Involvement of the pentose phosphate pathway and redox regulation in fertilization in the mouse

Glucose metabolism is necessary for successful fertilization in the mouse. Both spermatozoa and oocytes metabolize glucose through the pentose phosphate pathway (PPP), and NADPH appears required for gamete fusion. The aims of this study were to further characterize the utilization of glucose by the fertilizing spermatozoon and the fertilized oocyte, to demonstrate the importance of the PPP in different steps of fertilization, and to examine whether the beneficial effect of glucose could be mediated by a NADPH-dependent enzyme involved in redox regulation. By using a fluorescent analog of 2-deoxyglucose, glucose uptake was evidenced in both the head and flagellum of motile spermatozoa. After sperm-oocyte fusion, an increase in glucose uptake by the fertilized oocyte was observed but not before the formation of the male and female pronuclei. By using a microphotometric technique, activity of glucose 6-phosphate dehydrogenase (G6PDH), the key enzyme of the PPP, was localized to the sperm head and midpiece. When epididymal spermatozoa were released into a glucose-containing medium, the NADPH/NADP ratio increased with capacitation. Sperm-oocyte fusion and meiosis reinitiation of the fertilized oocyte was inhibited by the PPP inhibitor 6-aminonicotinamide (6-AN); inhibition of sperm-oocyte fusion was relieved by NADPH. Sperm-oocyte fusion and meiosis reinitiation were also inhibited by diphenylamine iodonium, which is a flavoenzyme inhibitor reported to prevent reactive oxygen species (ROS) generation in mouse spermatozoa and embryos. These findings indicate that the PPP is involved in different steps of fertilization. Subsequent regulation of a NADPH-dependent flavoenzyme responsible of ROS production is envisaged.     

Characterization of glycolysis and pentose phosphate pathway activity during sperm entry into the mouse oocyte

Studying the events that occur during gamete fusion and sperm decondensation in the oocyte remains difficult because sperm-oocyte fusion and subsequent sperm decondensation represent a short part of the fertilization process, and their exact timing is difficult to determine. There is therefore a need for greater understanding of the events that occur during this period. The main purpose of this study was to examine the metabolic aspects of this time frame by characterizing glucose metabolism (glycolytic and pentose phosphate pathway [PPP] activities) during sperm fusion and decondensation into zona-free oocytes in mice. The metabolism of glucose through both glycolysis and the PPP was measured in ovulated MII oocytes, free of cumulus cells, and the levels of glucose metabolized were found to be low. Upon sperm entry, both glycolytic and PPP activity increased substantially. To determine whether this elevation in glucose metabolism was part of the activation process, the metabolism of parthenogenetically activated oocytes was measured, and no increase in metabolism was observed. The characterization of glucose metabolism during sperm fusion and decondensation into the oocyte, and comparison to parthenogenetically activated oocytes, showed that the fertilizing sperm is responsible for an increase in both glycolytic and PPP activity during fusion and/or decondensation. The significance of this observation during the fertilization process and for the developing embryo is as yet unclear and warrants further investigation.     

Capacitated, acrosome reacted but immotile sperm, when microinjected under the mouse zona pellucida, will not fertilize the oocyte

We have devised a procedure for mechanically inserting intact, acrosome reacted spermatozoa under the mouse zona pellucida, and have examined the ability of sperm so inserted to fertilize the mouse oocyte. Sperm immobilized by a variety of different methods are unable to fertilize the egg, despite the fact that electron microscopy confirms that they are acrosome reacted. Control experiments show that the oocytes are capable of being fertilized by motile sperm after the microinjection procedure, and that the immobilized sperm are able to form male pronuclei after injection directly into the ctyoplasm. These results indicate that in addition to its importance for penetration of egg investments, sperm motility is required for fusion of the gametes. Alternatively, the findings suggest that the enzymatic machinery required for sperm motility is very similar to that utilized for gamete fusion, and that destruction of one is likely to lead to inactivation of the other.     

Up-regulation of glucose metabolism during male pronucleus formation determines the early onset of the s phase in bovine zygotes

After in vitro fertilization with spermatozoa from bulls with high in vitro fertility, a beneficial paternal effect is manifested during the G1 phase of the first cell cycle. This benefit determines an earlier onset of the first S phase, and then a successful morula-blastocyst transition 7 days later. We hypothesized that the origin of the paternal effect could be a shift of the metabolism of the fertilized oocyte, because in mice, sperm decondensation is responsible for a dramatic increase in glucose metabolism. In this study we investigated the interaction between both pronuclei and compared glycolysis and pentose phosphate pathway (PPP) activities in bovine oocytes fertilized with spermatozoa from bulls of high or low fertility. Here we demonstrate that male pronucleus formation is necessary for the onset of the S phase in the female pronucleus, and that the component promoting an early S phase in both pronuclei is metabolic and linked to an up-regulation of the PPP during the male pronucleus formation. This long-lasting paternal effect is more evidence of the important role of epigenetic control during early embryo development.     

Glucose metabolism in mouse cumulus cells prevents oocyte aging by maintaining both energy supply and the intracellular redox potential

Inhibiting oocyte postovulatory aging is important both for healthy reproduction and for assisted reproduction techniques. Some studies suggest that glucose promotes oocyte meiotic resumption through glycolysis, but others indicate that it does so by means of the pentose phosphate pathway (PPP). Furthermore, although pyruvate was found to prevent oocyte aging, the mechanism is unclear. The present study addressed these issues by using the postovulatory aging oocyte model. The results showed that whereas the oocyte itself could utilize pyruvate or lactate to prevent aging, it could not use glucose unless in the presence of cumulus cells. Glucose metabolism in cumulus cells prevented oocyte aging by producing pyruvate and NADPH through glycolysis and PPP. Whereas PPP was still functioning after inhibition of glycolysis, the glycolysis was completely inactivated after inhibition of PPP. Addition of fructose-6-phosphate, an intermediate product from PPP, alleviated oocyte aging significantly when the PPP was totally inhibited. Lactate prevented oocyte aging through its lactate dehydrogenase-catalyzed oxidation to pyruvate, but pyruvate inhibited oocyte aging by its intramitochondrial metabolism. However, both lactate and pyruvate required mitochondrial electron transport to prevent oocyte aging. The inhibition of oocyte aging by both PPP and pyruvate involved regulation of the intracellular redox status. Together, the results suggest that glucose metabolism in cumulus cells prevented oocyte postovulatory aging by maintaining both energy supply and the intracellular redox potential and that) glycolysis in cumulus cells might be defective, with pyruvate production depending upon the PPP for intermediate products.     

Proteomic analysis of bovine sperm YWHA binding partners identify proteins involved in signaling and metabolism

Posttranslational modification of proteins by phosphorylation is involved in regulation of sperm function. Protein phosphatase 1 gamma isoform 2 (PPP1CC_v2) and protein YWHA (also known as 14-3-3) are likely to be key molecules in pathways involving sperm protein phosphorylation. We have shown that phosphorylated PPP1CC_v2 is bound to protein YWHAZ in spermatozoa. In somatic cells, protein YWHA is known to bind a number of phosphoproteins involved in signaling and energy metabolism. Thus, in addition to PPP1CC_v2, it is likely that sperm contain other YWHA-binding proteins. A goal of the present study was to identify these sperm YWHA-binding proteins. The binding proteins were isolated by affinity chromatography with GST-YWHAZ followed by elution with a peptide, R-11, which is known to disrupt YWHA complexes. The YWHA-binding proteins in sperm can be classified as those involved in fertilization, acrosome reaction, energy metabolism, protein folding, and ubiquitin-mediated proteolysis. A subset of these putative YWHA-binding proteins contain known amino acid consensus motifs, not only for YWHA binding but also for PPP1C binding. Identification of sperm PPP1CC_v2-binding proteins by microcystin-agarose chromatography confirmed that PPP1CC_v2 and YWHA interactomes contain several common proteins. These are metabolic enzymes phosphoglycerate kinase 2, hexokinase 1, and glucose phosphate isomerase; proteins involved in sperm-egg fusion; angiotensin-converting enzyme, sperm adhesion molecule, and chaperones; heat shock 70-kDa protein 5 (glucose-regulated protein 78 kDa; and heat shock 70-kDa protein 1-like. These proteins are likely to be phosphoproteins and potential PPP1CC_v2 substrates. Our data suggest that in addition to potential regulation of a number of important sperm functions, YWHA may act as an adaptor molecule for a subset of PPP1CC_v2 substrates.     

Progesterone-induced increase of sperm cytosolic calcium is enhanced by previous fusion of spermatozoa to prostasomes

Ejaculated spermatozoa must undergo a number of modifications before becoming able to fertilize the oocyte. The interaction of sperm with other semen components may influence these phenomena; human semen contains vesicles of prostatic origin, called prostasomes that may fuse to sperm at slightly acidic to neutral pH values.Prostasomes contain calcium and it has been demonstrated that their fusion with spermatozoa produces a transient increase (wave) of [Ca(2+)](i) in these cells. The fusion process also transfers protein and lipid to spermatozoa. These phenomena may induce long-lasting changes of sperm properties. We test the hypothesis that spermatozoa, as modified by fusion, change their ability to undergo the progesterone-induced increase of [Ca(2+)](i) and we find that the increase of [Ca(2+)](i) produced by the fusion with prostasomes and by the stimulation with progesterone are independent and additive phenomena. We also find that spermatozoa present a stronger response to the progesterone-induced increase of [Ca(2+)](i) if they are previously made to fuse with prostasomes. This effect does not depend directly on the [Ca(2+)](i) increase due to fusion, since it is still present after the [Ca(2+)](i) has returned to resting values.     

Gamete membrane fusion in hamster spermatozoa with reacted equatorial segment

Mammalian spermatozoa must undergo many changes to be able to fertilize the oocyte. One of these changes, the acrosome reaction, has been established as a requisite for gamete membrane fusion to occur; it consists of the fusion and vesiculation of the sperm plasma membrane with the outer acrosomal membrane of the principal segment of the acrosome. Reaction of the equatorial segment has occasionally been observed. The objective of the present work was to determine whether the presence of the sperm plasma membrane over the equatorial segment is necessary for gamete membrane fusion to occur. Golden hamster spermatozoa were capacitated in vitro in TAPL 10K, and the maximum possible percentage of acrosome reaction was determined at 82.79% + 1.69% SD (P = 0.27; r = 0.21). Ultrastructural studies showed that 93.6% of the reacted spermatozoa in this population had their principal and equatorial segments reacted. The fertilizing ability of these spermatozoa was assayed using zona-free hamster oocytes. The percentage of fertilized ova obtained was 98.8% (308/312). Ultrastructural studies snowed the presence of spermatozoa with reacted equatorial segment inside the cytoplasm of immature oocytes. The evidence presented in this work demonstrates that the plasma membrane of spermatozoa with reacted equatorial segment retains its ability to fuse with the oocyte.     

Effect of sperm immobilisation and demembranation on the oocyte activation rate in the mouse.

To analyse the effect of the state of the sperm plasma membrane on oocyte activation rate following intracytoplasmic sperm injection (ICSI), three types of human and mouse spermatozoa (intact, immobilised and Triton X-100 treated) were individually injected into mouse oocytes. At 30, 60 and 120 min after injection, maternal chromosomes and sperm nuclei within oocytes were examined. Following human sperm injection, the fastest and the most efficient oocyte activation and sperm head decondensation occurred when the spermatozoa were treated with Triton X-100. Intact spermatozoa were the least effective in activating oocytes. Thus, the rate of mouse oocyte activation following human sperm injection is greatly influenced by the state of the sperm plasma membrane during injection. When mouse spermatozoa were injected into mouse oocytes, the rates of oocyte activation and sperm head decondensation within activated oocytes were the same irrespective of the type of sperm treatment prior to injection. We witnessed that live human spermatozoa injected into moue oocytes often kept moving very actively within the ooplasm for more than 60 min, whereas motile mouse spermatozoa usually became immotile within 20 min after injection into the ooplasm. In 0.002% Triton X-100 solution, mouse spermatozoa are immobilised faster than human spermatozoa. These facts seem to suggest that human sperm plasma membranes are physically and biochemically more stable than those of mouse spermatozoa. Perhaps the physical and chemical properties of the sperm plasma membrane vary from species to species. For those species whose spermatozoa have 'stable' plasma membranes, prior removal or 'damage' of sperm plasma membranes would increase the success rate of ICSI.     

Nitric oxide synthase inhibition in human sperm affects sperm-oocyte fusion but not zona pellucida binding

There is recent evidence that mouse and human spermatozoa contain constitutive nitric oxide synthase (cNOS) and can synthesize nitric oxide. The aim of this study was to investigate whether the inhibition of human sperm cNOS could affect sperm-oocyte fusion and sperm binding to the zona pellucida (ZP). N(G)-nitro-L-arginine methyl ester (L-NAME) was used as cNOS inhibitor. Sperm-oocyte fusion was evaluated using the hamster egg penetration test (HEPT). The ZP binding was evaluated using the hemizona assay. L-NAME added from the onset of capacitation strongly inhibited sperm-oocyte fusion. This inhibitory effect was dose dependent, stereospecific, and suppressed by L-arginine in a dose-dependent manner. L-NAME also inhibited sperm-oocyte fusion in the HEPT enhanced with progesterone (P), where P (5 microM) was added for 15 min to capacitated sperm. A lesser but significant inhibition was also observed when sperm suspensions were exposed to L-NAME following capacitation in both versions of HEPT. On the contrary, L-NAME did not affect ZP binding. In conclusion, the present study provides the evidence that cNOS plays a role in the human sperm's capacity to fuse with oocyte but not in the ZP binding.     

Effect of hyaluronidase, beta-glucuronidase and beta-N-acetylglucosaminidase inhibitors on sperm penetration of the mouse oocyte

The role of hyaluronidase, beta-glucuronidase and beta-N-acetylglucosaminidase in the penetration by mouse spermatozoa through the layers surrounding the oocyte was investigated by in vitro techniques. Myocrisin, fenoprofen, phosphorulated hesperidin and PS53 (a hydroquinone-sulfonic acid-formaldehyde polymer) inhibited fertilization when incubated with capacitated spermatozoa before the treated spermatozoa were mixed with intact oocytes but not when the inhibitor-treated, capacitated spermatozoa were added to oocytes free of follicle cells. The antifertility activity did not appear to be due to an effect on sperm motility or on the oocytes. These 4 compounds are known hyaluronidase inhibitors and, of the acrosomal enzymes tested, only share inhibition of hyaluronidase. Kinetic studies indicated that myocrisin is a reversible inhibitor of mouse sperm hyaluronidase whereas the other three are irreversible inhibitors. Adding saccharolactone, a beta-glucuronidase inhibitor, or N-acetylglucosaminolactone and N-acetylgalactosaminolactone, beta-N-acetylglucosaminidase inhibitors, to capacitated spermatozoa under the same conditions as the hyaluronidase inhibitors did not decrease fertilization. This was the case even though the beta-glucuronidase or beta-N-acetylglucosaminidase activities of the spermatozoa were completely inhibited, at least at the time that the inhibitor-treated, capacitated spermatozoa were mixed with the oocytes. The hyaluronidase activity of mouse spermatozoa remained unaltered during the incubation period required for capacitation; however, prolonged incubation caused a significant decrease in hyaluronidase. Untreated mouse spermatozoa caused hydrolysis of hyaluronic acid more effectively than did sperm extracts obtained by detergent extraction. These results are consistent with the theory of an essential role of hyaluronidase in mouse fertilization. At least in this species, the enzyme appears to be specifically involved in sperm penetration through the follicle cell layer. The data do not support an essential role for beta-glucuronidase and beta-N-acetylglucosaminidase in the penetration by mouse spermatozoa through the oocyte's investments. In contrast to some other species, sperm capacitation in mice does not result in a loss of hyaluronidase although part of the enzyme activity is lost on prolonged incubation. Mouse spermatozoa appear to be able to digest substrate (hyaluronic acid) even though hyaluronidase is not released.     

Glycolytic enzyme activity is essential for domestic cat (Felis catus) and cheetah (Acinonyx jubatus) sperm motility and viability in a sugar-free medium

We have previously reported a lack of glucose uptake in domestic cat and cheetah spermatozoa, despite observing that these cells produce lactate at rates that correlate positively with sperm function. To elucidate the role of glycolysis in felid sperm energy production, we conducted a comparative study in the domestic cat and cheetah, with the hypothesis that sperm motility and viability are maintained in both species in the absence of glycolytic metabolism and are fueled by endogenous substrates. Washed ejaculates were incubated in chemically defined medium in the presence/absence of glucose and pyruvate. A second set of ejaculates was exposed to a chemical inhibitor of either lactate dehydrogenase (sodium oxamate) or glyceraldehyde-3-phosphate dehydrogenase (alpha-chlorohydrin). Sperm function (motility and acrosomal integrity) and lactate production were assessed, and a subset of spermatozoa was assayed for intracellular glycogen. In both the cat and cheetah, sperm function was maintained without exogenous substrates and following lactate dehydrogenase inhibition. Lactate production occurred in the absence of exogenous hexoses, but only if pyruvate was present. Intracellular glycogen was not detected in spermatozoa from either species. Unexpectedly, glycolytic inhibition by alpha-chlorohydrin resulted in an immediate decline in sperm motility, particularly in the domestic cat. Collectively, our findings reveal an essential role of the glycolytic pathway in felid spermatozoa that is unrelated to hexose metabolism or lactate formation. Instead, glycolytic enzyme activity could be required for the metabolism of endogenous lipid-derived glycerol, with fatty acid oxidation providing the primary energy source in felid spermatozoa.     

Regulation of redox metabolism in the mouse oocyte and embryo

Energy homeostasis of the oocyte is a crucial determinant of fertility. Following ovulation, the oocyte is exposed to the unique environment of the Fallopian tube, and this is reflected in a highly specialised biochemistry. The minute amounts of tissue available have made the physiological analysis of oocyte intermediary metabolism almost impossible. We have therefore used confocal imaging of mitochondrial and cytosolic redox state under a range of conditions to explore the oxidative metabolism of intermediary substrates. It has been known for some time that the early mouse embryo metabolises external pyruvate and lactate but not glucose to produce ATP. We now show at the level of single oocytes, that supplied glucose has no effect on the redox potential of the oocyte. Pyruvate is a cytosolic oxidant but a mitochondrial reductant, while lactate is a strong cytosolic reductant via the activity of lactate dehydrogenase. Unexpectedly, lactate-derived pyruvate appears to be diverted from mitochondrial oxidation. Our approach also reveals that the level of reduced glutathione (GSH) in the oocyte is maintained by glutathione reductase, which oxidises intracellular NADPH to reduce oxidised glutathione. Surprisingly, NADPH does not seem to be supplied by the pentose phosphate pathway in the unfertilised oocyte but rather by cytosolic NADP-dependent isocitrate dehydrogenase. Remarkably, we also found that the oxidant action of pyruvate impairs development, demonstrating the fundamental importance of redox state on early development.     

Oocyte CD9 is enriched on the microvillar membrane and required for normal microvillar shape and distribution

Microvilli are found on the surface of many cell types, including the mammalian oocyte, where they are thought to act in initial contact of sperm and oocyte plasma membranes. CD9 is currently the only oocyte protein known to be required for sperm-oocyte fusion. We found CD9 is localized to the oocyte microvillar membrane using transmission electron microscopy (TEM). Scanning electron microscopy (SEM) showed that CD9 null oocytes, which are unable to fuse with sperm, have an altered length, thickness and density of their microvilli. One aspect of this change in morphology was quantified using TEM by measuring the radius of curvature at the microvillar tips. A small radius of curvature is thought to promote fusibility and the radius of curvature of microvillar tips on CD9 wild-type oocytes was found to be half that of the CD9 null oocytes. We found that oocyte CD9 co-immunoprecipitates with two Ig superfamily cis partners, EWI-2 and EWI-F, which could have a role in linking CD9 to the oocyte microvillar actin core. We also examined latrunculin B-treated oocytes, which are known to have reduced fusion ability, and found altered microvillar morphology by SEM and TEM. Our data suggest that microvilli may participate in sperm-oocyte fusion. Microvilli could act as a platform to concentrate adhesion/fusion proteins and/or provide a membrane protrusion with a low radius of curvature. They may also have a dynamic interaction with the sperm that serves to capture the sperm cell and bring it into close contact with the oocyte plasma membrane.     

Metabolic Reprogramming for Producing Energy and Reducing Power in Fumarate Hydratase Null Cells from Hereditary Leiomyomatosis Renal Cell Carcinoma

Fumarate hydratase (FH)-deficient kidney cancer undergoes metabolic remodeling, with changes in mitochondrial respiration, glucose, and glutamine metabolism. These changes represent multiple biochemical adaptations in glucose and fatty acid metabolism that supports malignant proliferation. However, the metabolic linkages between altered mitochondrial function, nucleotide biosynthesis and NADPH production required for proliferation and survival have not been elucidated. To characterize the alterations in glycolysis, the Krebs cycle and the pentose phosphate pathways (PPP) that either generate NADPH (oxidative) or do not (non-oxidative), we utilized [U-¹³C]-glucose, [U-¹³C,¹⁵N]-glutamine, and [1,2- ¹³C₂]-glucose tracers with mass spectrometry and NMR detection to track these pathways, and measured the oxygen consumption rate (OCR) and extracellular acidification rate (ECAR) of growing cell lines. This metabolic reprogramming in the FH null cells was compared to cells in which FH has been restored. The FH null cells showed a substantial metabolic reorganization of their intracellular metabolic fluxes to fulfill their high ATP demand, as observed by a high rate of glucose uptake, increased glucose turnover via glycolysis, high production of glucose-derived lactate, and low entry of glucose carbon into the Krebs cycle. Despite the truncation of the Krebs cycle associated with inactivation of fumarate hydratase, there was a small but persistent level of mitochondrial respiration, which was coupled to ATP production from oxidation of glutamine-derived α–ketoglutarate through to fumarate. [1,2- ¹³C₂]-glucose tracer experiments demonstrated that the oxidative branch of PPP initiated by glucose-6-phosphate dehydrogenase activity is preferentially utilized for ribose production (56-66%) that produces increased amounts of ribose necessary for growth and NADPH. Increased NADPH is required to drive reductive carboxylation of α-ketoglutarate and fatty acid synthesis for rapid proliferation and is essential for defense against increased oxidative stress. This increased NADPH producing PPP activity was shown to be a strong consistent feature in both fumarate hydratase deficient tumors and cell line models.     

The mammalian acrosome reaction: Gateway to sperm fusion with the oocyte?

Mammalian sperm undergo discharge of a single, anterior secretory granule following their attachment to the zona pellucida surrounding the oocyte. This secretory discharge is known for historical reasons as the acrosome reaction. It fulfils a number of purposes and without it, sperm are unable to penetrate the zona pellucida and fuse with the oocyte. In this review, we focus on the role of the acrosome reaction in the development of fusion competence in sperm. Any naturally occurring membrane fusion has two major sequential steps: a docking or adhesion step, in which two membranes adhere, and a fusion step, in which their lipid bilayers are destabilized and merged and a cellular compartment is either created or destroyed. Recent evidence suggests that there is an important role for oocyte integrins and sperm-bound disintegrins in mammalian sperm/oocyte adhesion and fusion. The fusion mechanism employed by sperm remains poorly understood, however, and circumstantial evidence suggests it is more complex than the interaction between a single protein species and its target. Sperm/oocyte fusion is probably the most accessible eukaryotic model for intercellular fusion currently available, partly because it is temporally separated from gene expression. Elucidation of the mechanism of sperm/oocyte fusion may throw light on the mechanism of other intercellular fusions such as myoblast fusion, and the evolutionary relationship of intercellular membrane fusion to intracellular membrane fusion.     

Structural requirements for the inhibitory action of the CD9 large extracellular domain in sperm/oocyte binding and fusion

CD9 has been shown to be essential for sperm/oocyte fusion in mice, the only non-redundant role found for a member of the tetraspanin family. CD9 can act in cis, reconstituting sperm/oocyte fusion when ectopically expressed in oocytes from CD9 null mice, or in trans, inhibiting sperm fusion when the large extracellular domain (LED) is added to CD9-positive oocytes as a soluble protein. In contrast to cis inhibition, the structural requirements of the trans inhibition by soluble CD9 LED are unknown. Here we show that human CD9 LED is as potent an inhibitor as mouse CD9 LED in mouse sperm/oocyte fusion assays and that CD9 LED can also inhibit sperm/oocyte binding. The two disulphide bridges that define membership of the tetraspanin family are critical for structure and function of human CD9 LED and mutation of a pentapeptide sequence in the hypervariable region further defines the critical region for trans inhibition.     

Evaluation of relative fertility of cryopreserved goat sperm

This study was designed to compare differences in the in vivo fertility of cryopreserved goat semen assessed by heterospermic insemination with differences in in vitro analyses. Five groups of does were inseminated with mixed frozen-thawed semen from different pairs of bucks. The percentage of offspring sired by each buck in the pair was compared with the relative ability of spermatozoa from that frozen-thawed ejaculate to penetrate zona-free hamster ova, relative post-thaw acrosomal integrity, ability to undergo an acrosome reaction during in vitro capacitation, and assessments of sperm motility. In 4 of the 5 different insemination pairs, the ratio of offspring born was other than 1:1. Acrosomal integrity, ability of spermatozoa to undergo an acrosome reaction, and parameters of sperm motility were not correlated with differences in relative fertility in this experiment using ejaculates from fertile bucks. The ability of spermatozoa to fuse with the oocyte plasma membrane was highly correlated with relative in vivo fertility (R(2) = 0.78, P = 0.04). This suggests that fusion with the oocyte plasma membrane is an event in the fertilization process in which significant variation exists among fertile bucks. Assessment of ability of spermatozoa to fuse with zona-free hamster ova may contribute to analysis of post-thaw fertility of frozen-thawed buck semen.     

The pathogenesis of transaldolase deficiency

The signaling networks that mediate cell growth, differentiation, and survival are dependent on complex metabolic and redox pathways. Metabolism of glucose through the pentose phosphate pathway (PPP) fulfills two unique functions: formation of ribose 5-phosphate for the synthesis of nucleotides, RNA, and DNA in support cell growth and formation of NADPH for biosynthetic reactions and neutralization of reactive oxygen intermediates (ROI). Balancing of NADPH and ROI levels by the PPP enzyme transaldolase (TAL) regulates the mitochondrial trans-membrane potential (Deltapsi(m)), a critical checkpoint of ATP synthesis and cell survival. While complete deficiency of glucose 6-phosphate dehydrogenase (G6PD) or transketolase (TK) is lethal, TAL-deficient mice developed normally with the exception of male sterility due to structural and functional damage of sperm cell mitochondria. Recently, two cases of complete TAL deficiency have been reported in patients with liver cirrhosis which results from increased cell death of hepatocytes. Delineation of the cell type-specific role that TAL plays in the PPP and cell death signal processing will be critical for understanding the pathogenesis of TAL deficiency.     

Regulation of the pentose phosphate pathway in cancer

Energy metabolism is significantly reprogrammed in many human cancers, and these alterations confer many advantages to cancer cells, including the promotion of biosynthesis, ATP generation, detoxification and support of rapid proliferation. The pentose phosphate pathway (PPP) is a major pathway for glucose catabolism. The PPP directs glucose flux to its oxidative branch and produces a reduced form of nicotinamide adenine dinucleotide phosphate (NADPH), an essential reductant in anabolic processes. It has become clear that the PPP plays a critical role in regulating cancer cell growth by supplying cells with not only ribose-5-phosphate but also NADPH for detoxification of intracellular reactive oxygen species, reductive biosynthesis and ribose biogenesis. Thus, alteration of the PPP contributes directly to cell proliferation, survival and senescence. Furthermore, recent studies have shown that the PPP is regulated oncogenically and/or metabolically by numerous factors, including tumor suppressors, oncoproteins and intracellular metabolites. Dysregulation of PPP flux dramatically impacts cancer growth and survival. Therefore, a better understanding of how the PPP is reprogrammed and the mechanism underlying the balance between glycolysis and PPP flux in cancer will be valuable in developing therapeutic strategies targeting this pathway.