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Query: EC:2.7.1.1 (hexokinase)
 5,274 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

X-ray structure analysis of actin and of the NH2-terminal domain of the heat-shock cognate protein Hsc70 has revealed an unexpected extensive structural similarity between these two molecules. Despite the absence of significant similarity of their amino acid sequences, both proteins share the same core architecture and a common nucleotide binding site resembling the structure of hexokinase. All three are ATPases or kinases and bind ATP in association with Mg2+ or Ca2+. The common fold consists of two alpha/beta domains, which are connected by a putative hinge with an ATP-binding site situated between the domains. Each domain contains a five-stranded beta-sheet of identical topology, which suggests that the molecules may have evolved by gene duplication. From a comparison of the three aligned structures, a fingerprint sequence of the adenine nucleotide binding pocket was derived, which predicted that members of the glycerol kinase family should also have a similar fold of their nucleotide binding domain. This was later confirmed when the X-ray structure was published. Data base search with a refined consensus sequence has retrieved other sugar kinases, as well as the prokaryotic cell cycle proteins FtsA, MreB, and StbA, and two Escherichia coli phosphatases. These proteins are predicted to possess a structure similar to actin in the common core region. As exemplified for actin, Hsc70, and glycerol kinase, the diversity of biological function is provided by the polymorphism of the loops joining the beta-strands and helices in the core region and by inserted domains that show high variability.
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PMID:The actin fold. 778 19

The release of glucokinase (hexokinase IV) from digitonin-permeabilized hepatocytes from rat, guinea pig or mouse liver is inhibited by physiological concentrations of Mg2+ (> 0.25 mM). Preincubation of hepatocytes with fructose increases glucokinase release during permeabilization in the presence of Mg2+ but decreases glucokinase release in the absence of Mg2+, suggesting that fructose causes translocation of glucokinase from the Mg(2+)-dependent site. Glucose (25 mM) and sorbitol (1 mM) also induce translocation of glucokinase from the Mg(2+)-dependent site in guinea-pig, as in rat hepatocytes, but glucose is less effective than fructose or sorbitol, and the concentrations of fructose and sorbitol that cause half-maximal activation (A50) are 3-fold and 20-fold higher, respectively, in guinea-pig than in rat hepatocytes (170 microM and 257 microM, compared with 61 microM and 13 microM). Dihydroxyacetone and glycerol have no effect on fructose-induced or sorbitol-induced translocation in guinea-pig hepatocytes, in contrast with the potentiation and inhibition, respectively, by these substrates in rat hepatocytes. Some, but not all, of the differences between rat and guinea-pig hepatocytes could be due to the more reduced cytoplasmic NADH/NAD+ redox state in guinea-pig cells. The activity of low-Km hexokinases accounts for 30% of total hexokinase activity (low-Km hexokinases + glucokinase) in guinea-pig hepatocytes. Of the low-Km hexokinase activity, approx. 30% is released in the presence of Mg2+, 9% shows Mg(2+)-dependent binding and 60% shows Mg(2+)-independent binding. There was no substrate-induced translocation of low-Km hexokinase activity, indicating that translocation is specific for hexokinase IV.
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PMID:Hexokinase and glucokinase binding in permeabilized guinea-pig hepatocytes. 798 Apr 53

It was found that the ability of rat skeletal muscle hexokinase isozyme II binding to mitochondrial membranes is realized in full in the presence of Mg2+, glucose and putrescine as adsorption reagent. The hexokinase-membrane complexes obtained through the use of these reagents displayed similar stability as could be judged from their dissociation under identical conditions: either in the presence of KCl used in high concentrations or under the effect of a specific solubilization reagent--glucose-6-phosphate used in physiological concentrations. Within the composition of enzyme-membrane complexes hexokinase had the same kinetic properties which differed, however, from those of the nonbound to mitochondria enzyme. The data obtained are discussed in relation to the hexokinase isozyme II domain responsible for the specific binding of the enzyme to mitochondrial membranes and termed as the "adsorption domain". The availability of this domain is postulated in terms of the concept on the adsorption mechanism of hexokinase isozyme II activity control in skeletal muscles.
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PMID:[Hexokinase isoenzyme II has a segment responsible for specific interaction of the enzyme with mitochondrial membranes]. 807 46

An ATP-diphosphohydrolase (EC 3.6.1.5) was identified in the tegumental fraction isolated from Schistosoma mansoni worms. Both ATP and ADP were hydrolyzed to AMP at similar rates by the enzyme. Other nucleotides were also degraded by the tegument enzyme, revealing a broad substrate specificity. Electrophoretic separation of tegumental proteins under non-denaturing conditions followed by addition of ATP or ADP as substrate revealed a single band of activity with similar mobility. In addition, similar heat-inactivation profiles were obtained for ATPase or ADPase activities, indicating that a single enzyme is responsible for degrading both nucleotides. The enzyme was not inhibited by vanadate, levamisole, tetramisole, ouabain or sodium azide. The ADPase activity was not affected by adenosine (5')-pentaphospho-(5')-adenosine (Ap5A) or by an excess of glucose and hexokinase used as an ATP-trapping system, thus excluding the presence of any significant adenylate kinase activity. The ATP-diphosphohydrolase displayed micromolar affinities for both Mg2+ and Ca2+, and the calcium-activated enzyme was inhibited by millimolar Mg2+. In intact live worms a calcium phosphate precipitate was formed on the outer tegumental surface upon incubation of the worms with either ATP or ADP, indicating the ectolocalization of this enzyme. In addition, ultrastructural histochemical localization of the enzyme was obtained. A distinct deposition of lead phosphate granules on the outer surface of the tegument was observed by electron microscopy, in the presence of either ATP or ADP as substrate. It is suggested that the ATP-diphosphohydrolase could regulate the concentration of purine nucleotides around the parasites and hence enable them to escape the host hemostasis by preventing ADP-induced platelet activation.
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PMID:Characterization and localization of an ATP-diphosphohydrolase on the external surface of the tegument of Schistosoma mansoni. 847 45

1. Single channel current recordings were used to study the characteristics of a large conductance Ca(2+)-activated K+ (BKCa) channel present in neurones acutely dissociated from the rat motor cortex. Application of ATP to the intracellular surface of excised inside-out patches produced a large, concentration-dependent increase in BKCa channel activity. 2. This ATP-mediated activation was dependent upon the presence of Mg2+ in the intracellular bathing solution and was diminished by the phosphatases 2,3-butanedione monoxime (BDM) or alkaline phosphatase and by the protein kinase inhibitors staurosporine, H-7 and PKI. 3. ADP stimulated BKCa channel activity in a Mg(2+)-dependent manner, an action also inhibited by the concomitant application of PKI or BDM. The effect of ADP was reduced by application of hexokinase and glucose or by application of the adenylate kinase inhibitor Ap5A. 4. Of other nucleotides tested, only CTP consistently activated BKCa channel activity. 5. Using the cell-attached configuration, bath application of forskolin or dibutyryl cAMP stimulated BKCa channel activity. 6. It is concluded that BKCa channel activity in the rat motor cortex is subject to modulation by the activity of a closely associated kinase. The ability of cAMP activators to stimulate BKCa channel activity in the intact cell suggests that this system may be of physiological importance.
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PMID:Characterization of an ATP-modulated large conductance Ca(2+)-activated K+ channel present in rat cortical neurones. 856 73

The interaction of ATP with the active site of hexokinase is unknown since the crystal structure of the hexokinase-ATP complex is unavailable. It was found that the ATP binding site of brain hexokinase is homologous to that of actin, heat shock protein hsc70, and glycerol kinase. On the basis of these similarities, the ATP molecule was positioned in the catalytic domain of human brain hexokinase, which was modeled from the X-ray structure of yeast hexokinase. Site-directed mutagenesis was performed to test the function of residues presumably involved in interaction with the tripolyphosphoryl moiety of ATP. Asp532, which is though to be involved in binding the Mg2+ ion of the MgATP2- complex, was mutated to Lys and Glu. The kcat values decreased 1000- and 200-fold, respectively, for the two mutants. Another residue, Thr680 was proposed to interact with the gamma-phosphoryl group of ATP through hydrogen bonds and was mutated to Val and Ser. The kcat value of the Thr680Val mutant decreased 2000-fold, whereas the kcat value of the Thr680Ser decreased only 2.5-fold, implying the importance of the hydroxyl group. The Km and dissociation constant values for either ATP or glucose of all the above mutants showed little or no change relative to the wild-type enzyme. The Ki values for the glucose 6-phosphate analogue 1,5-anhydroglucitol 6-phosphate, were the same as that of the wild-type enzyme, and the inhibition was reversed by inorganic phosphate (Pi) for all four mutants. The circular dichroism spectra of the mutants were the same as that of the wild-type enzyme. The results from the site-directed mutagenesis demonstrate that the presumed interactions of investigated residues with ATP are important for the stabilization of the transition state.
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PMID:ATP-binding site of human brain hexokinase as studied by molecular modeling and site-directed mutagenesis. 885 53

31P NMR was used to measure the intracellular free magnesium concentration ([Mg2+]i) in human erythrocytes while [Mg2+]i was changed between 0.01 and 1.2 mM using the divalent cationophore A23187. 13C NMR and [2-13C]glucose were used to determine the kinetic effects of [Mg2+]i by measuring the flux through several parts of the glucose pathway. Glucose utilization was strongly dependent on [Mg2+]i, with half-maximal flux occurring at 0.03 mM. The rate-limiting step was most likely at phosphofructokinase, which has a Km(Mg2+) of 0.025 mM in the purified enzyme. Phosphorylated glycolytic intermediate concentration was also strongly dependent on [Mg2+]i and [MgATP], and glucose transport plus hexokinase may have been partially rate-determining at [Mg2+]i below approximately 0.1 mM. The pentose phosphate shunt activity was too low to determine the dependence on [Mg2+]i. Phosphoglycerate kinase and 2, 3-diphosphoglycerate mutase fluxes were also measured, but were not rate-limiting for glycolysis and showed no Mg2+ dependence. Human erythrocyte [Mg2+]i varies between 0.2 mM (oxygenated) and 0.6 mM (deoxygenated), well above the measured [Mg2+]i(1/2). It is unlikely, then, that [Mg2+]i plays a regulatory role in normal erythrocyte glycolysis.
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PMID:The regulatory role for magnesium in glycolytic flux of the human erythrocyte. 891 May 48

Hexokinase and D-glucose-6-phosphate dehydrogenase (G6PDH) from Schizosaccharomyces pmbe have been purified 250-fold by an identical three-step. Both enzymes are dimeric with a molecular mass of 88 kDa for the kinase and 112 kDa for the dehydrogenase. Steady-state kinetic studies were performed on hexokinase and G6PDH, which form the glucose phosphate branch of the oxidative pentose phosphate pathway of S. pombe (fission yeast). Hexokinase promotes Mg(2+)-activated phosphorylation of D-glucose by the equilibrium random Bi Bi mechanism with formation of the abortive enzyme-ADP-glucose complex. ADP inhibits the kinase competitively versus ATP and noncompetitively versus D-glucose. The Mg2+ activation of hexokinase is associated with an increase in the maximal velocity by its interaction with the ternary complex to facilitate the transfer of the phosphoryl group. G6PDH catalyzes NADP(+)-linked oxidation of D-glucose-6-phosphate by the ordered Bi Bi mechanism with NADP+ as the leading reactant. High NADP+ concentration inhibits the dehydrogenase by forming the dead-end ternary complex. In addition, G6PDH is also subjected to product inhibition by NADPH and noncompetitive inhibition by A(G)TP. Thus, the oxidative pentose phosphate pathway in S. pombe may be regulated via inhibition of hexokinase by ADP in conjunction with inhibition of G6PDH by NADPH and ATP.
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PMID:Purification and kinetic characterization of hexokinase and glucose-6-phosphate dehydrogenase from Schizosaccharomyces pombe. 966 12

Changes in amount and activity of enzyme protein are critical factors in regulating intracellular metabolisms. However, since the metabolisms are proceeding in environment with complex architecture consisted of various membranes, spatial factors should be taken into consideration for the regulation. In this review, involvement of interaction between cytosolic and membrane proteins in metabolic regulation are discussed. It had been reported that hexokinase activity was found in mitochondrial fraction in spite of almost exclusive distribution of other glycolytic enzymes to soluble fraction, the tendency being marked in the brain and many types of tumor cells whereas mitochondrial hexokinase activity was quite low in the liver. Interested in such enzyme and tissue specificities, we investigated the significance and mechanism of the unique intracellular distribution of hexokinase. We found that mitochondria-bound hexokinase was more active than the cytosolic type in producing glucose 6-phosphate (G6P), probably due to the advantage in utilizing ATP produced in mitochondria. In addition, we also found that the binding stabilized hexokinase against G6P inhibition. As to the binding, it was reported that G6P released hexokinase from mitochondria while Mg2+ promoted the binding. In this respect, we found that polyamines promoted the binding at much lower concentration than that of Mg2+, and mitochondria-bound form had small hydrophobic domain at terminal region for the binding to porin on the outer membrane. Then, we found a protease which specifically cleaved the domain with little effect on catalytic activity and molecular size of the bindable form. Such a modifying protease was purified and identified as lysosomal cathepsin L. The protease activity was high in the liver and low in the brain, suggesting that the difference in the activity was responsible for the afore-mentioned tissue specificity. On the other hand, we examined regulatory mechanism for active oxygen production in neutrophils, since the production of superoxide anion (O2-) by NADPH oxidase was very low at the resting state while markedly increased on phagocytosis and chemical stimulation. Since the stimulants for the activation were so various in chemical nature, we postulated mechanism to converge the stimulation to the activation. Incidentally, we found increase in phosphorylation of 46-47 K protein, irrespective of the type of stimulation. Use of inhibitors and examination on the phosphorylation condition indicated protein kinase C (PKC) as the phosphorylating enzyme. In addition, we observed the 46-47 K protein existed in cytosol at resting state, while it was translocated to cell membranes in concurrence with the phosphorylation. Similar findings were obtained in many laboratories and those proteins were named cytosolic activating factors (and then p47-phox, etc.). These proteins associate with membrane proteins to constitutes the active from of NADPH oxidase. Next, we examined mechanism to shut off the O2- production, and found that the inactivation through disassembly of the constituents was attained by dephosphorylation of phosphorylated p47-phox by cytosolic protein phosphatase. Then we have also found that protein kinases other than PKC were involved in regulation of NADPH oxidase activity. Though phosphorylation of p47-phox etc. is deeply involved in the activation of NADPH oxidase, membrane perturbation, so-called priming, is required for the activation. We also reported some possible indications for the priming, and possible involvement of cytoskeletons in O2- production. Apart from protein phosphorylation, it has been reported that amphiphilic acidic compounds are potent activator for NADPH oxidase. We also have examined their effects to find that these compounds also caused the assembly of the NADPH oxidase constituents. Reversely, amphiphilic basic compounds suppressed suggesting significance of introduction of negative charge in NADPH oxidase activat
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PMID:[Cooperation of membrane proteins and cytosolic proteins in metabolic regulation--involvement of binding of hexokinase to mitochondria in regulation of glucose metabolism and association and complex formation between membrane proteins and cytosolic proteins in regulation of active oxygen production]. 992 8

The association of rat brain hexokinase with heterologous recombinant yeast mitochondria harboring human porin (Yh) is comparable to that with rat liver mitochondria in terms of cation requirements, cooperativity in binding, and the effect of amphipathic compounds. Mg2+, which is required for hexokinase binding to all mitochondria, can be replaced by other cations. The efficiency of hexokinases, however, depends on the valence of hydrophilic cations, or the partition of hydrophobic cations in the membrane, implying that these act by reducing a prohibitive negative surface charge density on the outer membrane rather than fulfilling a specific structural requirement. Macromolecular crowding (using dextran) has dual effects. Dextran added in excess increases hexokinase binding to yeast mitochondria, according to the porin molecule they harbor. This effect, significant with wild-type yeast mitochondria, is only marginal with Yh as well as rat mitochondria. On the other hand, an increase in the number of hexokinase binding sites on mitochondria is also observed. This increase, moderate in wild-type organelles, is more pronounced with Yh. Finally, dextran, which has no effect on the modulation of hexokinase binding by cations, abolishes the inhibitory effect of amphipathic compounds. Thus, while hexokinase binding to mitochondria is predetermined by the porin molecule, the organization of the latter in the membrane plays a critical role as well, indicative that porin must associate with other mitochondrial components to form competent binding sites on the outer membrane.
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PMID:Binding of rat brain hexokinase to recombinant yeast mitochondria: identification of necessary physico-chemical determinants. 1080 96


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