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Fructokinase (FK), one of the crucial enzymes for sugar metabolism in bacterial systems, catalyses the unidirectional phosphorylation reaction from fructose to fructose 6-phosphate, thereby allowing parallel entry of fructose into glycolysis beside glucose. The cscK gene from Vibrio cholerae O395 coding for the enzyme FK has been cloned, overexpressed in Escherichia coli BL21 (DE3) and purified using Ni-NTA affinity chromatography. Crystals of V. cholerae FK (Vc-FK) and its cocrystal with fructose, adenosine diphosphate (ADP) and Mg2+ were grown in the presence of polyethylene glycol 6000 and diffracted to 2.45 and 1.75 Šresolution, respectively. Analysis of the diffraction data showed that both crystal forms have symmetry consistent with space group P2(1)2(1)2, but with different unit-cell parameters. Assuming the presence of two molecules in the asymmetric unit, the Matthews coefficient for the apo Vc-FK crystals was estimated to be 2.4 Å3 Da(-1), which corresponds to a solvent content of 48%. The corresponding values for the ADP- and sugar-bound Vc-FK crystals were 2.1 Å3 Da(-1) and 40%, respectively, assuming the presence of one molecule in the asymmetric unit.

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In the cluster of genes for sucrose biosynthesis and cleavage in Methylomicrobium alcaliphilum 20Z, a gene whose encoded sequence showed high similarity to sugar kinases of the ribokinase family was found. By heterologous expression of this gene in Escherichia coli cells and following metal chelate affinity chromatography, the electrophoretically homogenous recombinant enzyme with six histidine residues on the C-end was obtained. The enzyme catalyzes ATP-dependent phosphorylation of fructose into fructose-6-phosphate but is not active with other sugars as phosphoryl acceptors. The fructokinase of M. alcaliphilum 20Z is most active in the presence of Mn(2+) at pH 9.0 and 60°C, being inhibited by ADP (K(i) = 2.50 ± 0.03 mM). The apparent K(m) values for fructose and ATP are 0.26 and 1.3 mM, respectively; the maximal activity is 141 U/mg protein. The enzyme shows the highest similarity of translated amino acid sequence with putative fructokinases of methylotrophic and autotrophic proteobacteria whose fruK gene is located in the gene cluster of sucrose biosynthesis. The involvement of fructokinase in sucrose metabolism in M. alcaliphilum 20Z and other methanotrophs and autotrophs is discussed.

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Ketohexokinase (KHK; E.C. 2.7.1.3) catalyses the (reversible) phosphorylation of fructose to fructose-1-phosphate. KHK is the first enzyme in a specialized catabolic pathway metabolizing dietary fructose to the glycolytic intermediate glyceraldehyde-3-phosphate. Mutations inactivating KHK underlie the metabolic disorder essential fructosuria. The primary structure of KHK shows no significant homology to other mammalian hexokinases. It is most similar to prokaryotic ribokinases, but catalyses a distinct phosphorylation reaction. Recombinant human KHK has been crystallized in the orthorhombic form (space group P2(1)2(1)2 or P2(1)2(1)2(1)). Single crystals of this polymorph suitable for X-ray diffraction have been obtained by vapour diffusion using 2-propanol and MPD as precipitants (pH 7.5). The crystals have unit-cell parameters a = 93.4, b = 121.5, c = 108.4 A. Diffraction data were collected to 4.3 A resolution. The asymmetric unit contains four protein molecules.

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Fructokinase (FK; ATP:D-fructose 6-phosphotransferase, EC 2.7.1.4) cloned from a tomato fruit cDNA library has been expressed in Escherichia coli. The recombinant protein was purified 159-fold to greater than 99% purity, based on SDS-PAGE analysis. The subunit molecular mass is estimated to be 35 kDa and the nondissociated molecular mass is 72.4 kDa, indicating that the functional form is a dimer. Two-dimensional IEF/SDS-PAGE analyses combined with immunodetection show that both native and recombinant proteins exhibit the same pattern of six closely grouped peptides with pI values ranging from 5.66 to 6.17. Biochemical characterization of the purified recombinant enzyme shows properties essentially identical to those of the native fructokinase purified from young tomato fruit: the pH optimum is 8.0, the K(m) for fructose is 0.22 mM, and severe substrate inhibition is observed when fructose concentration is greater than 0.5 mM (Ki = 3.0 mM). ATP is the preferred phosphate donor (K(m) = 0.13 mM and Vmax/K(m) = 212), followed by GTP (K(m) = 0.45 mM and Vmax/K(m) = 76) and UTP (K(m) = 1.68 mM and Vmax/K(m) = 20), but Vmax values are slightly greater with GTP and UTP. Product inhibition analyses show that the inhibition by ADP with respect to ATP is dependent on fructose concentration [Ki (ADP) = 0.41 mM with 0.5 mM fructose and decreased to 0.12 mM with 3 mM fructose]. Inhibition by fructose 6-P shows weak noncompetitive inhibition with respect to fructose; however, the recombinant protein is slightly more sensitive to fructose 6-P than the native FK.

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The gene encoding fructokinase (EC 2.7.1.4) from Zymomonas mobilis has been expressed at high level in Escherichia coli by modifying the ribosome binding site using the polymerase chain reaction. A simple two-step purification from extracts of the recombinant cells results in highly purified enzyme suitable for use in fructose determination. Using the polymerase chain reaction in mutagenic conditions, a variant of fructokinase was isolated which was more thermostable than the wild type, taking the 30 min half-life from 70.1 to 72.4 degrees C. The purified thermostable variant had the same specific activity as the wild type. Sequencing of the variant indicated that only one amino acid was changed, with Ser 69 becoming Ala. Searches of the mutant libraries for variants that were (a) active with glucose or (b) had reduced inhibition by glucose were unsuccessful.

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Ketohexokinase (ATP:D-fructose 1-phosphotransferase [EC 2.7.1.3]), detected for the first time in a prokaryote, i.e., the extreme halophile Haloarcula vallismortis, was isolated and characterized from the same archaebacterium. This enzyme was characterized with respect to its molecular mass, amino acid composition, salt dependency, immunological cross-reactivity, and kinetic properties. Gel filtration and sucrose density gradient centrifugation revealed a native molecular mass of 100 kDa for halobacterial ketohexokinase, which is larger than its mammalian counterpart. The enzyme could be labeled by UV irradiation in the presence of [ gamma-32P]ATP, suggesting the involvement of a phosphoenzyme intermediate. Other catalytic features of the enzyme were similar to those of its mammalian counterparts. No antigenic cross-reactivity could be detected between the H. vallismortis ketohexokinase and the ketohexokinases from different rat tissues.

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Two electrophoretically distinct proteins with fructokinase (ATP:fructose-6-phosphotransferase) activity were detected in Lactococcus lactis subsp. lactis K1. Whereas fructokinase I was induced specifically by growth of the organism on sucrose, fructokinase II was derepressed during growth on ribose, galactose, maltose, and lactulose. Fructokinase I was purified about 1000-fold to electrophoretic homogeneity (specific activity 112 units/mg). The amino acid composition, N-terminal sequence, nucleoside triphosphate, and metal requirement(s) of the enzyme are reported. Ultracentrifugal analysis showed that the enzyme was primarily dimeric with subunits of 33.5 kDa (+/- 5%). When completely reduced, fructokinase I migrated as a single protein (Mr = 32,000) by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, but in the absence of reducing agent two polypeptides (apparent Mr = 29,000 and 31,000) were detected. Isoelectric focusing also revealed two polypeptides (pI 5.6 and 5.8), and both species catalyzed the phosphorylation of fructose and mannose. Hybridization studies showed that: (i) a sucrose-negative mutant lacking the fructokinase I gene (scrK) retained fructokinase II activity and (ii) scrK is closely linked to scrA and scrB which encode Enzyme IIScr and sucrose-6-phosphate hydrolase, respectively. In L. lactis K1, these genes and the N5-(1-carboxyethyl)-L-ornithine synthase gene (ceo) are encoded on the sucrose-nisin transposon Tn5306 in the order ceo-scrKAB.

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Trichomonas vaginalis and Tritrichomonas foetus contain glucokinase and not a hexokinase of broad hexose specificity. Tritrichomonas foetus also contains a specific fructokinase which could be resolved from glucokinase by anion exchange chromatography. Native T. vaginalis glucokinase had a Mr of 76,000, and SDS-PAG electrophoresis showed two equally stained bands corresponding to Mr 40,000 and 38,000. Glucose and ATP were by far the best substrates for both trichomonad glucokinases, with Km values as low as 33-35 microM and 75-83 microM, respectively. Substrate saturation curves for these enzymes were all hyperbolic. Tritrichomonas foetus fructokinase required fructose and ATP, with Km values of 200 microM and 81 microM. None of the activities was affected by a number of potential regulatory metabolites, including glucose-6-phosphate. The only exception was AMP which in supraphysiological concentrations had an inhibitory effect on T. foetus fructokinase. In conclusion, the absence of regulation at the hexose phosphorylation step described here, as well as the presence of an easily reversible PPi: fructose-6-phosphate 1-phosphotransferase described previously (Mertens, E., Van Schaftingen, E. & Müller, M. 1989. Mol. Biochem. Parasitol., 37:183-190), suggest that the rate of the 1st part of glycolysis in trichomonads is controlled only by the intracellular availability of hexoses.

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Homogenates of rat pancreatic islets that had been heated for 5 min at 70 degrees C to inactive hexokinases, catalyzed the ATP-dependent phosphorylation of D-fructose. This reaction was dependent on the presence of K+ and was inhibited by D-tagatose although not by D-glucose or D-glucose 6-phosphate. The phosphorylation product was identified as fructose 1-phosphate through its conversion to a bisphosphate ester by Clostridium difficile fructose 1-phosphate kinase. These findings allowed the conclusion that fructokinase (ketohexokinase) was responsible for this process. Similar results were observed with tumoral insulin-producing cells (RINm5F line). Fructokinase may account for a large share of fructose phosphorylation in intact islets, particularly in the presence of D-glucose.

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The three enzymes glucokinase (EC 2.7.1.2), fructokinase (EC 2.7.1.4) and glucose-6-phosphate dehydrogenase (EC 1.1.1.49) were isolated in high yield from extracts of Zymomonas mobilis. The principal steps in the isolation procedures involved the use of selected dye-ligand adsorbent columns, with affinity elution of two of the three enzymes. Glucokinase and fructokinase are dimeric proteins (2 X 33000 Da and 2 X 28000 Da respectively) and glucose-6-phosphate dehydrogenase is a tetramer (4 X 52000 Da). Some similarities in the structural and kinetic parameters of the two kinases were noted, but they have absolute specificity for their substrates. Fructokinase is strongly inhibited by glucose; otherwise non-substrate sugars had little effect on any of the three enzymes.

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The phosphotransferase system (PTS) of the phototrophic bacterium Rhodopseudomonas sphaeroides consists of a component located in the cytoplasmic membrane and a membrane-associated enzyme called "soluble factor" (SF) [Saier, M. H., Feucht, B. U., & Roseman, S. (1971) J. Biol. Chem. 246, 7819--7821]. SF has been partially purified by a combination of hydrophobic interaction and ion-exchange and gel-permeation chromatography. SF is similar to Escherichia coli enzyme I in its molecular characteristics and enzymatic properties. It has a molecular weight of 85 000 and readily dimerizes. Phosphoenolpyruvate and Mg2+ stabilize the dimer. The enzyme catalyzes the conversion of phosphoenolpyruvate into pyruvate and becomes phosphorylated in the process. The phosphoryl group is subsequently transferred to fructose in the presence of R. sphaeroides membranes. SF substitutes for E. coli enzyme I in fructose or glucose phosphorylation with E. coli enzyme II and HPr. The activities of SF with the R. sphaeroides PTS and the E. coli PTS reside on structurally distinct molecules as shown by their response to limited proteolytic digestion and by immunochemical studies. The activity of SF with the E. coli PTS arises during the isolation procedure and is most likely due to the removal of HPr-like protein from SF.

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Transport and metabolism of sucrose in Streptococcus lactis K1 have been examined. Starved cells of S. lactis K1 grown previously on sucrose accumulated [14C]sucrose by a phosphoenolpyruvate-dependent phosphotransferase system (PTS) (sucrose-PTS; Km, 22 microM; Vmax, 191 mumol transported min-1 g of dry weight of cells-1). The product of group translocation was sucrose 6-phosphate (6-O-phosphoryl-D-glucopyranosyl-1-alpha-beta-2-D-fructofuranoside). A specific sucrose 6-phosphate hydrolase was identified which cleaved the disaccharide phosphate (Km, 0.10 mM) to glucose 6-phosphate and fructose. The enzyme did not cleave sucrose 6'-phosphate(D-glucopyranosyl-1-alpha-beta-2-D-fructofuranoside-6'-phosphate). Extracts prepared from sucrose-grown cells also contained an ATP-dependent mannofructokinase which catalyzed the conversion of fructose to fructose 6-phosphate (Km, 0.33 mM). The sucrose-PTS and sucrose 6-phosphate hydrolase activities were coordinately induced during growth on sucrose. Mannofructokinase appeared to be regulated independently of the sucrose-PTS and sucrose 6-phosphate hydrolase, since expression also occurred when S. lactis K1 was grown on non-PTS sugars. Expression of the mannofructokinase may be negatively regulated by a component (or a derivative) of the PTS.

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Fructokinase activity was demonstrated in seven strains of oral streptococci. The enzyme purified from Streptococcus mutans SL-1 was capable of phosphorylating both D-fructose and D-mmannose to their respective 6-phosphates. Phosphorylation of both fructose and mannose was dependent on adenosine 5'-triphosphate and a divalent metal ion. The molecular weight of the purified enzyme was estimated to be 49,000. The apparent Km of the enzyme for fructose was 0.63 mM. This enzyme also utilized mannose as a substrate, with an apparent Km for mannose of 0.37 mM. Since the activities of the enzyme toward mannose and fructose were not separated upon purification of the enzyme and since mannose was a competitive inhibitor of fructose phosphorylation, the purified kinase is a single enzyme, mannofructokinase, with dual specificity for both mannose and fructose. A role for this enzyme in carbohydrate metabolism in S. mutans is postulated.

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