Gene/Protein Disease Symptom Drug Enzyme Compound
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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)

Detailed time courses of uptake of labeled 3-O-methyl-D-glucose and 2-deoxy-D-glycose by untreated and ATP-depleted Novikoff rat hepatoma cells were determined as function of concentration (0.2-10 mM) by a rapid mixing/sampling technique which allows uptake measurements in time intervals as short as 1.5 seconds. Intracellular accumulation of 3-O-methylglucose in untreated and ATP-depleted cells and of deoxyglucose in ATP-depleted cells to equilibrium followed pseudo-first order kinetics and initial velocities were computed from overall time courses of substrate accumulation. Initial velocity was a Michaelis-Menten function of exogenous substrate concentration. The estimated kinetic constants for zero-trans transport of 3-O-methylglucose were about the same for untreated and ATP-depleted cells (Kztm = 1.73 +/- 0.24 mM; Vztmax = 28.8 +/- 3.6 pmoles/microliter cell H2O. sec) and were similar to those for deoxyglucose transport in ATP-depleted cells (Kztm = 0.65 +/- 0.1 mM; Vztmax = 19.6 +/- 1.6 pmoles/microliter cell H2O. sec). Similar kinetic parameters were obtained for the transport of D-glucose and D-galactose in ATP-depleted cells. The transport of 3-O-methylglucose and deoxyglucose were inhibited by each other in a simple competitive manner with apparent Ki's similar to their transport Km's. In untreated cells, in which deoxyglucose was phosphorylated, intracellular steady-state levels of free deoxyglucose accumulated within 10 to 20 seconds of incubation regardless of its concentration in the medium. Thereafter, the rate of deoxyglucose incorporation into total cell material reflected the rate of phosphorylation rather than the transport rate. The rate of deoxyglucose transport exceeded the initial rate of its phosphorylation by 20-40 %. The intracellular steady-state-levels observed during the first 2 minutes of incubation decreased from about 40% of equilibrium level at 0.2 mM deoxyglucose to about 8% at 10 mM. Computer fits of a kinetic equation describing transport and phosphorylation as independent processes operating in tandem to these data are consistent with the observed kinetic constants for hexose transport and hexokinase activity with deoxyglucose as substrate. Upon longer incubation (2-10 minutes) the rate of deoxyglucose uptake by the phosphorylating cells decreased progressively, concomitant with a decrease in intracellular ATP and an increase in intracellular deoxyglucose to equilibrium levels. It is demonstrated that the rate of deoxyglucose uptake, measured at two or more minutes, seriously underestimates the hexose transport rate and yields misleading conclusions regarding the extent and type of inhibition by transport inhibitors, such as persantin or cytochalasin B. Persantin inhibited hexose transport in a simple non-competitive manner (Ki = 20 muM) indicating that the drug affects the function of the hexose carrier.
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PMID:Deoxyglucose and 3-O-methylglucose transport in untreated and ATP-depleted Novikoff rat hepatoma cells. Analysis by a rapid kinetic technique, relationship to phosphorylation and effects of inhibitors. 67 Mar 3

Detailed histochemical studies have been conducted on the distribution of hexokinase, amylophosphorylase, aldolase, lactic dehydrogenase, succinic dehydrogenase and glucose-6-phosphate dehydrogenase in every component of the locus ceruleus, nucleus tractus mesencephalicus n. trigemini, nucleus dorsalis n. vagi and nucleus n. hypoglossi of the wistar strain rats. The locus ceruleus and nucleus dorsalis n. vagi which are considered to be belong to "exceptional nuclei" showed mild activity in the nerve cell bodies and strong activity in the surrounding glia cell for the hexokinase reaction. But, the nucleus tractus mesencephalicus n. trigemini and nucleus n. hypoglossi considered to be "usual nuclei" revealed strong activity in the nerve cell bodies and glia cells for the hexokinase reaction, however, glia cells did not show the tendency to surround the nerve cells in these nuclei. On the basis of the present findings, the glia cells may get their energy source from glucose in the circulating blood, and they may be energy donators to the nerve cells in the "exceptional nuclei" whereas the nerve cells may get their energy source directly from glucose in the circulating blood in the "usual nuclei". The former 2 nuclei showed low level activity of succinic dehydrogenase. These findings may indicate that the locus ceruleus and nucleus dorsalis n. vagi belong to the conception "exceptional nuclei" in this respect. However, the Embden-Meyerhof-Parnas (EMP) pathway was dominant in the locus ceruleus, while the WARBURG-DICKENS pathway (hexose monophosphate shunt = HMP shunt) was dominant in the nucleus dorsalis n. vagi in the present study. This descrepancy may strongly suggest that the locus ceruleus is distinctly different from the nucleus dorsalis n. vagi concerning the carbohydrate metabolism, though both nuclei are involved on the same conception "exceptional nuclei". The latter 2 nuclei (the nucleus tractus mesencephalicus n. trigemini and the nucleus n. hypoglossi) considered to be "usual nuclei" in 3 ways as that nerve cells get energy source directly from glucose in the circulating blood, that the 2 nuclei are equipped with enzymes involved in the EMP pathway and the HMP shunt to the same degree, and that they are rich in the tricarboxylic acid (TCA) cycle. The nucleus tractus mesencephalicus n. trigemini revealed considerably variable reactions for the hexokinase, aldolase, glucose-6-phosphate dehydrogenase and lactic dehydrogenase in the present study.
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PMID:Histochemical studies on the distribution of some enzymes concerned with carbohydrate metabolism in the locus ceruleus, nucleus tractus mesencephalicus n. trigemini, nucleus dorsalis n. vagi and nucleus n. hypoglossi of the rat. 80 76

Three glucose-phosphorylating enzymes having different specificities for glucose and fructose were separated from the cell-free extract of Candida tropicalis by means of ammonium sulfate fractionation and chromatography on DEAE-cellulose and Sephadex G-100. Two of them, which phosphorylated fructose 1.5 times faster than glucose, were designated as hexokinase I and II (ATP : D-hexose 6-phosphotransferase, EC 2.7.1.1.), and the other with very low or no fructose-phosphorylating activity, as glucokinase (ATP : D-glucose 6-phosphotransferase, EC 2.7.1.2). Km values for glucose with both hexokinase I and glucokinase were 0.3 mM, and that for fructose with hexokinase I was 2.2 mM. Time-course changes in the levels of these enzymes in C. tropicalis growing on glucose and on n-alkane revealed that hexokinase was induced specifically by the sugars, while glucokinase was a constitutive enzyme. Addition of cycloheximide to the culture medium prevented the increase in the hexose-phosphorylating activity and in the Fru/Glu ratio (the ratio of enzymatic phosphorylation of fructose to that of glucose) in the cells. Although Candida lipolytica also contained hexokinase and glucokinase, both enzymes seemed to be constitutive.
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PMID:Glucose-phosphorylating enzymes of Candida yeasts and their regulation in vivo. 83 48

Hexokinase from pyloric caeca of the starfish, Asterias amurensis, was purified to a specific activity of 148 units/mg protein. The purified enzyme appeared to be homogeneous on SDS-polyacrylamide gel electrophoresis. The molecular weight determined by SDS polyacrylamide gel electrophoresis and Ultrogel AcA 34 gel filtration was about 50,000. The enzyme showed a broad pH optimum ranging from 7.4 to 9.5. The Km values for D-glucose, D-fructose, 2-deoxy-D-glucose, D-mannose, D-glucosamine and ATP were 0.045, 4, 0.21, 0.05, 0.35 and 0.3 mM, respectively. N-Acetyl-D-glucosamine, D-xylose and D-galactose were not phosphorylated. The enzyme was strongly inhibited by the reaction products, glucose 6-phosphate and ADP, but not by high levels of D-glucose. The starfish hexokinase thus resembled mammalian isozyme A with respect to kinetic properties.
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PMID:Purification and properties of hexokinase from the starfish, Asterias amurensis. 89 76

Human erythrocyte hexokinase (ATP: D-hexose 6-phosphotransferase, EC 2.7.1.1) was inhibited competitively with respect to MgATP2- by glucose-6-P (Ki - 10.8 muM) and fructose-6-P (Ki = 160 muM). Low concentrations of inorganic phosphate were competitive with respect to glucose-6-P and fructose-6-P, although higher concentrations of Pi were not able to overcome completely the inhibition by the hexose phosphates. The results are consistent with a model in which hexokinase exists in equilibrium either as free or phosphate-associated enzyme, the latter having a reduced but still substantial affinity for hexose phosphate. An alternative explanation could be found in the presence of two different enzymes, one with a high affinity for glucose-6-P being sensitive to regulation by Pi, one with a lower affinity for glucose-6-P being insensitive to Pi. A similar but less pronounced effect of Pi, was found on the inhibition by 2,3-diphosphoglycerate (Ki = 4.0 mM). Pi in the absence of inhibitor was also a competitive inhibitor with respect to MgATP2- (Ki = 20 mM). Furthermore a competitive inhibition with respect to MgATP2- was found by fructose 1,6-diphosphate (Ki = 4.3 mM), glycerate-3-P (Ki = 3.8 mM), glycerate-2-P (Ki = 12.5 mM), MgADP- (Ki = 1.0 mM) and MgAMP (Ki = 1.7 mM).
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PMID:Regulation of human erythrocyte hexokinase. The influence of glycolytic intermediates and inorganic phosphate. 91 66

The marked stimulatory effect of insulin on the conversion of 20 mM D-[6-14C]glucose to CO2, glyceride-glycerol, and fatty acid observed in small rat adipocytes was greatly diminished in large cells from older rats. Similarly, total glucose utilization as estimated by summing the total metabolites accumulated intracellularly plus the release of labeled CO2 and lactate was substantially lower in large cells in the presence of insulin and 5 mM labeled glucose. However, under conditions of 0.2 mM medium glucose where transport of the hexose into adipocytes is relatively more rate-limiting for subsequent metabolism, large cells actually utilized slightly greater total amounts of glucose than small cells in the presence of insulin. Increments of total glucose utilization due to both submaximal and maximal doses of insulin were similar in large and small cells incubated with a low glucose concentration. Under these conditions, conversion of labeled glucose to CO2 and fatty acid in response to insulin was somewhat diminished in large cells, while conversion to glyceride-glycerol was enhanced. The activity of the D-glucose transport system in large and small cells was estimated by monitoring initial rates and small cells was estimated by monitoring initial rates of 3-O-[3H]methylglucose uptake by a rapid filtration method. Transport system activity on a per cell basis was actually severalfold higher in large adipocytes in the basal state as well as in the presence of submaximal and maximal concentrations of insulin compared to small cells. However, the percent stimulation by insulin was less in the large cells. Uptake of 2-deoxyglucose under basal conditions and in response to insulin was also higher in large cells compared to small cells. Analysis of the accumulated label in extracts from fat cells incubated with D-[14C]deoxyglucose revealed the presence of free deoxyglucose, deoxyglucose-6-phosphate, and 6-phosphodeoxygluconate. The levels of these metabolites were significantly higher in large cells compared to small cells indicating hexokinase activity appears not to account for the defective glucose utilization in large cells at high glucose concentrations. It is concluded that (a) possible defects in insulin receptor components, the D-glucose transport system, and the coupling mechanism which links these entities do not significantly contribute to the apparent insulin-insensitivity of large fat cells and (b) the principal cellular defect which confers this blunted insulin response to large rat adipocytes involves one or more intracellular enzymes involved in glucose metabolism.
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PMID:Cellular basis of insulin insensitivity in large rat adipocytes. 93 92

In human brain tumors of neuro-ectodermal and meningo-vascular series, using the method of enzymoelectrophoresis and specific tetrazole blue staining, three isoforms of hexokinase were revealed, these differ from each other by their activity and electrophoretic mobility in agar gel. Three isoforms of hexokinase were also found in benign and malignant uterine tumors in females, in 22 A mice hepatoma and homologous intact tissues. Morever, in muscles and muscle tumors (MOP, CRM-1) of rats and of these animals embryos two isoforms of hexokinase were found. The increased rate of hexose phosphorylation in malignant uterine tumors of female patients and in blastomas of mice liver and rat muscles is associated with the increased activity of I and II isoforms of hexokinase. An analogous phenomenon is observed in muscles of rat embryos. On the other hand, the decreased activity of phosphotransferases in blastomas of human brain depends on a decrease in the activity of separate isoforms of hexokinase.
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PMID:[Isoforms of human and animal tumor hexokinase]. 93 28

The change in intrinsic fluorescence observed when wheatgerm hexokinase combines with its substrates or products has been investigated. The dissociation constants for the enzyme - ligand complexes have been evaluated and found to be equal to their respective Michaelis constants, and confirm that fructose is the preferred hexose substrate. Both hexoses and nucleotides can bind independently to the enzyme and the data are consistent with previous proposals that conformation changes in the enzyme may accompany the random binding of substrates.
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PMID:Wheatgerm hexokinase (LII): fluorimetric measurement of the binding of substrates and products. 94 81

1. Human erythrocyte hexokinase (ADP:D-hexose 6-phosphotransferase, EC 2.7.1.1) was purified 50 000--100 000-fold with a final specific activity of about 25--50 units/mg protein using gel-filtration, ion-exchange chromatography and affinity chromagraphy. 2. After isoelectrofocusing ofthe preparation one major protein band could be detected besides a minor band. THe isoelectric point of the major protein band was found to be 4.7. 3. After purification the enzyme could be stabilized in a medium containing inorganic phosphate, glucose, glycerol and mercaptoethanol. 4. The molecular weight was determined by gel-filtration and was found to be 132 000+/-8000. 5. The enzyme shows a broad pH optimum ranging from 7.0 to 8.4. 6. The kinetic behavior of the purified enzyme at 37 degrees C was somewhat different from the normal Michaelis-Menten kinetics due to its instability. The affinity constants were 0.048--0.080 mM for glucose and 0.57--1.0 mM for Mg-ATP. 7. The enzyme was specific for Mg- ATP as the nucleotide substrate. Mg-UTP, Mg-ITP,Mg-GTP and Mg-CTP were not converted to corresponding diphosphates. Several hexoses could be phosphorylated by the enzyme. Mannose could be phosphorylated at the same rate as glucose, although the affinity for the enzyme was lower (5m=0.60mM). Much lower rates and lower affinities were found with 2-deoxy-D-glucose (5m=1.0mM), D(+)-glucosamine (5m=4.5 mM) and fructose (5m=10 mM). N-acetyl-D-glucosamine , galactose andsorbose were not phosphorylated at all.
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PMID:Purification and some properties of human erythrocyte hexokinase. 95 36

When initial velocities are measured with yeast hexokinase at pH 7, 17 degrees, the inert coordination complex chromium-ATP is competitive vs. MgATP and noncompetitive with glucose, with a dissociation constant of 4-6 muM in either the presence or absence of glucose. These patterns confirm a random kinetic mechanism for this enzyme. With CrATP present, however, the reaction slows down over the first several minutes to a much slower rate, suggesting tighter binding of CrATP with time. When CrATP, MgATP, and D-lyxose are preincubated with the enzyme for 10 min and the reaction started by addition of excess glucose, the dissociation constand of CrATP in now 0.13 muM and the reaction is linear with time. When glucose, CrATP, and enzyme are incubated together and then placed on a Sephadex column, 1 mol each of CrATP and glucose per active center is tightly bound to the enzyme, thus providing a simple and precise method of determining the concentration of active sites. This tight complex, after denaturation with acid, releases 25% free glucose and 75% of a chromium complex containing both ADP and sugar-6-P. CrADP-glucose-6-P is also slowly released from the enzyme during incubation, so that CrATP is actually a very slow substrate. Binding of CrATP with the formation of CrADP-sugar-6-P complexes is also induced by mannose, fructose, glucosamine, 2,5-anhydro-D-glucitol, 2,5-anhydro-D-mannose, and 2,5-anhydro-D-mannitol, while glucose-6-P, 6-deoxyglucose, and lyxose also induce tight binding of CrATP. With excess enzyme, only 25% of CrATP is bound, and the rest does not inhibit the hexokinase reaction. Since bidentate Cr(NH3)4ATP and monodentate CrADP also display inhibition which is tighter with time, but since bidentate CrADP is a poor inhibitor, the actural substrates in the hexokinase reaction appear to be beta, gamma-bidentate MgATP and beta-monodentate MgADP. Tighter inhibition by Cr-8-BrATP than by CrATP suggests that ATP ASSUMES THE SYN CONFORMATION ON THE ENZYME. The substrate inhibition by MgATP induced by the presence of lyxose is shown to be competitive vs. glucose and partial, and, together with other data available, to suggest a kinetic mechanism that is random, but where (1) the rate constant for release of glucose from E-glucose is equal to Vmax, and that for release of glucose from central complexes is less than Vmas; (2) the majority of the reaction flux when both substrates are present at Km levels goes through the path with glucose adding before MgATP, but where at physiological levels the flux through the two paths is more equal. Contd.
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PMID:Use of chromium-adenosine triphosphate and lyxose to elucidate the kinetic mechanism and coordination state of the nucleotide substrate for yeast hexokinase. 108 14


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