EC:2.7.1.1 - FACTA Search

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)

Measurements are reported on certain isotopic fluxes during the net conversion of glutamine, ADP and Pi to glutamate, NH3, and ATP by Escherichia coli glutamine synthetase (adenylylated form, Mn2+ activated) in presence of a hexokinase/glucose trap to remove the ATP formed during the reaction. The results show that the transfer of oxygens from Pi to glutamine is the most rapid of the measured isotopic interchanges, over five oxygens from Pi being transferred to glutamine for each glutamate formed by net reaction. Under similar conditions, the oxygen transfer from Pi to glutamate, was stimulated somewhat by an increase in the glutamate concentration but inhibited by an increase in the ammonia concentration. The enzyme from brain or peas did not show the rapid transfer of 18O from Pi to glutamine shown by the E. coli enzyme. Deductions are also made from the data about the availability of the oxygens of gamma-carboxyl of bound glutamate for reaction. The most logical explanation of the results with the E. coli enzyme is that the gamma-carboxyl group of bound glutamate has sufficient rotational freedom so that under conditions of rapid substrate interconversion either carboxylate oxygen can participate in the reaction. The results with the pea enzyme are consistent with hindered rotation of the gamma-care additional findings make likely a relative order of certain catalytic steps for the E. coli enzyme as follows: ATP release less than NH3 release less than glutamate release less than substrate interconversion less than glutamine release and Pi release and glutamate release less than ADP release.
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PMID:Rapid transfer of oxygens from inorganic phosphate to glutamine catalyzed by Escherichia coli glutamine synthetase. 0 91

The effect of Cr(NH3)2ATP, a virtually inert, inner sphere metal-ligand complex, on the kinetics of purified yeast hexokinase PII has been studied at pH 6.5 and pH 7.5. At pH 6.5, where the normal assays exhibit a slow burst-type transient, low concentrations of Cr(NH3)2ATP were found to activate both phii, the initial velocity, and phiII, the steady state velocity. At higher concentrations, Cr(NH3)2ATP was found to be a competitive inhibitor versus MgATP for both phii and phiII. The apparent Ki values for both velocities were the same. The inhibition by Cr(NH3)2ATP at pH 6.5 was found to be a slow process with half-times similar to those found for the normal burst-type transient at this pH value. At pH 7.5, where normal assays exhibit linear progress curves, Cr(NH3)2ATP behaved similarly to that observed before at pH 7 (Danenberg, D. D., and Cleland, W. W. (1975) Biochemistry 14, 28-39), i.e. it was a competitive inhibitor versus MgATP and it caused a slowing of the reaction rate over the first several minutes. The apparent Ki for the initial velocity was 8-fold higher than the apparent Ki for the steady state velocity, suggesting tighter binding of Cr(NH3)2ATP with time. Preincubation experiments indicated that the normal pH 6.5 burst-type transient could be eliminated by appropriate preincubation with Cr(NH3)2ATP and a sugar. In agreement with Danenberg and Cleland (1975), similar preincubations have been shown to produce linear assays at pH 7.5 in the presence of Cr(NH3)2ATP. Similar results were seen with MgITP as the nucleotide substrate, where a burst-type transient is not seen at either pH value under normal assay conditions. At pH 7.5, a slow decrease in the reaction rate is seen over the first several minutes in the presence of Cr(NH3)2ATP. The apparent Ki for phii was 7-fold higher than the apparent Ki value for phiII, again suggesting a tighter binding of Cr(NH3)2ATP with time. A similar observation was made at pH 6.5, but the Ki values for phii and phiII were the same, suggesting no tightening of the binding of Cr(NH3)2ATP with time at this pH value. These results suggested that both slow processes reflect the same basic molecular change, but the consequences are different at the two pH values, presumably because of the difference in the charge of the enzyme. The Cr(NH3)2ATP kinetics at pH 6.5 have been interpreted in terms of a modification of the slow transition mechanism for hexokinase (Shill, J. P., and Neet, K. E. (1975) J. Biol. Chem. 250, 2259-2268). It is postulated that glucose and Cr(NH3)2ATP induce the same slow conformational change at pH 6.5 as that induced by glucose and MgATP, which gives rise to the normal burst-type transient. This suggests that Cr(NH3)2ATP may be a useful tool for physical studies to determine the cause of the slow transition of yeast hexokinase. Activation by low concentrations of Cr(NH3)2ATP was interpreted as binding of the nucleotide to an activator site on the enzyme, causing a shift in the distribution of enzyme towards the more active form.
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PMID:pH-dependent effects of Cr(NH3)2ATP on kinetics of yeast hexokinase PII. Relationship to the slow transition mechanism. 1 69

The purpose of the present investigation was to shed some light on the suppression of the glycolytic pathway by anesthetics. The antimetabolite 6-aminonicotinamide (6-AN) was used to discriminate between the key enzymes hexokinase and phosphofructokinase which are suggested to be involved in the effect of anesthetics on glycolysis. The cerebral energy metabolism was studied in the isolated perfused rat brain after the addition of thiopental (0.15 mM) to the perfusion medium, after the administration of 6-AN (35mg/kg i.p.) to the intact animals 15 h before perfusion was started, as well as in brain preparations treated in the same manner with both 6-AN and thiopental. After a perfusion period of 30 min brain levels of the following substrates and metabolites were determined: phosphocreatine, ATP, ADP, AMP, glycogen, glucose, glucose 6-phosphate, fructose 6-phosphate, pyruvate, lactate, alpha-ketoglutarate, blutamate, ammonia, and 6-phosphogluconate. The metabolic alterations in the isolated rat brain caused by 6-AN or thiopental were such as reported in the literature. When the isolated brains of the 6-AN pretreated rats were perfused with thiopental we found as the most interesting result that the concentration of glucose 6-phosphate was reduced in comparison to that in brains only treated with 6-AN but still significantly higher than that in controls. The glucose concentration was significantly elevated and the lactate concentration decreased considerably. The effect of thiopental on cerebral glycolysis was interpreted as an inhibition of hexokinase activity.
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PMID:Inhibition of glucose phosphorylation in rat brain by thiopental. 13 93

The relationship between intra- and extramitochondrial ATP utilization was investigated in liver mitochondria isolated from normally fed, starved and high-protein fed rats. ATP export was provoked by adding a hexokinase-glucose-trap and intramitochondrial ATP consumption by adding ammonia, bicarbonate and ornithine in order to stimulate citrulline synthesis. Both processes compete for ATP produced via oxidative phosphorylation; the rate of citrulline formation declines as the extramitochondrial [ATP]/[ADP] ratio decreases. It is concluded that ATP for adenine nucleotide translocation and that for carbamoyl phosphate synthesis are delivered from a common intramitochondrial pool of adenine nucleotides. In mitochondria from rats with a high-protein diet, citrulline synthesis greatly stimulates the rate of oxidative phosphorylation (about two thirds of state 3 respiration). Under these conditions the intramitochondrial [ATP]/[ADP] ratio is significantly reduced. The intramitochondrial [ATP]/[ADP] ratio is not in thermodynamic equilibrium with the extramitochondrial one.
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PMID:Competition between extramitochondrial and intramitochondrial ATP-consuming processes. 16 25

The investigations carried out have shown that not only AMP but ADP also undergoes direct deamination in both soluble and mitochondrial fractions of rat brain tissue. Deamination of AMP is stimulated by the addition of ATP and the activity of one of the isoenzymes of AMP-aminohydrolase is markedly enhanced by both yeast and brain hexokinase. Activation by hexokinase is mainly due to its SH groups, through which hexokinase reacts with AMP-aminohydrolase, forming, probably, a protein-protein complex in which AMP aminohydrolase activity is considerably increased. Hexokinase does not affect the deamination of ADP and NAD. Further experiments are needed to find out whether the activation of AMP-aminohydrolase is accomplished by hexokinase itself or by an other protein contaminating it. Deamination of NAD, in contrast to AMP and ADP, takes place only in mitochondria and does not occur in the soluble fraction. In mitochondria besides deamination, AMP and ADP undergo intensive dephosphorylation, while the deamination of NAD is not accompanied by an increase of phosphate, i. e. mitochondria lack enzymes which breakdown NAD to mono nucleotides. Our data indicate that the formation of deamino -NAD from NAD and reamination of deamino-NAD by aspartate to NAD by the formation of intermediary NAD-succinate is of greater importance. The formation of the latter and that of deamino-NAD from NAD as well as the presence of preformed deamino-NAD in mitochondria have been demonstrated by Movsessian. The occurrence of these processes in mitochondria and their role in the formation of ammonia from amino acids is of importance in as much as oxaloacetate formation and its conversion to aspartate, which is necessary for the reamination of deamino-NAD, are localized in mitochondria. The main source of the amino nitrogen of aspartate is known to be glutamate, which incorporates the amino nitrogen of most amino acids. alpha-Keto-glutarate, which is necessary for the synthesis of glutamate, is also formed in mitochondria are the most favourable site for the formation of ammonia from amino acids with the participation of pyridine nucleotides. Of the purine mono and dinucleotides studied deamino-NAD is most effective in the formation of ammonia from amino acids in mitochondria since in contrast to purine mono nucleotides, deamino-NAD and NAD are not dephosphorylated in mitochondria. According to some authors the reamination of IMP by aspartate is of importance in the formation of ammonia from amino acids in brain tissue. In our studies, however, IMP was not effective in the formation of ammonia from aspartate in mitochondrial fractions. IDP was found to be more effective. IMP and IDP may probably participate in the formation of ammonia in the soluble fraction, where nucleotidase activity is considerably low.
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PMID:[Role of adenine mono- and dinucleotides in ammonia formation in brain tissue]. 18 42

31P NMR studies with Cd(II) and Zn(II) chelates of adenosine 5'-O-(3-thiotriphosphate) (ATPgammaS) and the Cd(II) chelate of adenosine 5'-O-(2-thiotriphosphate) (ATPbetaS) indicate that these metal ions chelate to the sulfur atom of the thiophosphate group. Since Mg(II) chelates to oxygen of the thiophosphate group of diastereoisomer is equivalent to the configuration of the Cd(II) chelate of the opposite diastereoisomer. As a consequence, an inversion of the stereospecificity is observed when Cd(II) is substituted for Mg(II) in the phosphoryl transfer reactions catalyzed by yeast hexokinase and rabbit muscle pyruvate kinase. When Co(II) is the activating ion for yeast hexokinase with ATPbetaS as substrate, no stereospecificity is observed. Since the absolute configuration for the diastereoisomer of Co(III)(NH3)4ATP which is the active substrate for yeast hexokinase has been established by Cornelius and Cleland (Cornelius, R. D., and Cleland, W. W. (1978) Biochemistry, in press), the absolute stereochemistry of the Mg(II) complex of the B isomer of ATPbetaS is now established by its stereospecificity in the hexokinase reaction.
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PMID:Divalent cation-dependent stereospecificity of adenosine 5'-O-(2-thiotriphosphate) in the hexokinase and pyruvate kinase reactions. The absolute stereochemistry of the diastereoisomers of adenosine 5'-O-(2-thiotriphosphate). 67 Jan 66

It is established that purified nuclear and mitochondrial fractions of the rat brain possess a noticeable AMP-deaminase activity. ATP is an effective activator of AMP-deaminase in the both fractions, but this enzyme is also stimulated by hexokinase in the mitochondrial fraction. The ammonia production from ADP in the mitochondrial fraction is connected with the formation on ATP and AMP under the influence of myokinase and subsequent deamination of AMP by AMP-deaminase.
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PMID:[AMP-deaminase activity of rat brain nuclear and mitochondrial fractions]. 72 89

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

1. The metabolism of glucose and glutamine was studied in the small intestine and the colon of rats after 4-5 weeks of hypothyroidism. 2. Hypothyroidism resulted in increases in the plasma concentrations of ketone bodies (P less than 0.05), cholesterol (P less than 0.001) and urea (P less than 0.001), but decreases in the plasma concentrations of free fatty acids (P less than 0.05) and triacylglycerol (P less than 0.001). These changes were associated with decreases in the plasma concentrations of total tri-iodothyronine, free tri-iodothyronine, total thyroxine and free thyroxine. 3. Hypothyroidism decreased both the DNA content (by 30.5%) and the protein content (by 23.6%) of intestinal mucosa, with the protein/DNA ratio remaining unchanged. The villi in the jejunum were shorter (P less than 0.05) and the crypt depth was decreased by about 26.5% in hypothyroid rats. 4. Portal-drained visceral blood flow showed no marked change in response to hypothyroidism, but was accompanied by decreased rates of extraction of glucose, lactate and glutamine and release of glutamate, alanine and ammonia. 5. Enterocytes and colonocytes isolated from hypothyroid rats showed decreased rates of utilization and metabolism of glucose and glutamine. 6. The maximal activities of hexokinase (EC 2.7.1.1), 6-phosphofructokinase (EC 2.7.1.11), pyruvate kinase (EC 2.7.1.40), citrate synthase (EC 4.1.3.28), oxoglutarate dehydrogenase (EC 1.2.4.2) and phosphate-dependent glutaminase (EC 3.5.1.2) were decreased in intestinal mucosal scrapings from hypothyroid rats. Similar decreases were obtained in colonic mucosal scrapings (except for citrate synthase and oxoglutarate dehydrogenase) from hypothyroid rats.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Effects of hypothyroidism on glucose and glutamine metabolism by the gut of the rat. 165 36

The importance and the value of applying metabolic-control logic to the question of fuels, their rates of utilization and their significance to the process of proliferation are presented. Application of the recently developed quantitative theory of metabolic control of branched pathways provides a hypothesis to account for the high rate of both glycolysis and glutaminolysis in lymphocytes, macrophages and, in particular, in tumor cells. Both glycolysis and glutaminolysis provide metabolic intermediates for biosynthetic pathways: for example, glucose-6-phosphate for the formation of ribose-5-phosphate, and glutamine, ammonia and aspartate which are required for the synthesis of purine and pyrimidine nucleotides. However, the rates of both glycolysis and glutaminolysis are greatly in excess (greater than 400-fold) of the requirements for the biosynthetic processes. If energy formation per se was the major reason for the high rate of glutamine utilization, why is the oxidation only partial? The ability of the cell to divide will require the synthesis of all the DNA, RNA, phospholipids, etc., at precise times in the cell cycle. Hence very high and accurate sensitivity of the processes that provide the precursors for these compounds to their specific regulators will be expected. Maintenance of high rates of glycolysis and glutaminolysis at all times can be seen therefore as a device to allow intermediates to be "tapped off" at the precise rate required whenever they are needed for biosynthesis. Maximal activities of some key enzymes of glycolysis, the tricarboxylic acid cycle and glutaminolysis from a variety of normal, neoplastic and suppressed cells are presented. The relative activities of hexokinase and 6-phosphofructokinase suggest that, particularly in neoplastic cells, in which the capacity for glucose transport is high, hexokinase could approach saturation in respect to intracellular glucose; consequently, hexokinase and phosphofructokinase could play an important role in the regulation of glycolytic flux in these cells. The activity of pyruvate kinase is considerably higher in tumorigenic cells than in nontumorigenic cells and higher in metastatic cells than in tumorigenic cells: for nontumorigenic cells the activities range from 28.4 to 574, for tumorigenic cells from 899 to 1280, and for metastatic cells from 1590 to 1627 nmol/min per mg of protein. The ratio of pyruvate kinase activity to 2 x phosphofructokinase activity is very high in neoplastic cells. The mean is 22.4 for neoplastic cells, whereas for muscle from 60 different animals it is only 3.8.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Application of metabolic-control logic to fuel utilization and its significance in tumor cells. 187 89

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