogenase [PDH]) were studied in buffalo in vitro–matured oocytes and in vitro–produced embryos cultured under different glucose concentrations (0 mM, 1.5 mM, 5.6 mM, and 10 mM) during in vitro maturation of oocytes and culture of IVF produced embryos. The expression of the genes varied significantly over the cleavage stages under different glucose concentrations. Developmental rate of embryos was highest under a constant glucose level (5.6 mM) throughout during maturation of oocytes and embryo culture. Expression pattern of glucose metabolism genes under optimum glucose level (5.6 mM) indicated that glycolysis is the major pathway of glucose metabolism during oocyte maturation and early embryonic stages (pre-maternal to zygotic transition [MZT]) and shifts to oxidative phosphorylation during post-MZT stages in buffalo embryos. Higher glucose level (10 mM) caused abrupt changes in gene expression and resulted in shifting toward anaerobic metabolism of glucose during post-MZT stages. This resulted in decreased development rate of embryos during post-MZT stages. High expression of LDH and PDH in the control groups (0 mM glucose) indicated that in absence of glucose, embryos try to use available pyruvate and lactate sources, but succumb to handle the post-MZT energy requirement, resulting to poor development rate. Expression pattern of G6PDH during oocyte maturation as well early embryonic development was found predictive of quality and development competence of oocytes/ embryos.     

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.     

Glucose inhibits development of hamster 8-cell embryos in vitro

Relative preferences of energy substrates (glucose, pyruvate, and lactate) for in vitro development of hamster 8-cell embryos were investigated. Using protein-free modified Tyrode's medium (TLP-PVA) containing 10 mM lactate (L), 0.1 mM pyruvate (P), and amino acids (Phe, Ile, Met and Gln), we found that development of hamster 8-cell embryos to blastocysts was supported better in the absence of glucose than in medium containing (standard) 5 mM glucose (88.1% and 50%, respectively). Addition of even 0.25 mM glucose to the medium significantly inhibited blastocyst formation (54.1%). Medium T-PVA, containing 5 mM glucose as sole energy substrate (without pyruvate, lactate, and amino acids), very poorly supported embryo development (less than or equal to 7.9% blastocysts), but addition of 0.1 mM pyruvate enhanced blastocyst formation (52%). Elimination of pyruvate in TL-PVA medium containing 5 mM glucose and amino acids markedly reduced blastocyst formation by 4-fold (13.5%); the optimal pyruvate concentration was 0.2 mM. However, if the same medium was devoid of glucose, blastocyst formation was high both in the absence (71.1%) and presence (83.3%) of 0.1 mM pyruvate. Similarly, in glucose-free T-PVA medium, addition of either 10 mM lactate or amino acids supported 8-cell embryo development to blastocysts (61.7% and 60.5%, respectively) as opposed to 18.8% and 30.6%, respectively, in the presence of 5 mM glucose. This augmented development in the absence of glucose is suggested to the due to the efficient conversion of lactate to pyruvate and of amino acids to amphibolic intermediates and hence their utilization via the Krebs cycle.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Methionine and iron as growth factors for rat embryos cultured in canine serum

Development of headfold-staged rat embryos cultured in canine serum containing various supplements was compared with development in rat serum to seek suitable alternatives to rat serum in rodent embryo culture and to identify nutritional factors for cultured rodent embryos that may have relevance for normal mammalian embryonic growth and development. Supplementation of canine serum with glucose, methionine, and a lipophilic iron chelate allowed growth and development of cultured rat embryos, approximating those obtained with rat serum. These findings suggest that properly supplemented canine serum can serve as a suitable rodent embryo culture medium and that glucose, iron, and methionine may be important nutrients in mammalian embryonic development.     

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.     

The development of preimplantation mouse parthenogenones in vitro in absence of glucose: Influence of the maternally inherited components

Mouse preimplantation embryo development is characterized by a switch from a dependence on the tricarboxylic acid cycle pre-compaction to a metabolism based on glycolysis post-compaction. In view of this, the role of glucose in embryo culture medium has come under increased analysis and has lead to improved development of outbred mouse embryos in glucose free medium. Another type of embryo that has proven difficult to culture is the parthenogenetic (PN) mouse embryo. With this in mind we have investigated the effect of glucose deprivation on PN embryo development in vitro. Haploid and diploid PN embryos were grown in medium M16 with or without glucose (M16-G) and development, glycolytic rate, and methionine incorporation rates assessed. Haploid PN and normal embryo development to the blastocyst stage did not differ in either M16 or M16-G. In contrast, although diploid PN embryos formed blastocysts in M16 (28.3%), they had difficulty in undergoing the morula/blastocyst transition in M16-G (7.6%). There was no significant difference in mean cell numbers of haploid PN, diploid PN and normal embryos cultured in M16 and M16-G at the morula and blastocyst stage. Transfer of diploid PN embryos from M16-G to M16 at the four- to eight-cell stage dramatically increased blastocyst development. At the morula stage diploid PN embryos grown in M16-G exhibited a higher glucose metabolism and protein synthesis compared to those grown in M16 and to haploid PN embryos. Difficulties of diploid PN embryos in undergoing the morula/blastocyst transition in absence of glucose infer the existence of a link between the maternally inherited components and the preimplantation embryos dependence on glucose. © 1996 Wiley-Liss, Inc.     

Development of rat embryos in culture media containing different concentrations of normal and diabetic rat serum.

In vitro culture of rodent embryos has been extensively used in the search for teratologic agents, with possible relevance to diabetic pregnancy. However, the high concentrations of rat serum added to the culture medium (approximately 75%) have raised concern that the teratogenic effects of some compounds may be attenuated or masked in this culture system and thereby forced the addition of pharmacological concentrations of the compounds (e.g., D-glucose and beta-hydroxybutyrate) to the medium. This issue has been examined in the present study where the effects of different concentrations of rat serum on growth and differentiation of rat embryos were recorded in cultures supplemented with increased concentrations of D-glucose and beta-hydroxybutyrate. The embryonic development was also evaluated after culture in medium supplied with serum from diabetic rats. Compared with normal rat serum, the diabetic serum had an elevated glucose concentration as well as markedly increased levels of triglycerides and branched amino acids, indicating a potentially rich supply of major nutrients for the cultured embryos. Lowering the serum concentration in the culture medium from 80% to 50% yielded progressively retarded embryonic growth but no increased rate of other morphological malformations. At 40% serum concentration, however, there was a sharp rise in the incidence of somatic malformations, in addition to the prevailing growth retardation. When the embryonic growth and development were compared at 50% and 80% serum concentrations, increased D-glucose or beta-hydroxybutyrate concentrations caused similar degrees of embryonic dysmorphogenesis. Also, the uptake of each compound by the embryos exposed to elevated levels of the two agents were similar in 50% and 80% serum cultures. There was, therefore, no protection against the teratogenic and growth-retarding effects of increased D-glucose or beta-hydroxybutyrate offered by high serum concentrations in the culture medium (i.e., 80% vs. 50%). Embryos cultured in 50% or 80% diabetic rat serum at 30 mmol/L or 50 mmol/L D-glucose concentration showed similar rates of somatic malformations as did embryos exposed to the same proportion of normal rat serum at similar glucose concentrations. By contrast, the diabetic rat serum amplified the general retarding effects of high D-glucose levels, yielding lower protein levels and somite numbers in embryos from diabetic serum culture than in embryos cultured in normal rat serum.(ABSTRACT TRUNCATED AT 400 WORDS)     

Effects of glucose and protein sources on bovine embryo development in vitro

Oviductal factors may be obtained by ultrafiltration of conditioned medium, added to a simple media and used in bovine embryo culture. In this study, we aimed to analyze the development of bovine embryos produced with oviductal factors compared to those cultured in the presence of BSA or serum, the effects of glucose in presence of these protein supplements, and the ability of oviductal factors to support embryo development during the entire culture period. In vitro produced bovine zygotes from slaughterhouse ovaries were cultured in modified-synthetic oviduct fluid (mSOF) alone or supplemented with (1) oviductal factors, (2) BSA and (3) FCS. Oviductal factors showed embryotrophic activity, although with blastocyst rates lower than those in BSA and FCS. Glucose (1.5 mM) added at Day 2 of culture did not affect development in the presence of oviductal factors. The number of cells in expanded blastocysts was unaffected by the presence of glucose or any of the protein supplements used. Both BSA and FCS, respectively, improved blastocyst rates of Day 6 embryos produced with oviductal factors. The effect of oviductal factors was masked by the presence of BSA during the entire culture. FCS promoted an earlier appearance of blastocysts. It is concluded that the effect of glucose on in vitro embryo development depends upon the source of protein. Oviductal factors are not an appropriate supplement for embryos beyond Day 6 of culture in SOF, although blastocyst rates of such embryos may be increased by culturing them in the presence of FCS or BSA.     

Effects of low temperature storage upon subsequent energy metabolism of rabbit embryos

The oxidation of pyruvate by two-cell rabbit embryos occurred at a very low rate at 10 °C, but increased 10–15 times upon rewarming to 37 °C. Pyruvate utilization of these embryos increased with continued development parallel to embryos not cooled to 10 °C, but incubated directly at 37 °C. Storage at 10 °C did not affect the amount of glucose subsequently oxidized at 37 °C, nor the shift from the pentose shunt to glycolysis and the Krebs cycle that normally occurs between the morula and blastocyst stage. Thus, the temporary inhibition of carbohydrate metabolism induced through temperature reduction did not impair the subsequent ability of the embryos to metabolize pyruvate and glucose normally.