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.     

The phosphoryl-transfer mechanism of Escherichia coli phosphoenolpyruvate carboxykinase from the use of AlF(3).

The mechanism of reversible transfer of the gamma-phosphate group of ATP by Escherichia coli phosphoenolpyruvate carboxykinase (PCK) on to its substrate is of great interest. It is known that metallofluorides are accurate analogs of the transition state in the context of kinase mechanisms. Therefore, two complexes of PCK, one with AlF(3), Mg(2+) and ADP (complex I), the other with AlF(3), Mg(2+), ADP and pyruvate (complex II) were crystallized. The X-ray crystal structures of these two complexes were determined at 2.0 A resolution. The Al atom has trigonal bipyramidal geometry that mimics the transition state of phosphoryl transfer. The Al atom is at a distance of 2.8 A and 2.9 A from an oxygen atom of the beta-phosphoryl group of ADP in complex I and II, respectively. A water molecule in complex I and an oxygen atom of the pyruvate in complex II are located along the axis of the trigonal bipyramid on the side opposite to the beta-phosphoryl oxygen with respect to the equatorial plane, suggesting that the complexes are close mimics of the transition state. Along with the presence of positively charged species around the AlF(3) moiety, these results indicate that phosphoryl transfer occurs via a direct displacement mechanism with associative qualities.     

Crystal structure of a transition state mimic of the catalytic subunit of cAMP-dependent protein kinase

To understand the molecular mechanism underlying phosphoryl transfer of cAMP-dependent protein kinase, the structure of the catalytic subunit in complex with ADP, aluminum fluoride, Mg2+ ions and a substrate peptide was determined at 2.0 A resolution. Aluminum fluoride was modeled as AlF3 in a planar geometry; it is positioned 2.3 A from both the donor oxygen of ADP and the hydroxyl group of the recipient Ser residue. In this configuration, the aluminum atom forms a trigonal bipyramidal coordination with the oxygen atoms of the donor and recipient groups at the apical positions. This arrangement suggests that aluminum fluoride mimics the transition state and provides the first direct structural evidence for the in-line mechanism of phosphoryl transfer in a protein kinase.     

Metaphosphate in the active site of fructose-1,6-bisphosphatase

The hydrolysis of a phosphate ester can proceed through an intermediate of metaphosphate (dissociative mechanism) or through a trigonal bipryamidal transition state (associative mechanism). Model systems in solution support the dissociative pathway, whereas most enzymologists favor an associative mechanism for enzyme-catalyzed reactions. Crystals of fructose-1,6-bisphosphatase grow from an equilibrium mixture of substrates and products at near atomic resolution (1.3 A). At neutral pH, products of the reaction (orthophosphate and fructose 6-phosphate) bind to the active site in a manner consistent with an associative reaction pathway; however, in the presence of inhibitory concentrations of K+ (200 mm), or at pH 9.6, metaphosphate and water (or OH-) are in equilibrium with orthophosphate. Furthermore, one of the magnesium cations in the pH 9.6 complex resides in an alternative position, and suggests the possibility of metal cation migration as the 1-phosphoryl group of the substrate undergoes hydrolysis. To the best of our knowledge, the crystal structures reported here represent the first direct observation of metaphosphate in a condensed phase and may provide the structural basis for fundamental changes in the catalytic mechanism of fructose-1,6-bisphosphatase in response to pH and different metal cation activators.     

Cyclin B and Cyclin A Confer Different Substrate Recognition Properties on CDK2

The transitions of the cell cycle are regulated by the cyclin dependent protein kinases(CDKs). The cyclins activate their respective CDKs and confer substrate recognitionproperties. We report the structure of phospho-CDK2/cyclin B and show that cyclin Bconfers M phase-like properties on CDK2, the kinase that is usually associated with S phase.Cyclin B produces an almost identical activated conformation of CDK2 as that produced bycyclin A. There are differences between cyclin A and cyclin B at the recruitment site, whichin cyclin A is used to recruit substrates containing an RXL motif. Because of sequencedifferences this site in cyclin B binds RXL motifs more weakly than in cyclin A. Despitesimilarity in kinase structures, phospho-CDK2/cyclin B phosphorylates substrates, such asnuclear lamin and a model peptide derived from p107, at sequences SPXX that differ fromthe canonical CDK2/cyclin A substrate recognition motif, SPXK. CDK2/cyclin Bphosphorylation at these non-canonical sites is not dependent on the presence of a RXLrecruitment motif. The p107 peptide contained two SP motifs each followed by a noncanonicalsequence of which only one site (Ser640) is phosphorylated by pCDK2/cyclin Awhile two sites are phosphorylated by pCDK2/cyclin B. The second site is too close to theRXL motif to allow the cyclin A recruitment site to be effective, as previous work has shownthat there must be at least 16 residues between the catalytic site serine and the RXL motif.Thus the cyclins A and B in addition to their role in promoting the activatory conformationalswitch in CDK2, also provide differential substrate specificity.     

The structure of cyclin E1/CDK2: implications for CDK2 activation and CDK2-independent roles

Cyclin E, an activator of phospho-CDK2 (pCDK2), is important for cell cycle progression in metazoans and is frequently overexpressed in cancer cells. It is essential for entry to the cell cycle from G0 quiescent phase, for the assembly of prereplication complexes and for endoreduplication in megakaryotes and giant trophoblast cells. We report the crystal structure of pCDK2 in complex with a truncated cyclin E1 (residues 81-363) at 2.25 A resolution. The N-terminal cyclin box fold of cyclin E1 is similar to that of cyclin A and promotes identical changes in pCDK2 that lead to kinase activation. The C-terminal cyclin box fold shows significant differences from cyclin A. It makes additional interactions with pCDK2, especially in the region of the activation segment, and contributes to CDK2-independent binding sites of cyclin E. Kinetic analysis with model peptide substrates show a 1.6-fold increase in kcat for pCDK2/cyclin E1 (81-363) over kcat of pCDK2/cyclin E (full length) and pCDK2/cyclin A. The structural and kinetic results indicate no inherent substrate discrimination between pCDK2/cyclin E and pCDK2/cyclin A with model substrates.     

A model of the transition state in the alkaline phosphatase reaction

A high resolution crystal structure of Escherichia coli alkaline phosphatase in the presence of vanadate has been refined to 1.9 A resolution. The vanadate ion takes on a trigonal bipyramidal geometry and is covalently bound by the active site serine nucleophile. A coordinated water molecule occupies the axial position opposite the serine nucleophile, whereas the equatorial oxygen atoms of the vanadate ion are stabilized by interactions with both Arg-166 and the zinc metal ions of the active site. This structural complex supports the in-line displacement mechanism of phosphomonoester hydrolysis by alkaline phosphatase and provides a model for the proposed transition state in the enzyme-catalyzed reaction.     

Mechanism of hydrolysis of phosphate esters by the dimetal center of 5'-nucleotidase based on crystal structures

5'-Nucleotidase belongs to a large superfamily of distantly related dinuclear metallophosphatases including the Ser/Thr protein phosphatases and purple acid phosphatases. The protein undergoes a 96 degrees domain rotation between an open (inactive) and a closed (active) enzyme form. Complex structures of the closed form with the products adenosine and phosphate, and with the substrate analogue inhibitor alpha,beta-methylene ADP, have been determined at 2.1 A and 1.85 A resolution, respectively. In addition, a complex of the open form of 5'-nucleotidase with ATP was analyzed at a resolution of 1.7 A. These structures show that the adenosine group binds to a specific binding pocket of the C-terminal domain. The adenine ring is stacked between Phe429 and Phe498. The N-terminal domain provides the ligands to the dimetal cluster and the conserved His117, which together form the catalytic core structure. However, the three C-terminal arginine residues 375, 379 and 410, which are involved in substrate binding, may also play a role in transition-state stabilization. The beta-phosphate group of the inhibitor is terminally coordinated to the site 2 metal ion. The site 1 metal ion coordinates a water molecule which is in an ideal position for a nucleophilic attack on the phosphorus atom, assuming an in-line mechanism of phosphoryl transfer. Another water molecule bridges the two metal ions.     

X-ray structure reveals a new class and provides insight into evolution of alkaline phosphatases

The alkaline phosphatase (AP) is a bi-metalloenzyme of potential applications in biotechnology and bioremediation, in which phosphate monoesters are nonspecifically hydrolysed under alkaline conditions to yield inorganic phosphate. The hydrolysis occurs through an enzyme intermediate in which the catalytic residue is phosphorylated. The reaction, which also requires a third metal ion, is proposed to proceed through a mechanism of in-line displacement involving a trigonal bipyramidal transition state. Stabilizing the transition state by bidentate hydrogen bonding has been suggested to be the reason for conservation of an arginine residue in the active site. We report here the first crystal structure of alkaline phosphatase purified from the bacterium Sphingomonas. sp. Strain BSAR-1 (SPAP). The crystal structure reveals many differences from other APs: 1) the catalytic residue is a threonine instead of serine, 2) there is no third metal ion binding pocket, and 3) the arginine residue forming bidentate hydrogen bonding is deleted in SPAP. A lysine and an aspargine residue, recruited together for the first time into the active site, bind the substrate phosphoryl group in a manner not observed before in any other AP. These and other structural features suggest that SPAP represents a new class of APs. Because of its direct contact with the substrate phosphoryl group, the lysine residue is proposed to play a significant role in catalysis. The structure is consistent with a mechanism of in-line displacement via a trigonal bipyramidal transition state. The structure provides important insights into evolutionary relationships between members of AP superfamily.     

NMR studies of the mechanism of cyclic AMP-dependent protein kinase

NMR has been used to study the role of the divalent cation, the conformations, arrangement, and exchange rates of the enzyme-bound metal-ATP and peptide substrates, the mechanism of the phosphoryl transfer, and the structure and role of the regulatory subunit on type II cyclic AMP (cAMP)-dependent protein kinase from bovine heart. The active complex consists of an enzyme-ATP-metal bridge in which the metal is beta, gamma coordinated, with delta chirality at P beta, and a torsional angle at the adenine-ribose bond in the high-anti range (x approximately 80 degrees). The bound heptapeptide substrate Leu-Arg-Arg-Ala-Ser-Leu-Gly is extended in conformation, forming either a coil or, less likely, a beta turn but not an alpha helix or beta sheet. The distance from the gamma-P of bound ATP analogs to the Ser-OH of the bound peptide (5.3 +/- 0.7 A) would permit a metaphosphate or an elongated phosphorane intermediate or transition state. The regulatory subunit (R2) blocks the peptide- or protein-binding site of the catalytic subunit. The 31P chemical shift of cAMP is not greatly altered on binding to R2, but the resonance is broadened to approximately 32 Hz, which indicates no chemical change but marked immobilization of bound cAMP. A narrower (approximately 7 Hz) 31P resonance at 4.44 ppm is assigned to P-serine-95 of R2 because it disappears with catalytic subunit, Mg2+, and an ADP-generating system.     

Phosphoryl transfer in Ras proteins,conclusive or elusive?

The chemical mechanism of GTP hydrolysis by GTP-binding proteins of the Ras superfamily continues to inspire both experimental and computational biologists. The debate centres on the nature of the transition state, with arguments for both dissociative and associative, and whether there is a common GTPase mechanism for these proteins. In a recent structural analysis of Rab11, the product P(i) was found in an unusual configuration. This finding indicates that substrate-assisted catalysis might operate as a mechanism to enable nucleophilic attack in the intrinsic GTPase reaction, and would thus favour a pentavalent phosphorane intermediate. Recent findings on the GAP-mediated reaction of different Ras proteins suggest that a common mechanism might not exist and that G proteins probably show a continuum of electronic configurations in the transition state.     

The power of vanadate in crystallographic investigations of phosphoryl transfer enzymes

The formation of transition state mimics of phosphoryl transfer reactions with the metal oxoanion vanadate is a powerful technique in macromolecular crystallography. The tendency of vanadate to form pentacovalent complexes exhibiting trigonal bipyramidal geometry makes this compound a close approximation of the transition state for such reactions. In many cases, vanadate complexes provide the most accurate visualization of the transition state that can be reasonably achieved. A survey of the Protein Data Bank reveals that a relatively small number of structures (39, representing 23 unique proteins) include vanadate, yet these structures represent four of the six E.C. categories of enzymes, and were obtained in crystals with pH values ranging from 5.0 to 7.8. Vanadate has additional advantages over other compounds such as aluminum fluoride, beryllium fluoride and nitrate used for visualization of transition state mimics in that vanadate readily forms covalent bonds with a variety of ligands and has produced a wider variety of transition state mimics. Given the hundreds of crystal structures that have been solved for phosphoryl transfer enzymes, it is surprising that vanadate has not been used more frequently for visualization of transition state analogs. We propose that an opportunity exists for vanadate to become a more commonly utilized component of the macromolecular crystallographer's toolbox.     

High-resolution structures of adenylate kinase from yeast ligated with inhibitor Ap5A, showing the pathway of phosphoryl transfer.

The structure of adenylate kinase from yeast ligated with the two-substrate-mimicking inhibitor Ap5A and Mg2+ has been refined to 1.96 A resolution. In addition, the refined structure of the same complex with a bound imidazole molecule replacing Mg2+ has been determined at 1.63 A. These structures indicate that replacing Mg2+ by imidazole disturbs the water structure and thus the complex. A comparison with the G-proteins shows that Mg2+ is exactly at the same position with respect to the phosphates. However, although the Mg2+ ligand sphere of the G-proteins is a regular octahedron containing peptide ligands, the reported adenylate kinase has no such ligands and an open octahedron leaving space for the Mg2+ to accompany the transferred phosphoryl group. A superposition of the known crystalline and therefore perturbed phosphoryl transfer geometries in the adenylate kinases demonstrates that all of them are close to the start of the forward reaction with bound ATP and AMP. Averaging all observed perturbed structures gives rise to a close approximation of the transition state, indicating in general how to establish an elusive transition state geometry. The average shows that the in-line phosphoryl transfer is associative, because there is no space for a dissociative metaphosphate intermediate. As a side result, the secondary dipole interaction in the alpha-helices of both protein structures has been quantified.     

Activation mechanism of CDK2: role of cyclin binding versus phosphorylation

Activation of the cyclin-dependent kinases is a two-step process involving cyclin binding followed by phosphorylation at a conserved threonine residue within the kinase activation loop. In this study, we describe the separate roles of cyclin A binding versus phosphorylation in the overall activation mechanism of CDK2. Interaction of CDK2 with cyclin A results in a partially active complex that is moderately defective in the binding of the protein substrate, but not ATP, and severely defective in both phosphoryl group transfer and turnover. Alternatively, phosphorylation of the CDK2 monomer also results in a partially activated species, but one that is severely (> or = 480-fold) defective in substrate binding exclusively. Catalytic turnover in the phosphorylated CDK2 monomer is largely unimpaired (approximately 8-fold lower). Our data support a model for the activation of CDK2 in vivo, in which interaction of unphosphorylated CDK2 with cyclin A serves to configure the active site for ground-state binding of both ATP and the protein substrate, and further aligns ATP in the transition state for phosphoryl transfer. Optimizing the alignment of protein substrates in the phosphoryl transfer reaction is the principal role of phosphorylation at Thr(160).     

The crystal structure of beryllofluoride Spo0F in complex with the phosphotransferase Spo0B represents a phosphotransfer pretransition state

A number of regulatory circuits in biological systems function through the exchange of phosphoryl groups from one protein to another. Spo0F and Spo0B are components of a phosphorelay that control sporulation in the bacterium Bacillus subtilis through the exchange of a phosphoryl group. Using beryllofluoride as a mimic for phosphorylation, we trapped the interaction of the phosphorylated Spo0F with Spo0B in the crystal lattice. The transition state of phosphoryl transfer continues to be a highly debated issue, as to whether it is associative or dissociative in nature. The geometry of Spo0F binding to Spo0B favors an associative mechanism for phosphoryl transfer. In order to visualize the autophosphorylation of the histidine kinase, KinA, and the subsequent phosphoryl transfer to Spo0F, we generated in silico models representing these reaction steps.     

The interaction of phosphorothioate analogues of ATP with phosphomevalonate kinase. Kinetic and 31P NMR studies

The diastereomers of adenosine 5'-O-(1-thiotriphosphate) (ATP alpha S), adenosine 5'-O-(2-thiotriphosphate) (ATP beta S), and adenosine 5'-O-(3-thiotriphosphate) (ATP gamma S) could act as substrates for phosphomevalonate kinase in the presence of Mg2+ and Cd2+ as activating divalent metal cations. The Sp diastereomer of ATP alpha S was the preferred substrate regardless of the metal ion used, consistent with the metal ion not binding to the alpha-phosphate. With ATP beta S, the Sp diastereomer was the preferred substrate with Mg2+, and the Rp diastereomer was the preferred substrate with Cd2+. The reversal of specificity establishes that the metal is chelated through the beta-phosphate in the active site of the phosphomevalonate kinase reaction. A comparison of the Vmax values as a function of substitution of oxygen by sulfur showed the order for Mg2+ to be: ATP greater than ATP alpha S(Sp) greater than ATP alpha S(Rp) greater than ATP beta S(Sp) greater than ATP gamma S greater than ATP beta S(Rp). With Cd2+ as the activating metal ion, the order was: ATP greater than ATP alpha S(Sp) greater than ATP alpha S(Rp) greater than ATP beta S(Rp) greater than ATP gamma S greater than ATP beta S(Sp). It is concluded that the chelate structure of metal ATP substrate in the phosphomevalonate kinase reaction is the delta, beta, gamma-bidentate complex. 31P NMR measurements and radioassay with [2-14C] phosphomevalonate were used to measure the equilibrium of the reaction catalyzed by phosphomevalonate kinase with ATP and phosphorothioate analogues of ATP as the phosphoryl group donor. The order as a phosphate donor as determined by both methods in the phosphomevalonate kinase reaction is ATP beta S greater than ATP alpha S greater than ATP greater than ATP gamma S. Except for ATP gamma S, the equilibrium is shifted in the direction of formation of ADP alpha S and ADP beta S relative to ADP formation. Thus, ATP beta S rather than ATP would be effective for the synthesis of diphosphomevalonate. The phosphomevalonate kinase reaction could also be used to synthesize mevalonate 5-(2-thiodiphosphate) using ATP gamma S as the phosphoryl group donor.     

Pentacoordinated phosphorus revisited by high‐level QM/MM calculations

Enzymes catalyzing phosphoryl transfer reactions are extremely efficient and are involved in crucial biochemical processes. The mechanisms of these enzymes are complex due to the diversity of substrates that are involved. The reaction can proceed through a pentacoordinated phosphorus species that is either a stable intermediate or a transition state (TS). Because of this, the first X‐ray structure of a pentacoordinated phosphorus intermediate in the β‐phosphoglucomutase enzyme aroused great interest but also much controversy. To provide new insights into the nature of that structure, we have determined the reaction path of the phosphorylation step using high‐level QM/MM calculations, and have also calculated the geometry of a complex with a transition state analogue (TSA) that has been suggested to be the actual species in the crystal. The protein crystalline environment has been modeled so as to mimic the experimental conditions. We conclude that the pentacoordinated phosphorus formed in this enzyme is not a stable species but a TS, which gives an activation energy for phosphorylation in agreement with kinetic results. We also show that the TSA is a good mimic of the true TS. We have performed a new crystallographic refinement of the original diffraction map of the pentacoordinated phosphorus structure with the MgF TSA. The new fit improves significantly with respect to the original one, which strongly supports that Allen and coworkers wrongly assigned the X‐ray structure to a pentavalent phosphorane. Proteins 2010. © 2010 Wiley‐Liss, Inc.     

Studies of the mechanism of action and regulation of cAMP-dependent protein kinase

Magnetic resonance and kinetic studies of the catalytic subunit of a Type II cAMP-dependent protein kinase from bovine heart have established the active complex to be an enzyme-ATP-metal bridge. The metal ion is β,γ coordinated with Δ chirality at the β-phosphorous atom. The binding of a second metal ion at the active site which bridges the enzyme to the three phosphoryl groups of ATP, partially inhibits the reaction. Binding of the metal-ATP substrate to the enzyme occurs in a diffusion-controlled reaction followed by a 40 ° change in the glycosidic torsional angle. This conformational change results from strong interaction of the nucleotide base with the enzyme. NMR studies of four ATP-utilizing enzymes show a correlation between such conformational changes and high nucleotide base specificity. Heptapeptide substrates and substrate analogs bind to the active site of the catalytic subunit at a rate significantly lower than collision frequency indicating conformational selection by the enzyme or a subsequent slow conformational change. NMR studies of the conformation of the enzyme-bound peptide substrates have ruled out α-helical and β-pleated sheet structures. The results of kinetic studies of peptide substrates in which the amino acid sequence was systematically varied were used to rule out the obligatory requirement for all possible β-turn conformations within the heptapeptide although an enzymatic preference for a β_2–5 or β_3–6 turn could not be excluded. Hence if protein kinase has an absolute requirement for a specific secondary structure, then this structure must be a coil. In the enzyme-substrate complex the distance along the reaction coordinate between the γ-P of ATP and the serine oxygen of the peptide substrate (5.3 ± 0.7 Å) allows room for a metaphosphate intermediate. This finding together with kinetic observations as well as the location of the inhibitory metal suggest a dissociative mechanism for protein kinase, although a mechanism with some associative character remains possible. Regulation of protein kinase is accomplished by competition between the regulatory subunit and peptide or protein substrates at the active site of the catalytic subunit. Thus, the regulatory subunit is found by NMR to block the binding of the peptide substrate to the active site of protein kinase but allows the binding of the nucleotide substrate and divalent cations. The dissociation constant of the regulatory subunit from the active site (10^?10m) is increased ~10-fold by phosphorylation and ~10⁴-fold by the binding of cAMP, to a value (10^?5m) which exceeds the intracellular concentration of the R₂C₂ holoenzyme complex (10^?6m). The resulting dissociation of the holoenzyme releases the catalytic subunit, permitting the active site binding of peptide or protein substrates.     

Mechanism of aminoglycoside antibiotic kinase APH(3')-IIIa: role of the nucleotide positioning loop

The aminoglycoside antibiotic resistance kinases (APHs) and the Ser/Thr/Tyr protein kinases share structural and functional homology but very little primary sequence conservation (<5%). A region of structural, but not amino acid sequence, homology is the nucleotide positioning loop (NPL) that closes down on the enzyme active site upon binding of ATP. This loop region has been implicated in facilitating phosphoryl transfer in protein kinases; however, there is no primary sequence conservation between APHs and protein kinases in the NPL. There is an invariant Ser residue in all APH NPL regions, however. This residue in APH(3')-IIIa (Ser27), an enzyme widespread in aminoglycoside-resistant Enterococci, Streptococci, and Staphylococci, directly interacts with the beta-phosphate of ATP through the Ser hydroxymethyl group and the amide hydrogen in the 3D structure of the enzyme. Mutagenesis of this residue to Ala and Pro supported a role for the Ser amide hydrogen in nucleotide capture and phosphoryl transfer. A molecular model of the proposed dissociative transition state, which is consistent with all of the available mechanistic data, suggested a role for the amide of the adjacent Met26 in phosphoryl transfer. Mutagenesis studies confirmed the importance of the amide hydrogen and suggest a mechanism where Ser27 anchors the ATP beta-phosphate facilitating bond breakage with the gamma-phosphate during formation of the metaphosphate-like transition, which is stabilized by interaction with the amide hydrogen of Met26. The APH NPL therefore acts as a lever, promoting phosphoryl transfer to the aminoglycoside substrate, with the biological outcome of clinically relevant antibiotic resistance.