Aesthetic tooth alignment using etched porcelain restorations.

In restorative dentistry, aesthetics often depends upon the creation of symmetry at the patient's midline. This concept can be taken further in that an aesthetic smile has symmetry and harmony between horizontal and vertical planes. This article demonstrates a prosthodontic alternative to orthodontic therapy for patients who require an immediate change to their smile rather than submitting to the latter's extended treatment period. While orthodontic treatment remains the standard for the majority of these cases, other modalities are required for patients who refuse it.

Kinetic mechanism and pH dependence of the kinetic parameters of Pseudomonas aeruginosa phosphomannomutase/phosphoglucomutase.

The enzyme phosphomannomutase/phosphoglucomutase (PMM/PGM) is responsible for the formation of mannose 1-phosphate and glucose 1-phosphate in the human pathogenic bacterium Pseudomonas aeruginosa. Mannose 1-phosphate and glucose 1-phosphate are required for the biosynthesis of polysaccharides that contribute to the virulence of P. aeruginosa, so inhibitors of PMM/PGM may lead to clinically useful compounds. The V/K values for mannose 6-phosphate and glucose 6-phosphate show that they are equally good substrates for the enzyme. PMM/PGM overexpressed in Escherichia coli is isolated as a phosphoenzyme; surprisingly, mutation of serine 108 where phosphorylation occurs results in phosphorylation of a different residue so that activity is reduced only 20-fold from that of wild-type enzyme. In the reverse reaction glucose 1-phosphate exhibits substrate inhibition, which arises through its competition with the activator glucose 1,6-bisphosphate for binding to dephosphoenzyme. This phenomenon is consistent with a mechanism in which the enzyme phosphorylates the substrate to generate a bisphosphorylated intermediate that reorients in the active site to return its original phosphoryl group to the enzyme and generate the observed product. The pH dependence of the kinetic parameters suggests that the active site contains a residue that serves as a general base in the catalytic reaction and one that acts as a general acid. However, the pK of the general acid is 7.4 and that of the general base is 8.4 so these residues exist in a state of reverse protonation in the active enzyme.

Crystallization and initial crystallographic analysis of phosphomannomutase/phosphoglucomutase from Pseudomonas aeruginosa.

The enzyme phosphomannomutase/phosphoglucomutase (PMM/PGM) catalyzes the conversion of mannose 6-phosphate to mannose 1-phosphate in the second step of the alginate biosynthetic pathway of Pseudomonas aeruginosa. PMM/PGM has been crystallized by hanging-drop vapor diffusion in space group P2(1)2(1)2(1). Crystals diffract to 1.75 A resolution on a synchrotron X-ray source under cryo-cooling conditions. PMM/PGM substituted with selenomethionine has been purified and crystallizes isomorphously with the native enzyme. Structure determination by MAD phasing is under way. Because of its role in alginate biosynthesis, PMM/PGM is a potential target for therapeutic inhibitors to combat P. aeruginosa infections.

Identification and purification of hydroxyisourate hydrolase, a novel ureide-metabolizing enzyme.

We report the identification and purification of a novel enzyme from soybean root nodules that catalyzes the hydrolysis of 5-hydroxyisourate, which is the true product of the urate oxidase reaction. The product of this reaction is 2-oxo-4-hydroxy-4-carboxy-5-ureidoimidazoline, and the new enzyme is designated 5-hydroxyisourate hydrolase. The enzyme was purified from crude extracts of soybean root nodules approximately 100-fold to apparent homogeneity with a final specific activity of 10 micromol/min/mg. The enzyme exhibited a native molecular mass of approximately 68 kDa by gel filtration chromatography and migrated as a single band on SDS-polyacrylamide gel electrophoresis with a subunit molecular mass of 68 +/- 2 kDa. The purified enzyme obeyed normal Michaelis-Menten kinetics, and the K(m) for 5-hydroxyisourate was determined to be 15 microM. The amino-terminal end of the purified protein was sequenced, and the resulting sequence was not found in any available data bases, confirming the novelty of the protein. These data suggest the existence of a hitherto unrecognized enzymatic pathway for the formation of allantoin.

Spectroscopic characterization of intermediates in the urate oxidase reaction.

The oxidation of urate catalyzed by soybean urate oxidase was studied under single-turnover conditions using stopped-flow absorbance and fluorescence spectrophotometry. Two discrete enzyme-bound intermediates were observed; the first intermediate to form had an absorbance maximum at 295 nm and was assigned to a urate dianion species; the second intermediate had an absorbance maximum at 298 nm and is believed to be urate hydroperoxide. These data are consistent with a catalytic mechanism that involves formation of urate hydroperoxide from O2 and the urate dianion, collapse of the peroxide to form dehydrourate, and hydration of dehydrourate to form the observed product, 5-hydroxyisourate. The rate of formation of the first intermediate was too fast to measure accurately at 20 degreesC; the second intermediate formed with a rate constant of 32 s-1 and decayed with a rate constant of 6.6 s-1. The product of the reaction, 5-hydroxyisourate, is fluorescent, and its release from the active site occurred with a rate constant of 31 s-1.

Kinetic mechanism and cofactor content of soybean root nodule urate oxidase.

The kinetic mechanism of urate oxidase isolated from soybean root nodules has been determined by initial velocity kinetic studies monitoring oxygen uptake, in order to avoid potential artifacts in the spectrophotometric assay which arise from absorbance due to unidentified products of the enzymatic reaction. Urate and O2 bind to the enzyme sequentially; xanthine is a competitive inhibitor versus urate and a noncompetitive inhibitor versus O2, which suggests that urate binds to the enzyme before O2. This kinetic mechanism was confirmed by an 18O isotope-trapping experiment, which demonstrated that O2 does not bind productively to the enzyme in the absence of urate. The pH dependence of V and (V/K)urate reveal the presence of an ionizable residue on the enzyme with a pK of approximately 6.2, which must be unprotonated for the catalytic reaction to occur. The (V/K)O2 profile is pH independent; these data are accomodated by a model in which a unimolecular step intervenes between the binding of urate and O2. The pKi profile for 9-methylurate, a competitive inhibitor versus urate, is pH independent, confirming that the protonation state of the ionizable residue is not important for binding. The pKi profile for xanthine defines a pK of 7.4, which demonstrates that the monoanion of xanthine binds to the enzyme; by analogy, the monoanion of urate is predicted to be the substrate. The four isomeric N-methylurates were examined as potential inhibitors of urate oxidase. Only 9-methylurate showed significant inhibition suggesting that ionization at N9 of urate is not required for binding; it is proposed that the N3-deprotonated urate monoanion is the species which binds to urate oxidase. The gene encoding urate oxidase was cloned from soybeans and expressed in Escherichia coli. The metal content of the recombinant enzyme was examined by inductively coupled argon plasma emission spectroscopy, and only trace quantities of copper were found. The molecular mass of the protein was determined by MALDI-TOF mass spectrometry and found to be 35,059.8 Da. The calculated molecular mass of urate oxidase is 35,052 Da; therefore, these data suggest that there is no covalently bound cofactor in urate oxidase.

Role of the divalent metal ion in the NAD:malic enzyme reaction: an ESEEM determination of the ground state conformation of malate in the E:Mn:malate complex.

The conformation of L-malate bound at the active site of Ascaris suum malic enzyme has been investigated by electron spin echo envelope modulation spectroscopy. Dipolar interactions between Mn2+ bound to the enzyme active site and deuterium specifically placed at the 2-position, the 3R-position, and the 3S-position of L-malate were observed. The intensities of these interactions are related to the distance between each deuterium and Mn2+. Several models of possible Mn-malate complexes were constructed using molecular graphics techniques, and conformational searches were conducted to identify conformers of malate that meet the distance criteria defined by the spectroscopic measurements. These searches suggest that L-malate binds to the enzyme active site in the trans conformation, which would be expected to be the most stable conformer in solution, not in the gauche conformer, which would be more similar to the conformation required for oxidative decarboxylation of oxalacetate formed from L-malate at the active site of the enzyme.

Transient-state kinetic analysis of the oxidative decarboxylation of D-malate catalyzed by tartrate dehydrogenase.

The oxidative decarboxylation of D-malate catalyzed by tartrate dehydrogenase has been analyzed by transient-state kinetic methods and kinetic isotope effect measurements. The reaction time courses show a burst of NADH formation prior to the attainment of the steady-state velocity. The binding of the inhibitor tartronate to the enzyme was examined by monitoring the quenching of the protein's intrinsic fluorescence; the tartronate concentration dependence of the observed rate constant for association was hyperbolic, supporting a two-step model for inhibitor binding. Analysis of the time courses for D-malate oxidation yielded values for many of the microscopic rate constants governing the reaction. The range of possible solutions for the microscopic rate constants was constrained by comparison of the time course for oxidation of unlabeled malate with that of deuterated malate; this analysis relied on the determination of the intrinsic isotope effect on hydride transfer via measurement of D(V/K), T(V/K), and the oxaloacetate partition ratio. The results of the transient-state kinetic analyses suggest that the rate of D-malate oxidation is largely limited by the rate of decarboxylation of the intermediate oxaloacetate which occurs at 11 s-1. Hydride transfer from D-malate to NAD+ occurs with a rate constant of 300 s-1, and (D)k for this step is 5.5. The agreement between experimentally measured steady-state kinetic parameters and kinetic isotope effects and their values calculated from the microscopic rate constants derived from the transient-state kinetic analyses was quite good.

A colorimetric assay for cytokinin oxidase.

A simple and rapid colorimetric assay for cytokinin oxidase is described. The assay is based on the formation of a Schiff base between the enzymatic reaction product 3-methyl-2-butenal and p-aminophenol. The assay is effective in the submicromolar concentration range and can be used in crude plant extracts as well as in more highly purified preparations.

Substrate determinants of the course of tartrate dehydrogenase-catalyzed reactions.

The substrate specificity of tartrate dehydrogenase has been probed using a series of alternative substrates to identify the molecular interactions which determine whether a particular substrate undergoes enzyme-catalyzed decarboxylation or not. A series of 3-substituted malate analogs, in which F, Cl, Br, I, SH, or NH2 substituents were placed at the 3R- or 3S-position, was prepared, and the product resulting from the action of tartrate dehydrogenase on each compound was identified. All of the halomalates and both diastereomers of aminomalate underwent oxidative decarboxylation; both diastereomers of 3-thiomalate underwent net nonoxidative decarboxylation. The results were interpreted in terms of a model in which decarboxylation is conformationally controlled. The data are not consistent with a model which suggests that substrates assume the conformation that is necessary to avoid steric crowding between the enzyme and the substituent at the 3-position of the substrate. These data are consistent with a model in which the course of the reaction with (+)-tartrate and meso-tartrate is dictated by the coordination of the substrate hydroxyls to the active site Mn2+. However, the observed reactivities of the 3-methyltartrate diastereomers are not consistent with this model, either: (2R,3R)-3-methyltartrate undergoes oxidative decarboxylation, and (2R,3S)-3-methyltartrate undergoes simple oxidation. These results suggest that for these compounds the conformation is dictated by the positioning of the hydrophobic substituent in a specific binding pocket.(ABSTRACT TRUNCATED AT 250 WORDS)

Tartrate dehydrogenase-oxalate complexes: formation of a stable analog of a reaction intermediate complex.

Oxalate has been shown to form a stable complex with Mn-tartrate dehydrogenase-NADH complexes which are proposed to mimic an intermediate formed during catalytic turnover. The formation of this complex can be detected under turnover conditions, where oxalate acts as a time-dependent inhibitor, and under equilibrium conditions, where oxalate binding triggers a slow protein conformation change detectable by fluorescence spectroscopy. Both the rate constant for the change in fluorescence intensity upon oxalate binding and the magnitude of the fluoresence change show a hyperbolic dependence on oxalate concentration. The time-dependent inhibition by oxalate is not consistent with a model in which oxalate binds to enzyme-NAD; rather, it is proposed that inhibition arises from binding to enzyme-NADH. The apparent dissociation constants of oxalate from enzyme-NAD+ and the enzyme-NADH complexes are 80 and 1 microM, respectively. The fluorescence changes which accompany oxalate binding are suggested to arise from a protein conformational change which serves to sequester reactants in the active site. Consistent with this hypothesis, it was observed that although some alternative pyridine nucleotide cofactors supported the multistep tartrate dehydrogenase-catalyzed net nonoxidative decarboxylation of meso-tartrate only at drastically reduced rates, none of the intermediate hydroxypyruvate was released into solution. In addition, fluorescence anisotropy measurements were conducted to investigate the mode of NADH binding.

Tartrate dehydrogenase, a new member of the family of metal-dependent decarboxylating R-hydroxyacid dehydrogenases.

The gene encoding tartrate dehydrogenase has been cloned from Pseudomonas putida and sequenced. The gene is 1098 nucleotides long and encodes a protein 365 amino acids in length with a calculated M(r) of 40,636. The gene and the protein encoded by it show strong homology to prokaryotic isopropylmalate dehydrogenases and, to a lesser extent, isocitrate dehydrogenase. Thus, tartrate dehydrogenase is the third member to be identified of the family of metal-dependent decarboxylating R-hydroxyacid dehydrogenases which have an evolutionarily distinct NAD(+)-binding domain. The poor catalytic properties of tartrate dehydrogenase suggest that it has not been under strong selective pressure to maximize its ability to turn over (+)-tartrate for very long; the homology with isopropylmalate dehydrogenase makes it an attractive candidate for a recent progenitor of tartrate dehydrogenase. beta-Isopropylmalate is a substrate for tartrate dehydrogenase with a Km of 14 +/- 2 microM; it is turned over with a Vmax that is 35% of Vmax in the (+)-tartrate reaction. The gene encoding tartrate dehydrogenase has been expressed in Escherichia coli and large quantities of soluble enzyme can be obtained.

Intermediate partitioning in the tartrate dehydrogenase-catalyzed oxidative decarboxylation of D-malate.

The oxidative decarboxylation of D-malate catalyzed by tartrate dehydrogenase has been examined in detail. Enzyme-catalyzed partitioning of oxalacetate has been determined to proceed with formation of pyruvate and D-malate in a ratio of 3.7 to 1. These data, along with the deuterium and tritium kinetic isotope effects on hydride transfer, allow exact calculation of the intrinsic isotope effect and the forward and reverse commitments to catalysis, which have values of 5.1 +/- 0.8, 6.3 +/- 1.0, and 2.0 +/- 0.3, respectively. The viscosity dependence of the tritium isotope effect was measured, which allowed determination of the internal and external components of the commitment factors. The reverse commitment has no external portion, but the forward commitment can be divided into external and internal portions of 3.7 +/- 1.2 and 2.6 +/- 1.6, respectively. These data indicate that the reaction becomes committed to catalysis in the forward direction by formation of the Michaelis complex; reverse hydride transfer from NADH to OAA is twice as fast as decarboxylation of OAA, and recarboxylation of pyruvate occurs at a negligible rate. The rate constant for dissociation of OAA from the enzyme active site was estimated to be approximately 4 orders of magnitude slower than that for dissociation of oxaloglycolate, which is the product of the enzyme-catalyzed oxidation of (+)-tartrate.

Pulsed EPR analysis of tartrate dehydrogenase active-site complexes.

Mn2+.tartrate dehydrogenase.substrate complexes have been examined by electron spin echo envelope modulation spectroscopy. The occurrence of dipolar interactions between Mn2+ and 2H on [2H]pyruvate and [4-2H]NAD(H) confirms that Mn2+ binds at the enzyme active site. The 2H signal arising from labeled pyruvate was lost if the sample was incubated at room temperature, indicating that the enzyme catalyzes exchange between the pyruvate methyl protons and solvent protons. Mn-133Cs dipolar coupling was also observed, which suggests that the monovalent cation cofactor also binds in the active site. The tartrate analogue oxalate was observed to have a significant effect on the binding of NAD(H). Oxalate appears to constrain the binding of NAD(H) so that the nicotinamide portion of the cofactor is held in close proximity to Mn2+. Spectra of enzyme complexes prepared with (R)-[4-2H]NADH showed a more intense 2H signal than analogous complexes prepared with (S)-[4-2H]NADH, demonstrating that the pro-R position of NADH is closer to Mn2+ than the pro-S position and suggesting that tartrate dehydrogenase is an A-side-specific dehydrogenase. Oxalate also affected Cs+ binding; the intensity of the 133Cs signal increased in the presence of oxalate, which suggest that oxalate facilitates binding of Cs+ to the active site or that Cs+ binds closer to Mn2+ when oxalate is present. In addition to signals from substrates, electron spin echo envelope modulation spectra revealed 14N signals that arose from coordination to Mn2+ by nitrogen-containing ligands from the protein; however, the identity of this ligand or ligands remains obscure.

Characterization of the multiple catalytic activities of tartrate dehydrogenase.

Tartrate dehydrogenase (TDH) has been purified to apparent homogeneity from Pseudomonas putida and has been demonstrated to catalyze three different NAD(+)-dependent reactions. TDH catalyzes the oxidation of (+)-tartrate to form oxaloglycolate and the oxidative decarboxylation of D-malate to form pyruvate and CO2. D-Glycerate and CO2 are formed from meso-tartrate in a reaction that is formally a decarboxylation with no net oxidation or reduction. The steady-state kinetics of the first two reactions have been investigated and found to follow primarily ordered mechanisms. The pH dependence of V and V/K was determined and indicates that catalysis requires that a base on the enzyme with a pK of 6.7 be unprotonated. TDH activity requires a divalent and a monovalent cation. Kinetic data suggest that the cations function in substrate binding and facilitation of the decarboxylation of beta-ketoacid intermediates.

Electron spin echo envelope modulation studies of pyruvate kinase active-site complexes.

Electron spin echo envelope modulation (ESEEM) spectroscopy, with Mn2+ and VO2+ as paramagnetic probes, was used to examine active-site structures at the protein-based divalent cation site of rabbit muscle pyruvate kinase in the presence of substrates, products, and the requisite inorganic cofactors. Two different VO.protein complexes were clearly distinguished, which differed with respect to coordination of the active-site lysine to VO2+. Lysine coordination was sensitive to the presence of pyruvate and phosphoenolpyruvate (PEP) and to the nature of the monovalent cation. In the presence of MgATP and oxalate, a 4-MHz 31P contact interaction was observed, which indicates that the ATP is directly coordinated to Mn2+ at the protein-based site. No 31P contact interactions were observed, however, in the presence of PEP. Pyruvate was determined to be a bidentate ligand of VO2+, on the basis of the observation of 2.2- and 5.4-MHz 13C contact interactions between VO2+ and [1-13C]pyruvate and [2-13C]pyruvate, respectively. Magnetic coupling between VO2+ or Mn2+ and 23Na, 39K, and 133Cs was observed, demonstrating the close proximity of the monovalent cation and the protein-based divalent cation.

Catalytic mechanism of biotin carboxylase: steady-state kinetic investigations.

Biotin carboxylase was purified from Escherichia coli by a new procedure, and its steady-state kinetic parameters were examined. MgATP and bicarbonate add to the enzyme randomly, followed by addition of biotin. Both bicarbonate and MgATP add in rapid equilibrium. A catalytic base with a pK of 6.6 is observed in V/K profiles. Inactivation studies also revealed a sulfhydryl group in the active site that is essential for catalysis. It is proposed that the acid-base catalysts are necessary for the tautomerization of biotin, which presumably enhances its nucleophilicity toward the carboxyl group donor. A second enzymic group with a pK of 6.6, whose role is unknown, is seen in Vmax profiles. The pH profiles for the biotin carboxylase catalyzed phosphorylation of ADP by carbamoyl phosphate have the same shape as the profiles for the forward reaction, which demonstrates that the enzymic bases assume the same protonation states for catalysis of transphosphorylation in either direction. The lack of reactivity of thionucleotide analogues of ATP when Mg is used as the divalent metal ion suggests that both metal ions required for reaction coordinate to the nucleotide. The second metal ion appears to be absolutely required for reaction and not merely an activator of the reaction. Characterization of a bicabonate-dependent biotin-independent ATPase activity strongly suggests that carboxylation proceeds via a carboxyphosphate intermediate.

Carbon-13 and deuterium isotope effects on the catalytic reactions of biotin carboxylase.

13C and 2H kinetic isotope effects have been used to investigate the mechanism of enzymic biotin carboxylation. D(V/K) is 0.50 in 80% D2O at pD 8.0 for the forward reaction and 0.57 at pD 8.5 for the phosphorylation of ADP by carbamoyl phosphate. These values approach the theoretical maximum limit for a reaction in which a proton is transferred from a sulfhydryl to a nitrogen or oxygen base. Therefore, it appears that this portion of the reaction is at or near equilibrium. 13(V/K) at pH 8 is 1.007; the small magnitude of this number suggests that the reaction is almost fully committed by the time the carbon-sensitive steps are reached. There does not appear to be a reverse commitment to the reaction under the conditions in which 13(V/K) was determined. A large forward commitment is consistent with the failure to observe positional isotope exchange from the beta gamma-bridge position to the beta-nonbridge position in [18O4]ATP or washout of 18O from the gamma-nonbridge positions. Transfer of 18O from bicarbonate to inorganic phosphate in the forward reaction was clearly observed, however. These observations suggest that biotin carboxylase exists in two distinct forms which differ in the protonation states of the two active-site bases, one of which is a sulfhydryl. Only when the sulfhydryl is ionized and the second base protonated can catalysis take place. Carboxylation of biotin is postulated to occur via a pathway in which carboxyphosphate in formed by nucleophilic attack of bicarbonate on ATP.(ABSTRACT TRUNCATED AT 250 WORDS)

Carbon-13 isotope effects on reactions involving carbamate and carbamoyl phosphate.

Several 13C isotope effects of relevance to reactions involving carbamate and carbamoyl phosphate have been determined. The fractionation factor of carbamate relative to aqueous CO2 is 1.011; the equilibrium isotope effect on the reaction catalyzed by carbamate kinase is 0.9983. From these data we can calculate that the fractionation factor of carbamoyl phosphate relative to aqueous CO2 is 1.013. The kinetic 13C isotope effect on the decomposition of carbamoyl phosphate to cyanate and phosphate is 1.058. The environment of the carbon atom in carbamate and carbamoyl phosphate and the mechanism of carbamoyl phosphate decomposition are discussed in light of these values.

Carbon-13 and deuterium isotope effects on oxalacetate decarboxylation by pyruvate carboxylase.

Deuterium and 13C isotope effects for the enzymic decarboxylation of oxalacetate showed that both deuterium- and 13C-sensitive steps in the reaction are partially rate limiting. A normal alpha-secondary effect of 1.2 per deuterium was calculated for the reaction in which pyruvate-d3 was the substrate, suggesting that the enolate of pyruvate was an intermediate in the reaction. The large normal alpha-secondary deuterium isotope effect of 1.7 when oxalacetate-d2 was the substrate suggests that the motions of the secondary hydrogens are coupled to that of the primary hydrogen during the protonation of the enolate of pyruvate. The reduction in the magnitude of the 13C isotope effect for the oxamate-dependent decarboxylation of oxalacetate from 1.0238 to 1.0155 when the reaction was performed in D2O (primary deuterum isotope effect = 2.1) clearly indicates that the transfer of the proton and carboxyl group between biotin and pyruvate does not occur via a single concerted reaction. Mechanisms in which biotin is activated to react with CO2 (prior to transfer of the proton on N-1) by bond formation between the sulfur and the ureido carbon, or in which the sequence of events is decarboxylation of oxalacetate, proton transfer from biotin to enolpyruvate, and carboxylation of enolbiotin, predict that the 13C isotope effect in D2O should be substantially lower than the observed value. A stepwise mechanism that does fit the data is one in which a proton is removed from biotin by a sulfhydryl group on the enzyme prior to carboxyl transfer, as long as the sulfhydryl group has an abnormally low pK.(ABSTRACT TRUNCATED AT 250 WORDS)