Crystalline hexokinase,heterophosphatase; method of isolation and properties

1. Crystalline hexokinase has been isolated from baker''s yeast. 2. Crystalline hexokinase is a protein of albumin type of a molecular weight of 96,000. Its isoelectric point is at about pH 4.8. 3. The method of isolation consists in separating the proteins of an aqueous extract of toluene-treated yeast by means of fractional precipitation with ammonium sulfate and with alcohol. 4. The procedure involves also the separation of several crystalline proteins, including one yellow crystalline protein, which do not possess hexokinase activity. The biological and the physicochemical properties of these proteins are still under investigation. 5. The crystallization of hexokinase proceeds at about 5°C. in the presence of ammonium sulfate and dilute phosphate buffer pH 7.0. 6. Crystalline hexokinase becomes relatively pure after 2 or 3 recrystallizations as tested by solubility, sedimentation in the ultracentrifuge, and electrophoresis. The enzymatic activity remains constant on repeated crystallization. 7. The enzymatic activity is associated with the protein nature of the material. Inactivation is accompanied by denaturation of the protein. 8. Crystalline hexokinase is relatively stable when stored in the form of crystalline filter cake. Solutions of hexokinase in dilute buffers are most stable at pH 5.0. 9. Crystalline hexokinase requires the presence of magnesium ions for its catalytic activity.     

PROPERTIES OF MEMBRANE-BOUND HEXOKINASE IN RAT BRAIN

Abstract— —-(1) The total hexokinase activity present in the mitochondrial fraction can be solubilized completely by incubation with salt and Triton X-100. This activity cannot be entirely released by washing with sucrose or by freezing and thawing.
(2) A part of the particle bound hexokinase exists in a latent form. The latent form is apparent after incubation with high salt concentrations, detergents or by freezing and thawing.
(3) Solubilization of membrane bound hexokinase is pH-dependent. Incubation in salt solutions increases the specific activity ten-fold. The salt concentration and pH are con-current. At pH 7.0 part of the hexokinase is solubilized. The lower the pH the less salt is required to release the same amount of activity.
(4) Triton X-100 solubilizes particle-bound hexokinase, but to a less extent than salts. The activation of hexokinase is greater with Triton X-100 than with salt.
(5) The possible nature of the bonds between hexokinase and mitochondrial membranes is discussed.     

The localization of hexokinase isoenzymes in red and white skeletal muscles of the rat

Summary Maximum assayable hexokinase activities vary with the proportion of red, fast-twitch, oxidative-glycolytic and intermediate, slow-twitch, oxidative fibres in different rat skeletal muscles. The major isoenzymic form, type II hexokinase, is present throughout the intermyofibrillar sarcoplasm in all fibres but a proportion of the total activity appears to be weakly associated with mitochondria. Variations in the histochemical staining intensity between fibre types correlate with their mitochondrial content and seem to be due mainly to differences in mitochondrially-associated hexokinase activity. Changes in the strength of this association may be important in controlling increases in glucose metabolism in response to prolonged increased muscular activity while regulation of the equilibrium between free and loosely-bound forms may be an important control feature in all skeletal muscle. Type I hexokinase is a minor isoenzymic component of skeletal muscle and occurs mainly in blood vessels and nerves in the perimysia and endomysia. The majority of this isoenzyme is tightly bound to mitochondria and is not detectable in homogenates prepared in the absence of Triton X-100.     

CO2 mass transfer and acid-base balance under conditions of muscular activity at sea level and in the mountains

The state of the blood acid-base balance and dynamics of carbonic acid gas mass transfer were studied in sportsmen at the sea level and in mountains. It is shown that at the sea level due to an intensive muscular activity large amounts of CO2 are formed and excreted; the mass transfer of this gas is multiply accelerated, simultaneously, a pronounced decompensated metabolic acidosis is observed which in some cases is complicated respiratory acidosis. The similar exercises in mountains are followed by a more pronounced disturbance in the acid-base balance and a more intensified mass-transfer of CO2. After 12-day acclimatization and training in mountains the buffer blood capacity increases, the metabolic acidosis under conditions of muscular activity is less pronounced.     

Stabilization of hexokinases I and II of ELD cells by binding to mitochondria

Significance of the binding of hexokinase to mitochondria was examined with respect to stabilization of the enzyme by the binding. Stability during the incubation of the mitochondria-bound forms of hexokinases I and II, both prepared from Ehrlich-Lettre ascites hyperdiploid tumor cells (ELD cells), were compared with that of the corresponding free forms. During the incubation at pH 7.4 and 37 degrees C up to 60 min, hexokinase activities decreased gradually, and the decrease in the activity of the free form was much more marked than that of the bound form for both hexokinases. Hexokinase II was much less stable than I, and the activity of the free form of the former was almost lost by the incubation for 15 min. But, more than a half of the original activity of hexokinase II was retained even after 60 min of the incubation when the enzyme was bound to mitochondria. Addition of 50 mM glucose increased the stability of hexokinase II, but the stabilizing effect was less marked for hexokinase I. On the other hand, addition of 28 mg/ml of bovine serum albumin markedly stabilized hexokinase I to almost the same extent as was observed with mitochondria. On the contrary, the serum albumin had little stabilizing effect on hexokinase II. These findings indicate that the binding to mitochondria stabilizes the hexokinases of ELD cells, though the stability is different by nature between hexokinases I and II.     

The binding of glycerol kinase to the outer membrane of rat liver mitochondria: its importance in metabolic regulation

Glycerol kinase was found to associate with the hexokinase binding protein. The binding of glycerol kinase has a high specificity as illustrated by the fact that the magnitude of binding was reduced by glycerophosphate and antibodies against the hexokinase binding protein. A possible function of glycerol kinase binding to the mitochondria with respect to metabolic regulation is proposed for the following reasons: (i) Glycerol kinase seems to bind to the same binding protein as hexokinase. (ii) Both kinases were observed to be reversibly bound to the mitochondria in different metabolic situations, i.e., 10% of total cellular activity from both kinases is bound in starved rats whereas no activity of glycerol kinase and 30% of hexokinase become bound in fed rats. (iii) The kinetic properties of the associated glycerol kinase change in an analogous manner to those known for structure-bound hexokinase. (iv) With the binding of glycerol kinase to the mitochondria, it is possible to propose a metabolic pathway for glycerol oxidation to dihydroxyacetone phosphate by a combined action involving the enzyme, glycerol phosphate oxidase, and oxidative phosphorylation.     

Rat red blood cell hexokinase purification,properties and age-dependence

Summary Rat erythrocytes, in contrast to red blood cells from other mammals, have been shown to contain only one hexokinase isozymic form identified as type I by chromatographic and kinetic properties. Rat reticulocytes contain 3.6-times the hexokinase activity found in mature erythrocytes but exactly the same isozyme. By a combination of ion-exchange chromatography, dye-ligand chromatography and high-pressure liquid chromatography the rat erythrocyte hexokinase was purified more than 84 000-fold to a specific activity of 143 units/mg protein and shown to be homogeneous by sodium dodecyl sulfate-gel electrophoresis. The native protein showed a molecular weight of 100 000 by gel-filtration and an apparent molecular weight of 98 000 under denaturating conditions in sodium dodecyl sulfate-gel electrophoresis. The isoelectric point was shown to be 6.3 pH units. This data provides evidence of only one form of hexokinase in the erythrocytes of a mammal.     

Dissociation and catalysis in yeast hexokinase A.

1. The specific activity of yeast hexokinase A depends on the concentration of the protein in the solution being assayed. When a solution containing 13.5 mg of hexokinase A/ml is diluted 10--100-fold at various values of pH and temperature, there is a gradual decline in the specific activity of the enzyme until an equilibrium value is reached, which varies with the chosen experimental conditions. 2. The catalytic activity lost when hexokinase A (1 mg/ml) is incubated at 30degreesC is recovered by lowering the temperature to 25degreesC. 3. These concentration- and temperature-dependent phenomena are consistent with the existence of a monomer-dimer equilibrium in which the dimer alone is the catalytic form of the enzyme. 4. Glucose alone prevents the decline in specific activity of hexokinase A after dilution, but it does not re-activate dilute solutions solutions of the enzyme. It is concluded that glucose binds to both the dimer and the monomer and prevents both association and dissociation. 5. The progress curve describing the phosphorylation of glucose catalysed by hexokinase A does not attain a steady state. It is possible that dissociation of catalytically active dimers in a ternary complex with glucose and ATP (or glucose 6-phosphate and ADP) could explain the non-linearity of this progress curve.     

31P NMR and 13C NMR studies of recombinant Saccharomyces cerevisiae with altered glucose phosphorylation activities

Manipulation of cellular metabolism to maximize the yield and rate of formation of desired products may be achieved through genetic modification. Batch fermentations utilizing glucose as a carbon source were performed for three recombinant strains of Saccharomyces cerevisiae in which the glucose phosphorylation step was altered by mutation and genetic engineering. The host strain (hxk1 hxk2 glk) is unable to grow on glucose or fructose; the three plasmids investigated expressed hexokinase PI, hexokinase PII, or glucokinase, respectively, enabling more rapid glucose and fructose phosphorylation in vivo than that provided by wild-type yeast.Intracellular metabolic state variables were determined by ³¹P NMR measurements of in vivo fermentations under nongrowth conditions for high cell density suspensions. Glucose consumption, ethanol and glycerol production, and polysaccharide formation were determined by ¹³C NMR measurements under the same experimental conditions as used in the ³¹P NMR measurements. The trends observed in ethanol yields for the strains under growth conditions were mimicked in the nongrowth NMR conditions.Only the strain with hexokinase PI had higher rates of glucose consumption and ethanol production in comparison to healthy diploid strains in the literature. The hexokinase PII strain drastically underutilized its glucose-phosphorylating capacity. A regulation difference in the use of magnesium-free ATP for this strain could be a possible explanation. Differences in ATP levels and cytoplasmic pH values among the strains were observed that could not have been foreseen. However, cytoplasmic pH values do not account for the differences observed among in vivo and in vitro glucose phosphorylation activities of the three recombinant strains.     

Hexose metabolism in pancreatic islets: compartmentation of hexokinase in islet cells

Hexokinase activity was found in both soluble (cytosolic) and particulate subcellular fractions prepared from rat pancreatic islet homogenates. The bound enzyme was associated with mitochondria rather than secretory granules. Relative to the total hexokinase activity, the amount of bound enzyme was higher in islet homogenates prepared at pH 6.0 (72 +/- 7%) than in islets homogenized at pH 7.4 (38 +/- 1%). The affinity of hexokinase for equilibrated D-glucose was not different in the cytosolic and mitochondrial fractions. In both fractions, hexokinase displayed a greater affinity for alpha- than beta-D-glucose, but a higher maximal velocity with the beta- than alpha-anomer. Glucose 6-phosphate inhibited to a greater extent cytosolic than mitochondrial hexokinase. A high Km glucokinase-like enzymic activity was also present in both subcellular fractions. It is proposed that the ambiguity of hexokinase plays a propitious role in the glucose-sensing function of pancreatic islet cells.     

The role of the mitochondrial outer membrane in energy metabolism of tumor cells

The outer mitochondrial membrane contains a pore structure which is composed of a 30,000 Da protein, porin. The pore has an internal diameter of 2 nm and exhibits a molecular-sieving exclusion limit between 3000 and 6000 Da. These pores, therefore, provide the exit/entrance port for metabolites moving between mitochondria and the cytosol. Hexokinase binds to porin on the outer surface of mitochondria. The location of hexokinase has evoked a number of theories in which bound hexokinase is given a central role in regulating glycolysis, and, perhaps, the metabolic communication between oxidative and glycolytic metabolism. This is of particular importance in rapidly growing tumor cells in which the aerobic production of lactate and hexokinase activity are highly induced. In the present paper, we summarize the suggested roles of the outer membrane and bound hexokinase in regulation glycolysis of tumor cells. Experiments attempting to elucidate the role of hexokinase binding in the regulation of tumor cell metabolism are presented.     

Effects of activators on chemically modified yeast hexokinase.

Enzymic studies performed with chemically modified yeast hexokinase (ATP : D-hexose-6-phosphotransferase) confirm previous results indicating that the sulfhydryl, imidazol and most of the reactive amino groups do not seem to be directly implicated in the enzyme active site. On the other hand the modification of these functional groups of the enzyme does not affect the transition between the acidic inactive form to an active enzyme form after deprotonation. The chemically modified forms of hexokinase and the native enzyme are affected in the same way by activators (citrate, D-malate, 3-phosphoglycerate and Pi) when the activity was measured at pH 6.6. Moreover the loss of enzyme activity observed in the course of the chemical modifications is accompanied by an increase of the activation effect. This increase must be related to some reorganization of the enzyme active site in presence of the effectors, since the same effect was observed when hexokinase was denatured with 3M urea at pH 7.5. However no increase in the activation effect was observed when the denaturation was carried out at pH 6.5 At this pH the loss in activity and the change of optical absorption at 286 nm were much slower than at pH 7.5, which indicates a great difference in the protein structure between these pHs.     

Study on ATP-generating system and related hexokinase activity in mitochondria isolated from undifferentiated or differentiated HT29 adenocarcinoma cells

The functional properties of mitochondria bound hexokinase are compared in two subpopulations of the HT29 human colon cancer cell-line: (1) the HT29 Glc+ cells, cultured in the presence of glucose, which are poorly differentiated and highly glycolytic and (2) the HT29 Glc- cells, adapted to grow in a glucose-free medium, which are 'enterocyte-like' differentiated and less glycolytic when given glucose (Zweibaum et al. (1985) J. Cell Physiol. 122, 21-28). The activities of hexokinase, phosphofructokinase-1 and pyruvate kinase are found to be twice as high in Glc+ cells when compared to Glc- cells. Besides, the respiration rate is decreased in Glc+ cells compared to Glc- cells. These results correlate with the higher glycolytic rate in Glc+ cells. In many tissues, it has been shown that the binding of hexokinase to the mitochondrial outer membrane allows a preferential utilization of the ATP generated by oxidative phosphorylation which, in turn, is activated by immediate restitution of ADP. In highly glycolytic cancer cells, although a large fraction of hexokinase is bound to the mitochondria, the existence of such a channeling of nucleotides is still poorly documented. The rates of glucose phosphorylation by bound hexokinase were investigated in mitochondria isolated from both Glc+ and Glc- cells either with exogenous ATP or with ATP generated by mitochondria supplied with ADP and succinate (endogenous ATP). Diadenosine pentaphosphate (Ado2P5), oligomycin and carboxyatractyloside (CAT) were used in combination or separately as metabolic inhibitors of adenylate kinase, ATP synthase and ATP/ADP translocator, respectively. Exogenous ATP appears to be 6.5-times more efficient than endogenous ATP in supporting hexokinase activity in the mitochondria from Glc+ cells and only 1.8-times cells. The rate of oxidative phosphorylation being higher in mitochondria from Glc- cells, hexokinase activity is higher in this model when ATP is generated by respiration. Furthermore, in Glc+ mitochondria, the adenylate kinase reaction appears to be an important source of endogenous ATP for bound hexokinase, while, in Glc- mitochondria, hexokinase activity is almost totally dependent on the ATP generated by oxidative phosphorylation. This result might be explained by our previous finding that mitochondria from Glc+ cells lack contact sites between outer and inner membrane, whereas numerous contacts were observed in mitochondria from Glc- cells (Denis-Pouxviel et al. (1987) Biochim. Biophys. Acta 902, 335-348).     

Kinetic properties of hexokinase under near-physiological conditions. Relation to metabolic arrest in Artemia embryos during anoxia

Previous analyses of glycolytic metabolites in Artemia embryos indicate that an acute inhibition of glucose phosphorylation occurs during pHi-mediated metabolic arrest under anoxia. We describe here kinetic features of hexokinase purified from brine shrimp embryos in an attempt to explain the molecular basis for this inhibition. At saturating concentrations of cosubstrate, ADP is an uncompetitive inhibitor toward glucose and a partial noncompetitive inhibitor toward ATP (Kis = 0.86 mM, Kii = 1.0 mM, Kid = 1.9 mM). With cosubstrates at subsaturating concentrations, the uncompetitive inhibition versus glucose becomes noncompetitive, while inhibition versus ATP remains partial noncompetitive. The partial noncompetitive inhibition of ADP versus ATP is characterized by a hyperbolic intercept replot. These product inhibition patterns are consistent with a random mechanism of enzyme action that follows the preferred order of glucose binding first and glucose-6-P dissociating last. We propose that inhibition by glucose-6-P (Kis = 65 microM) occurs primarily by competing with ATP at the active site, resulting in the formation of the dead-end complex, enzyme-glucose-glucose-6-P. Versus glucose, inhibition by glucose-6-P is uncompetitive at pH 8.0 and noncompetitive at pH 6.8. Over a physiologically relevant pH range of 8.0 to 6.8 alterations in Km and Ki values do not account for the reduction in glucose phosphorylation, and no evidence suggests that Artemia hexokinase activity is modulated by reversible binding to intracellular structures. Total aluminum in the embryos is 4.01 +/- 0.36 micrograms/g dry weight, or, based upon tissue hydration, 72 microM. This concentration of aluminum dramatically reduces enzyme activity at pH values less than 7.2, even in the presence of physiological metal ion chelators (citrate, phosphate). When pH, aluminum, citrate, phosphate, substrates, and products were maintained at cellular levels measured under anoxia, we can account for a 90% inhibition of hexokinase relative to activity under control (aerobic) conditions.     

Estimation of fructokinase in crude tissue preparations

An assay for fructokinase activity is described that permits an accurate estimation of specific fructokinase in crude tissue preparations without interference of hexokinase activity. It utilizes two properties of hexokinases which differentiate hexokinase from fructokinase: (1) hexokinase activity is more labile to [H⁺] than is fructokinase, and (2) hexokinase activity is markedly inhibited by N-acetylglucosamine while fructokinase activity is relatively unaffected.     

Periodic muscular activity and its possible functions in pupae of Tenebrio molitor

Abstract. During pupal development, Tenebrio molitor L. show regular periods of rhythmic muscular contractions and associated body movements. These periods of activity last 2.5-5.8 min and are more frequent in newly ecdysed pupae ( c. 3h^-1). They become less frequent ( c. 1.5 h^-1) when the basal metabolism reaches its lowest level. In the pharate adult stage the clear pattern of muscular activity disappears.
Muscular activity is temperature-dependent and is commonly absent below 20C. Muscular activity did not disturb the cyclic output of CO₂, which is characteristic of metamorphosis. The heart shows characteristic periods (1–3 min) of activity during pupal development. The frequency of these heart pulsation periods depends on metabolic rate. Heart pumping was correlated mostly with muscular contractions. Therefore we suggest that the main physiological function of muscular activity is to support circulation.     

Relationship between brain mitochondrial hexokinase and neuronal function

Mitochondrially bound brain hexokinase is solubilized by anesthetics and this effect has been suggested to contribute to anesthesia. In the present investigation the influence of the metabolic inhibitor 2-deoxy-D-glucose (2-DOG) was studied. An isolated rat brain preparation was used to avoid the contribution of peripheral reactions. Isolated rat brains were perfused for 45 min with media containing 4 mmol/l glucose, 10 mmol/l 2-DOG and/or 0.4 mmol/l thiopental. The EEG was monitored and acetylcholine, 2-DOG and its 6-phosphate, as well as the intracellular distribution of hexokinase activity were determined in brain tissue. Soluble hexokinase activity in brain cortex was enhanced by 2-DOG, as also by thiopental, and even more pronounced by both drugs used together. Results from in vitro experiments suggest that solubilization of mitochondrial hexokinase after 2-DOG is mediated by intracellularly accumulated 2-DOG-6-phosphate. 2-DOG produced a significant impairment of neuronal activity, revealing EEG patterns similar to those caused by thiopental anesthesia. Cortical acetylcholine levels were elevated by 2-DOG, as well as by thiopental, and again both drugs showed an additive effect when used in combination. This effect which may be the result of an inhibition of acetylcholine release, was also detectable in mice in vivo after 5 g 2-DOG/kg i.p., whereas the same dose of 3-O-methylglucose had no effect. The results provide further evidence that mitochondrial hexokinase may be involved in the relationship between cerebral metabolism and brain function.A preliminary report of these results has been made at the 22^nd spring meeting of the Deutsche Pharmakologische Gesellschaft at Mainz (38).     

Hexokinase and glucose-phosphoenolpyruvate phosphotransferase synthesis in Klebsiella aerogenes strains growing in continuous culture.

Considerable differences in steady-state hexokinase specific activity were found in 16 N.C.I.B. strains of Klebsiella aerogenes grown in identical conditions in glucose-limited chemostats. Strains of N.C.I.B. 8258 had no detectable activity, but its glucose-phosphoenolpyruvate phosphotransferase specific activity and that of the other strains were closely similar, and it is concluded that this phosphotransferase activity regulates the overall utilization of glucose, in which hexokinase plays no essential role. The hexokinase activity was subject to regulation by the availability of phosphorus, but this did not affect the glucose phosphotransferase activity. tlactose-grown organisms (including strain N.C.I.B. 8258) had no glucose phosphotransferase activity, but more than adequate hexokinase activity to phosphorylate the intracellularly liberated glucose.     

Inactivation of yeast hexokinase by o-phthalaldehyde: evidence for the presence of a cysteine and a lysine at or near the active site

Yeast hexokinase (ATP:D-hexose 6-phosphotransferase, EC 2.7.1.1), a homodimer, was rapidly and irreversibly inactivated by o-phthalaldehyde at 25 degrees C (pH 7.3). The reaction followed pseudo-first-order kinetics over a wide range of the inhibitor concentration. The second-order-rate constant for the inactivation of hexokinase was estimated to be 45 M-1.s-1. Hexokinase was protected more by sugar substrates than by nucleoside triphosphates during inactivation by o-phthalaldehyde. Absorption spectrum (lambda max 338 nm), and fluorescence excitation (lambda max 363 nm) and emission (lambda max 403 nm) spectra of the hexokinase-o-phthalaldehyde adduct were consistent with the formation of an isoindole derivative. These results also suggest that sulfhydryl and epsilon-amino functions of the cysteine and lysine residues, respectively, participating in the isoindole formation are about 3 A apart in the native enzyme. About 2 mol of the isoindole per mol of hexokinase dimer were formed following complete loss of the phosphotransferase activity. Chemical modification of hexokinase by iodoacetamide in the presence of mannose resulted in the modification of six sulfhydryl groups per mol of hexokinase with retention of the phosphotransferase activity. Subsequent reaction of the iodoacetamide modified hexokinase with o-phthalaldehyde resulted in complete loss of the phosphotransferase activity with concomitant modification of the remaining two sulfhydryl groups of hexokinase. Chemical modification of hexokinase by iodoacetamide in the absence of mannose resulted in complete inactivation of the enzyme. The iodoacetamide inactivated hexokinase failed to react with o-phthalaldehyde as evidenced by the absence of a fluorescence emission maximum characteristic of the isoindole derivative. The holoenzyme failed to react with [5'-(p-fluorosulfonyl)benzoyl]adenosine. The dissociated hexokinase could be inactivated by [5'-(p-fluorosulfonyl)benzoyl]adenosine; the degree of inactivation paralleled the extent of reaction between o-phthalaldehyde and the nucleotide-analog modified enzyme. Thus, it is concluded that two cysteines and lysines at or near the active site of the hexokinase were involved in reaction with o-phthalaldehyde following complete loss of the phosphotransferase activity. An important finding of this investigation is that the lysines, involved in isoindole formation, located at or near the active site are probably buried.(ABSTRACT TRUNCATED AT 400 WORDS)     

Possible processing of mitochondria-bindable hexokinase to the nonbindable form by a lysosomal protease in rat liver

As a possible mechanism for the absence of mitochondria-bindable hexokinase in the liver, the presence of a protease similar in action to chymotrypsin, which specifically eliminates the binding ability of the bindable hexokinase without changing its catalytic properties, was investigated in rat liver. The lysosomal fraction prepared from the liver converted the bindable hexokinase prepared from rat brain to the nonbindable form with little change in catalytic activity. The activity of such a "processing protease" was much lower in rat brain, where the bindable form is predominant. The processing activity cosedimented with lysosomal marker enzyme activities in the subcellular fractionation of livers from normal and Triton WR-1339-injected rats. A fair portion of the activity was detected in the lysosomes without disruption. The activity was maximal at pH 6.0-7.0, inactivated almost completely by tosylphenylalanine chloromethyl ketone, tosyllysine chloromethyl ketone, leupeptin, antipain, and chymostatin, and dependent on dithiothreitol and mercaptoethanol. These results suggest that a protease, properties of which are fairly similar to those of cathepsin M, may be involved in the post-translational processing of original bindable hexokinase to the nonbindable form in rat liver.