Crystal Structures of Escherichia coli ATP-Dependent Glucokinase and Its Complex with Glucose

Intracellular glucose in Escherichia coli cells imported byphosphoenolpyruvate-dependent phosphotransferase system-independentuptake is phosphorylated by glucokinase by using ATP to yieldglucose-6-phosphate. Glucokinases (EC 2.7.1.2) are functionallydistinct from hexokinases (EC 2.7.1.1) with respect to theirnarrow specificity for glucose as a substrate. While structuralinformation is available for ADP-dependent glucokinases fromArchaea, no structural information exists for the large sequencefamily of eubacterial ATP-dependent glucokinases. Here we reportthe first structure determination of a microbial ATP-dependentglucokinase, that from E. coli O157:H7. The crystal structureof E. coli glucokinase has been determined to a 2.3-Åresolution (apo form) and refined to final R_work/R_free factorsof 0.200/0.271 and to 2.2-Å resolution (glucose complex)with final R_work/R_free factors of 0.193/0.265. E. coli GlK isa homodimer of 321 amino acid residues. Each monomer folds intotwo domains, a small ${alpha}$ /ß domain (residues 2 to 110and 301 to 321) and a larger ${alpha}$ +ß domain (residues 111to 300). The active site is situated in a deep cleft betweenthe two domains. E. coli GlK is structurally similar to Saccharomycescerevisiae hexokinase and human brain hexokinase I but is distinctfrom the ADP-dependent GlKs. Bound glucose forms hydrogen bondswith the residues Asn99, Asp100, Glu157, His160, and Glu187,all of which, except His160, are structurally conserved in humanhexokinase 1. Glucose binding results in a closure of the smalldomains, with a maximal C ${alpha}$ shift of $~$ 10 Å. A catalytic mechanismis proposed that is consistent with Asp100 functioning as thegeneral base, abstracting a proton from the O6 hydroxyl of glucose,followed by nucleophilic attack at the ${gamma}$ -phosphoryl group ofATP, yielding glucose-6-phosphate as the product.

INTRODUCTION

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Introduction

Growth of Escherichia coli by using various fermentable sugarsas carbon sources, including glucose, maltose, galactose, andsucrose, primarily involves the phosphoenolpyruvate-dependentphosphotransferase system (PTS) (reviewed in reference 54).However, a secondary, PTS-independent system for utilizationof glucose also exists, consisting of glucose uptake by galactosepermease (GalP; galactose proton symporter), followed by phosphorylationby glucokinase (GlK; EC 2.7.1.2) to yield the metabolic intermediateglucose-6-phosphate. Although glk mutant strains of E. coli(43) and Bacillus subtilis (63) are not visibly physiologicallyimpaired, this enzyme retains the important function of phosphorylatingany free intracellular glucose. Free cytoplasmic glucose mayarise from di-saccharide hydrolysis, for example, the cleavageof trehalose phosphate in Bacillus subtilis (25), or from metabolismof maltose or isomaltose (61). Indeed, studies of a PTS^–E. coli strain have shown that a growth rate approximately 89%that of wild-type cells can be obtained by overexpression ofGalP alone, suggesting that glucose transport, not GlK-dependentphosphorylation, is limiting growth (28). There is considerableindustrial interest in enhancing the ability of E. coli to transportand phosphorylate glucose in a PTS-independent manner due tothe ability of these strains to direct more carbon flux to aromaticsynthesis pathways (20, 21, 28).

Microbial glucokinases can be divided into three families basedon sequence comparisons. Group I (protein families database[PFAM] accession number PF04587) (7) consists of ATP- and ADP-dependentglucokinases (EC 2.7.1.147) from archaea (reviewed in reference60) and have also been recently identified in eukaryotes (56).This group also includes a novel, bifunctional ADP-dependentGlK/PfK enzyme from Methanococcus jannaschii (59). Group I isthe only group for which crystal structures have been determinedto date. Group II glucokinases (PFAM accession numbers PF02685and COG0837) are ATP-dependent glucokinases that do not havethe classical repressor open reading frame kinase (ROK) sequencemotif (69) and consist of over 50 full and partial protein sequences,including E. coli GlK (43). The overwhelming number of thesesequences (49 of 52) are from bacteria, including both cyanobacteria(8 sequences) and proteobacteria (41 sequences). Group III consistsof ATP-dependent glucokinases from both archaea (24) and bacteria(23, 63, 64) that possess the ROK sequence signature (PFAM accessionnumber PF00480) and have a conserved CXCGX(2)GCXE motif (conservedCys residues are highlighted) (42). Mutagenesis of any of theseCys residues to Ala in Bacillus subtilis GlK results in an inactiveenzyme, suggesting their functional importance (42). The ATP/polyphosphateglucokinase from Mycobacterium tuberculosis (30) and glucomannokinasefrom Anthrobacter sp. strain KM (45) as well as the strictlypolyphosphate-dependent GlK from Microlunatus phosphovorus (66)are also members of this group.

Enzymes that transfer a phosphoryl group to the 6 hydroxyl groupof a hexose include both hexokinases (EC 2.7.1.1), having broadsugar specificity, and glucokinases (EC 2.7.1.2), more specificfor glucose (reviewed in reference 72). In many cases, theseenzymes have been somewhat arbitrarily classified as one orthe other, owing to incomplete experimental data on their sugarspecificity. Glucokinases that utilize ATP as a phosphoryl donormay, in addition, use other nucleoside triphosphates (37, 58)or polyphosphate (reviewed in reference 53) as substrates orboth ATP and polyphosphate (30, 52). Recently, a strictly polyphosphate-dependentglucokinase (EC 2.7.1.63) has been purified from Microlunatusphosphovorus (66). GlK from E. coli has been cloned, purified,and studied kinetically (43). It is a cytoplasmic enzyme having321 residues and a monomeric mass of 35 kDa. This enzyme showsmuch greater activity with glucose than with either mannoseor galactose and shows no activity with fructose, thereby definingit as a glucokinase (43).

Several crystal structures of hexokinases have been determined,including hexokinase A(PI) (10) and B(PII) (4, 38), both fromSaccharomyces cerevisiae, rat type I and Schistosoma mansonihexokinase (46), human brain type I (1, 2, 3, 57), and, recently,human type IV (glucokinase) (36). Only three microbial ADP-dependentGlK structures are available, all from sequence group I. Theseinclude the enzyme from Thermococcus litoralis bound to ADP(33), Pyrococcus horikoshii GlK (70), and Pyrococcus furiosusGlK bound to glucose and AMP (34). However, no structures ofmicrobial glucokinases from either group II or group III arecurrently known.

We have determined the first structure of a member of the groupII microbial glucokinase family, that from E. coli O157:H7 (ecGlK).This structure reveals a dimeric enzyme that has a similar foldto human and yeast hexokinases, indicative of a common ancestralenzyme, although the sequence identity is low (16 to 18%). Keyresidues responsible for glucose and nucleotide binding andcatalysis are conserved, both in sequence as short motifs andin structure. The structure of ecGlK is distinct from that ofthe ADP-dependent GlKs from Archaea. Glucose binding resultsin domain closure, as found in both archaeal GlKs and hexokinases.

MATERIALS AND METHODS

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Materials and Methods

Cloning, expression, and purification. The gene for ecGlK was amplified from E. coli O157:H7 genomicDNA (50) obtained from the American Type Culture Collectionby using primers from Integrated DNA Technologies (Coralville,Iowa) and Pfu DNA polymerase (Stratagene, La Jolla, Calif.).The amplicon was cloned into a pET15 vector derivative in framewith an N-terminal, noncleavable His₆ tag by using a BamHI/EcoRIcloning strategy and was transformed into E. coli BL21(DE3)for expression. For protein production, a 1-liter culture ofLeMaster medium (27) containing ampicillin at a concentrationof 100 µg/liter was inoculated with a 100-ml overnightculture and grown for 2 h at 37°C. isopropyl-ß-D-thiogalactopyranoside(Sigma) was added at a final concentration of 0.1 mM, and theculture continued for 6 h. Cells were harvested by centrifugation(4,000 x g at 4°C for 25 min) and stored at –20°C.

For purification, the cell pellet was resuspended in 30 ml oflysis buffer (50 mM Tris-Cl [pH 7.5], 400 mM NaCl, 10 mM ß-mercaptoethanol,5% (wt/vol) glycerol, 1x BugBuster cell lysis detergent (Novagen),300 U of bezonase nuclease (Novagen), 1.5 mg of lysozyme (Sigma),and 1 tablet of complete EDTA-free protease inhibitor cocktail(Roche Molecular Biologicals). This lysate was applied to a2-ml bed volume of DEAE-Sepharose (Amersham) packed in an Econocolumn (Bio-Rad) and equilibrated with the same buffer. Followingincubation, the mixture was poured into an Econo column, andthe flowthrough was collected. This was applied to a 4-ml bedvolume of Ni-NTA resin (Qiagen) preequilibrated in the samebuffer. Following washing, first in buffer with 1 M NaCl, followedby buffer with 0.3 M NaCl, proteins were eluted by using 25ml of 200 mM imidazole, pH 8. Protein fractions were checkedfor purity by sodium dodecyl sulfate and native polyacrylamidegel electrophoresis; pure fractions were concentrated, and bufferwas exchanged into 20 mM Tris (pH 8), 0.2 M NaCl, 5% glycerol,and 10 mM dithiothreitol by ultrafiltration (Centriprep, Millipore).Approximately 8 mg of pure GlK protein was obtained per literof culture. Protein concentration was determined by the methodof Bradford (14).

DLS. Dynamic light scattering (DLS) was performed by using a DynaProMSPRII molecular sizing instrument (Proterion Corp., Piscataway,N.J.) and analyzed by using Dynamics V6 software. A volume of20 µl of protein (6.3 mg/ml) in buffer (20 mM Tris-Cl[pH 8], 0.2 M NaCl, 5% glycerol, 10 mM dithiothreitol) was analyzedin a 96-well plate at room temperature.

Crystallization. Crystals of apo-ecGlK were obtained by the hanging drop vapordiffusion method in drops containing 2 µl of SeMet-labeledprotein (6.8 mg/ml) and 4 µl of reservoir solution [1.7M (NH₄)₂SO₄, 0.1 M Tris-Cl (pH 8.5)] suspended over 1 ml ofreservoir solution. The crystals belong to the space group P4₃2₁2with the cell dimensions a = b = 81.5 and c = 234.7 Å;the crystals contain two molecules in the asymmetric unit.

Crystals of the ecGlK-glc complex were obtained by the hangingdrop vapor diffusion method in drops containing 2 µl ofSeMet-labeled protein (6.8 mg/ml) and 4 µl of reservoirsolution (18.5 to 20%, wt/vol) (PEG6000; 0.1 M Tris-Cl buffer[pH 8.5], 0.2 M MgCl₂) with the addition of 2 to 3 mM ADP and2 mM glucose suspended over 1 ml of reservoir solution. Thecrystals belong to the space group P2₁ with the following celldimensions: a = 78.5, b = 53.6, and c = 91.1 Å; ß= 113.0°. The crystals contain two molecules in the asymmetricunit.

Data collection, phasing, and refinement. Prior to data collection the crystals were immersed for 10 sin a cryoprotectant solution containing either 2 M (NH₄)₂SO₄,0.1 M Tris-Cl (pH 8.5), 3 M sodium formate (for apo-ecGlK) or23% (wt/vol) PEG6000, 0.1 M Tris-Cl buffer (pH 8.5), 0.2 M MgCl₂,20% (wt/vol) glycerol (for ecGlK-glc), mounted in a nylon loopand flash-cooled in a cold stream of N₂ gas at 100 K. Data werecollected at the beamlines X8C and X25 of the National SynchrotronLight Source (NSLS), Brookhaven National Laboratory, by usinga quantum 4 charge-coupled device detector (X8C) or Q-315 detector(X25) and were processed with either HKL2000 (49) or d*TREK(51).

The structure of ecGlK was determined by using a three-wavelengthmultiwavelength anomalous diffraction experiment at the Se Kedge from SeMet-labeled apo-protein (Table 1). All 10 expectedSe sites were identified by using the program SOLVE (68). Densitymodification and model building were performed by using RESOLVE(67), resulting in a model containing 73% (472 of 642) mainchain and 67% (3,284 of 4,911) total atoms. Further model buildingwas performed by using O (35), alternating with cycles of refinementby using the program Refmac5 (47). The model has been refinedto a final R factor of 0.200 and R_free of 0.271 at a 2.3-Åresolution with no ${sigma}$ -cutoff. The model contains two moleculesin the asymmetric unit and includes residues 2 to 321 in eachmonomer and 387 water molecules.

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TABLE 1. Data collection and refinement statistics

The structure of the ecGlK-glc complex was solved by molecularreplacement by using the program MOLREP (71) from the CCP4 suite(73) with apo-ecGlK used as the starting model. Refinement wasperformed by using the program REFMAC5 (47), giving a finalR factor of 0.193 and R_free of 0.265 at a 2.2-Å resolutionwith no ${sigma}$ -cutoff. The model contains two molecules in the asymmetricunit and includes residues 3 to 321 (monomer A) and 2 to 321(monomer B), one molecule of glucose bound to each monomer,and 465 water molecules. Data collection and refinement statisticsare summarized in Table 1. Both models have good geometry withoutoutliers, as shown by the program PROCHECK (39).

Coordinates. Coordinates of ecGlK have been deposited in the Research Collaboratoryfor Structural Bioinformatics Protein Data Bank (PDB) (11) withaccession codes 1Q18 (apo form) and 1SZ2 (glucose complex).

RESULTS AND DISCUSSION

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Results and Discussion

Structure of the GlK monomer. The structure of apo-ecGlK from the P4₃2₁2 crystal form wasdetermined by a three-wavelength multiwavelength anomalous diffractionexperiment from SeMet-labeled protein (26) and refined to anR factor of 0.200 (R_free = 0.271) at a 2.3-Å resolution.This model contains two molecules in the asymmetric unit andincludes residues 2 to 321 in each monomer. Data collectionand refinement statistics are presented in Table 1.

Each monomer of ecGlK consists of a small ${alpha}$ /ß domainmade of two noncontiguous segments (residues 2 to 110 and 300to 321) and a larger ${alpha}$ +ß domain (residues 111 to 299)(Fig. 1). A total of 13 ß-strands and 11 ${alpha}$ -helicesmake up the monomer and are labeled consecutively from the Nto C terminus, as shown in Fig. 1. The small domain consistsof a single, central, five-stranded mixed ß-sheet(ß3-ß2-ß1-ß4-ß7),with ß2 antiparallel to the rest. This ß-sheetis flanked on one face by a pair of ${alpha}$ -helices ( ${alpha}$ 1 and ${alpha}$ 2) and aß-hairpin (ß5-ß6) and on the oppositeface by a pair of ${alpha}$ -helices ( ${alpha}$ 3 and ${alpha}$ 11). This five-turn-long ${alpha}$ -helix( ${alpha}$ 11, residues 301 to 321) is not contiguous with the rest ofthe domain and comes from the C-terminal end of the monomer.It forms part of the interface between the large and small domains.

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FIG. 1. Ribbon model of the ecGlK monomer. Model uses rainbow colors from the N terminus (blue) to the C terminus (red). ß-strands and ${alpha}$ -helices are numbered sequentially from the N to C terminus. This and subsequent figures were prepared with either PyMOL (18; http://www.pymol.org) or Molscript (19) and Raster3D (41).

The large domain contains a mixed, six-stranded ß-sheet(ß8-ß13-ß12-ß9-ß10-ß11)with ß8 and ß10 antiparallel to the rest.One face of this sheet is adjacent to a cluster of seven ${alpha}$ -helices( ${alpha}$ 4 to ${alpha}$ 10), while the other face is directed toward the smalldomain. A longer central helix, ${alpha}$ 7, forms the core of the ${alpha}$ -helixcluster. The interface between the large and small domains formsthe active site cleft $~$ 28 Å wide and $~$ 20 Å deep. Asingle helix, ${alpha}$ 3 (residues 100 to 109), connects the two domains.

ecGlK dimer structure. Analysis of purified ecGlK by DLS suggested it to be a dimerin solution. Crystallographic analysis of ecGlK revealed a dimerwithin the asymmetric unit. The association of ecGlK monomersto form the dimer structure (Fig. 2) occurs through interactionsbetween the large domains of each monomer such that both activesite clefts are solvent accessible. Secondary structure elementscontributing to the dimer interface include helix ${alpha}$ 4 and adjacentloops, the C-terminal tip of helix ${alpha}$ 7, strand ß10 andthe loop connecting this to strand ß11 (Fig. 2). Thetotal buried surface area upon dimer formation is $~$ 3,060 Å²for both monomers, equivalent to $~$ 10% of the accessible surfacearea of each monomer. Generally, ATP-dependent GlKs of bacterialor archaeal origin are dimeric enzymes, although the GlK fromthe archaeon Aeropyrum pernix is monomeric (24, 58), as is humanglucokinase (36).

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FIG. 2. Ribbon model of the ecGlK dimer. The small domain is depicted in light gray, and the large domain is in dark gray for one monomer (left); the corresponding domains of the second monomer (right) are shown in dark and light gray, respectively. The two glucose molecules bound to the dimer are shown in stick representation.

Many hydrogen bonds and van der Waals contacts are formed betweenthe two monomers (chains A and B) of ecGlK. Hydrogen bonds areformed between the side chains of Arg150(A) and Asp148(B), aswell as Asp162(A) and Lys284(B). There are also backbone H-bondsbetween Leu250(A) and Glu157(B), as well as numerous water-mediatedhydrogen bonds. Contacts between the two monomers are also providedthrough stacking interactions between the side chains of Phe287of one monomer and His160 of the other. As described in thefollowing, Glu157 and His160 are also part of the glucose-bindingsite.

Comparison with yeast and human hexokinases. A recent exhaustive analysis of over 17,000 sequences of kinasesand their relationship to structure (16) classified ecGlK (COG0837)within the RNase H-like kinase group, with representative structuresfrom hexokinase (4), glycerol kinase (32), and acetate kinase(15). These kinases are also members of the sugar kinase-heatshock protein 70-actin superfamily (12, 31) and are classifiedwithin the actin-like ATPase superfamily within SCOP (5). Analignment of selected GlK protein sequences is shown in Fig.3.

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FIG.3. Sequence alignment of representative members of group II glucokinases (PFAM PF02685) as well as human glucokinase (PDB 1V4S) (36), human brain hexokinase I (PDB 1DGK) (3), and hexokinase PII (PDB 1IG8) (38) by means of the ClustalW program (17). Identical residues are shaded. Residues associated with glucose binding (gray triangles) and the catalytic Asp (black rectangle) are indicated. The conserved ß-strand-loop-ß-strand motif associated with ATP-binding (Leu6-Leu19) with identical residues indicated by dark gray ovals is highlighted. The secondary structure elements ( ${alpha}$ -helices and ß-strands) of ecGlK are depicted above the sequence alignment. This figure was prepared by using ESPript (22).

A search for similar structures by using the DALI server (29;http://www.ebi.ac.uk/dali/) found that the most similar structureswere human brain hexokinase I (PDB code 1QHA) (57) and hexokinaseB (also known as hexokinase PII) from S. cerevisiae (PDB 2YHX)(4). Yeast hexokinase PII is somewhat larger than ecGlK, comprising486 residues (38), while human hexokinase type I is much larger,consisting of two $~$ 50-kDa chains (72). Each chain contains twoglobular units, an N-terminal regulatory domain (residues 1to 474) and a C-terminal catalytic domain (residues 475 to 917)separated by a long ${alpha}$ -helical linker (1). Each domain of humanhexokinase I is structurally similar to the yeast hexokinasemonomer (1) and to monomeric human glucokinase (36). Superpositionof ecGlK with the human brain hexokinase I catalytic domaingave a root mean square deviation (rmsd) of 1.66 Å for157 C ${alpha}$ atoms and 1.88 Å for 188 C ${alpha}$ atoms for human glucokinase,while a similar superposition between ecGlK and yeast hexokinasePII gave an rmsd of 1.77 Å for 149 C ${alpha}$ atoms. A redeterminationof the yeast hexokinase PII structure reported by Anderson etal. (4) with the correct amino acid sequence (PDB 1IG8) (38)reveals a very similar fold for the two yeast PII hexokinasestructures.

A superposition of ecGlK and yeast and human hexokinases isshown in Fig. 4. Structural similarities are most pronouncedin the core regions of the structures. This structural similarityexists despite low ( $~$ 16 to 18%) sequence identity between ecGlKand the two hexokinases. Bacterial glucokinases, of which ecGlKis a member, along with yeast and human hexokinases had previouslybeen identified as members of the "hexokinase family," sharingseveral short sequence motifs and predicted to have similarfolds (13). Comparison of the structures of ecGlK and humanhexokinase I shows that the fold of the small domain is verysimilar, except for the absence of the ß-hairpin (ß5-ß6)in human hexokinase I (Fig. 5). There are greater differencesbetween the large domains (Fig. 5). The core mixed ß-sheet(ß13-ß12-ß9-ß10-ß11)is preserved in both hexokinase and ecGlK, although there isone extra ß-strand (ß8) at the C-terminalside of the sheet in ecGlK and one extra ß-strand(ß1) which comes from the N-terminal segment at theopposite side of the sheet in hexokinase (Fig. 5). Absent fromecGlK are specific structural features of eukaryotic hexokinases,including an N-terminal mitochondrial membrane-targeting sequence(46), and distinct, specific binding sites for the allostericinhibitor glucose-6-phosphate (1) or nucleotide related to dissociationof hexokinase from the membrane (57). Evidently, yeast and humanhexokinases as well as ecGlK evolved from a common ancestor,retaining similar overall structures while diverging in sequence.

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FIG. 4. Structure superposition of ecGlK (red), S. cerevisiae hexokinase PII (PDB 1IG8, green) (38), and the catalytic domain (residues 475 to 917) of human brain hexokinase I (PDB 1QHA, blue) (57). The dotted line delineates the small domain (top) from the large domain (bottom).

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FIG. 5. Comparison of fold topologies of ecGlK monomer (a) and catalytic domain (residues 475 to 917) (b) of human brain hexokinase I (PDB 1IG8).

A comparison of the structures of ecGlK and the ADP-dependentGlKs revealed no significant structural similarity between thesetwo groups of glucokinases. Both enzymes consist of a smalland a large domain, with the active site cleft between the domains.The folds of both small and large domains differ in ecGlK andthe ADP-dependent GlKs. This result is consistent with the ideathat ADP-dependent GlKs adopt a ribokinase-like fold (16, 33).

In rat hexokinase (46) and human hexokinase I (1), the dimeris formed through the association of N- and C-terminal domainsfrom the two respective chains, yielding a head-to-tail arrangement.Dimerization is not essential for human hexokinase I in vitro,as monomeric enzyme retains activity (72). A comparison of thedimerization interfaces of ecGlK with the interface of humanhexokinase I (PDB 1QHA) reveals that opposite faces of the respectivemonomers are associated with the dimer interface in these twoenzymes, although the monomers themselves are structurally similar(Fig. 4). Similarly, the region of ecGlK involved in dimerizationis not structurally conserved in the S. cerevisiae hexokinasePII (PDB 2YHX) structure (4). The monomer-dimer equilibriumof yeast PII hexokinase is influenced by pH, ionic strength,glucose concentration, and phosphorylation at Ser14 (8). Whetheryeast hexokinase PII functions as a monomer or dimer in vivois unclear.

A further difference between ecGlK and the ADP glucokinasesis at the level of quaternary structure. The ADP-dependent GlKfrom P. furiosus does appear to be a dimer both in solutionand in the crystal, with a disulfide bond between the side chainsof Cys94 (34). The nearly identical enzyme activity of the C94Smutant GlK, which does not dimerize, compared with that of thenative enzyme, as well as the lack of sequence conservationof this Cys residue in other GlKs suggests that the covalentlylinked dimer is not the physiologically relevant structure ofthis enzyme (34). The two ADP-dependent GlKs structurally characterizedfrom P. horikoshii (70) and T. litoralis (33) are monomericenzymes.

Glucose-binding site. Crystals of apo-ecGlK soaked in reservoir solution containinglow concentrations of glucose immediately cracked and dissolved,prohibiting structure determination. Cocrystallization experimentsof ecGlK in the presence of glucose yielded a new crystal formin space group P2₁. The structure of the ecGlK-glc complex wasdetermined by molecular replacement by using the native structureas the search model and was refined to an R factor of 0.193(R_free = 0.265) at a resolution of 2.2 Å.

Inspection of the initial F_o-F_c difference map in the activesite region revealed the presence of density corresponding tobound glucose in both ecGlK monomers (Fig. 6a). The bound glucosemolecule is in a chair conformation and adopts the ß-anomericconfiguration. Both glucose molecules are well ordered withlow B-factors, indicating good occupancy for their respectivebinding sites.

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FIG. 6. (a) F_o-F_c omit map of the ecGlK active site region, showing electron density for glucose. Glucose and water molecules were omitted prior to refinement. This map is contoured at the level of 3 ${sigma}$ . Hydrogen bonds between glucose and ecGlK active site residues and waters are shown as dashed lines. (b) Structural superposition of the active site regions of ecGlK-glc (light gray) and human brain hexokinase I (PDB 1DGK; dark gray) depicted in stereo. The superposition was generated by using the atoms of the glucose molecule and residues corresponding to Asn99, Asp100, Glu157, and Glu187 of ecGlK.

Each glucose molecule participates in an extensive hydrogenbonding network within the active site pocket (Table 2 and Fig.6a). All of the interacting residues are highly conserved withinthe related sequences of group II GlKs (PFAM accession numberP46880) (Fig. 3). The residues Asn99, Asp100, Glu157, and Glu187are also conserved both in sequence (Fig. 3) and structurally(Fig. 6b) in human hexokinase I. In human hexokinase I (PDB1DGK), structurally equivalent residues to those of ecGlK (inparentheses) are Glu708 (Glu157), Gln739 (His160), Glu742 (Glu187),Asn656 (Asn99), and Asp657 (Asp100). Site-specific mutationsof Asp657, Glu708, and Glu742 of human hexokinase I have beenpreviously shown to abolish activity in vitro (6). The Glu708Alaand Glu742Ala mutations reduced the K_M for glucose by 50- and14-fold, respectively (6). A water-mediated hydrogen bond betweenthe O6 atom of glucose and the amide N of Gly138 is also presentin human hexokinase I.

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TABLE 2. Summary of direct and water-mediated hydrogen bonds between ecGlK and glucose^a

Intrinsic flexibility of ecGlK. The cracking and dissolving of apo-ecGlK crystals when soakedin the presence of glucose was suggestive of ligand-inducedconformational changes in the enzyme, analogous to those foundinitially in yeast hexokinase (9, 65) and subsequently in humanhexokinase I (2) and ADP-dependent GlKs (34). Superpositionof yeast hexokinase and its complex with glucose revealed closingof the domains relative to one another, effectively buryingthe substrate (65). A similar finding has been observed withP. furiosus GlK in the presence of bound glucose (34), wherecomparison of this structure with the related apo-GlK from T.litoralis showed a maximal shift in C ${alpha}$ positions of 12 Åat the tip of the small domain.

The dimer interfaces for ecGlK and ecGlK-glc are very similarbut not identical. In ecGlK-glc, the H bond between Asp148^OD1(A)-Arg150^NH1(B)is not maintained. Dimers of ecGlK and ecGlK-glc were superimposedby using C ${alpha}$ atoms of the large domains (residues 120 to 300)of both molecules of the dimer, giving an rmsd of 0.42 Åfor 372 C ${alpha}$ atoms. While the large domains are fixed through theirinteractions in the dimer, the small domains in both monomersare rotated by $~$ 15°, resulting in a maximum C ${alpha}$ displacementof $~$ 10 Å (Fig. 7a). As a consequence of this movement,the active site cleft becomes more closed.

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FIG.7. Domain-domain movements of ecGlK. (a) Superposition of dimers of ecGlK (red) and ecGlK-glc (blue). The superposition is based on the large domains of each model, showing the large relative movement of the small domains. Glucose is shown in stick representation. (b) Superposition of the large domains of ecGlK and ecGlK-glc with both monomers within the asymmetric unit in both crystal forms, showing the intrinsic conformational flexibility of ecGlK. Shown are the two monomers of ecGlK (monomer A, blue; monomer B, yellow) and the two monomers of ecGlK-glc (monomer A, cyan; monomer B, magenta). (c) Close-up of superposition of monomer A of ecGlK (red) and ecGlK-glc (blue) showing the glucose-binding site. Glucose is shown in stick representation.

Comparison of the overall structures of the two monomers ofthe apo-ecGlK dimer reveals that a few loops within the smalldomain have different conformations in the two monomers. Superpositionof the two apo-ecGlK monomers by using only the large domainsreveals the intrinsic conformational flexibility of this enzyme(Fig. 7b), as has been previously observed with yeast hexokinasein solution studies (55). The maximal C ${alpha}$ displacement for residuesin the small domain in this superposition is for Thr78, displacedby 7 Å, part of the loop which closes the glucose-bindingsite. Superposition of the two monomers gave an rmsd of 1.3Å for 320 C ${alpha}$ atoms, while superposition of C ${alpha}$ atoms of thelarge domain alone gave an rmsd of 0.38 Å for 186 C ${alpha}$ atoms.In ecGlK-glc, glucose binding stabilizes these flexible loops,resulting in their adopting the same conformation in both monomers.These observations imply that while glucose binding stabilizesthe closed form, domain-domain movements occur in apo-ecGlKindependently of glucose binding and reflect the intrinsic flexibilityof the enzyme.

The only structural change observed within the small domainsthemselves upon glucose binding is a movement of the loop consistingof residues 73 to 79. Between large and small domains, a numberof hydrogen bonds are broken as a result of domain closure includingthose between Glu315^NE2 and Trp131 O, Glu315^OE1 and Trp151 N,and Asn303^OD1 and Arg16^NH1 as well as Thr32^OG1 and Arg16^NE.New hydrogen bonds formed after domain closure include thosebetween Asn303^OD and Arg16^NE and between Thr32^OG and Arg16^NH1.Several van der Waals contacts are also broken and reformedas a consequence of domain movement. Of those residues involvedin glucose binding, only Asn99 and Asp100 undergo significantmovement in comparison to apo-ecGlK and glucose-bound ecGlK(Fig. 7c).

Putative ATP-binding site. Although we could not obtain a complex between ecGlK and ADP/Mg²⁺,either in the presence or absence of glucose, a comparison ofecGlK with the structures of mutant human hexokinase I boundto ADP-glucose (3) or yeast hexokinase PII bound to sulfate(38) offers insights into the likely ATP-binding site of ecGlK.The ADP-binding site of a quadruple mutant of hexokinase I hasbeen determined (PDB 1DGK) (3). Indeed, the nucleotide-bindingsite is structurally conserved in all members of this superfamily,as predicted by Bork et al. (12).

First, the positions of the sulfate anion of apo-yeast hexokinasePII and P ${alpha}$ of ADP from the human hexokinase binary complex superimpose,with a 0.65-Å distance between the P and S atoms, respectively.This position has been identified as a high-affinity anion bindingsite in a number of hexokinase structures (10, 46). In the caseof human hexokinase I, the ${alpha}$ -phosphoryl group makes hydrogenbonds with Thr680^OG1 and Thr680N as well as with Thr863N. Inyeast hexokinase PII, Ser419^OG1, the structural equivalent ofThr863, forms a hydrogen bond with an O atom of the sulfateanion. Other hydrogen bonds with the sulfate are formed withSer419N, Thr234^OG1, and Thr234N. This last residue is the yeastequivalent of Thr680 of human hexokinase. Superposition of thesemodels with ecGlK reveals that Thr137 of ecGlK is structurallyequivalent to Thr234 of yeast hexokinase and Thr680 of humanhexokinase. In addition, Thr137N could participate in a hydrogenbond with the ${alpha}$ -phosphoryl group, analogous to that of Thr234Nand Thr680N of yeast and human hexokinases, respectively.

As with other kinases, a metal ion, such as Mg²⁺ or Mn²⁺, isexpected to be an essential component of the catalytic machinery(40). No cocrystal structure of hexokinase or glucokinase withbound Mg²⁺ has yet been reported. The side chains of Thr680(Thr137 of ecGlK), Asp532 (Asp9 of ecGlK) or Asp861 (HK1; PDB1DGK) appear proximal enough to the phosphoryl groups of thenucleotide binding site that they could participate in Mg²⁺binding. Both Thr137 and especially Asp9 are highly conservedin the sequences of group II GlKs (Fig. 3). A combination ofmodeling (3) and electron paramagnetic resonance studies insolution (48) suggest that Mn²⁺ or Mg²⁺ may only form water-mediatedinteractions with the enzyme. Consistent with the importanceof Asp532, the mutations Asp532Lys and Asp532Glu have been shownto decrease k_cat of human hexokinase I by 1,000- and 200-fold,respectively (74). A hydrated Mg²⁺ binding site has also beensuggested for the P. furiosus ADP-dependent glucokinase (34).

In the human hexokinase I complex, key residues interactingwith ADP include Thr680^OG1 (P ${alpha}$ ), Thr683^OG1 (Pß andO5' of ribose), and Asn537^ND2 (Pß). Asn537 is partof a loop, conserved in sequence between ecGlK (Asn14) and yeasthexokinase (Asn91), and is associated with nucleotide binding.A Thr680Val mutant of hexokinase I showed a decrease in k_catof $~$ 2,000-fold, while the Thr680Ser mutant only decreased $~$ 2.5-fold,showing the importance of this hydrogen bond in catalysis (74).

A conserved sequence and structural motif consisting of twoß-strands connected by a loop within the small domain(residues Leu6-Leu19 of ecGlK) (Fig. 3) has the sequence L-(A/V)-X-D-X-G-G-T-N-X-R-X-X-L(conserved Asp and Gly residues are in boldface) and is proximalto the ATP phosphoryl group binding site. In particular, theresidues equivalent to Leu6, Asp9, Gly11, Gly12, Asn14, Arg16,and Leu19 are completely conserved in the sequence alignmentof ecGlK, human hexokinase, and yeast hexokinase as well ashuman glucokinase (Fig. 3). A similar motif [X₂-D-(I/L/V)-G-G-(S/T-X₃);conserved Asp and Gly residues are in boldface] is conservedas well in group III (ROK) glucokinases (30, 45) and is equivalentto a portion of the phosphate 1 motif identified originallyby Bork et al. (13). The two conserved Gly residues contributeto formation of the loop and could form main chain hydrogenbonds with the ATP phosphates. Indeed, the mutation Gly534Alaof hexokinase I (Gly11 of ecGlK) results in a decrease of k_catby 4,000-fold (75). In the human hexokinase I-ADP-glucose complex,this loop has adopted the most closed conformation and makesdirect hydrogen bonds between the phosphate O atom bridgingthe ${alpha}$ and ß phosphoryl groups and Ala536N, as wellas between a P_ß O atom and Asn537N (Fig. 8). Importantly,in the human hexokinase I binary complex, Thr536 has been mutatedto Ala, yet k_cat/K_M for neither glucose nor ATP is significantlyperturbed (3). This argues that the backbone conformation ofthis loop is important for nucleotide binding, rather than thepresence of the Thr536 side chain specifically, although modelingsuggests that Thr536^OG can evidently form a hydrogen bond withthe P-P_ß bridging O (data not shown). Asn537^ND2 alsoforms a hydrogen bond with an O atom of P_ß. We suggestthat similar interactions would be found in yeast hexokinaseand ecGlK in the presence of bound nucleotide and glucose. Itis evident that a secondary conformational change of this conservedstrand-loop-strand motif must occur upon nucleotide binding,resulting in further domain closure, in addition to that whichoccurs upon glucose binding (Fig. 8).

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FIG. 8. Potential ATP-binding site of ecGlK. Superposition of the ADP-binding site of the catalytic domain (residues 475 to 917) of mutant human hexokinase bound to ADP and glucose (PDB 1DGK; blue) (3), yeast PII hexokinase bound to sulfate (PDB 1IG8; green) (38), and ecGlK (magenta). Hydrogen bonds between Thr and Asn of human hexokinase and ADP are shown. The conserved sequence motif near the ATP-binding site [L-(A/V)-X-D-X-G-G-T-N-X-R-X-X-L] is shown as thicker lines.

Catalytic mechanism. The expected chemical mechanism of catalysis for ecGlK, analogousto that of other kinases, is S_N2 nucleophilic attack of theO6 atom of glucose on the electropositive P atom of the ${gamma}$ -phosphorylgroup of ATP. Initial abstraction of the proton from the CH₂OHgroup of O6 is presumably performed by Asp100 acting as a generalbase. Asp100^OD2 is positioned 2.7 Å from O6 and is welloriented to fulfill this role (Fig. 6a). The Asp100 side chainposition is anchored by hydrogen bonds to O4 of glucose andAsn99^OD1, a highly conserved residue (Fig. 3). This mechanismis consistent with the complete conservation of Asp100 in groupII glucokinase sequences and in human hexokinase (Asp657 ofhuman hexokinase I) and glucokinase. Of the residues involvedin glucose binding, the mutant Asp657Ala showed the largesteffect on activity, resulting in a reduction in k_cat of 100-foldrelative to wild-type enzyme (6).

In the ADP-dependent glucokinases, the residue Asp451 of T.litoralis GlK is predicted to function as a general base. Thisresidue interacts with the O6 atom of glucose and when mutatedto Ala shows a specific activity of <0.001% compared to wild-typeenzyme (34). A structurally equivalent residue, Asp440 of P.furiosus GlK, is predicted to function as a general base inthis enzyme (34).

In human hexokinase I, a second residue, Lys621, is also withinhydrogen bonding distance of Glc O6 and has been suggested asa possible catalytic residue (46). However, there is no structuralequivalent of the Lys621 residue in ecGlK. Modeling of ATP boundto ecGlK, based on the superposition with ADP-bound human hexokinaseI, positions the O6 atom of glucose to within a suitable distanceof the ${gamma}$ -phosphoryl group for in-line nucleophilic attack. Thedistance between O6 of glucose and the P atom of mutant humanhexokinase I (PDB 1DGK) is 5.6 Å. To accomplish the correctorientation of the ${gamma}$ -phosphoryl group, the ATP ß- and ${gamma}$ -phosphoryl groups would need to adopt an extended conformation.No specific residue required to function as a general acid,responsible for protonating ADP as the leaving group, has beenidentified in hexokinase, although the possibility that it arisesfrom a water molecule coordinated to Mg²⁺ has been suggested(3).

The kinetic mechanism of several glucokinases has been investigatedand found to have a preferred order of substrate addition andproduct release. In the ATP-dependent glucokinases from Zymomonasmobilis (62), Propionibacterium shermanii, (37) and rat liverhexokinase IV (glucokinase, 44), the preferred order of substrateaddition is glucose (or 2-deoxyglucose) followed by ATP or Mg²⁺.This kinetic mechanism in consistent with the ecGlK crystalstructures, in that glucose binding stabilizes a closed formof ecGlK that can bind ATP, in turn resulting in a small butimportant conformational change necessary to form a catalyticallycompetent form of the enzyme.

ACKNOWLEDGMENTS

We thank Leon Flaks (NSLS; beamline X8C) and Michael Becker(NSLS; beamline X25) for assistance in data collection, StephaneRaymond for maintenance of the computing environment, and FredericOuellet and J. Sivaraman for assistance in protein purificationand crystallization.

This research was supported in part by the Canadian Institutesof Health Research grant 200103GSP-90094-GMX-CFAA-19924 to M.C.

FOOTNOTES

* Corresponding author. Mailing address: Biotechnology Research Institute, NRCC, 6100 Royalmount Ave., Montreal, Quebec H4P 2R2 Canada. Phone: (514) 496-2557. Fax: (514) 496-5143. E-mail: allan.matte{at}nrc-cnrc.gc.ca.

REFERENCES

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