EC:2.7.1.1 - FACTA Search

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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)

DNA polymorphisms in the glucokinase gene have recently been shown to be tightly linked to early-onset non-insulin-dependent diabetes mellitus in approximately 80% of French families with this form of diabetes. We previously identified a nonsense mutation in exon 7 in one of these families and showed that it was the likely cause of glucose intolerance in this dominantly inherited disorder. Here we report the isolation and partial sequence of the human glucokinase gene and the identification of two missense mutations in exon 7, Thr-228----Met and Gly-261----Arg, that cosegregate with early-onset non-insulin-dependent diabetes mellitus. To assess the molecular mechanism by which mutations at these two sites may affect glucokinase activity, the crystal structure of the related yeast hexokinase B was used as a simple model for human beta-cell glucokinase. Computer-assisted modeling suggests that mutation of Thr-228 affects affinity for ATP and mutation of Gly-261 may alter glucose binding. The identification of mutations in glucokinase, a protein that plays an important role in hepatic and beta-cell glucose metabolism, indicates that early-onset non-insulin-dependent diabetes mellitus may be primarily a disorder of carbohydrate metabolism.
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PMID:Human glucokinase gene: isolation, characterization, and identification of two missense mutations linked to early-onset non-insulin-dependent (type 2) diabetes mellitus. 150 86

Recent studies from this and other laboratories have resulted in the cloning and sequencing of hexokinases from a variety of tissues including yeast, human kidney, rat brain, rat liver, and mouse hepatoma. Significantly, studies on the hepatoma enzyme conducted in this laboratory (Arora, K.K., Fanciulli, M., and Pedersen, P.L. (1990) J. Biol. Chem. 265, 6481-6488) resulted also in its overexpression in Escherichia coli in active form. We have now used site-directed mutagenesis for the first time in studies of hexokinase to evaluate the role of amino acid residues predicted to interact with either glucose or ATP. Four amino acid residues (Ser-603, Asp-657, Glu-708, and Glu-742) believed to interact with glucose were mutated to alanine or glycine, whereas a lysine residue (Lys-558) thought to be directly involved in binding ATP was mutated to either methionine or arginine. Of all the mutations in residues believed to interact with glucose, the Asp-657----Ala mutation is the most profound, reducing the hexokinase activity to a level less than 1% of the wild type. The relative Vmax values for Ser-603----Ala, Glu-708----Ala, and Glu-742----Ala enzymes are 6, 10, and 6.5%, respectively, of the wild-type enzyme. Glu-708 and Glu-742 mutations increase the apparent Km for glucose 50- and 14-fold, respectively, while the Ser-603----Ala mutation decreases the apparent Km for glucose 5-fold. At the putative ATP binding site, the relative Vmax for Lys-558----Arg and Lys-558----Met enzymes are 70 and 29%, respectively, of the wild-type enzyme with no changes in the apparent Km for glucose. No changes were observed in the apparent Km for ATP with any mutation. These results support the view that all 4 residues predicted to interact with glucose from earlier x-ray studies may play a role in binding and/or catalysis. The Asp-657 and Ser-603 residues may be involved in both, while Glu-708 and Glu-742 clearly contribute to binding but are not essential for catalysis. In contrast, Lys-558 appears to be essential neither for binding nor catalysis.
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PMID:Glucose phosphorylation. Site-directed mutations which impair the catalytic function of hexokinase. 200 85

The N-terminal sequence of rat brain hexokinase (ATP: D-hexose-6-phosphotransferase, EC 2.7.1.1) has been determined to be X-NH-Met-Ile-(Ala, Gln)-Ala-Leu-Leu-Ala-Tyr-, where X is a blocking group on the N-terminal methionine, probably an N-acetyl group. Modification of this hydrophobic N-terminal segment by endogenous proteases in crude brain extracts resulted in loss of the ability to bind to mitochondria, but had no effect on catalytic activity, resulting in the appearance of nonbindable enzyme reported by several previous investigators to be present in purified hexokinase preparations. Similar results can be obtained by deliberate limited digestion with chymotrypsin (cleavage points marked by arrows in sequence above). Both bindable and nonbindable enzyme, the latter generated either by endogenous proteases or with chymotrypsin, have an identical C-terminal dipeptide sequence, Ile-Ala. The great susceptibility of the N-terminus to proteolysis plus the marked effect that its proteolytic modification has on binding of hexokinase to anion exchange or hydrophobic (phenyl-Sepharose) matrices suggest that this N-terminal segment is prominently displayed at the enzyme surface. Epitopes recognized by two monoclonal antibodies which block binding of hexokinase to mitochondria (but have no effect on catalytic activity) have been mapped to a 10K fragment cleaved from the N-terminus by limited tryptic digestion. Thus the binding of hexokinase to mitochondria appears to occur via a "binding domain" constituting the N-terminal region of the molecule, with maintenance of an intact hydrophobic sequence at the extreme N-terminus being critical to this interaction. A resulting specific orientation of the molecule on the mitochondrial surface is considered to be a prerequisite for the observed coupling of hexokinase activity and mitochondrial oxidative phosphorylation.
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PMID:An intact hydrophobic N-terminal sequence is critical for binding of rat brain hexokinase to mitochondria. 257 71

Despite extensive sequence similarity between the N- and C-terminal halves of the Type I isozyme of mammalian hexokinase (ATP:D-hexose 6-phosphotransferase; EC 2.7.1.1), they are functionally distinct, the C-terminal half being responsible for catalysis and the N-terminal half thought to play a regulatory role. We have examined the effects of several site-directed mutations on kinetic and regulatory properties of the rat Type I isozyme. Mutation of the C-terminal residues, Asp 532 to Asn, Arg 539 to Met, and Gly 896 or Gly 898 to Val, resulted in drastic loss of catalytic activity (< 10% of wild-type enzyme), consistent with previous suggestions that these residues are involved in binding of ATP. Mutation of the corresponding residues in the N-terminal half of the enzyme caused much less marked (> 50% of wild type), but significant, effects on activity which are presumed to result from subtle effects on conformation of the enzyme. Mutation of Lys 899 to Met resulted in an approximately 50% decrease in specific activity and an approximately fivefold increase in the Km for ATP, consistent with the view that Lys 899 participates in binding of ATP through electrostatic interactions with the phosphate sidechain. Cys residues corresponding to Cys 158 and Cys 606 of Type I hexokinase are found in other hexokinases that exhibit marked sensitivity to inhibition by the product, glucose 6-phosphate (Glc-6-P), but analogous residues are not found in hexokinases insensitive to Glc-6-P. However, this correlation appears to be coincidental since neither the mutation of Cys 158 or Cys 606 to Ala nor any of the other mutations examined abolished sensitivity of Type I hexokinase to inhibition by the Glc-6-P analog 1,5-anhydroglucitol-6-P or to antagonism of this inhibition by P(i).
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PMID:Residues putatively involved in binding of ATP and glucose 6-phosphate to a mammalian hexokinase: site-directed mutation at analogous positions in the N- and C-terminal halves of the type I isozyme. 764 67

A Xenopus oocyte expression system was used to examine how glucose transporters (GLUT 2 and GLUT 3) and glucokinase (GK) activity affect glucose utilization. Uninjected oocytes and low rates of both glucose transport and phosphorylation; expression of GLUT 2 or GLUT 3 increased glucose phosphorylation approximately 20-fold by a low Km, endogenous hexokinase at glucose concentrations < or = 1 mM, but not at higher glucose concentrations. Coexpression of functional GK isoforms with GLUT 2 or 3 increased glucose utilization approximately an additional two- to threefold primarily at the physiologic glucose concentrations of 5-20 mM. The Km for glucose of both the hepatic and beta cell isoforms of GK, determined in situ, was approximately 5-10 mM when coexpressed with either GLUT 2 or GLUT 3. The increase in glucose utilization by coexpression of GLUT 3 and GK was dependent upon glucose phosphorylation since two missense GK mutations linked with maturity-onset diabetes, 182: Val-->Met and 228:Thr-->Met, did not increase glucose utilization despite accumulation of both a similar amount of immunoreactive GK protein and glucose inside the cell. Coexpression of a mutant GK and a normal GK isoform did not interfere with the function of the normal GK enzyme. Since the coexpression of GK and a glucose transporter in oocytes resembles conditions in the hepatocyte and pancreatic beta cell, these results indicate that increases in glucose utilization at glucose concentrations > 1 mM depend upon both a functional glucose transporter and GK.
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PMID:Coexpression of glucose transporters and glucokinase in Xenopus oocytes indicates that both glucose transport and phosphorylation determine glucose utilization. 792 12

The cAMP-dependent protein kinase anchoring protein, d-AKAP1, has two N-terminal splice variants. The shorter forms (N0, d-AKAP1a, and -1c) target to mitochondria, and the longer forms (N1, d-AKAP1b, and -1d) with 33 additional residues N-terminal to N0 target to the endoplasmic reticulum (ER) (Huang, L. J., Wang, L., Ma, Y., Durick, K., Perkins, G., Deerinck, T. J., Ellisman, M. H., and Taylor, S. S. (1999) J. Cell Biol. 145, 951-959). In d-AKAP1a, translation may initiate from both Met-34 or Met-49 producing two molecules both targeted to mitochondria. The shorter molecule contains the 15-residue targeting motif, homologous to the N-terminal mitochondrial targeting motif of hexokinase I. Extensive mutagenesis showed that one hydrophobic surface of the 15-residue hexokinase-homologous segment contained the key elements for mitochondrial targeting. The same 15 residues are also part of the ER-targeting signal, but for ER targeting multiple hydrophobic residues are required that encompass both surfaces of the helix. The different involvement of the same helical motif for targeting to the two organelles appears to reflect different modes of interaction with the two organelles. This is the first example of a bifunctional helical element that is required for both ER and mitochondrion targeting.
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PMID:A 15-residue bifunctional element in D-AKAP1 is required for both endoplasmic reticulum and mitochondrial targeting. 1199 83

Mammalian hexokinase (HXK) is found at the outer mitochondrial membrane, exposed to mitochondrial oxygen- and nitrogen-radicals. Given the important role of this enzyme in metabolic pathways and diseases, the effect of S-nitrosoglutathione (GSNO) on HXK A structure and activity was studied. To focus on the catalytic domain, yeast HXK A was used because it has a significant homology to the mammalian domain that contains both the regulatory and catalytic sites. Biologically relevant [GSNO]/[HXK] caused a significant decrease in V(max) with glucose (but not with fructose), along with oxidation of 5 Met and nitration of 4 Tyr. Preincubation of HXK with glucose abrogated the effect of GSNO whereas fructose was ineffective. These results are interpreted by considering the tight binding of glucose to the enzyme as opposed to that of fructose. The segment comprised from amino acids 304 to 306 contained the most modifications. Given that this sequence is highly conserved in HXK from various species, a decline in activity is expected when a high-affinity substrate is presented. Considering that changes in primary structure are envisioned at high [GSNO]/[HXK] ratios, like those present under normal conditions, it could be hypothesized that the high concentration of hexokinase present in fast growing tumors may serve not only to sustain high glycolysis rates, but also to minimize protein damage that might result in activity decline, compromising energy metabolism.
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PMID:Kinetic and proteomic analyses of S-nitrosoglutathione-treated hexokinase A: consequences for cancer energy metabolism. 1705 22