Kinetic characterization of human phosphopantothenoylcysteine synthetase

Phosphopantothenoylcysteine synthetase (PPCS) catalyzes the formation of phosphopantothenoylcysteine from (R)-phosphopantothenate and l-cysteine with the concomitant consumption of a nucleotide triphosphate. Herein, the human coaB gene encoding PPCS is cloned into pET23a and overexpressed in E. coli BL21(DE3), to yield 10 mg of purified enzyme per liter of culture. Detailed kinetic studies found that this PPCS follows a similar Bi Uni Uni Bi Ping Pong mechanism as previously described for the E. faecalis PPCS, except that the human enzyme can use both ATP and CTP with similar affinity. One significant difference for human PPCS catalysis with respect to ATP and CTP is that the enzyme shows cooperative binding of ATP, measured as a Hill constant of 1.7. PPCS catalysis under CTP conditions displayed Michaelis constants of 265 μM, 57 μM, and 16 μM for CTP, PPA, and cysteine, respectively, with a k_cat of 0.53 ± 0.01 s^? 1 for the reaction. Taking into account the cooperativity under ATP condition, PPCS exhibited Michaelis constants of 269 μM, 13 μM, and 14 μM for ATP, PPA, and cysteine, respectively, with a k_cat of 0.56 s^? 1 for the reaction. Oxygen transfer studies found that ¹⁸O from [carboxyl-¹⁸O] phosphopantothenate is incorporated into the AMP or CMP produced during PPCS catalysis, consistent with the formation of a phosphopantothenoyl cytidylate or phosphopantothenoyl adenylate intermediate, supporting similar catalytic mechanisms under both CTP and ATP conditions. Inhibition studies with GTP and UTP as well as product inhibition studies with CMP and AMP suggest that human PPCS lacks strong nucleotide selectivity.     

Regulation of the pho regulon of Escherichia coli K-12. Cloning of the regulatory genes phoB and phoR and identification of their gene products

We report here results of crystallographic studies at 3.0 Å resolution of complexes of phosphate ligands with aspartate carbamoyltransferase from Escherichia coli. Specifically, we interpret the binding of CTP, ATP, 5-bromo-CTP, 8-bromo-GTP. formycin A 5′-triphosphate. 3,N⁶-etheno-ATP. phosphate/carbamoyl-d.l-aspartate and pyrophosphate to the catalytic and regulatory chains of the enzyme.We observed two modes of binding of ligands to the phosphate crevice of the catalytic chain. Pyrophosphate and phosphate penetrate deeply into the cleft between the two domains of a catalytic monomer. In contrast. ATP, CTP. formycin A 5′-triphosphate and 3,N⁶-etheno-ATP bind to an exposed region of this cleft through their β and γ phosphates. Although the β and γ phosphates of 8-bromo-GTP bind to the same region as do the non-brominated nucleotides. 8-bromo-GTP interacts with the protein through all three of its phosphates and its ribose.Ser52, Arg54. Thr55, Arg105, His134. Gln137 and Arg167 are residues of the catalytic chain near density corresponding to phosphate ligands. The interactions of phosphate ligands are consistent with results of nuclear magnetic resonance, kinetics and equilibrium binding studies.Nucleoside triphosphates also bind to the regulatory chain in two modes. ATP and CTP bind in similar conformations to nearly the same site of the allosteric domain. The effector 8-bromo-GTP interacts at a location that does not overlap with the ATP-CTP site. The phosphates are in an extended conformation for all effectors. Furthermore, ATP. 5-bromo-CTP and 8-bromo-GTP bind to the protein in the anti conformation.Interactions of ATP and CTP with the protein are essentially consistent with the proposals put forward by London &; Schmidt (1972). We suggest, however, a modification of the London &; Schmidt model on the basis of our results with 8-bromo-GTP. In addition, we propose that the allosteric binding sites of nucleoside triphosphates are coupled to each other through the N-terminal segments of monomers of a regulatory dimer.     

Structural basis of CTP-dependent peptide bond formation in coenzyme A biosynthesis catalyzed by Escherichia coli PPC synthetase

Phosphopantothenoylcysteine (PPC) synthetase forms a peptide bond between 4'-phosphopantothenate and cysteine in coenzyme A biosynthesis. PPC synthetases fall into two classes: eukaryotic, ATP-dependent and eubacterial, CTP-dependent enzymes. We describe the first crystal structure of E. coli PPC synthetase as a prototype of bacterial, CTP-dependent PPC synthetases. Structures of the apo-form and the synthetase complexed with CTP, the activated acyl-intermediate, 4'-phosphopantothenoyl-CMP, and with the reaction product CMP provide snapshots along the reaction pathway and detailed insight into substrate binding and the reaction mechanism of peptide bond formation. Binding of the phosphopantothenate moiety of the acyl-intermediate in a cleft at the C-terminal end of the central beta sheet of the dinucleotide binding fold is accomplished by an otherwise flexible flap. A second disordered loop may control access of cysteine to the active site. The conservation of functionalities involved in substrate binding and catalysis provides insight into similarities and differences of prokaryotic and eukaryotic PPC synthetases.     

Crystal structures of CTP synthetase reveal ATP, UTP, and glutamine binding sites

CTP synthetase (CTPs) catalyzes the last step in CTP biosynthesis, in which ammonia generated at the glutaminase domain reacts with the ATP-phosphorylated UTP at the synthetase domain to give CTP. Glutamine hydrolysis is active in the presence of ATP and UTP and is stimulated by the addition of GTP. We report the crystal structures of Thermus thermophilus HB8 CTPs alone, CTPs with 3SO4(2-), and CTPs with glutamine. The enzyme is folded into a homotetramer with a cross-shaped structure. Based on the binding mode of sulfate anions to the synthetase site, ATP and UTP are computer modeled into CTPs with a geometry favorable for the reaction. Glutamine bound to the glutaminase domain is situated next to the triad of Glu-His-Cys as a catalyst and a water molecule. Structural information provides an insight into the conformational changes associated with the binding of ATP and UTP and the formation of the GTP binding site.     

Structural Basis for the Reaction Mechanism of S-Carbamoylation of HypE by HypF in the Maturation of [NiFe]-Hydrogenases

As a remarkable structural feature of hydrogenase active sites, [NiFe]-hydrogenases harbor one carbonyl and two cyano ligands, where HypE and HypF are involved in the biosynthesis of the nitrile group as a precursor of the cyano groups. HypF catalyzes S-carbamoylation of the C-terminal cysteine of HypE via three steps using carbamoylphosphate and ATP, producing two unstable intermediates: carbamate and carbamoyladenylate. Although the crystal structures of intact HypE homodimers and partial HypF have been reported, it remains unclear how the consecutive reactions occur without the loss of unstable intermediates during the proposed reaction scheme. Here we report the crystal structures of full-length HypF both alone and in complex with HypE at resolutions of 2.0 and 2.6 Å, respectively. Three catalytic sites of the structures of the HypF nucleotide- and phosphate-bound forms have been identified, with each site connected via channels inside the protein. This finding suggests that the first two consecutive reactions occur without the release of carbamate or carbamoyladenylate from the enzyme. The structure of HypF in complex with HypE revealed that HypF can associate with HypE without disturbing its homodimeric interaction and that the binding manner allows the C-terminal Cys-351 of HypE to access the S-carbamoylation active site in HypF, suggesting that the third step can also proceed without the release of carbamoyladenylate. A comparison of the structure of HypF with the recently reported structures of O-carbamoyltransferase revealed different reaction mechanisms for carbamoyladenylate synthesis and a similar reaction mechanism for carbamoyltransfer to produce the carbamoyl-HypE molecule.     

Differences between CTP and ATP as substrates for the (Na + K)-ATPase

CTP was a poorer substrate than ATP when substituted in the (Na + K)-ATPase reaction assay, not only in terms of K_m but also of V. CDP was a poorer inhibitor than ADP, so product inhibition cannot account for CTP being a poorer substrate. In the Na-ATPase reaction, which the enzyme also catalyzes, substituting CTP for ATP resulted in greater activity, arguing against CTP being less effective than ATP in forming the enzyme-phosphate intermediate common to both reactions. Ligands that favor the E₂ conformational state of the enzyme, K⁺, Mg²⁺, and Mn₂⁺, inhibited the (Na + K)-CTPase reaction more than the (Na + K)-ATPase. Conversely, Triton X-100, which favors the E₁ conformational state of the enzyme, K⁺, Mg²⁺, and Mn²⁺, inhibited the (Na + K)-CTPase ATPase reaction but stimulated the (Na + K)-CTPase. Although the (Na + K)-ATPase reaction sequence probably involves cyclical interconversion between E₁ and E₂ conformational states (and is thus inhibitable by ligands favoring either state), the K-phosphatase reaction catalyzed by the enzyme apparently functions entirely in the E₂ state. This reaction is better stimulated by CTP plus Na⁺ than by ATP plus Na⁺; moreover, CTP lessens inhibition by Triton X-100, and ATP lessens inhibition by inorganic phosphate (which reacts with the E₂ state). These observations indicate that CTP is a poorer substrate than ATP because it is less effective in promoting conversion of E₂ to E₁, essential for the (Na + K)-dependent reaction mechanism. However, contrary to this rationale, dimethyl sulfoxide stimulated the (Na + K)-CTPase reaction although by other criteria, including inhibition of the (Na + K)-ATPase, the reagent appears to favor the E₂ over the E₁ conformational state.     

Divergent allosteric patterns verify the regulatory paradigm for aspartate transcarbamylase

The native Escherichia coli aspartate transcarbamoylase (ATCase, E.C. 2.1.3.2) provides a classic allosteric model for the feedback inhibition of a biosynthetic pathway by its end products. Both E. coli and Erwinia herbicola possess ATCase holoenzymes which are dodecameric (2(c3):3(r2)) with 311 amino acid residues per catalytic monomer and 153 and 154 amino acid residues per regulatory (r) monomer, respectively. While the quaternary structures of the two enzymes are identical, the primary amino acid sequences have diverged by 14 % in the catalytic polypeptide and 20 % in the regulatory polypeptide. The amino acids proposed to be directly involved in the active site and nucleotide binding site are strictly conserved between the two enzymes; nonetheless, the two enzymes differ in their catalytic and regulatory characteristics. The E. coli enzyme has sigmoidal substrate binding with activation by ATP, and inhibition by CTP, while the E. herbicola enzyme has apparent first order kinetics at low substrate concentrations in the absence of allosteric ligands, no ATP activation and only slight CTP inhibition. In an apparently important and highly conserved characteristic, CTP and UTP impose strong synergistic inhibition on both enzymes. The co-operative binding of aspartate in the E. coli enzyme is correlated with a T-to-R conformational transition which appears to be greatly reduced in the E. herbicola enzyme, although the addition of inhibitory heterotropic ligands (CTP or CTP+UTP) re-establishes co-operative saturation kinetics. Hybrid holoenzymes assembled in vivo with catalytic subunits from E. herbicola and regulatory subunits from E. coli mimick the allosteric response of the native E. coli holoenzyme and exhibit ATP activation. The reverse hybrid, regulatory subunits from E. herbicola and catalytic subunits from E. coli, exhibited no response to ATP. The conserved structure and diverged functional characteristics of the E. herbicola enzyme provides an opportunity for a new evaluation of the common paradigm involving allosteric control of ATCase.     

An aspartate transcarbamylase lacking catalytic subunit interactions. II. Regulatory subunits are responsible for the lack of co-operative interactions between catalytic sites. Drastic feedback inhibition does not restore these interactions

It has been previously reported (Kerbiriou &; Hervé, 1972) that, when a uracil-requiring mutant of Escherichia coli is derepressed for the biosynthesis of the enzymes of the pyrimidine pathway in the presence of 2-thiouracil, it synthesizes a modified aspartate transcarbamylase which is still sensitive to the feedback inhibitor CTP, but which does not show homotropic positive interactions between catalytic sites. It is shown here that these homotropic interactions do not reappear upon strong inhibition by CTP, indicating that the two types of interactions are really disconnected and must involve different molecular mechanisms. CTP is acting at the level of the apparent K_m of the enzyme for aspartate. It is also the case for ATP, which stimulates 2-thiouracil aspartate-transcarbamylase. Kinetic studies of the hybrid molecules made up of subunits prepared from normal and modified enzymes show that it is a modification at the level of the regulatory subunits which is responsible for the lack of co-operative interactions between catalytic sites. These results are discussed in terms of a four-state model.     

Structure-based Mechanism of CMP-2-keto-3-deoxymanno-octulonic Acid Synthetase: CONVERGENT EVOLUTION OF A SUGAR-ACTIVATING ENZYME WITH DNA/RNA POLYMERASES*

The enzyme CMP-Kdo synthetase (KdsB) catalyzes the addition of 2-keto-3-deoxymanno-octulonic acid (Kdo) to CTP to form CMP-Kdo, a key reaction in the biosynthesis of lipopolysaccharide. The reaction catalyzed by KdsB and the related CMP-acylneuraminate synthase is unique among the sugar-activating enzymes in that the respective sugars are directly coupled to a cytosine monophosphate. Using inhibition studies, in combination with isothermal calorimetry, we show the substrate analogue 2β-deoxy-Kdo to be a potent competitive inhibitor. The ligand-free Escherichia coli KdsB and ternary complex KdsB-CTP-2β-deoxy-Kdo crystal structures reveal that Kdo binding leads to active site closure and repositioning of the CTP phosphates and associated Mg²⁺ ion (Mg-B). Both ligands occupy conformations compatible with an S_n2-type attack on the α-phosphate by the Kdo 2-hydroxyl group. Based on strong similarity with DNA/RNA polymerases, both in terms of overall chemistry catalyzed as well as active site configuration, we postulate a second Mg²⁺ ion (Mg-A) is bound by the catalytically competent KdsB-CTP-Kdo ternary complex. Modeling of this complex reveals the Mg-A coordinated to the conserved Asp¹⁰⁰ and Asp²³⁵ in addition to the CTP α-phosphate and both the Kdo carboxylic and 2-hydroxyl groups. EPR measurements on the Mn²⁺-substituted ternary complex support this model. We propose the KdsB/CNS sugar-activating enzymes catalyze the formation of activated sugars, such as the abundant CMP-5-N-acetylneuraminic acid, by recruitment of two Mg²⁺ to the active site. Although each metal ion assists in correct positioning of the substrates and activation of the α-phosphate, Mg-A is responsible for activation of the sugar-hydroxyl group.     

Structural Basis for the ATP-dependent Configuration of Adenylation Active Site in Bacillus subtilis o-Succinylbenzoyl-CoA Synthetase

o-Succinylbenzoyl-CoA synthetase, or MenE, is an essential adenylate-forming enzyme targeted for development of novel antibiotics in the menaquinone biosynthesis. Using its crystal structures in a ligand-free form or in complex with nucleotides, a conserved pattern is identified in the interaction between ATP and adenylating enzymes, including acyl/aryl-CoA synthetases, adenylation domains of nonribosomal peptide synthetases, and luciferases. It involves tight gripping interactions of the phosphate-binding loop (P-loop) with the ATP triphosphate moiety and an open-closed conformational change to form a compact adenylation active site. In MenE catalysis, this ATP-enzyme interaction creates a new binding site for the carboxylate substrate, allowing revelation of the determinants of substrate specificities and in-line alignment of the two substrates for backside nucleophilic substitution reaction by molecular modeling. In addition, the ATP-enzyme interaction is suggested to play a crucial catalytic role by mutation of the P-loop residues hydrogen-bonded to ATP. Moreover, the ATP-enzyme interaction has also clarified the positioning and catalytic role of a conserved lysine residue in stabilization of the transition state. These findings provide new insights into the adenylation half-reaction in the domain alteration catalytic mechanism of the adenylate-forming enzymes.     

Structure-Based Engineering Increased the Catalytic Turnover Rate of a Novel Phenazine Prenyltransferase

Prenyltransferases (PTs) catalyze the regioselective transfer of prenyl moieties onto aromatic substrates in biosynthetic pathways of microbial secondary metabolites. Therefore, these enzymes contribute to the chemical diversity of natural products. Prenylation is frequently essential for the pharmacological properties of these metabolites, including their antibiotic and antitumor activities. Recently, the first phenazine PTs, termed EpzP and PpzP, were isolated and biochemically characterized. The two enzymes play a central role in the biosynthesis of endophenazines by catalyzing the regiospecific prenylation of 5,10-dihydrophenazine-1-carboxylic acid (dhPCA) in the secondary metabolism of two different Streptomyces strains. Here we report crystal structures of EpzP in its unliganded state as well as bound to S-thiolodiphosphate (SPP), thus defining the first three-dimensional structures for any phenazine PT. A model of a ternary complex resulted from in silico modeling of dhPCA and site-directed mutagenesis. The structural analysis provides detailed insight into the likely mechanism of phenazine prenylation. The catalytic mechanism suggested by the structure identifies amino acids that are required for catalysis. Inspection of the structures and the model of the ternary complex furthermore allowed us to rationally engineer EpzP variants with up to 14-fold higher catalytic reaction rate compared to the wild-type enzyme. This study therefore provides a solid foundation for additional enzyme modifications that should result in efficient, tailor-made biocatalysts for phenazines production.     

Conformational changes in the reaction of pyridoxal kinase

To understand the processes involved in the catalytic mechanism of pyridoxal kinase (PLK),1 we determined the crystal structures of PLK.AMP-PCP-pyridoxamine, PLK.ADP.PLP, and PLK.ADP complexes. Comparisons of these structures have revealed that PLK exhibits different conformations during its catalytic process. After the binding of AMP-PCP (an analogue that replaced ATP) and pyridoxamine to PLK, this enzyme retains a conformation similar to that of the PLK.ATP complex. The distance between the reacting groups of the two substrates is 5.8 A apart, indicating that the position of ATP is not favorable to spontaneous transfer of its phosphate group. However, the structure of PLK.ADP.PLP complex exhibited significant changes in both the conformation of the enzyme and the location of the ligands at the active site. Therefore, it appears that after binding of both substrates, the enzyme-substrate complex requires changes in the protein structure to enable the transfer of the phosphate group from ATP to vitamin B(6). Furthermore, a conformation of the enzyme-substrate complex before the transition state of the enzymatic reaction was also hypothesized.     

Asymmetry of binding and physical assignments of CTP and ATP sites in aspartate transcarbamoylase.

The allosteric effectors of aspartate transcarbamoylase from Escherichia coli, CTP and ATP, associate with both the regulatory and the catalytic moieties of the enzyme. Studies with isolated, active subunits yield one binding site per regulatory dimer and one per catalytic trimer. Investigations of effector association with hybrid enzymes, containing either the three regulatory dimers or the two catalytic trimers in inactivated forms, indicate that the data obtained with isolated subunits can be used to analyze the binding patterns of these ligands to the native hexamer. Thus, the nonlinear Scatchard plots, characteristic of the binding of CTP and ATP to the native enzyme, can be interpreted in terms of three effector molecules associating with the regulatory subunits, and two binding to the catalytic moiety of the enzyme. Results with native protein in the presence of saturating concentrations of active site ligands support these assignments. The differences between the binding isotherms of CTP and ATP to the enzyme are due to their different affinities to the two types of subunits. The apparent half-of-the-site saturation of the regulatory moiety of aspartate transcarbamoylase supports the concept that this protein has a tendency to exist in an asymmetric state.     

Phosphopantothenoylcysteine synthetase from Escherichia coli. Identification and characterization of the last unidentified coenzyme A biosynthetic enzyme in bacteria

Phosphopantothenoylcysteine synthase catalyzes the formation of (R)-4'-phospho-N-pantothenoylcysteine from 4'-phosphopantothenate and l-cysteine: this enzyme, involved in the biosynthesis of coenzyme A (CoA), has not previously been identified. Recently it was shown that the NH(2)-terminal domain of the Dfp protein from bacteria catalyzes the next step in CoA biosynthesis, the decarboxylation of (R)-4'-phospho-N-pantothenoylcysteine to form 4'-phosphopantetheine (Kupke, T., Uebele, M., Schmid, D., Jung, G., Blaesse, M., and Steinbacher, S. (2000) J. Biol. Chem. 275, 31838-31846). We have partially purified phosphopantothenoylcysteine decarboxylase from Escherichia coli and demonstrated that the protein encoded by the dfp gene, here renamed coaBC, also has phosphopantothenoylcysteine synthetase activity, using CTP rather than ATP as the activating nucleoside 5'-triphosphate. This discovery completes the identification of all the enzymes involved in the biosynthesis of coenzyme A in bacteria.     

Coexistence of two ATP sites on the ouabain-complexed (Na+ + K+)-ATPase

When the effects of varying concentrations of ATP on the dissociation rate of the ouabain-enzyme complex were studied, the dissociation rate constant increased with increasing ATP concentrations up to 1 mM, and then decreased with further rise in ATP; indicating that ATP binds to two distinct sites on the complex. ADP and AMP-PNP had similar biphasic effects. GTP, CTP, UTP, and AMP-PCP reduced the dissociation rate. AMP and Pi had no effects. Increase in dissociation rate caused by 0.5 mM ATP was not abolished by saturating CTP, indicating the binding of CTP to only one of the two ATP sites. The data suggest the existence of separate catalytic and regulatory sites, with different affinities and nucleotide specificities.     

Regulation of uridine kinase. Evidence for a regulatory site

Uridine kinase from mouse Ehrlich ascites tumor cells may exist at 4 degrees C in multiple aggregation states that only slowly equilibrate with one another. Increasing the temperature leads to dissociation, and the appearance of a single predominant species: at 22 degrees C the enzyme exists as a tetramer. There is also a break in the dependence of enzyme activity on temperature as measured in an Arrhenius plot. The feedback inhibitors CTP and UTP cause the enzyme to dissociate to the monomer, whereas the substrate ATP reverses this process. Kinetic studies show that the monomer has little or no activity. Studies of the reaction mechanism show that binding of substrates is ordered, leading to a ternary complex, and release of products is ordered: uridine is the first substrate bound, ADP the first product released. Except for the inhibitors UTP and CTP, all other nucleoside triphosphates, whether purine or pyrimidine, or containing ribose or deoxyribose, act as phosphate donor. Especially interesting are the opposite effects of CTP and dCTP on uridine kinase: unlike CTP, dCTP does not dissociate the enzyme and is competent as a phosphate donor. We propose that the various effects of different ligands are best explained by the existence of a regulatory site (with more stringent specificity than the catalytic site) that controls dissociation of uridine kinase to the inactive monomer.     

Crystal structures of aminotransferases Aro8 and Aro9 from Candida albicans and structural insights into their properties

Aminotransferases catalyze reversibly the transamination reaction by a ping-pong bi-bi mechanism with pyridoxal 5′-phosphate (PLP) as a cofactor. Various aminotransferases acting on a range of substrates have been reported. Aromatic transaminases are able to catalyze the transamination reaction with both aromatic and acidic substrates. Two aminotransferases from C. albicans, Aro8p and Aro9p, have been identified recently, exhibiting different catalytic properties. To elucidate the multiple substrate recognition of the two enzymes we determined the crystal structures of an unliganded CaAro8p, a complex of CaAro8p with the PLP cofactor bound to a substrate, forming an external aldimine, CaAro9p with PLP in the form of internal aldimine, and CaAro9p with a mixture of ligands that have been interpreted as results of the enzymatic reaction. The crystal structures of both enzymes contains in the asymmetric unit a biologically relevant dimer of 55?kDa for CaAro8 and 59?kDa for CaAro9p protein subunits. The ability of the enzymes to process multiple substrates could be related to a feature of their architecture in which the active site resides on one subunit while the substrate-binding site is formed by a long loop extending from the other subunit of the dimeric molecule. The separation of the two functions to different chemical entities could facilitate the evolution of the substrate-binding part and allow it to be flexible without destabilizing the conservative catalytic mechanism.     

Divergent evolutions of trinucleotide polymerization revealed by an archaeal CCA-adding enzyme structure

CCA-adding enzyme [ATP(CTP):tRNA nucleotidyltransferase], a template-independent RNA polymerase, adds the defined 'cytidine-cytidine-adenosine' sequence onto the 3' end of tRNA. The archaeal CCA-adding enzyme (class I) and eubacterial/eukaryotic CCA-adding enzyme (class II) show little amino acid sequence homology, but catalyze the same reaction in a defined fashion. Here, we present the crystal structures of the class I archaeal CCA-adding enzyme from Archaeoglobus fulgidus, and its complexes with CTP and ATP at 2.0, 2.0 and 2.7 A resolutions, respectively. The geometry of the catalytic carboxylates and the relative positions of CTP and ATP to a single catalytic site are well conserved in both classes of CCA-adding enzymes, whereas the overall architectures, except for the catalytic core, of the class I and class II CCA-adding enzymes are fundamentally different. Furthermore, the recognition mechanisms of substrate nucleotides and tRNA molecules are distinct between these two classes, suggesting that the catalytic domains of class I and class II enzymes share a common origin, and distinct substrate recognition domains have been appended to form the two presently divergent classes.     

Phosphoryl Transfer Reaction Snapshots in Crystals: INSIGHTS INTO THE MECHANISM OF PROTEIN KINASE A CATALYTIC SUBUNIT*

To study the catalytic mechanism of phosphorylation catalyzed by cAMP-dependent protein kinase (PKA) a structure of the enzyme-substrate complex representing the Michaelis complex is of specific interest as it can shed light on the structure of the transition state. However, all previous crystal structures of the Michaelis complex mimics of the PKA catalytic subunit (PKAc) were obtained with either peptide inhibitors or ATP analogs. Here we utilized Ca²⁺ ions and sulfur in place of the nucleophilic oxygen in a 20-residue pseudo-substrate peptide (CP20) and ATP to produce a close mimic of the Michaelis complex. In the ternary reactant complex, the thiol group of Cys-21 of the peptide is facing Asp-166 and the sulfur atom is positioned for an in-line phosphoryl transfer. Replacement of Ca²⁺ cations with Mg²⁺ ions resulted in a complex with trapped products of ATP hydrolysis: phosphate ion and ADP. The present structural results in combination with the previously reported structures of the transition state mimic and phosphorylated product complexes complete the snapshots of the phosphoryl transfer reaction by PKAc, providing us with the most thorough picture of the catalytic mechanism to date.     

Conformational Itinerary of Pseudomonas aeruginosa 1,6-Anhydro-N-acetylmuramic Acid Kinase during Its Catalytic Cycle

Anhydro-sugar kinases are unique from other sugar kinases in that they must cleave the 1,6-anhydro ring of their sugar substrate to phosphorylate it using ATP. Here we show that the peptidoglycan recycling enzyme 1,6-anhydro-N-acetylmuramic acid kinase (AnmK) from Pseudomonas aeruginosa undergoes large conformational changes during its catalytic cycle, with its two domains rotating apart by up to 32° around two hinge regions to expose an active site cleft into which the substrates 1,6-anhydroMurNAc and ATP can bind. X-ray structures of the open state bound to a nonhydrolyzable ATP analog (AMPPCP) and 1,6-anhydroMurNAc provide detailed insight into a ternary complex that forms preceding an operative Michaelis complex. Structural analysis of the hinge regions demonstrates a role for nucleotide binding and possible cross-talk between the bound ligands to modulate the opening and closing of AnmK. Although AnmK was found to exhibit similar binding affinities for ATP, ADP, and AMPPCP according to fluorescence spectroscopy, small angle x-ray scattering analyses revealed that AnmK adopts an open conformation in solution in the absence of ligand and that it remains in this open state after binding AMPPCP, as we had observed for our crystal structure of this complex. In contrast, the enzyme favored a closed conformation when bound to ADP in solution, consistent with a previous crystal structure of this complex. Together, our findings show that the open conformation of AnmK facilitates binding of both the sugar and nucleotide substrates and that large structural rearrangements must occur upon closure of the enzyme to correctly align the substrates and residues of the enzyme for catalysis.