Refined structure of porcine cytosolic adenylate kinase at 2.1 A resolution

The crystal structure of porcine cytosolic adenylate kinase has been established at 2.1 A resolution using a restrained least-squares refinement method. Based on 11,251 independent reflections of better than 10 A resolution, a final R-factor of 19.3% was obtained with a model obeying standard geometry within 0.026 A in bond lengths and 3.3 degrees in bond angles. In comparison with the previous structure at 3 A resolution, there is a significant improvement. The high resolution structure has been used to rationalize the strictly conserved residues in the adenylate kinase family. Among these is the glycine-rich loop, which forms a giant anion hole accommodating a sulfate ion which mimics a phosphoryl group of a substrate. Such a structure seems to occur in a large group of mononucleotide binding proteins. Moreover, a conserved cis-proline has been detected in the active center. A structural comparison with the complex between adenylate kinase from yeast and a substrate-analog at medium resolution indicates that this kinase performs appreciable mechanical movements during a catalytic cycle. The reported structure presumably represents an open form of the enzyme, similar to that in solution in the absence of substrates. However, since there are large intermolecular contacts in the crystal, some deviation from the solution structure has to be expected.     

The glycine-rich loop of adenylate kinase forms a giant anion hole

The conformation of the glycine-rich loop of adenylate kinase is described in detail. It forms a giant anion hole for a sulfate ion, which presumably mimicks a nucleotide phosphoryl group. This loop had been called flexible, because at pH values of 6 or below it is displaced in the crystal. In the region of this loop the adenylate kinases are probably homologous to the p21 proteins. Is is known that a mutation in this loop at residue 12 of p21 causes cell transformation and therefore cancer. Other potentially homologous proteins are indicated.     

Structure of the complex of yeast adenylate kinase with the inhibitor P1,P5-di(adenosine-5'-)pentaphosphate at 2.6 A resolution

Adenylate kinase from yeast cytosol was crystallized as a 1:1 complex with the inhibitor P1,P5-di(adenosine-5'-)pentaphosphate. The crystalline structure was solved by multiple isomorphous replacement at a resolution of 3 A (1 A = 0.1 nm) and subsequent structural refinement at 2.6 A resolution. The yeast enzyme belongs to the group of large variants among the adenylate kinases, whereas the structurally known porcine cytosolic enzyme is a small variant. A comparison showed that the additional 31-residue segment of the large variants covers the active center. This had not been expected, because small and large variants show similar enzyme kinetics. Apart from this insertion, the chain folds of both adenylate kinases are the same. The yeast enzyme with bound inhibitor, however, assumes a much more closed form. In relation to the porcine enzyme without substrate, a segment of 28 residues containing two helices is rotated by about 30 degrees, closing the deep cleft at the active center. This corresponds to the expected induced fit. Sequence comparisons with other adenylate kinases suggest that one of the adenosine moieties of the inhibitor does not bind at a native nucleotide-binding site of the enzyme.     

Conformational changes during the catalytic cycle of gluconate kinase as revealed by X-ray crystallography

The crystal structure of gluconate kinase from Escherichia coli has been determined to 2.0 A resolution by X-ray crystallography. The three-dimensional structure was solved by multi-wavelength anomalous dispersion, using a crystal of selenomethionine-substituted enzyme. Gluconate kinase is an alpha/beta structure consisting of a twisted parallel beta-sheet surrounded by alpha-helices with overall topology similar to nucleoside monophosphate (NMP) kinases, such as adenylate kinase. In order to identify residues involved in substrate binding and catalysis, structures of binary complexes with ATP, the ATP analogue adenosine 5'-(beta,gamma-methylene) triphosphate and the product, gluconate-6-phosphate have been determined. Significant conformational changes are induced upon binding of ATP to the enzyme. The largest changes involve a hinge-bending motion of the NMP(bind) part and a motion of the LID with adjacent helices, which opens the cavity to the second substrate, gluconate. Opening of the active site cleft upon ATP binding is the opposite of what has been observed in the NMP kinase family so far, which usually close their active site to prevent fortuitous hydrolysis of ATP. The conformational change positions the side-chain of Arg120 to stack with the purine ring of ATP and the side-chain of Arg124 is shifted to interact with the alpha-phosphate in ATP, at the same time protecting ATP from solvent water. The beta and gamma-phosphate groups of ATP bind in the predicted P-loop. A conserved lysine side-chain interacts with the gamma-phosphate group, and might promote phosphoryl transfer. Gluconate-6-phosphate binds with its phosphate group in a similar position as the gamma-phosphate of ATP, consistent with inline phosphoryl transfer. The gluconate binding-pocket in GntK is located in a different position than the nucleoside binding-site usually found in NMP kinases.     

The crystal structure of Mycobacterium tuberculosis adenylate kinase in complex with two molecules of ADP and Mg2+ supports an associative mechanism for phosphoryl transfer

The crystal structure of Mycobacterium tuberculosis adenylate kinase (MtAK) in complex with two ADP molecules and Mg2+ has been determined at 1.9 A resolution. Comparison with the solution structure of the enzyme, obtained in the absence of substrates, shows significant conformational changes of the LID and NMP-binding domains upon substrate binding. The ternary complex represents the state of the enzyme at the start of the backward reaction (ATP synthesis). The structure is consistent with a direct nucleophilic attack of a terminal oxygen from the acceptor ADP molecule on the beta-phosphate from the donor substrate, and both the geometry and the distribution of positive charge in the active site support the hypothesis of an associative mechanism for phosphoryl transfer.     

Dynamic features of cAMP-dependent protein kinase revealed by apoenzyme crystal structure

To better understand the mechanism of ligand binding and ligand-induced conformational change, the crystal structure of apoenzyme catalytic (C) subunit of adenosine-3',5'-cyclic monophosphate (cAMP)-dependent protein kinase (PKA) was solved. The apoenzyme structure (Apo) provides a snapshot of the enzyme in the first step of the catalytic cycle, and in this unliganded form the PKA C subunit adopts an open conformation. A hydrophobic junction is formed by residues from the small and large lobes that come into close contact. This "greasy" patch may lubricate the shearing motion associated with domain rotation, and the opening and closing of the active-site cleft. Although Apo appears to be quite dynamic, many important residues for MgATP binding and phosphoryl transfer in the active site are preformed. Residues around the adenine ring of ATP and residues involved in phosphoryl transfer from the large lobe are mostly preformed, whereas residues involved in ribose binding and in the Gly-rich loop are not. Prior to ligand binding, Lys72 and the C-terminal tail, two important ATP-binding elements are also disordered. The surface created in the active site is contoured to bind ATP, but not GTP, and appears to be held in place by a stable hydrophobic core, which includes helices C, E, and F, and beta strand 6. This core seems to provide a network for communicating from the active site, where nucleotide binds, to the peripheral peptide-binding F-to-G helix loop, exemplified by Phe239. Two potential lines of communication are the D helix and the F helix. The conserved Trp222-Phe238 network, which lies adjacent to the F-to-G helix loop, suggests that this network would exist in other protein kinases and may be a conserved means of communicating ATP binding from the active site to the distal peptide-binding ledge.     

Two conformations of crystalline adenylate kinase.

Pig muscle adenylate kinase (EC2.7.4.3) can exist in three crystal forms, which are interconvertible. For crystal form A the enzyme structure is known in atomic detail. We report the X-ray diffraction analysis of crystal form B at 4.7 Å resolution and a comparison with the A form. During the transition from A to B the packing arrangement of the molecules changes slightly. Moreover, the individual molecule undergoes an appreciable conformational change: by displacing a chain segment of seven residues and two adjacent α-helices a hydrophobic pocket is opened deep in the cleft near the centre of the molecule. Concomitantly the β-pleated sheet is enlarged by about four hydrogen bonds in the B form. Several lines of evidence indicate that the observed conformational change is an intrinsic property of the molecule and is not induced by crystal packing forces.     

Associative mechanism for phosphoryl transfer: a molecular dynamics simulation of Escherichia coli adenylate kinase complexed with its substrates

The ternary complex of Escherichia coli adenylate kinase (ECAK) with its substrates adenosine monophosphate (AMP) and Mg-ATP, which catalyzes the reversible transfer of a phosphoryl group between adenosine triphosphate (ATP) and AMP, was studied using molecular dynamics. The starting structure for the simulation was assembled from the crystal structures of ECAK complexed with the bisubstrate analog diadenosine pentaphosphate (AP(5)A) and of Bacillus stearothermophilus adenylate kinase complexed with AP(5)A, Mg(2+), and 4 coordinated water molecules, and by deleting 1 phosphate group from AP(5)A. The interactions of ECAK residues with the various moieties of ATP and AMP were compared to those inferred from NMR, X-ray crystallography, site-directed mutagenesis, and enzyme kinetic studies. The simulation supports the hypothesis that hydrogen bonds between AMP's adenine and the protein are at the origin of the high nucleoside monophosphate (NMP) specificity of AK. The ATP adenine and ribose moieties are only loosely bound to the protein, while the ATP phosphates are strongly bound to surrounding residues. The coordination sphere of Mg(2+), consisting of 4 waters and oxygens of the ATP beta- and gamma-phosphates, stays approximately octahedral during the simulation. The important role of the conserved Lys13 in the P loop in stabilizing the active site by bridging the ATP and AMP phosphates is evident. The influence of Mg(2+), of its coordination waters, and of surrounding charged residues in maintaining the geometry and distances of the AMP alpha-phosphate and ATP beta- and gamma-phosphates is sufficient to support an associative reaction mechanism for phosphoryl transfer.     

Conversion of the maltogenic alpha-amylase Novamyl into a CGTase

Novamyl is a thermostable five-domain maltogenic alpha-amylase that shows sequence and structural homology with the cyclodextrin glycosyltransferases (CGTases). Comparing X-ray crystal structures of Novamyl and CGTases, two major differences in the active site cleft were observed: Novamyl contains a loop insertion consisting of five residues (residues 191-195) and the location of an aromatic residue known to be essential to obtain an efficient cyclization reaction. To convert Novamyl into a cyclodextrin (CD)-producing enzyme, the loop was deleted and two substitutions, F188L and T189Y, were introduced. Unlike the parent Novamyl, the obtained variant is able to produce beta-CD and showed an overall conversion of starch to CD of 9%, compared with CGTases which are able to convert up to 40%. The lower conversion compared with the CGTase is probably due to additional differences in the active site cleft and in the starch-binding E domain. A variant with only the five-residue loop deleted was not able to form beta-CD.     

Structure of yeast hexokinase. 3. Low resolution structure of a second crystal form showing a different quaternary structure, heterologous interaction of subunits and substrate binding

A 7 Å resolution electron density map of a second crystal form (called BII) of yeast hexokinase B has been obtained. This crystal form, unlike the first crystal form (BI), binds nucleotide and sugar substrates. While the overall tertiary structure of each subunit appears to be largely the same in both crystal forms, the quaternary structure of the dimer is completely different in the two crystals. The two subunits in the crystallographic asymmetric unit of form BII are related by a molecular screw axis; that is, the two subunits are related by a 160 ° rotation and a 13 Å translation of one subunit relative to the other along the symmetry axis resulting in non-equivalent environments for the two chemically identical subunits. A deep cleft divides each subunit into two domains or lobes of roughly equal size. The helical regions which are clearly visible as rods of electron density in this map constitute at least 40 to 50% of the polypeptide chain and 70 to 80% of one of the lobes. At this resolution the molecule does not appear to be homologous in detail to other kinases such as phosphoglycerate kinase and adenylate kinase. Sugar substrates and inhibitors bind deeply in the cleft which separates the two lobes and produce substantial alterations in the protein structure.     

Structure of the Methanococcus jannaschii mevalonate kinase, a member of the GHMP kinase superfamily.

The mevalonate-dependent pathway is used by many organisms to synthesize isopentenyl pyrophosphate, the building block for the biosynthesis of many biologically important compounds, including farnesyl pyrophosphate, dolichol, and many sterols. Mevalonate kinase (MVK) catalyzes a critical phosphoryl transfer step, producing mevalonate 5'-phosphate. The crystal structure of thermostable MVK from Methanococcus jannaschii has been determined at 2.4 A, revealing an overall fold similar to the homoserine kinase from M. jannaschii. In addition, the enzyme shows structural similarity with mevalonate 5-diphosphate decarboxylase and domain IV of elongation factor G. The active site of MVK is in the cleft between its N- and C-terminal domains. Several structural motifs conserved among species, including a phosphate-binding loop, have been found in this cavity. Asp(155), an invariant residue among MVK sequences, is located close to the putative phosphate-binding site and has been assumed to play the catalytic role. Analysis of the MVK model in the context of the other members of the GHMP kinase family offers the opportunity to understand both the mechanism of these enzymes and the structural details that may lead to the design of novel drugs.     

In vivo import of yeast adenylate kinase into mitochondria affected by site-directed mutagenesis.

Site-directed mutagenesis and deletions were used to study mitochondrial import of a major yeast adenylate kinase, Aky2p. This enzyme lacks a cleavable presequence and occurs in active and apparently unprocessed form both in mitochondria and cytoplasm. Mutations were applied to regions known to be surface-exposed and to diverge between short and long isoforms. In vertebrates, short adenylate kinase isozymes occur exclusively in the cytoplasm, whereas long versions of the enzyme have mitochondrial locations. Mutations in the extra loop of the yeast (long-form) enzyme did not affect mitochondrial import of the protein, whereas variants altered in the central, N- or C-terminal parts frequently displayed increased or, in the case of a deletion of the 8 N-terminal triplets, decreased import efficiencies. Although the N-terminus is important for targeting adenylate kinase to mitochondria, other parameters like internal sequence determinants and folding velocity of the nascent protein may also play a role.     

Ligand binding-induced conformational changes in riboflavin kinase: structural basis for the ordered mechanism

Riboflavin kinase (RFK) is an essential enzyme catalyzing the phosphorylation of riboflavin (vitamin B(2)) in the presence of ATP and Mg(2+) to form the active cofactor FMN, which can be further converted to FAD. Previously, the crystal structures of RFKs from human and Schizosaccharomyces pombe have been determined in the apo form and in complex with MgADP. These structures revealed that RFK adopts a novel kinase fold and utilizes a unique nucleotide binding site. The structures of the flavin-bound RFK obtained by soaking pre-existing crystals were also reported. Because of crystal packing restraints, these flavin-bound RFK complexes adopt conformations nearly identical with that of corresponding flavin-free structures. Here we report the structure of human RFK cocrystallized with both MgADP and FMN. Drastic conformational changes associated with flavin binding are observed primarily at the so-called Flap I and Flap II loop regions. As a result, the bound FMN molecule now interacts with the enzyme extensively and is well-ordered. Residues from Flap II interact with Flap I and shield the FMN molecule from the solvent. The conformational changes in Flap I resulted in a new Mg(2+) coordination pattern in which a FMN phosphate oxygen and Asn36 side chain carbonyl are directly coordinating to the Mg(2+) ion. The proposed catalytic base Glu86 is well-positioned for activation of the O5' hydroxyl group of riboflavin for the phosphoryl transfer reaction. The structural data obtained so far on human and yeast RFK complexes provide a rationale for the ordered kinetic mechanism of RFK.     

Crystallographic and solution studies of an activation loop mutant of the insulin receptor tyrosine kinase: insights into kinase mechanism

The tyrosine kinase domain of the insulin receptor is subject to autoinhibition in the unphosphorylated basal state via steric interactions involving the activation loop. A mutation in the activation loop designed to relieve autoinhibition, Asp-1161 --> Ala, substantially increases the ability of the unphosphorylated kinase to bind ATP. The crystal structure of this mutant in complex with an ATP analog has been determined at 2.4-A resolution. The structure shows that the active site is unobstructed, but the end of the activation loop is disordered and therefore the binding site for peptide substrates is not fully formed. In addition, Phe-1151 of the protein kinase-conserved DFG motif, at the beginning of the activation loop, hinders closure of the catalytic cleft and proper positioning of alpha-helix C for catalysis. These results, together with viscometric kinetic measurements, suggest that peptide substrate binding induces a reconfiguration of the unphosphorylated activation loop prior to the catalytic step. The crystallographic and solution studies provide new insights into the mechanism by which the activation loop controls phosphoryl transfer as catalyzed by the insulin receptor.     

Elucidation of human choline kinase crystal structures in complex with the products ADP or phosphocholine

Choline kinase, responsible for the phosphorylation of choline to phosphocholine as the first step of the CDP-choline pathway for the biosynthesis of phosphatidylcholine, has been recognized as a new target for anticancer therapy. Crystal structures of human choline kinase in its apo, ADP and phosphocholine-bound complexes, respectively, reveal the molecular details of the substrate binding sites. ATP binds in a cavity where residues from both the N and C-terminal lobes contribute to form a cleft, while the choline-binding site constitutes a deep hydrophobic groove in the C-terminal domain with a rim composed of negatively charged residues. Upon binding of choline, the enzyme undergoes conformational changes independently affecting the N-terminal domain and the ATP-binding loop. From this structural analysis and comparison with other kinases, and from mutagenesis data on the homologous Caenorhabditis elegans choline kinase, a model of the ternary ADP.phosphocholine complex was built that reveals the molecular basis for the phosphoryl transfer activity of this enzyme.     

A double-headed cathepsin B inhibitor devoid of warhead

Most synthetic inhibitors of peptidases have been targeted to the active site for inhibiting catalysis through reversible competition with the substrate or by covalent modification of catalytic groups. Cathepsin B is unique among the cysteine peptidase for the presence of a flexible segment, known as the occluding loop, which can block the primed subsites of the substrate binding cleft. With the occluding loop in the open conformation cathepsin B acts as an endopeptidase, and it acts as an exopeptidase when the loop is closed. We have targeted the occluding loop of human cathepsin B at its surface, outside the catalytic center, using a high-throughput docking procedure. The aim was to identify inhibitors that would interact with the occluding loop thereby modulating enzyme activity without the help of chemical warheads against catalytic residues. From a large library of compounds, the in silico approach identified [2-[2-(2,4-dioxo-1,3-thiazolidin-3-yl)ethylamino]-2-oxoethyl] 2-(furan-2-carbonylamino) acetate, which fulfills the working hypothesis. This molecule possesses two distinct binding moieties and behaves as a reversible, double-headed competitive inhibitor of cathepsin B by excluding synthetic and protein substrates from the active center. The kinetic mechanism of inhibition suggests that the occluding loop is stabilized in its closed conformation, mainly by hydrogen bonds with the inhibitor, thus decreasing endoproteolytic activity of the enzyme. Furthermore, the dioxothiazolidine head of the compound sterically hinders binding of the C-terminal residue of substrates resulting in inhibition of the exopeptidase activity of cathepsin B in a physiopathologically relevant pH range.     

Crystal structures of ADP and AMPPNP-bound propionate kinase (TdcD) from Salmonella typhimurium: comparison with members of acetate and sugar kinase/heat shock cognate 70/actin superfamily

Recently, it has been shown that l-threonine can be catabolized non-oxidatively to propionate via 2-ketobutyrate. Propionate kinase (TdcD; EC 2.7.2.-) catalyses the last step of this metabolic process by enabling the conversion of propionyl phosphate and ADP to propionate and ATP. To provide insights into the substrate-binding pocket and catalytic mechanism of TdcD, the crystal structures of the enzyme from Salmonella typhimurium in complex with ADP and AMPPNP have been determined to resolutions of 2.2A and 2.3A, respectively, by molecular replacement using Methanosarcina thermophila acetate kinase (MAK; EC 2.7.2.1). Propionate kinase, like acetate kinase, contains a fold with the topology betabetabetaalphabetaalphabetaalpha, identical with that of glycerol kinase, hexokinase, heat shock cognaten 70 (Hsc70) and actin, the superfamily of phosphotransferases. The structure consists of two domains with the active site contained in a cleft at the domain interface. Examination of the active site pocket revealed a plausible structural rationale for the greater specificity of the enzyme towards propionate than acetate. This was further confirmed by kinetic studies with the purified enzyme, which showed about ten times lower K(m) for propionate (2.3 mM) than for acetate (26.9 mM). Comparison of TdcD complex structures with those of acetate and sugar kinase/Hsc70/actin obtained with different ligands has permitted the identification of catalytically essential residues involved in substrate binding and catalysis, and points to both structural and mechanistic similarities. In the well-characterized members of this superfamily, ATP phosphoryl transfer or hydrolysis is coupled to a large conformational change in which the two domains close around the active site cleft. The significant amino acid sequence similarity between TdcD and MAK has facilitated study of domain movement, which indicates that the conformation assumed by the two domains in the nucleotide-bound structure of TdcD may represent an intermediate point in the pathway of domain closure.     

Catalytic domain crystal structure of protein kinase C-theta (PKCtheta)

A member of the novel protein kinase C (PKC) subfamily, PKC, is an essential component of the T cell synapse and is required for optimal T cell activation and interleukin-2 production. Selective involvement of PKC in TCR signaling makes this enzyme an attractive therapeutic target in T cell-mediated disease processes. In this report we describe the crystal structure of the catalytic domain of PKC at 2.0-A resolution. Human recombinant PKC kinase domain was expressed in bacteria as catalytically active phosphorylated enzyme and co-crystallized with its subnanomolar, ATP site inhibitor staurosporine. The structure follows the classic bilobal kinase fold and shows the enzyme in its active conformation and phosphorylated state. Inhibitory interactions between conserved features of staurosporine and the ATP-binding cleft are accompanied by closing of the glycine-rich loop, which also maintains an inhibitory arrangement by blocking the phosphate recognition subsite. The two major phosphorylation sites, Thr-538 in the activation loop and Ser-695 in the hydrophobic motif, are both occupied in the structure, playing key roles in stabilizing active conformation of the enzyme and indicative of PKC autocatalytic phosphorylation and activation during bacterial expression. The PKC-staurosporine complex represents the first kinase domain crystal structure of any PKC isotypes to be determined and as such should provide valuable insight into PKC specificity and into rational drug design strategies for PKC selective leads.     

Crystal structures of two mutants of adenylate kinase from Escherichia coli that modify the Gly-loop

Two mutants of adenylate kinase from Escherichia coli have been crystallized and analyzed by X-ray diffraction at resolutions of 3.4 and 2.4 Å, respectively. These mutants are Pro-9→Leu and Gly-10→Val. They were selected for their positions in the highly conserved Gly-loop forming a giant anion hole for the β-phosphate of ATP (GTP) in adenylate kinases, H-ras-p21, and other nucleotide-binding proteins. Mutants at these positions of H-ras-p21 cause cancer. In adenylate kinase these mutations cause smallish changes at the active site. Relating the structural changes to the known changes in catalysis indicates that these mutants hinder the induced-fit movements. As a side result we find that mutant Pro-9→Leu and wild-type form one very similar crystal packing contact that is crystallographic in one case and noncrystallographic in the other, while all other packing contacts and the space groups are quite at variance. © 1993 Wiley-Liss, Inc.     

Crystal structure of yeast hexokinase PI in complex with glucose: A classical "induced fit" example revised

Hexokinase is the first enzyme in the glycolytic pathway that catalyzes the transfer of a phosphoryl group from ATP to glucose to form glucose-6-phosphate and ADP. Two yeast hexokinase isozymes are known, namely PI and PII. Here we redetermined the crystal structure of yeast hexokinase PI from Saccharomyces cerevisiae as a complex with its substrate, glucose, and refined it at 2.95 A resolution. Comparison of the holo-PI yeast hexokinase and apo-hexokinase structures shows in detail the rigid body domain closure and specific loop movements as glucose binds and sheds more light on structural basis of the "induced fit" mechanism of reaction in the HK enzymatic action. We also performed statistical coupling analysis of the hexokinase family, which reveals two co-evolved continuous clusters of amino acid residues and shows that the evolutionary coupled amino acid residues are mostly confined to the active site and the hinge region, further supporting the importance of these parts of the protein for the enzymatic catalysis.