Effects of changes in the concentration of systemic progesterone on ions, amino acids and energy substrates in cattle oviduct and uterine fluid and blood.

Early embryo loss is a major factor affecting the conception rate in cattle. Up to 40% of cattle embryos die within 3 weeks of fertilisation while they are nutritionally dependent on oviduct and uterine fluids for their survival. Inadequate systemic progesterone is one of the factors contributing to this loss. We have characterised the effects of changes in systemic progesterone on amino acid, ion and energy substrate composition of oviduct and uterine fluids on Days 3 and 6, respectively, of the oestrus cycle in cattle. Oviduct and uterine fluids were collected in situ following infusion of progesterone. There was no effect of progesterone on oviduct fluid secretion rate; however, uterine fluid secretion rate was lowered. Progesterone increased uterine glucose, decreased oviduct sulfate and, to a lesser degree, oviduct sodium, but had no effect on any of the ions in the uterus. The most marked effect of progesterone was on oviducal amino acid concentrations, with a twofold increase in glycine, whereas in the uterus only valine was increased. These results provide novel information on the maternal environment of the early cattle embryo and provide further evidence of progesterone regulation of oviduct amino acid concentrations in cattle.

Energy substrates in bovine oviduct and uterine fluid and blood plasma during the oestrous cycle.

Up to 40 percent of cattle embryos die within 3 weeks of fertilization but there is little or no published information on the composition of the oviduct and uterine fluids essential for their survival during this time. We have measured the concentrations of the energy substrates, glucose, lactate, and pyruvate in cattle oviduct fluid on Days 0, 2, 4, and 6 and uterine fluid on Days 6, 8, and 14 of the oestrous cycle and corresponding blood samples. Oviduct and uterine fluids were collected in situ. Glucose concentrations in oviduct and uterine fluids were similar on all days and lower than in plasma (P < 0.05). Oviduct lactate concentration was up to eightfold higher than uterine or plasma concentration (P < 0.01). Oviduct pyruvate concentrations were similar on all days and lower than plasma concentrations on Days 0 and 2 (P < 0.005). Pyruvate concentrations were similar in the uterus and in plasma except on Day 14 when the concentration in plasma was higher (P < 0.05). There were no associations between systemic progesterone or oestradiol and glucose, lactate or pyruvate. There was a linear positive relationship (P < 0.001) between oviduct fluid secretion rate and oviduct glucose concentration and a linear negative relationship (P < 0.001) between oviduct fluid secretion rate and oviduct lactate, but no association between uterine fluid secretion rate and energy substrates. The different concentrations and associations between the energy substrates in oviduct and uterine fluids and blood plasma indicate a differential regulation of the secretion of these energy substrates by the oviduct and uterine epithelium.

Amino acid metabolism of the porcine blastocyst.

The pattern of depletion and appearance of a mixture of amino acids by single porcine blastocysts incubated in two different media has been determined non-invasively using high performance liquid chromatography. Zygotes were produced by the in vitro fertilisation of in vitro-matured, abattoir-derived immature oocytes and cultured in medium NCSU 23 with or without amino acids. Embryos grown in the absence of amino acids up to the blastocyst stage were transferred to amino acid-containing culture medium for measurement of turnover (Experiment 1). Blastocysts grown in NCSU 23+amino acids were transferred into fresh droplets of the same medium (Experiment 2). Although the specific pattern of amino acid production and depletion varied between experiments, a general pattern emerged, with arginine being significantly depleted (p<0.001) and alanine consistently appearing in the media, in quantities that varied depending with culture conditions. The data suggest that arginine is important during porcine blastocyst development, most likely contributing to the formation of nitric oxide and polyamines and that alanine is produced as a means of disposing of excess amino groups. A model for the interactions of amino acids during porcine early embryo development is proposed. The profile of amino acid metabolism by porcine blastocysts is qualitatively and quantitatively similar to that given by human embryos during the morula:blastocyst transition suggesting that the porcine blastocyst is a good model for the human.

Identification of viable embryos in IVF by non-invasive measurement of amino acid turnover.

BACKGROUND: IVF is limited by low success rates and an unacceptably high multiple pregnancy rate. These outcomes would be improved significantly if a single embryo of high viability could be replaced in each treatment cycle, but widespread acceptance of such a policy is hindered by the lack of predictive factors for embryo selection. We have conducted a retrospective clinical study of a novel non-invasive method of embryo selection based on the depletion/appearance of amino acids in the culture medium. METHODS: Fifty-three cycles of IVF treatment using ICSI were studied. Embryos were cultured for 24 h in 4 microl drops of medium containing a physiological mixture of 18 amino acids. The spent medium was analysed for amino acid content by high performance liquid chromatography. RESULTS: The turnover of three amino acids, Asn, Gly and Leu, was significantly correlated with a clinical pregnancy and live birth. These correlations were independent of known predictors, such as female age, basal levels of FSH, embryo cell number and embryo morphological grade. CONCLUSIONS: Non-invasive assay of amino acid turnover has the potential to improve significantly the prospective selection of the most viable embryos, or single embryo, for replacement in an IVF cycle.

Amino acid turnover by elongating cattle blastocysts recovered on days 14-16 after insemination.

Blastocyst elongation from day 14 to day 16 after insemination coincides with a major phase of embryo loss in cattle. Protein synthesis, reflected in protein content, increases markedly over this period but little is known about the amino acid requirement of elongating blastocysts at this time. Cattle blastocysts produced in vivo were recovered on days 14-16 after insemination and cultured individually for up to 8 h in synthetic oviduct fluid containing a physiological mixture of amino acids plus 1 mmol glutamine l(-1) and 0.1% (w/v) polyvinyl alcohol (SOFaaPVA). After 1, 4 and 8 h in culture, an aliquot of culture medium was removed and the rate of amino acid depletion or production was calculated per unit of protein and per hour of culture. Amino acids were depleted or produced at different rates. Arginine was depleted from the medium at a significant rate (P < 0.05) during all culture periods. Alanine and glutamate were produced at a significant rate (P < 0.05) during all culture periods. The rate of alanine production was significantly greater (P < 0.05) in blastocysts recovered on day 14 compared with days 15 or 16 after insemination. Alanine production and arginine depletion tended to be greater in smaller embryos recovered on day 14 compared with larger and later stage embryos, indicating that earlier stage embryos may have higher metabolic activity than later stage embryos. Qualitatively, the pattern of amino acid consumption and production during elongation was similar to that shown from the zygote to early blastocyst stage.

Effect of elevated systemic concentrations of ammonia and urea on the metabolite and ionic composition of oviductal fluid in cattle.

High dietary protein leads to elevated systemic concentrations of ammonia and urea, and these, in turn, have been associated with reduced fertility in cattle. The effect of elevating systemic concentrations of ammonia and urea on the concentrations of electrolytes and nonelectrolytes in bovine oviductal fluid were studied using estrus-synchronized, nulliparous heifers (n = 25). Heifers were randomly assigned to 1 of 3 treatments consisting of jugular vein infusion with either ammonium chloride (n = 8), urea (n = 8), or saline (n = 9). Oviducts were catheterized, and fluid was recovered over a 3-h period on either Day 2 or 8 of the estrous cycle. No difference (P > 0.05) was found in the concentrations of any electrolyte or nonelectrolyte between oviducts ipsi- or contralateral to the corpus luteum. Plasma and oviductal concentrations of urea were increased by infusion with urea (P < 0.001) and ammonium chloride (P < 0.05) but not by saline (P > 0.05). Plasma and oviductal concentrations of ammonia were elevated by infusion with ammonium chloride (P < 0.001) but not by infusion with urea or saline (P > 0.05). No effect (P > 0.05) of treatment was found on oviductal or plasma concentrations of glucose, lactate, magnesium, potassium, or sodium or on plasma concentrations of insulin or progesterone. The concentration of calcium in oviductal fluid was reduced by urea infusion and was negatively associated with systemic and oviductal concentrations of urea. Oviductal concentrations of sodium were higher on Day 8 than on Day 2 (P < 0.05). No effect of sample day was found on any of the other electrolytes or nonelectrolytes measured (P > 0.05). Elevated systemic concentrations of ammonia and urea are unlikely to reduce embryo survival through disruptions in the oviductal environment.

Meiotic induction in cumulus cell-enclosed mouse oocytes: involvement of the pentose phosphate pathway.

In this study we tested the hypothesis that the pentose phosphate pathway (PPP) participates in the meiotic induction of mouse oocytes. The electron acceptors methylene blue, phenazine ethosulfate (PES), and pyrroline-5-carboxylate (P5C) oxidize NADPH to NADP and activate the NADP-dependent enzymes of the PPP. Each of these compounds triggered a dose-dependent increase in meiotic maturation in hypoxanthine-arrested cumulus cell-enclosed oocytes during 17- to 18-h cultures. More than 96% of the oocytes underwent germinal vesicle breakdown (GVB) at the highest concentrations of P5C and PES tested (250 and 1 microM, respectively) as compared to only 45-52% of control oocytes. P5C was also stimulatory to denuded oocytes. Analysis of energy substrates in microdrop cultures revealed a 3.6-fold increase in glucose consumption by PES-treated oocyte-cumulus cell complexes that was associated with stimulation of GVB. On the other hand, 2-deoxyglucose, which interferes with glucose utilization, prevented the induction of maturation brought about by P5C. Apocynin and diphenyleneiodonium, inhibitors of NADPH oxidase, prevented meiotic maturation in the presence or absence of FSH. Gonadotropin-induced maturation was also prevented by 6-aminonicotinamide (6-AN) and dehydroepiandrosterone (DHEA), inhibitors of the two NADP-dependent enzymes of the PPP, and this was accompanied by suppression of glucose consumption. Phosphoribosyl-pyrophosphate (PRPP) is an important compound required in purine metabolism and can be formed from the end product of the oxidative arm of the PPP, ribose-5-phosphate. Ribose, which can be metabolized to PRPP, increased PRPP synthesis in complexes and induced meiotic maturation when added to hypoxanthine-arrested cumulus cell-enclosed oocytes in glucose-free medium in both the presence and absence of FSH. PRPP levels within complexes were also increased by glucose and FSH, but were reduced by hypoxanthine, 6-AN, and DHEA. In addition, exogenous PRPP stimulated maturation in hypoxanthine-arrested oocytes. These results support the proposition that glucose metabolism through the PPP is important in the meiotic induction mechanism and may involve the generation of PRPP that acts, at least in part, through the purine metabolizing pathways.

Substrate utilization and maturation of cumulus cell-enclosed mouse oocytes: evidence that pyruvate oxidation does not mediate meiotic induction.

This study was performed to address the possible role of pyruvate in meiotic induction in mouse oocytes. Cumulus cell-enclosed oocytes from primed, immature mice were cultured in 7.5 microliters microdrops under oil for 9 or 18 h in medium containing 4 mmol hypoxanthine l-1 plus 0.23 mmol pyruvate l-1, 1 mmol pyruvate l-1, or 1 mmol pyruvate l-1 plus 5.5 mmol glucose l-1. When compared with cultures containing 0.23 mmol pyruvate l-1, 1 mmol pyruvate l-1 induced germinal vesicle breakdown, and this was preceded by an increase in pyruvate utilization. Addition of glucose prevented both the increase in pyruvate consumption and the meiotic induction. When different combinations of pyruvate and glucose were tested on oocyte maturation in microdrop cultures, a high concentration of pyruvate or glucose alone was stimulatory to maturation. Addition of the complementary energy substrate prevented the induction of germinal vesicle breakdown and reduced the amount of substrate consumption. During spontaneous maturation in vitro, oocyte-cumulus cell complexes consumed glucose for the first 3 h; however, during the second 3 h period, which followed germinal vesicle breakdown, glucose consumption decreased and net pyruvate utilization was initiated. Treatment of hypoxanthine-arrested oocytes with dichloroacetate, an activator of pyruvate dehydrogenase, stimulated pyruvate consumption but had no effect on germinal vesicle breakdown. Although FSH stimulates meiotic resumption, no changes in pyruvate consumption were observed in response to this gonadotrophin. Measurement of oxygen consumption by hypoxanthine-treated complexes revealed no effect of high concentrations of pyruvate on respiration, and FSH treatment resulted in a suppression of oxygen utilization. These data indicate that, in mouse oocyte-cumulus cell complexes, pyruvate and glucose can each modulate metabolism of the other substrate, and the can significantly influence meiotic maturation of the oocyte. In addition, augmentation of pyruvate oxidation does not appear to play a mediating role in meiotic induction triggered by energy substrate manipulation or gonadotrophin treatment.

Glucose utilization during gonadotropin-induced meiotic maturation in cumulus cell-enclosed mouse oocytes.

Earlier work from this laboratory has determined that glucose plays an important role in the mechanisms regulating meiotic maturation in mammalian oocytes. In the current study, we have further explored the role of glucose in hormone-induced germinal vesicle breakdown (GVB) in an effort to better understand how glucose utilization and metabolism relate to the control of meiotic maturation in mouse cumulus cell-enclosed oocytes (CEO). When CEO were cultured in medium containing 4 mM hypoxanthine (to maintain meiotic arrest), 5.5 mM glucose, and 0.23 mM pyruvate, follicle-stimulating hormone (FSH) stimulated lactate accumulation in a time-dependent manner. Addition of 2-deoxyglucose (2-DG) to the medium at various times after the initiation of culture resulted in rapid termination of lactate production and suppression of FSH-induced GVB scored after 18 hr of culture, the effectiveness diminishing the longer the delay before addition of 2-DG. By 8 hr, addition of 2-DG was without effect on GVB. Similar effects were seen when FSH-treated CEO were washed free of glucose. In a 2-DG dose-response experiment, gonadotropin-induced lactate production was prevented, but this inhibition did not necessarily prevent GVB. The activities of six metabolic enzymes were measured in extracts of freshly isolated complexes, and in order of increasing activity were: hexokinase, 6-phosphogluconate dehydrogenase, glucose-6-phosphate dehydrogenase, phosphofructokinase, lactate dehydrogenase, and pyruvate kinase. Of the six enzymes examined, only hexokinase activity was increased in CEO exposed to FSH. CEO were cultured in microdrops in the presence or absence of FSH, and aliquots from the same microdrop were assayed for glucose, lactate, and pyruvate. In response to FSH, utilization of glucose in microdrop cultures by CEO was markedly increased and was accompanied by comparable lactate production and limited pyruvate production. Cycloheximide and alpha-amanitin both blocked FSH-induced oocyte maturation, but only cycloheximide prevented the increase in hexokinase activity and glucose consumption. These data suggest that hexokinase is an important rate-limiting enzyme for glucose utilization that is under translational control and participates in the mechanisms controlling the reinitiation of meiosis. However, stimulation of glycolytic activity does not appear to be a necessary concomitant for meiotic induction.

Characterization of follicular energy metabolism.

It has been shown that mouse ovarian follicles have a large glycolytic capacity, and this study was undertaken to determine whether follicles can develop normally using glycolysis alone. Pre-antral mouse follicles were grown using an in-vitro system which supports development to the preovulatory stage within 5 days. Cultures were maintained in either aerobic conditions in the presence of the inhibitor of oxidative phosphorylation, sodium malonate, or under anaerobic conditions. Samples of media were removed every 24 h and analysed for oestradiol using an enzyme-linked immunosorbent assay (ELISA) technique and for lactate and glucose using a fluorometric assay. Follicle size, oestradiol production and glycolytic rate were not significantly different between control and sodium malonate-treated follicles. Follicles cultured under anaerobic conditions showed significantly slower rates of growth and oestradiol production compared with controls. However, the rate of glycolysis was significantly higher during anoxia. Results indicated that anaerobic glycolysis may sustain limited periods of growth during the pre-antral phase, but that the presence of oxygen is vital to ensure normal development. It is concluded that pre-antral follicles can undergo development to the preovulatory stage using glycolysis alone, a feature which may allow them to conserve their limited supply of oxygen for other vital biosynthetic processes.

The effect of glucose metabolism on murine follicle development and steroidogenesis in vitro.

Previous studies have shown that mouse ovarian follicles produce large amounts of lactate during growth and maturation in vitro, suggesting a metabolic preference for glycolysis. Further investigations were therefore undertaken to determine firstly the effect of gonadotrophins on glucose uptake and secondly the role of glucose in follicle lactate production, development and steroidogenesis. Pre-antral mouse follicles were cultured individually in media containing different concentrations of glucose (1-5.5 mM) using a system which supported development to the pre-ovulatory stage within 5 days. Samples of media were removed every 24 h and analysed for oestradiol using an enzyme-linked immunosorbent assay technique and for glucose uptake and lactate production using a fluorimetric assay. Results showed that all the glucose consumed was converted to lactate, irrespective of the glucose concentration. Growth and steroidogenesis were also dependent on glucose concentration, and at concentrations below 2 mM, follicle development was significantly retarded. Results confirm that follicles adopt a predominantly glycolytic mode of energy production to sustain growth and steroidogenesis, and that the glycolytic rate is stimulated by gonadotrophins.

Pattern of lactate production and steroidogenesis during growth and maturation of mouse ovarian follicles in vitro.

A model culture system for the study of follicular metabolism has been developed from existing methods of whole-follicle culture. The modified system mimics the in vivo growth and maturation of mouse ovarian follicles from primary to preovulatory stages and the modulating influences of the LH and FSH. This is the first study to demonstrate ovulation in vitro from individual ovarian follicles. The pattern of follicular lactate production relative to steroidogenesis was studied throughout in vitro follicular development over a period of 6 days. Twenty-four-hour samples of medium from individual follicles were analyzed for lactate and pyruvate by an automated analytical technique, and for estradiol and progesterone by an immunoenzymatic method. Follicles produced remarkably large quantities of lactate and estradiol during FSH-stimulated development in vitro. LH further stimulated lactate production but resulted in a significant decrease in estradiol secretion and an ovulation rate of 30%. Progesterone production was not detectable throughout the culture period, and follicles showed no evidence of pyruvate uptake. These findings demonstrate the validity of using this model culture system for the study of follicular metabolism and provide new information on the pattern of carbohydrate metabolism relative to steroidogenesis during follicular growth and maturation.

Profiles of hypoxanthine guanine phosphoribosyl transferase and adenine phosphoribosyl transferase activities measured in single preimplantation human embryos by high-performance liquid chromatography.

The profiles of hypoxanthine guanine phosphoribosyl transferase (HGPRT) and adenine phosphoribosyl transferase (APRT) activities were examined in normally fertilized human embryos developing at the normal rate in vitro between the 2-4-cell stage on Day 2 and the blastocyst stage on Day 6 after insemination. The activities of both enzymes were assayed simultaneously in extracts of single embryos by measuring the rate of production of the reaction products, inosine monophosphate (IMP) and adenine monophosphate (AMP), separated by high-performance liquid chromatography (HPLC). The activity profiles of the two enzymes over this period showed marked differences. The activity of HGPRT, coded by the X chromosome, increased between Days 2 and 4 (P less than 0.01) but declined sharply by Day 6 (P less than 0.001), whereas autosome-coded APRT activity remained low between Days 2 and 5, but increased on Day 6 (P less than 0.05). The profile of HGPRT activity may reflect a combination of decreasing levels of maternal enzyme inherited from the oocyte and the initiation of embryonic gene expression followed by X inactivation at the blastocyst stage on Day 6.

Two preparations for the study of the isolated rabbit oviduct.

When rabbit oviducts were slit open along their length, cut into small pieces, and incubated in Krebs--Ringer--bicarbonate medium, the tissue slices took up O2 at a steady rate for 40 min, retained approximately 70% of their adenine nucleotides, and were suitable for metabolic studies of the oviduct. In a second preparation, oxygenated Krebs--Ringer--bicarbonate medium was recirculated at 700 microliters/min through the lumen of the whole oviduct, severed of its blood supply, while the serosal surface was bathed in a similar medium. The preparation took up O2, maintained a steady potential difference across its mucosal and serosal surfaces, and transported 2-deoxy D-glucose selectively for at least 40 min. In oviducts taken from rabbits injected 3 days previously with hCG, there was greater than 4-fold increase in the initial transmural potential difference.

Microtubules and angiosperm bordered pit formation.

Microtubules have been shown to run around the perimeter of the pit aperture of developing bordered pits of Salix fragilis, L. These microtubules are parallel to the microfibrils being produced and do not converge with them. Although microtubules may be parallel to microfibrils in differentiating vessel elements as well as in fibres, many cases have been found where microtubules are not so orientated. There is no direct evidence for the involvement of microtubules in the orientation of microfibrils in the secondary wall, although their position during wall synthesis suggests some ancillary role.

Phytoferritin in plastids of the cambial zone of willow.

"Crystalline" and "paracrystalline" arrays of electron-opaque granules have been found in plastids of the cambial zone and its immediate derivatives in crack willow (Salix fragilis L.). These granules have a diameter of 55 to 70 Å and, when in crystalline arrangement, show a centre to centre spacing of 100 Å with adjacent, slightly curved, or linear rows running parallel. The 70 Å particles have a substructure of four to six subunits 15 Å in diameter. These units are arranged around an electron-translucent core 20 Å diameter. It is suggested that this complex is phytoferritin. It is assumed that the electron-translucent area around the opaque granules represents the proteinaceous shell characteristic of both plant and animal ferritin as described by other authors. The phytoferritin is commonly found spread in a thin, regular, array over the surface of plastoglobuli in the plastids.It is further suggested that the phytoferritin is an iron-protein complex which allows the plant to store iron in non-toxic form. This theory would be in accord with the presence of phytoferritin in plastids which appear to be morphologically mature but which, on account of their position within the stem, would not be expected to be photosynthetically very active.