Glucose regulates glucokinase activity in cultured islets from rat pancreas

In this study, we have used isolated pancreatic islets cultured for 7 days in 3 or 30 mM glucose to explore whether glucokinase is induced or activated by high glucose concentrations and has related enzyme activity to glucose-stimulated insulin release. Islets cultured in low glucose medium or low glucose medium plus 350 ng/ml insulin did not respond to high glucose stimulation. Islets cultured in medium containing high glucose concentrations showed a high rate of basal insulin secretion when perifused with 5 mM glucose, and the insulin release was greatly augmented in a biphasic secretion profile when the glucose concentration was raised to 16 mM. Islet glucokinase and hexokinase activities were determined by a sensitive and specific fluorometric method. Glucokinase activity was reduced to approximately 50% in islets cultured in low glucose medium with or without insulin present compared to results with fresh islets. However, islets cultured in 30 mM glucose showed that glucokinase activity was elevated to 236% compared to results with fresh islets. It is concluded that (a) glucose is the physiological regulator of glucokinase in the islet of Langerhans and that (b) the activity of glucokinase plays a crucial role in glucose-induced insulin secretion.     

Identification,expression and bioactivity of hexokinase in amphioxus: Insights into evolution of vertebrate hexokinase genes

Hexokinase family includes hexokinases I, II, III and IV, that catalyze the phosphorylation of glucose to produce glucose 6-phosphate. Hexokinase IV, also known as glucokinase, is only half size of the other types of hexokinases that contain two hexokinase domains. Despite the enormous progress in the study of hexokinases, the evolutionary relationship between glucokinase and other hexokinases is still uncertain, and the molecular processes leading to the emergence of hexokinases in vertebrates remain controversial. Here we clearly demonstrated the presence of a single hexokinase-like gene in the amphioxus Branchiostoma japonicum, Bjhk, which shows a tissue-specific expression pattern, with the most abundant expression in the hepatic caecum, testis and ovary. The phylogenetic and synteny analyses both reveal that BjHK is the archetype of vertebrate hexokinases IV, i.e. glucokinases. We also found for the first time that recombinant BjHK showed functional enzyme activity resembling vertebrate hexokinases I, II, III and IV. In addition, a native glucokinase activity was detected in the hepatic caecum. Finally, glucokinase activity in the hepatic caecum was markedly reduced by fasting, whereas it was considerably increased by feeding. Altogether, these suggest that Bjhk represents the archetype of glucokinases, from which vertebrate hexokinase gene family was evolved by gene duplication, and that the hepatic caecum plays a role in the control of glucose homeostasis in amphioxus, in favor of the notion that the hepatic caecum is a tissue homologous to liver.     

Distribution of hexokinase isoenzymes depending on a carbon source in Saccharomyces cerevisiae.

DEAE cellulose chromatography and agar gel electrophoresis of glucose-phosphorylating enzymes in Saccharomyces cerevisiae showed the existence of glucokinase and two hexokinase isoenzymes ( designated as hexokinase I and II ). The distribution of hexokinase isoenzymes was dependent on a carbon source in the medium, while that of glucokinase was not dependent. The cells grown on 3 % ethanol as carbon source showed the isoenzyme pattern with predominant hexokinase I and a little hexokinase II. The isoenzyme pattern of the cells grown on 6 % glucose, which was differnt from that of the cells grown on ethanol, showed that hexokinase I and II were minor and major parts respectively. When the cells grown on 3 % ethanol were incubated on the medium containing 6 % glucose, hexokinase I was repressed and hexokinase II inducted. These facts suggest that two hexokinase isoenzymes, but not glucokinase, are adaptive enzyme.     

Characterization of hexokinase isoenzyme types I and II in ascites tumor cells by an interaction with mitochondrial membrane

Summary A difference was observed in the intracellular distribution between type I and II hexokinases in Ehrlich-Lettre hyperdiploid ascites tumor cells (ELD cells). Experiment of the rebinding to the mitochondria for either each or mixture of the partially purified preparations of the two types of hexokinase indicated that the accepting site on the mitochondrial membrane was common for both types. Mild treatment of the two isoenzymes with chymotrypsin resulted in loss of the binding ability to mitochondria without change in the catalytic activity. It was deduced from these results that the essential region in the two types of hexokinase to interact with mitochondria, which was cleaved by chymotrypsin, was the same or near-similar.Secondly, rebinding to and releasing from mitochondria were examined for the two hexokinase isoenzymes in the presence of various factors affecting the interaction between hexokinase and mitochondria, such as divalent cations, glucose 6-phosphate, and Pi. In the absence of divalent cations, about a half of the type I isoenzyme was bound to mitochondria, whereas almost no type II was bound. A difference was also seen between the two types in the concentration of divalent cations required for the saturation of the binding. A more marked difference was observed in the effect of Pi either alone or in combination with glucose 6-phosphate on the activity and binding ability of the two hexokinases. For type I isoenzyme, Pi relieved both inhibitory and releasing effects of glucose 6-phosphate. On the contrary, for type II, Pi had no such a modulating effect on the releasing action of glucose 6-phosphate, and had the inhibitory effect for itself on the enzyme activity.From these results, it is likely that the difference in the intracellular distribution between type I and II hexokinases in ELD cells is due to the difference in their catalytic regions in the reaction with these ligands, which would induce the structural change in the region responsible for the binding to mitochondria.     

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.     

All hexokinase isoenzymes coexist in rat hepatocytes.

The cellular distribution of hexokinase isoenzymes, N-acetylglucosamine Kinase and pyruvate kinases in rat liver was studied. Hepatocytes and non-parenchymal cells with high viability and almost no cross-contamination were obtained by perfusion in situ of the liver with collagenase, with the use of an enriched cell-culture medium in all steps of cell isolation. Separation of hexokinase isoenzymes was done by DEAE-cellulose chromatography, and enzyme activities were measured by a specific radioassay. Cytosol from isolated hepatocytes contained high-affinity hexokinases A, B and C, in addition to hexokinase D. The last-mentioned represented about 95% of total glucose-phosphorylating activity. Only hexokinase A was found associated t the particulate fraction. Isolated non-parenchymal cells contained only hexokinases A, B and C. N-Acetylglucosamine kinase was measured with a specific radioassay and was found as a single enzyme form in both hepatocytes and non-parenchymal cells, with higher activities in the former. Pyruvate kinase isoenzyme L was present only in the hepatocytes and isoenzyme K only in the non-parenchymal liver cells, confirming that they are good cellular markers.     

Hexokinase of Angiostrongylus cantonensis: presence of a glucokinase.

1. Angiostrongylus cantonensis contains a glucokinase which was isolated by DEAE-cellulose column chromatography. 2. This enzyme has a much higher affinity toward glucose (apparent Km, 0.2 mM) than fructose (apparent Km, 85 mM). Glucose-6-phosphate (10 mM) does not inhibit glucose phosphorylation. 3. Molecular weight obtained by a molecular sieve chromatography (60,000) is also close to the value of mammalian glucokinase. 4. While Vmax value for mannose is one-third smaller than that for glucose, Km for mannose is rather lower than that for glucose. 5. In addition to the cytosol enzyme, a particle bound hexokinase is found in the worm.     

Glucose repression in Saccharomyces cerevisiae is directly associated with hexose phosphorylation by hexokinases PI and PII

Genetic and biochemical analyses showed that hexokinase PII is mainly responsible for glucose repression in Saccharomyces cerevisiae, indicating a regulatory domain mediating glucose repression. Hexokinase PI/PII hybrids were constructed to identify the supposed regulatory domain and the repression behavior was observed in the respective transformants. The hybrid constructs allowed the identification of a domain (amino acid residues 102-246) associated with the fructose/glucose phosphorylation ratio. This ratio is characteristic of each isoenzyme, therefore this domain probably corresponds to the catalytic domain of hexokinases PI and PII. Glucose repression was associated with the C-terminal part of hexokinase PII, but only these constructs had high catalytic activity whereas opposite constructs were less active. Reduction of hexokinase PII activity by promoter deletion was inversely followed by a decrease in the glucose repression of invertase and maltase. These results did not support the hypothesis that a specific regulatory domain of hexokinase PII exists which is independent of the hexokinase PII catalytic domain. Gene disruptions of hexokinases further decreased repression when hexokinase PI was removed in addition to hexokinase PII. This proved that hexokinase PI also has some function in glucose repression. Stable hexokinase PI overproducers were nearly as effective for glucose repression as hexokinase PII. This showed that hexokinase PI is also capable of mediating glucose repression. All these results demonstrated that catalytically active hexokinases are indispensable for glucose repression. To rule out any further glycolytic reactions necessary for glucose repression, phosphoglucoisomerase activity was gradually reduced. Cells with residual phosphoglucoisomerase activities of less than 10% showed reduced growth on glucose. Even 1% residual activity was sufficient for normal glucose repression, which proved that additional glycolytic reactions are not necessary for glucose repression. To verify the role of hexokinases in glucose repression, the third glucose-phosphorylating enzyme, glucokinase, was stably overexpressed in a hexokinase PI/PII double-null mutant. No strong effect on glucose repression was observed, even in strains with 2.6 U/mg glucose-phosphorylating activity, which is threefold increased compared to wild-type cells. This result indicated that glucose repression is only associated with the activity of hexokinases PI and PII and not with that of glucokinase.     

Hexokinase isoenzymes from the Novikoff hepatoma. Purification, kinetic and structural characterization, with emphasis on hexokinase C.

The purification to homogeneity of hexokinases B and C from the cytosol of rat Novikoff hepatoma was achieved by a protocol using an initial chromatography on Blue 2-agarose to separate the isoenzymes from each other. After that step each hexokinase was subjected to chromatography on DEAE-cellulose, hydroxyapatite and Sephacryl S-300, followed by re-chromatography on hydroxyapatite. The final preparations of hexokinases B and C had specific activities of 86 and 23.5 units/mg of protein respectively, and gave single bands on electrophoresis under non-denaturing conditions or in SDS/polyacrylamide gels. Mr values of about 100,000 were found for both isoenzymes either by Sephacryl S-300 chromatography or by SDS/polyacrylamide-gel electrophoresis. Values of apparent Km for glucose and ATP of pure hexokinase B were similar to those reported for the enzyme from other sources. The apparent Km value for glucose of hexokinase C was 0.025 mM. Marked inhibition of hexokinase C by glucose concentrations above 0.2 mM was found. The effect was partially relieved by ATP concentrations above 1 mM and was independent of pH. Glucose 6-phosphate was inhibitory, but the Ki value (0.18 mM) is higher than those reported for other animal hexokinases. The amino acid composition of hexokinase C was found to be similar to those reported for hexokinases B and D. Also, an immune serum directed against hexokinase A was able, at low dilutions, to bind hexokinases B and C. An immune serum directed against hexokinase C was able, at low dilutions, to bind hexokinase B and also, but weakly, hexokinase A.     

Impaired enzyme-to-enzyme channelling between hexokinase isoenzyme(s) and phosphoglucoisomerase in rat pancreatic islets incubated at a low concentration of D-glucose

It was recently proposed that in rat pancreatic islets exposed to 8.3 mM D-glucose, alpha-D-glucose-6-phosphate undergoes enzyme-to-enzyme channelling between hexokinase isoenzyme(s) and phosphoglucoisomerase. To explore the identity of the hexokinase isoenzyme(s) involved in such a tunnelling process, the generation of 3HOH from the alpha- and beta-anomers of either D-[2-3H]glucose or D-[5-3H]glucose was now measured over 60 min incubation at 4 degrees C in pancreatic islets exposed only to 2.8 mM D-glucose, in order to decrease the relative contribution of glucokinase to the phosphorylation of the hexose. Under these experimental conditions, the ratio for 3HOH production from D-[2-3H]glucose/D-[5-3H]glucose at anomeric equilibrium (39.7 +/- 11.6%) and the beta/alpha ratios for the generation of 3HOH from either the D-[2-3H]glucose anomers (70.9 +/- 12.6%) or the D-[5-3H]glucose anomers (59.6 +/- 12.4%) indicated that a much greater fraction of alpha-D-glucose-6-phosphate escapes from the process of enzyme-to-enzyme channelling in the islets exposed to 2.8 mM, rather than 8.3 mM D-glucose. These findings suggest, therefore, that the postulated process of enzyme-to-enzyme channelling involves mainly glucokinase.     

Purification of the hexokinases by affinity chromatography on sepharose-N-aminoacylglucosamine derivates. Design of affinity matrices from free solution kinetics.

The purification is described of rat hepatic hexokinase type III and kidney hexokinase type I on a large scale by using a combination of conventional and affinity techniques similar to those previously used for the purification of rat hepatic glucokinase [Holroyde, Allen, Storer, Warsy, Chesher, Trayer, Cornish-Bowden & Walker (1976) Biochem. J. 153, 363-373] and muscle hexokinase type II [Holroyde & Trayer (1976) FEBS Lett. 62, 215-219]. The key to each purification was the use of a Sepharose-N-aminoacylglucosamine affinity matrix in which a high degree of specificity for a particular hexokinase isoenzyme could be introduced by either varying the length of the aminoacyl spacer and/or varying the ligand concentration coupled to the gel. This was predicted from a study of the free solution kinetic properties of the various N-aminoacylglucosamine derivatives used (N-aminopropionyl, N-aminobutyryl, N-aminohexanoyl and N-aminooctanoyl), synthesized as described by Holroyde, Chesher, Trayer & Walker [(1976) Biochem. J. 153, 351-361]. All derivatives were competitive inhibitors, with respect to glucose, of the hexokinase reaction, and there was a direct correlation between the Ki for a particular derivative and its ability to act as an affinity matrix when immobilized to CNBr-activated Sepharose 4B. Muscle hexokinase type II could be chromatographed on the Sepharose conjugates of all four N-aminoacylglucosamine derivatives, although the N-aminohexanoylglucosamine derivative proved best. This same derivative was readily able to bind hepatic glucokinase and hexokinase type III, but Sepharose-N-amino-octanoyl-glucosamine was better for these enzymes and was the only derivative capable of binding kidney hexokinase type I efficiently. Separate studies with yeast hexokinase showed that again only the Sepharose-N-amino-octanoylglucosamine was capable of acting as an efficient affinity matrix for this enzyme. Implications of these studies in our understanding of affinity-chromatography operation are discussed.     

Anomeric specificity of hexokinase and glucokinase activities in liver and insulin-producing cells.

Conflicting data have been reported concerning the anomeric specificity of glucokinase. In the present study, liver hexokinase (Km for D-glucose 0.4 mM) displayed a higher affinity for but lower Vmax. with alpha- than with beta-D-glucose. The velocity of the reaction catalysed by liver glucokinase was higher with with beta- than with alpha-D-glucose, whatever the glucose concentration. The apparent Km of glucokinase was somewhat lower, however, with alpha- than with beta-D-glucose. Comparable results were obtained for the high-Km glucokinase-like enzymic activity present in normal pancreatic islets or insulin-producing tumoral cells. These results suggest that the anomeric specificity of glucokinase cannot account for the higher rate of glycolysis found in islets exposed to alpha- as distinct from beta-D-glucose.     

Subcellular distribution of hexokinase isoenzymes in pancreatic islet cells exposed to digitonin after incubation at a low or high concentration of D-glucose

It was recently proposed that stimulation of pancreatic islet by D-glucose results in the translocation of glucokinase from the perinuclear area to the cell periphery, where the enzyme might conceivably interact with either the glucose transporter GLUT-2 or some other proteins and, by doing so, become better able to express its full catalytic activity. To explore the possible interaction between glucokinase and the cell boundary, dispersed rat pancreatic islet cells were preincubated for 60 min at a low (2.8 mM) or high (16.7 mM) concentration of D-glucose, then exposed for 1 min to digitonin (0.5 mg/ml) and eventually centrifuged through a layer of oil for separation of the cell pellet from the supernatant fraction containing the material released by digitonin. Under these conditions, the bulk of lactate dehydrogenase and glutamate dehydrogenase activities were recovered in the supernatant fraction and cell pellet, respectively. The measurement of hexokinase isoenzyme activities in th e two subcellular fractions, as conducted at low or high hexose concentrations and in either the absence or presence of exogenous hexose phosphates (3.0 mM glucose 6-phosphate and 1.0 mM fructose 1-phosphate) indicated a preferential location of the low-Km hexokinase in the cell pellet and of the high-Km glucokinase in the cytosolic fraction. Such a distribution pattern failed to be significantly affected by the concentration of D-glucose used during the initial incubation of the dispersed islet cells. These findings argue against the view that the glucose-induced translocation of glucokinase would result in any sizeable binding of the enzyme to a plasma membrane-associated protein. (Mol Cell Biochem 175: 131–136, 1997)     

Functional studies of yeast glucokinase.

Glucose phosphorylation capacity is known to be in excess of glucose flux in Saccharomyces cerevisiae wild type but not in a mutant strain lacking the two hexokinases but still having glucokinase. Nonetheless, we show here that in the latter strain, as in the wild type, the internal concentration of glucose is apparently low during growth on glucose and that additional glucokinase activity does not increase glucose flux. The glucokinase-dependent strain accumulates substantial amounts of glucose internally in batch culture after exhaustion of glucose, as well as from maltose. In both of these situations, low concentrations of radioactive glucose provided to the medium are used with incomplete, if any, mixing with the internal pool. Furthermore, in contrast to activity of hexokinase and other enzymes, little glucokinase activity is revealed by toluene treatment of cells. These results may point to a connection between glucose entry and its phosphorylation by glucokinase, but separate explanations for the various findings are also possible.     

Cloning and biochemical characterization of a novel mouse ADP-dependent glucokinase

Glycolysis, the catabolism of glucose to pyruvate, is an iconic central metabolic pathway and often used as a paradigm for explaining the general principles of the regulation/control of cellular metabolism. The ubiquitous mammalian ATP-dependent hexokinases I-III and hexokinase IV, also termed glucokinase, initiate the process by phosphorylating glucose to glucose-6-phosphate. Despite glycolysis having been studied extensively for over 70 years and the last new mammalian ATP-dependent hexokinase isotype having been described in the 1960s, we report here the biochemical characterization of a recombinant ADP-dependent glucokinase cloned from a full-length Mus musculus cDNA, identified by sequence analysis. The recombinant enzyme is quite specific for glucose, is monomeric, has an apparent Km for glucose and ADP of 96 and 280 microM, respectively, and is inhibited by both high concentrations of glucose and AMP. The metabolic role of this enzyme in cells would be dependent on the relative level of its activity to those of the ATP-dependent hexokinases. The greatest advantage of an ADP-GK would clearly be during ischemia/hypoxia, clinically relevant conditions in multiple major disease states, by decreasing the priming cost for the phosphorylation of glucose, saving ATP.     

Fructose is a good substrate for rat liver ''glucokinase'' (hexokinase D).

Rat liver 'glucokinase' (hexokinase D) catalyses the phosphorylation of fructose with a maximal velocity about 2.5-fold higher than that for the phosphorylation of glucose. The saturation function is hyperbolic and the half-saturation concentration is about 300 mM. Fructose is a competitive inhibitor of the phosphorylation of glucose with a Ki of 107 mM. Fructose protects hexokinase D against inactivation by 5,5'-dithiobis-(2-nitrobenzoic acid), and the apparent dissociation constants are about 300 mM in the presence of different concentrations of the inhibitor. The co-operativity of the enzyme in the phosphorylation of glucose can be abolished by addition of fructose to the reaction medium. Fructose appears to be no better as a substrate for the other mammalian hexokinases than it is for hexokinase D. It is proposed that the name 'glucokinase' ought to be reserved for enzymes that are truly specific for glucose, such as those of micro-organisms and invertebrates, and that liver glucokinase must be called hexokinase D (or hexokinase IV) within the classification EC 2.7.1.1.     

Effects of null mutations in the hexokinase genes of Saccharomyces cerevisiae on catabolite repression.

Saccharomyces cerevisiae has two homologous hexokinases, I and II; they are 78% identical at the amino acid level. Either enzyme allows yeast cells to ferment fructose. Mutant strains without any hexokinase can still grow on glucose by using a third enzyme, glucokinase. Hexokinase II has been implicated in the control of catabolite repression in yeasts. We constructed null mutations in both hexokinase genes, HXK1 and HXK2, and studied their effect on the fermentation of fructose and on catabolite repression of three different genes in yeasts: SUC2, CYC1, and GAL10. The results indicate that hxk1 or hxk2 single null mutants can ferment fructose but that hxk1 hxk2 double mutants cannot. The hxk2 single mutant, as well as the double mutant, failed to show catabolite repression in all three systems, while the hxk1 null mutation had little or no effect on catabolite repression.     

Glucose metabolism in the mucosa of the small intestine. A study of hexokinase activity

1. The intracellular distribution of hexokinase activity was studied in the mucosa of rat and guinea-pig small intestine. In the rat 60% and in the guinea pig 45% of the hexokinase activity of homogenates were recovered in a total particulate fraction that contained only 5-17% of the homogenate activity of hexose phosphate isomerase, pyruvate kinase, lactate dehydrogenase and overall glycolysis (formation of lactate from glucose). 2. Fractionation of homogenates from guineapig small intestine showed that the particulate hexokinase activity was chiefly in the mitochondrial fraction with a small proportion in the nuclei plus brush-border fraction. 3. After chromatography of the particle-free supernatants on DEAE-cellulose, hexokinase types I and II were determined quantitatively. No evidence was obtained for the presence of hexokinase type III or glucokinase. In the preparations from guinea pigs, hexokinase types I and II amounted to 69% and 31% respectively of the eluted activity; the corresponding values for preparations from rats were 5.8% and 94.2%. 4. Total and specific hexokinase activities decreased significantly in homogenates and particle-free supernatants prepared from the intestinal mucosa of rats starved for 36hr. and increased again after re-feeding. The decrease in hexokinase activity in the particle-free supernatant from starved rats was chiefly due to a decrease in the type II enzyme.