The binding of glycolytic enzymes to the cytoskeleton--influence of pH

In a continuing study of the interactions between glycolytic enzymes and cytoskeletal structure, the influence of a variation of the pH of the eluting medium has been investigated. This treatment resulted in an increased degree of binding of most of the glycolytic enzymes with a decrease in pH, with the most marked increases in binding occurring with phosphofructokinase, glyceraldehydephosphate dehydrogenase, enolase and pyruvate kinase. The significance of this data has been discussed with reference to the relative affinities of interaction of the individual glycolytic components and the physiological correlations of these phenomena.     

The association of glycolytic enzymes with cellular and model membranes

This article deals with the binding of glycolytic enzymes with membranous or protein subcellular structures. The representative papers of the last three decades dealing with this matter are reviewed. The studies evidencing the binding of some glycolytic enzymes to insoluble subcellular proteins and membranous structures are presented. It is currently generally accepted that the glycolytic enzymes work in some organisation. Such organisation undoubtedly plays a marked role, although still poorly known, in the regulation processes of glycolysis. From this review, the conclusion emerges that the regulatory ability of the binding of glycolytic enzymes to cellular membranes should be added to the list of well-known mechanisms of post-translational regulation of the glycolytic enzymes. Some of the results presented are the background for the hypothesis that planar phospholipid domains in/on the membrane surface are capable of functioning as binding sites for these enzymes. Such binding can modify the conformation state of the enzymes, which results in changes in their kinetic properties; thus, it may function as a regulator of catalytic activity     

Experimental determination of control of glycolysis in Lactococcus lactis

The understanding of control of metabolic processes requires quantitative studies of the importance of the different enzymatic steps for the magnitude of metabolic fluxes and metabolite concentrations. An important element in such studies is the modulation of enzyme activities in small steps above and below the wild-type level. We review a genetic approach that is well suited for both Metabolic Optimization and Metabolic Control Analysis and studies on the importance of a number of glycolytic enzymes for metabolic fluxes in Lactococcus lactis. The glycolytic enzymes phosphofructokinase (PFK), glyceraldehyde-3-phosphate dehydrogenase (GAPDH), pyruvate kinase (PYK) and lactate dehydrogenase (LDH) are shown to have no significant control on the glycolytic flux in exponentially growing cells of L. lactis MG1363. Introduction of an uncoupled ATPase activity results in uncoupling of glycolysis from biomass production. With MG1363 growing in defined medium supplemented with glucose, the ATP demanding processes do not have a significant control on the glycolytic flux; it appears that glycolysis is running at maximal rate. It is likely that the flux control is distributed over many enzymes in L. lactis, but it cannot yet be excluded that one of the remaining glycolytic steps is a rate-limiting step for the glycolytic flux.     

Rapid enzyme assays investigating the variation in the glycolytic pathway in field-caught populations ofFundulus heteroclitus

Variation in enzyme expression may be important in evolutionary adaptation, yet is seldom studied. Furthermore, no studies have examined the expression of all enzymes in a defined metabolic pathway. Enzyme concentration is a measure of enzyme expression and was ascertained by assaying maximal activity. Presented here is an analysis of variation of maximal enzyme activity for all the enzymes in a single metabolic pathway, glycolysis, from three clinically distributed populations of the fish,Fundulus heteroclitus. Techniques for rapidly analyzing maximal enzyme activity for all the enzymes of an entire metabolic pathway from many individuals are described. The high degree of repeatability (mean coefficient of variation for replicates, 4.4%) and sensitivity (less than 3 mg of tissue is required to measure all 10 enzymes) of these assays demonstrate the utility of such an approach for analyzing variation among populations for a large numbers of enzymes. Results from these studies indicate that (1) the average coefficient of variation for all enzyme determinations within a population is 45.3% and (2) between populations, the activity of 5 of the 10 glycolytic enzymes are significantly different. This considerable variation occurs even in populations where there is little allelic variation. These data demonstrating substantial variation in enzyme expression support the idea that changes in gene regulation may be as important as, or even more important than, changes in biochemical kinetic parameters in evolutionary processes.     

Changes in phosphofructokinase and pyruvate kinase in rat brain regions during alloxan-induced diabetes

Changes in the profile of two glycolytic enzymes, phosphofructokinase and pyruvate kinase, in different regions of rat brain were studied under alloxan-induced diabetes. A regional variation of the effect of diabetes on brain was noted - the cerebral hemispheres and cerebellum showed decreased activity of the enzymes, while the brain stem remained relatively unaffected. The changes in enzyme activities in the brain regions were more pronounced at the early days of diabetes, particularly at 8 days. Insulin administration to the diabetic animals restored the activity of the enzymes. The results indicate a regionally variable effect of diabetes on the two key glycolytic enzymes, and bring out a role of insulin in the regulation of brain glycolysis.     

Association of rabbit muscle glycolytic enzymes with filamentous actin. A counter-current distribution study at high ionic strength

The association between purified glycolytic enzymes and filamentous actin from rabbit muscle has been studied by counter-current distribution. The co-distribution of a glycolytic enzyme and filamentous actin leads to a significant change in the counter-current distribution profile of the enzyme whereas that of actin is unaffected. The changes in the distribution profiles clearly demonstrated that all glycolytic enzymes studied, though to different extents, bind to filamentous actin. The aqueous two-phase system used for the studies contained dextran, poly(ethyleneglycol) and 150 millimolal potassium phosphate buffer, pH 7.0. Since the ionic strength of the two-phase system is determined mainly by the buffer, the glycolytic enzymes are evidently able to associate with filamentous actin, at least in the presence of neutral polymers, at ionic strengths comparable to or higher than those assumed to prevail in vivo.     

Electrophoretic methods for differentiating glycolytic enzymes of mouse and human origin

Summary Methods for electrophoresis and specific staining of all of the enzymes of the glycolytic pathway are illustrated. Interspecies differences between the enzymes of moue and of human origin are readily demonstrated and are applicable to studies, in mouse-human hybrid cell clones, of linkage, chromosomal assignment, and regulation of the gene loci controlling glycolytic enzymes This study was supported by Grants 1-F03-HD 43122-01 and GM 15253 from the National Institutes of Health.     

The effect of enzyme-enzyme complexes on the overall glycolytic rate in vivo.

Recent studies have demonstrated that most glycolytic enzymes can reversibly associate to form heterogeneous enzyme-enzyme (binary) complexes in vitro. However, kinetic analysis of these complexes has shown that the individual enzymes have a varied response to complex formation: some enzymes are inhibited, some are activated and some are unaffected. In order to determine the potential role of binary complexes in regulating glycolytic flux, we have mathematically calculated enzyme distributions and activities using data from in vitro binding and kinetic studies. These calculations suggest that, overall, formation of binary complexes would lower flux through phosphofructokinase and aldolase, would increase flux through glyceraldehyde-3-phosphate dehydrogenase and lactate dehydrogenase, and would not affect flux through triosephosphate isomerase, phosphoglycerate kinase and pyruvate kinase. The implications of these results are discussed with respect to the effect of complex formation on overall glycolytic flux and on the flux through individual enzyme loci.     

Therapeutic Potential of Riboflavin,Niacin and Ascorbic Acid on Carbohydrate Metabolizing Enzymes in Secondary Endometrial Carcinoma Bearing Rats

Curative potential of riboflavin, niacin and ascorbic acid against tamoxifen mediated endometrial carcinoma was established by studies on carbohydrate metabolizing enzymes. The enzymes investigated were glycolytic enzymes namely, hexokinase; aldolase; phosphoglucoisomerase and the gluconeogenic enzymes namely, glucose-6-phosphatase and fructose-1, 6-biphosphatase in endometrial carcinoma bearing rats. A significant increase in glycolytic enzymes and a subsequent decrease in gluconeogenic enzymes were observed in plasma, liver and kidney of endometrial carcinoma animals. The administration of riboflavin (45 mg/kg bw/day), niacin (100 mg/kg bw/day) and ascorbic acid (200 mg/kg bw/day) along with tamoxifen (45 mg/kg bw/day) caused a significant decrease in the activity of glycolytic enzymes and a significant increase in the activities of gluconeogenic enzymes to near normal levels in experimental animals. Our results suggest that riboflavin, niacin and ascorbic acid have potential combination therapy against tamoxifen mediated secondary endometrial carcinoma in experimental rats. However, there were no deleterious side effects observed in combinants alone treated animals.     

Reconstructing the mosaic glycolytic pathway of the anaerobic eukaryote Monocercomonoides

All eukaryotes carry out glycolysis, interestingly, not all using the same enzymes. Anaerobic eukaryotes face the challenge of fewer molecules of ATP extracted per molecule of glucose due to their lack of a complete tricarboxylic acid cycle. This may have pressured anaerobic eukaryotes to acquire the more ATP-efficient alternative glycolytic enzymes, such as pyrophosphate-fructose 6-phosphate phosphotransferase and pyruvate orthophosphate dikinase, through lateral gene transfers from bacteria and other eukaryotes. Most studies of these enzymes in eukaryotes involve pathogenic anaerobes; Monocercomonoides, an oxymonad belonging to the eukaryotic supergroup Excavata, is a nonpathogenic anaerobe representing an evolutionarily and ecologically distinct sampling of an anaerobic glycolytic pathway. We sequenced cDNA encoding glycolytic enzymes from a previously established cDNA library of Monocercomonoides and analyzed the relationships of these enzymes to those from other organisms spanning the major groups of Eukaryota, Bacteria, and Archaea. We established that, firstly, Monocercomonoides possesses alternative versions of glycolytic enzymes: fructose-6-phosphate phosphotransferase, both pyruvate kinase and pyruvate orthophosphate dikinase, cofactor-independent phosphoglycerate mutase, and fructose-bisphosphate aldolase (class II, type B). Secondly, we found evidence for the monophyly of oxymonads, kinetoplastids, diplomonads, and parabasalids, the major representatives of the Excavata. We also found several prokaryote-to-eukaryote as well as eukaryote-to-eukaryote lateral gene transfers involving glycolytic enzymes from anaerobic eukaryotes, further suggesting that lateral gene transfer was an important factor in the evolution of this pathway for denizens of this environment.     

Biochemical mechanisms of red blood cell 2,3-diphosphoglycerate increase at high altitude

Red blood cell 2,3 diphosphoglycerate (2,3-DPG) levels increase after ascent to high altitude. Studies were undertaken to identify the biochemical mechanisms responsible for eliciting the 2,3-DPG response in several types of subjects. These included (1) short-term exposure to 3400 m in ten subjects; (2) exposure to 4300 m in an additional ten subjects; (3) studies in 28 high-altitude normal residents of 3100 m; and (4) studies in 28 high-altitude residents with chronic mountain polycythemia. Controls were 41 residents of 240 m. Regression analysis identified the glycolytic variables, termed “key variables,” on which variation in 2,3-DPG levels was dependent (P < .05). Key variables common to the short-term studies were glucose-6-phosphate, phosphoenolpyruvate, and the ratio of the levels of adenosine diphosphate to adenosine triphosphate. The positions of these key variables in the glycolytic pathway and their mean levels suggest erythrocyte hexokinase and pyruvate kinase activation as possible enzymatic mechanisms. Key variables unique to the 3400 m study suggested phosphofructokinase activation also acted to increase 2,3-DPG levels. 2,3-DPG levels in the normal 3100 m residents were not different from low-altitude values, and 2,3-DPG levels in these samples did not appear to be dependent on any of the glycolytic variables examined. Among the high-altitude residents with polycythemia, higher 2,3-DPG levels were dependent on glucose-6-phosphate, fructose diphosphate, dihydroxyacetone phosphate, and the ratio of adenosine diphosphate to adenosine triphosphate levels. The positions of these variables in the glycolytic pathway and their mean levels suggested activation of the hexokinase and phosphofructokinase enzymes.     

Multiple glycolytic enzymes are tightly bound to the fibrous sheath of mouse spermatozoa

The fibrous sheath is a cytoskeletal structure located in the principal piece of mammalian sperm flagella. Previous studies showed that glyceraldehyde 3-phosphate dehydrogenase, spermatogenic (GAPDHS), a germ cell-specific glycolytic isozyme that is required for sperm motility, is tightly bound to the fibrous sheath. To determine if other glycolytic enzymes are also bound to this cytoskeletal structure, we isolated highly purified fibrous sheath preparations from mouse epididymal sperm using a sequential extraction procedure. The isolated fibrous sheaths retain typical ultrastructural features and exhibit little contamination by axonemal or outer dense fiber proteins in Western blot analyses. Proteomic analysis using peptide-mass fingerprinting and MS/MS peptide fragment ion matching identified GAPDHS and two additional glycolytic enzyme subunits, the A isoform of aldolase 1 (ALDOA) and lactate dehydrogenase A (LDHA), in isolated fibrous sheaths. The presence of glycolytic enzymes in the fibrous sheath was also examined by Western blotting. In addition to GAPDHS, ALDOA, and LDHA, this method determined that pyruvate kinase is also tightly bound to the fibrous sheath. These data support a role for the fibrous sheath as a scaffold for anchoring multiple glycolytic enzymes along the length of the flagellum to provide a localized source of ATP that is essential for sperm motility.     

An investigation of lipogenic and glycolytic enzyme activity in the liver of sexually immature and mature domestic fowl

In the non-laying pullet and the cockerel it was observed that there was no significant variation in the activities of ATP citrate lyase and ;malic' enzyme whereas in the laying hen there was a significantly greater activity of both these enzymes. Parallel increases in liver lipid content in the laying hen were also observed. Three glycolytic enzymes, phosphofructokinase, fructose diphosphate aldolase and pyruvate kinase, did not exhibit any significant variation in enzyme activity with the onset of egg laying. These results are discussed in relation to the hormonal status of the birds and also the demands of egg production for lipid.     

Comparative levels between enzymes of the glycolytic pathway from erythrocytes and somatic tissues of the chicken Gallus gallus domesticus

A comparative study on the glycolytic enzymes from chicken erythrocytes and somatic tissues has been carried out, the results being shown as active units per mg protein in supernatants of 1085, 12,100 and 106,000 g fractionated centrifugation. The profiles of the glycolytic enzymes have been analyzed in terms of their activity relative to hexokinase and as the ratios between pairs of enzymes bearing a product-substrate relationship. Chicken erythrocyte displays a very peculiar profile of glycolytic enzymes. It possesses a FruP2-activated pyruvate kinase of the L isoenzyme type, which does not seem to be the predominant isoenzyme together with the M type, the content in glycolytic enzymes being much lower than in the somatic tissues.     

Co-ordinate control of phosphofructokinase and pyruvate kinase by fructose diphosphate: a mechanism for amplification and step changes in the regulation of glycolysis in liver

Activation of both phosphofructokinase and pyruvate kinase by fructose diphosphate in liver provides a means of amplifying effects of other activators or inhibitors in controlling the rate of glycolysis. Two types of behavior can occur, depending on the choice of affinity constants of the two enzymes for fructose diphosphate in a simple model: (i) there may be a steady state corresponding to each value of the fructose diphosphate concentration, so that the glycolytic rate is continuously variable, or (ii) there may be two (or more) regions of stable steady states, separated by a zone of instability, so that the system shifts abruptly between low and high glycolytic rates at critical concentrations of fructose diphosphate. A low glycolytic rate corresponds to net gluconeogenesis when the gluconeogenic enzymes are included. Calculations from data from perfused liver support the proposal that the free fructose diphosphate concentration is a major factor controlling glycolysis in liver and amplifying the effect of changes in the fructose 6-phosphate concentration which occur in response to variation in the glucose concentration.     

Targeting of Several Glycolytic Enzymes Using RNA Interference Reveals Aldolase Affects Cancer Cell Proliferation through a Non-glycolytic Mechanism

In cancer, glucose uptake and glycolysis are increased regardless of the oxygen concentration in the cell, a phenomenon known as the Warburg effect. Several (but not all) glycolytic enzymes have been investigated as potential therapeutic targets for cancer treatment using RNAi. Here, four previously untargeted glycolytic enzymes, aldolase A, glyceraldehyde 3-phosphate dehydrogenase, triose phosphate isomerase, and enolase 1, are targeted using RNAi in Ras-transformed NIH-3T3 cells. Of these enzymes, knockdown of aldolase causes the greatest effect, inhibiting cell proliferation by 90%. This defect is rescued by expression of exogenous aldolase. However, aldolase knockdown does not affect glycolytic flux or intracellular ATP concentration, indicating a non-metabolic cause for the cell proliferation defect. Furthermore, this defect could be rescued with an enzymatically dead aldolase variant that retains the known F-actin binding ability of aldolase. One possible model for how aldolase knockdown may inhibit transformed cell proliferation is through its disruption of actin-cytoskeleton dynamics in cell division. Consistent with this hypothesis, aldolase knockdown cells show increased multinucleation. These results are compared with other studies targeting glycolytic enzymes with RNAi in the context of cancer cell proliferation and suggest that aldolase may be a useful target in the treatment of cancer.     

Interactions between glycolytic enzymes of Mycoplasma pneumoniae

With only 688 protein-coding genes, Mycoplasma pneumoniae is one of the smallest self-replicating organisms. These bacteria use glycolysis as the major pathway for ATP production by substrate-level phosphorylation, suggesting that this pathway must be optimized to high efficiency. In this study, we have investigated the interactions between glycolytic enzymes using the bacterial adenylate cyclase-based two-hybrid system. We demonstrate that most of the glycolytic enzymes perform self-interactions, suggesting that they form dimers or other oligomeric forms. In addition, enolase was identified as the central glycolytic enzyme of M. pneumoniae due to its ability to directly interact with all other glycolytic enzymes. Our results support the idea of the formation of a glycolytic complex in M. pneumoniae and we suggest that the formation of this complex might ensure higher fluxes through the glycolytic pathway than would be possible with isolated non-interacting enzymes.     

Therapeutic Targeting of Cancer Metabolism with Triosephosphate Isomerase

The increase in glycolytic flux in cancer, known as aerobic glycolysis, is one of the most important hallmarks of cancer. Therefore, glycolytic enzymes have importance in understanding the molecular mechanism of cancer progression. Triosephosphate isomerase (TPI) is one of the key glycolytic enzymes. Furthermore, it takes a part in gluconeogenesis, pentose phosphate pathway and fatty acid biosynthesis. To date, it has been shown altered levels of TPI in various cancer types, especially in metastatic phenotype. According to other studies, TPI might be considered as a potential therapeutic target and a cancer‐related biomarker in different types of cancer. However, its function in tumor formation and development has not been fully understood. Here, we reviewed the relationship between TPI and cancer for the first time     

Intraspecific variation in aerobic metabolism and glycolytic enzyme expression in heart ventricles

A previous phylogenetic analysis among 15 taxa of the teleost fish Fundulus suggested that there should be thermal-adaptive differences in heart metabolism among populations. To test this hypothesis, the rate of oxygen consumption and the activities of all 11 glycolytic enzymes were measured in isolated heart ventricle from two populations of Fundulus heteroclitus. Heart ventricular metabolism is greater in a northern population versus a southern population of these fish. Analysis of the amount of glycolytic enzymes indicates that 87% of the variation in cardiac metabolism within and between populations is explained by the variation in three enzymes (pyruvate kinase, glyceraldehyde-3-phosphate dehydrogenase, and lactate dehydrogenase). These enzymes are the same three enzymes that were predicted to be important based on previously determined phylogenetic patterns of expression. Our data indicate that near-equilibrium enzymes, as well as classically defined rate-limiting enzymes, can also influence metabolism.