Roles for Arg426 and Trp111 in the modulation of NADH oxidase activity of the catalase-peroxidase KatG from Burkholderia pseudomallei inferred from pH-induced structural changes

Crystals of Burkholderia pseudomallei KatG retain their ability to diffract X-rays at high resolution after adjustment of the pH from 5.6 to 4.5, 6.5, 7.5, and 8.5, providing a unique view of the effect of pH on protein structure. One significant pH-sensitive change lies in the appearance of a perhydroxy group attached to the indole nitrogen of the active site Trp111 above pH 7, similar to a modification originally observed in the Ser324Thr variant of the enzyme at pH 5.6. The modification forms rapidly from molecular oxygen in the buffer with 100% occupancy after one minute of soaking of the crystal at room temperature and pH 8.5. The low temperature (4 K) ferric EPR spectra of the resting enzyme, being very sensitive to changes in the heme iron microenvironment, confirm the presence of the modification above pH 7 in native enzyme and variants lacking Arg426 or Met264 and its absence in variants lacking Trp111 or Tyr238. The indole-perhydroxy group is very likely the reactive intermediate of molecular oxygen in the NADH oxidase reaction, and Arg426 is required for its reduction. The second significant pH-sensitive change involves the buried side chain of Arg426 that changes from one predominant conformation at low pH to a second at high pH. The pH profiles of the peroxidase, catalase, and NADH oxidase reactions can be correlated with the distribution of Arg426 conformations. Other pH-induced structural changes include a number of surface-situated side chains, but there is only one change involving a displacement of main chain atoms triggered by the protonation of His53 in a deep pocket in the vicinity of the molecular 2-fold axis.     

Structure of catalase HPII from Escherichia coli at 1.9 A resolution

Catalase HPII from Escherichia coli, a homotetramer of subunits with 753 residues, is the largest known catalase. The structure of native HPII has been refined at 1.9 A resolution using X-ray synchrotron data collected from crystals flash-cooled with liquid nitrogen. The crystallographic agreement factors R and R(free) are respectively 16.6% and 21.0%. The asymmetric unit of the crystal contains a whole molecule that shows accurate 222-point group symmetry. The structure of the central part of the HPII subunit gives a root mean square deviation of 1.5 A for 477 equivalencies with beef liver catalase. Most of the additional 276 residues of HPII are located in either an extended N-terminal arm or in a C-terminal domain organized with a flavodoxin-like topology. A small number of mostly hydrophilic interactions stabilize the relative orientation between the C-terminal domain and the core of the enzyme. The heme component of HPII is a cis-hydroxychlorin gamma-spirolactone in an orientation that is flipped 180 degrees with respect to the orientation of the heme found in beef liver catalase. The proximal ligand of the heme is Tyr415 which is joined by a covalent bond between its Cbeta atom and the Ndelta atom of His392. Over 2,700 well-defined solvent molecules have been identified filling a complex network of cavities and channels formed inside the molecule. Two channels lead close to the distal side heme pocket of each subunit suggesting separate inlet and exhaust functions. The longest channel, that begins in an adjacent subunit, is over 50 A in length, and the second channel is about 30 A in length. A third channel reaching the heme proximal side may provide access for the substrate needed to catalyze the heme modification and His-Tyr bond formation. HPII does not bind NADPH and the equivalent region to the NADPH binding pocket of bovine catalase, partially occluded in HPII by residues 585-590, corresponds to the entrance to the second channel. The heme distal pocket contains two solvent molecules, and the one closer to the iron atom appears to exhibit high mobility or low occupancy compatible with weak coordination.     

Catalase-peroxidases (KatG) exhibit NADH oxidase activity

Catalase-peroxidases (KatG) produced by Burkholderia pseudomallei, Escherichia coli, and Mycobacterium tuberculosis catalyze the oxidation of NADH to form NAD+ and either H2O2 or superoxide radical depending on pH. The NADH oxidase reaction requires molecular oxygen, does not require hydrogen peroxide, is not inhibited by superoxide dismutase or catalase, and has a pH optimum of 8.75, clearly differentiating it from the peroxidase and catalase reactions with pH optima of 5.5 and 6.5, respectively, and from the NADH peroxidase-oxidase reaction of horseradish peroxidase. B. pseudomallei KatG has a relatively high affinity for NADH (Km=12 microm), but the oxidase reaction is slow (kcat=0.54 min(-1)) compared with the peroxidase and catalase reactions. The catalase-peroxidases also catalyze the hydrazinolysis of isonicotinic acid hydrazide (INH) in an oxygen- and H2O2-independent reaction, and KatG-dependent radical generation from a mixture of NADH and INH is two to three times faster than the combined rates of separate reactions with NADH and INH alone. The major products from the coupled reaction, identified by high pressure liquid chromatography fractionation and mass spectrometry, are NAD+ and isonicotinoyl-NAD, the activated form of isoniazid that inhibits mycolic acid synthesis in M. tuberculosis. Isonicotinoyl-NAD synthesis from a mixture of NAD+ and INH is KatG-dependent and is activated by manganese ion. M. tuberculosis KatG catalyzes isonicotinoyl-NAD formation from NAD+ and INH more efficiently than B. pseudomallei KatG.     

Structural and biochemical features distinguish the foot-and-mouth disease virus leader proteinase from other papain-like enzymes

The structures of the two leader protease (Lpro) variants of foot-and-mouth disease virus known to date were solved using crystals in which molecules were organized as molecular fibers. Such crystals diffract to a resolution of only approximately 3 A. This singular, pseudo-polymeric organization is present in a new Lpro crystal form showing a cubic packing. As molecular fiber formation appeared unrelated to crystallization conditions, we mutated the reactive cysteine 133 residue, which makes a disulfide bridge between adjacent monomers in the fibers, to serine. None of the intermolecular contacts found in the molecular fibers was present in crystals of this variant. Analysis of this Lpro structure, refined at 1.9 A resolution, enables a detailed definition of the active center of the enzyme, including the solvent organization. Assay of Lpro activity on a fluorescent hexapeptide substrate showed that Lpro, in contrast to papain, was highly sensitive to increases in the cation concentration and was active only across a narrow pH range. Examination of the Lpro structure revealed that three aspartate residues near the active site, not present in papain-like enzymes, are probably responsible for these properties.     

Structure of human rhinovirus serotype 2 (HRV2)

Human rhinoviruses are classified into a major and a minor group based on their binding to ICAM-1 or to members of the LDL-receptor family, respectively. They can also be divided into groups A and B, according to their sensitivity towards a panel of antiviral compounds. The structure of human rhinovirus 2 (HRV2), which uses the LDL receptor for cell attachment and is included in antiviral group B, has been solved and refined at 2.6 A resolution by X-ray crystallography to gain information on the peculiarities of rhinoviruses, in particular from the minor receptor group. The main structural differences between HRV2 and other rhinoviruses, including the minor receptor group serotype HRV1A, are located at the internal protein shell surface and at the external antigenic sites. In the interior, the N termini of VP1 and VP4 form a three-stranded beta-sheet in an arrangement similar to that present in poliovirus, although myristate was not visible at the amino terminus of VP4 in the HRV2 structure. The betaE-betaF loop of VP2, a linear epitope within antigenic site B recognized by monoclonal antibody 8F5, adopts a conformation considerably different from that found in the complex of 8F5 with a synthetic peptide of the same sequence. This either points to considerable structural changes impinged on this loop upon antibody binding, or to the existence of more than one single conformation of the loop when the virus is in solution. The hydrophobic pocket of VP1 was found to be occupied by a pocket factor apparently identical with that present in the major receptor group virus HRV16. Electron density, consistent with the presence of a viral RNA fragment, is seen stacked against a conserved tryptophan residue.     

The 1.5 A resolution crystal structure of the carbamate kinase-like carbamoyl phosphate synthetase from the hyperthermophilic Archaeon pyrococcus furiosus, bound to ADP, confirms that this thermostable enzyme is a carbamate kinase, and provides insight into substrate binding and stability in carbamate kinases

Carbamoyl phosphate (CP), an essential precursor of arginine and the pyrimidine bases, is synthesized by CP synthetase (CPS) in three steps. The last step, the phosphorylation of carbamate, is also catalyzed by carbamate kinase (CK), an enzyme used by microorganisms to produce ATP from ADP and CP. Although the recently determined structures of CPS and CK show no obvious mutual similarities, a CK-like CPS reported in hyperthermophilic archaea was postulated to be a missing link in the evolution of CP biosynthesis. The 1.5 A resolution structure of this enzyme from Pyrococcus furiosus shows both a subunit topology and a homodimeric molecular organization, with a 16-stranded open beta-sheet core surrounded by alpha-helices, similar to those in CK. However, the pyrococcal enzyme exhibits many solvent-accessible ion-pairs, an extensive, strongly hydrophobic, intersubunit surface, and presents a bound ADP molecule, which does not dissociate at 22 degrees C from the enzyme. The ADP nucleotide is sequestered in a ridge formed over the C-edge of the core sheet, at the bottom of a large cavity, with the purine ring enclosed in a pocket specific for adenine. Overall, the enzyme structure is ill-suited for catalyzing the characteristic three-step reaction of CPS and supports the view that the CK-like CPS is in fact a highly thermostable and very slow (at 37 degrees C) CK that, in the extreme environment of P. furiosus, may have the new function of making, rather than using, CP. The thermostability of the enzyme may result from the extension of the hydrophobic intersubunit contacts and from the large number of exposed ion-pairs, some of which form ion-pair networks across several secondary structure elements in each enzyme subunit. The structure provides the first information on substrate binding and catalysis in CKs, and suggests that the slow rate at 37 degrees C is possibly a consequence of slow product dissociation.     

Structure of the C2 domain from novel protein kinase Cepsilon. A membrane binding model for Ca(2+)-independent C2 domains

Protein kinase Cepsilon (PKCepsilon) is a member of the novel PKCs which are activated by acidic phospholipids, diacylglycerol and phorbol esters, but lack the calcium dependence of classical PKC isotypes. The crystal structures of the C2 domain of PKCepsilon, crystallized both in the absence and in the presence of the two acidic phospholipids, 1,2-dicaproyl-sn-phosphatidyl-l-serine (DCPS) and 1,2-dicaproyl-sn-phosphatidic acid (DCPA), have now been determined at 2.1, 1.7 and 2.8 A resolution, respectively. The central feature of the PKCepsilon-C2 domain structure is an eight-stranded, antiparallel, beta-sandwich with a type II topology similar to that of the C2 domains from phospholipase C and from novel PKCdelta. Despite the similar topology, important differences are found between the structures of C2 domains from PKCs delta and epsilon, suggesting they be considered as different PKC subclasses. Site-directed mutagenesis experiments and structural changes in the PKCepsilon-C2 domain from crystals with DCPS or DCPA indicate, though phospholipids were not visible in these structures, that loops joining strands beta1-beta2 and beta5-beta6 participate in the binding to anionic membranes. The different behavior in membrane-binding and activation between PKCepsilon and classical PKCs appears to originate in localized structural changes, which include a major reorganization of the region corresponding to the calcium binding pocket in classical PKCs. A mechanism is proposed for the interaction of the PKCepsilon-C2 domain with model membranes that retains basic features of the docking of C2 domains from classical, calcium-dependent, PKCs.     

X-ray structure of a minor group human rhinovirus bound to a fragment of its cellular receptor protein

Although many viral receptors have been identified, the ways in which they interact with their cognate viruses are not understood at the molecular level. We have determined the X-ray structure of a complex between calcium-containing modules of the very low-density lipoprotein receptor and the minor group human rhinovirus HRV2. The receptor binds close to the icosahedral five-fold vertex, with only one module per virus protomer. The binding face of this module is defined by acidic calcium-chelating residues and, in particular, by an exposed tryptophan that is highly conserved. The attachment site on the virus involves only residues from VP1, particularly a lysine strictly conserved in all minor group HRVs. The disposition of the attached ligand-binding repeats around the five-fold axis, together with the proximity of the N- and C-terminal ends of adjacent modules, suggests that more than one repeat in a single receptor molecule might attach simultaneously.     

Additional binding sites for anionic phospholipids and calcium ions in the crystal structures of complexes of the C2 domain of protein kinase calpha

The C2 domain of protein kinase Calpha (PKCalpha) corresponds to the regulatory sequence motif, found in a large variety of membrane trafficking and signal transduction proteins, that mediates the recruitment of proteins by phospholipid membranes. In the PKCalpha isoenzyme, the Ca2+-dependent binding to membranes is highly specific to 1,2-sn-phosphatidyl-l-serine. Intrinsic Ca2+ binding tends to be of low affinity and non-cooperative, while phospholipid membranes enhance the overall affinity of Ca2+ and convert it into cooperative binding. The crystal structure of a ternary complex of the PKCalpha-C2 domain showed the binding of two calcium ions and of one 1,2-dicaproyl-sn-phosphatidyl-l-serine (DCPS) molecule that was coordinated directly to one of the calcium ions. The structures of the C2 domain of PKCalpha crystallised in the presence of Ca2+ with either 1,2-diacetyl-sn-phosphatidyl-l-serine (DAPS) or 1,2-dicaproyl-sn-phosphatidic acid (DCPA) have now been determined and refined at 1.9 A and at 2.0 A, respectively. DAPS, a phospholipid with short hydrocarbon chains, was expected to facilitate the accommodation of the phospholipid ligand inside the Ca2+-binding pocket. DCPA, with a phosphatidic acid (PA) head group, was used to investigate the preference for phospholipids with phosphatidyl-l-serine (PS) head groups. The two structures determined show the presence of an additional binding site for anionic phospholipids in the vicinity of the conserved lysine-rich cluster. Site-directed mutagenesis, on the lysine residues from this cluster that interact directly with the phospholipid, revealed a substantial decrease in C2 domain binding to vesicles when concentrations of either PS or PA were increased in the absence of Ca2+. In the complex of the C2 domain with DAPS a third Ca2+, which binds an extra phosphate group, was identified in the calcium-binding regions (CBRs). The interplay between calcium ions and phosphate groups or phospholipid molecules in the C2 domain of PKCalpha is supported by the specificity and spatial organisation of the binding sites in the domain and by the variable occupancies of ligands found in the different crystal structures. Implications for PKCalpha activity of these structural results, in particular at the level of the binding affinity of the C2 domain to membranes, are discussed.