Phosphorus-containing inhibitors of aspartate transcarbamoylase from Escherichia coli

A tetrahedral intermediate is the prominent feature of the generally accepted mechanism for aspartate transcarbamoylase. We have synthesized N-pyrophosphoryl-L-aspartate as a charged analogue of the postulated intermediate. Surprisingly, its affinity for the enzyme from Escherichia coli was substantially lower than that of the previously known inhibitor phosphonoacetyl-L-aspartate which contained a trigonal carbonyl group. Similar results were obtained with the corresponding mercaptosuccinate derivatives. We also tested a number of new pyrophosphate analogues as inhibitors. Our results cast doubt on some aspects of the current model for the mechanism of this enzyme.     

Development of an HPLC assay for Staphylococcus aureus sortase: evidence for the formation of the kinetically competent acyl enzyme intermediate

Many bacterial surface proteins containing an LPXTG motif are anchored to the cell wall peptidoglycan by catalysis with the thiol transpeptidase sortase. The transpeptidation and hydrolysis reactions of sortase have been proposed to proceed through a common acyl enzyme intermediate. The reactions of Staphylococcus aureus sortase with fluorogenic substrate Abz-LPETG-Dnp in the presence or absence of triglycine were characterized in this study to gain additional insight into the kinetic mechanism of sortase. We report here the development of a reverse-phase HPLC assay to identify and characterize sortase reaction intermediates. The HPLC results provide for the first time clear evidence for the formation of a kinetically competent acyl enzyme intermediate during the overall transpeptidation reaction. The results also suggest that sortase undergoes an unexpected intramolecular acyl transfer reaction in the absence of a nucleophile. The significance of this type of HPLC assay as a tool to study enzyme mechanism is discussed.     

Catalytic mechanism of fungal homoserine transacetylase

Homoserine transacetylase is a required catalyst in the biochemical pathway that metabolizes Asp to Met in fungi. The enzyme from the yeast Schizosaccharomyces pombe activates the hydroxyl group of L-homoserine by acetylation from acetyl coenzyme A. This enzyme is unique to fungi and some bacteria and presents an important new target for drug discovery. Steady-state kinetic parameters provide evidence that this enzyme follows a ping-pong mechanism. Proton inventory was consistent with a single-proton transfer, and pH studies suggested the participation of at least one residue with a pKa value of 6.4-6.6, possibly a His or Asp/Glu in catalysis. Protein sequence alignments indicate that this enzyme belongs to the alpha/beta-hydrolase fold superfamily of enzymes, indicating the involvement of an active-site nucleophile and possibly a canonical catalytic triad. We constructed site-specific mutants and identified Ser163, Asp403, and His432 as the likely active-site residues of a catalytic triad based on steady-state kinetics and genetic complementation of a yeast null mutant. Moreover, unlike the wild-type enzyme, inactive site mutants were not capable of producing an acetyl-enzyme intermediate. Homoserine transacetylase therefore catalyzes the acetylation of L-homoserine via a covalent acyl-enzyme intermediate through an active-site Ser. These results form the basis of future exploitation of this enzyme as an antimicrobial target.     

Studies on the mechanism of formyltetrahydrofolate synthetase. The Peptococcus aerogenes enzyme

Two conflicting mechanisms have been proposed for formyltetrahydrofolate synthetase (EC 6.3.4.3). Detailed studies with a clostridial enzyme support a sequential mechanism, while a stepwise mechanism with formation of a dissociable intermediate has been proposed for the Peptococcus aerogenes synthetase. However, the data supporting the P. aerogenes mechanism were obtained using synthetase of questionable purity and the results supporting the mechanism could be attributed to contaminating activities. Consequently, uncertainty still exists with regard to the enzyme mechanism. To resolve this uncertainty, the P. aerogenes formyltetrahydrofolate synthetase has been purified to homogeneity and used in experiments to reinvestigate the reaction mechanism. The results of P1:ATP, ADP:ATP, and formate:10-formyltetrahydrofolate exchange experiments as well as a steady state kinetic analysis revealed no difference in the mechanisms of the P. aerogenes or clostridial synthetases. The results are inconsistent with a stepwise mechanism involving a dissociable intermediate and consistent only with a sequential mechanism.     

Identification of intermediate and product from methemoglobin-catalyzed oxidation of <Emphasis Type="Italic">o</Emphasis>-phenylenediamine in two-phase aqueous—organic system

Methemoglobin (metHb) was used as a mimetic enzyme for peroxidase to catalyze the oxidation reaction of o-phenylenediamine (OPDA) with H2O2 functioning as an oxidant. A reaction intermediate was obtained in two-phase aqueous-organic system and an absorption peak at 710 nm was confirmed to be that of the intermediate in relation to OPDA. The isolated product and intermediate were characterized by UV-Vis and IR spectrophotometry and HPLC-tandem mass spectrometry. The results showed that the product is 2,3-diaminophenazine, the molecular mass of the intermediate is 212 daltons, and a conceivable structure of the intermediate is suggested. Combining the catalyzed reaction mechanism of peroxidase and our experimental results, a conceivable oxidation reaction mechanism of OPDA and H2O2 using metHb as catalyst is proposed.     

Structural basis of pyrrole polymerization in human porphobilinogen deaminase

Human porphobilinogen deaminase (PBGD), the third enzyme in the heme pathway, catalyzes four times a single reaction to convert porphobilinogen into hydroxymethylbilane. Remarkably, PBGD employs a single active site during the process, with a distinct yet chemically equivalent bond formed each time. The four intermediate complexes of the enzyme have been biochemically validated and they can be isolated but they have never been structurally characterized other than the apo- and holo-enzyme bound to the cofactor. We present crystal structures for two human PBGD intermediates: PBGD loaded with the cofactor and with the reaction intermediate containing two additional substrate pyrrole rings. These results, combined with SAXS and NMR experiments, allow us to propose a mechanism for the reaction progression that requires less structural rearrangements than previously suggested: the enzyme slides a flexible loop over the growing-product active site cavity. The structures and the mechanism proposed for this essential reaction explain how a set of missense mutations result in acute intermittent porphyria.     

Channeling of 3-hydroxy-4-trans-decenoyl coenzyme A on the bifunctional beta-oxidation enzyme from rat liver peroxisomes and on the large subunit of the fatty acid oxidation complex from Escherichia coli

Rates of the NAD+-dependent oxidation of 2-trans,4-trans-decadienoyl-CoA, a metabolite of trans-omega-6-unsaturated fatty acids, catalyzed by the mitochondrial enoyl-CoA hydratase plus 3-hydroxyacyl-CoA dehydrogenase and by the corresponding enzymes from peroxisomes, as well as Escherichia coli, were compared. The study of the mitochondrial system revealed that the conventional kinetic theory of coupled enzyme reactions cannot be applied to systems in which the primary reaction has a small equilibrium constant, and/or the concentration of coupling enzyme is higher than 0.01 Km for the intermediate and higher than the steady-state concentration of the intermediate. In contrast to the results obtained with the mitochondrial beta-oxidation system of unlinked enzymes, the steady-state velocities of 2-trans,4-trans-decadienoyl-CoA degradation catalyzed by either the peroxisomal bifunctional enzyme or by the E. coli fatty acid oxidation complex were found to be equal to the activities of enoyl-CoA hydratase even though the concentration of coupling enzyme was equal to that of the primary enzyme, and the quotient of Vmax/Km for the dehydration of 3-hydroxy-4-trans-decenoyl-CoA is much larger than the Vmax/Km for its dehydrogenation. The extraordinarily high efficiencies of these two multifunctional proteins in catalyzing the degradation of 2-trans,4-trans-decadienoyl-CoA is best explained by the direct transfer of the 3-hydroxy-4-trans-decenoyl-CoA intermediate from the active site of enoyl-CoA hydratase to that of 3-hydroxyacyl-CoA dehydrogenase. The discovery of an intermediate channeling mechanism on the peroxisomal bifunctional enzyme explains on the molecular level why the peroxisomal beta-oxidation system is well suited for the degradation of trans-fatty acids.     

Reaction mechanism of the Co2+-activated multifunctional bromoperoxidase-esterase from Pseudomonas putida IF-3.

The reaction mechanism of the Co2+-activated bromoperoxidase-esterase of Pseudomonas putida IF-3 was studied. Site-directed mutagenesis suggested that the serine residue of the catalytic triad conserved in serine hydrolases participates in the bromination and ester hydrolysis reactions. The enzyme released a trace amount of free peracetic acid depending on the concentration of H2O2, which had been considered the intermediate in the reaction of nonmetal haloperoxidases to oxidize halide ions to hypohalous acid. However, the formation of free peracetic acid could not explain the enzyme activation effect by Co2+ ions which completely depleted the free peracetic acid. In addition, the kcat value of the enzymatic bromination was 900-fold higher than the rate constant of free peracetic acid-mediated bromination. Those results strongly suggested that the peracetic acid-like intermediate formed at the catalytic site is the true intermediate and that the formation of free peracetic acid is only a minor reaction involving the enzyme. We propose the possible reaction mechanism of this multifunctional enzyme based on these findings.     

A catalytic mechanism for benzylamine oxidase from pig plasma. Stopped-flow kinetic studies

1. Ammonium ion is shown to decrease the rate constants for Schiff's base formation and formation of a reduced intermediate during the catalytic cycle of benzylamine oxidase from pig plasma. The rat constant for reoxidation of the reduced intermediate is also inhibited whilst the rate constant for conversion of the oxidised enzyme form back to native enzyme is stimulated by ammonium ion. 2. Ammonium ion changes the electron paramagnetic resonance spectrum of the cupric centres in the enzyme, indicating that ammonia binds to the copper. 3. A catalytic mechanism for benzylamine oxidase is proposed on the basis of these and other results. This mechanism includes a novel step in which a hydroxyl coordinated to copper acts as a nucleophyle to facilitate hydride ion transfer to oxygen during the reoxidation process.     

Characterization of the oxidase activity in mammalian catalase

Catalase is a highly conserved heme-containing antioxidant enzyme known for its ability to degrade hydrogen peroxide into water and oxygen. In low concentrations of hydrogen peroxide, the enzyme also exhibits peroxidase activity. We report that mammalian catalase also possesses oxidase activity. This activity, which is detected in purified catalases, cell lysates, and intact cells, requires oxygen and utilizes electron donor substrates in the absence of hydrogen peroxide or any added cofactors. Using purified bovine catalase and 10-acetyl-3,7-dihydroxyphenoxazine as the substrate, the oxidase activity was found to be temperature-dependent and displays a pH optimum of 7-9. The Km for the substrate is 2.4 x 10(-4) m, and Vmax is 4.7 x 10(-5) m/s. Endogenous substrates, including the tryptophan precursor indole, the neurotransmitter precursor beta-phenylethylamine, and a variety of peroxidase and laccase substrates, as well as carcinogenic benzidines, were found to be oxidized by catalase or to inhibit this activity. Several dietary plant micronutrients that inhibit carcinogenesis, including indole-3-carbinol, indole-3-carboxaldehyde, ferulic acid, vanillic acid, and epigallocatechin-3-gallate, were effective inhibitors of the activity of catalase oxidase. Difference spectroscopy revealed that catalase oxidase/substrate interactions involve the heme-iron; the resulting spectra show time-dependent decreases in the ferric heme of the enzyme with corresponding increases in the formation of an oxyferryl intermediate, potentially reflecting a compound II-like intermediate. These data suggest a mechanism of oxidase activity involving the formation of an oxygen-bound, substrate-facilitated reductive intermediate. Our results describe a novel function for catalase potentially important in metabolism of endogenous substrates and in the action of carcinogens and chemopreventative agents.     

Kinetic competence of enzymic intermediates: fact or fiction?

A number of enzymatic reactions involve intermediates that are not normally released during the reaction. Whether such an intermediate when added to the enzyme reacts as fast or faster than the normal substrates, and thus is "kinetically competent", depends on the degree to which the equilibrium constant for forming the intermediate from the substrates is different on the enzyme surface and in solution, as well as on the relative affinities of the enzyme for substrate and intermediate. Similar values for these equilibrium constants require that the intermediate react slowly, while a far more favorable value for intermediate formation on the enzyme allows the intermediate to react at up to the diffusion-limiting rate. When one intermediate is formed from two substrates, it may react much more rapidly than when two intermediates are formed from two substrates, or one from one. Comparison of the kinetics of the putative intermediate(s) and the substrate(s) can reveal a great deal about the mechanism of the catalytic reaction and the kinetic barrier that normally keeps the intermediate(s) on the enzyme.     

Promotion of Enzyme Flexibility by Dephosphorylation and Coupling to the Catalytic Mechanism of a Phosphohexomutase

The enzyme phosphomannomutase/phosphoglucomutase (PMM/PGM) from Pseudomonas aeruginosa catalyzes an intramolecular phosphoryl transfer across its phosphosugar substrates, which are precursors in the synthesis of exoproducts involved in bacterial virulence. Previous structural studies of PMM/PGM have established a key role for conformational change in its multistep reaction, which requires a dramatic 180° reorientation of the intermediate within the active site. Here hydrogen-deuterium exchange by mass spectrometry and small angle x-ray scattering were used to probe the conformational flexibility of different forms of PMM/PGM in solution, including its active, phosphorylated state and the unphosphorylated state that occurs transiently during the catalytic cycle. In addition, the effects of ligand binding were assessed through use of a substrate analog. We found that both phosphorylation and binding of ligand produce significant effects on deuterium incorporation. Phosphorylation of the conserved catalytic serine has broad effects on residues in multiple domains and is supported by small angle x-ray scattering data showing that the unphosphorylated enzyme is less compact in solution. The effects of ligand binding are generally manifested near the active site cleft and at a domain interface that is a site of conformational change. These results suggest that dephosphorylation of the enzyme may play two critical functional roles: a direct role in the chemical step of phosphoryl transfer and secondly through propagation of structural flexibility. We propose a model whereby increased enzyme flexibility facilitates the reorientation of the reaction intermediate, coupling changes in structural dynamics with the unique catalytic mechanism of this enzyme.     

Structural analysis and reaction mechanism of the disproportionating enzyme (D‐enzyme) from potato

Starch produced by plants is a stored form of energy and is an important dietary source of calories for humans and domestic animals. Disproportionating enzyme (D‐enzyme) catalyzes intramolecular and intermolecular transglycosylation reactions of α‐1, 4‐glucan. D‐enzyme is essential in starch metabolism in the potato. We present the crystal structures of potato D‐enzyme, including two different types of complex structures: a primary Michaelis complex (substrate binding mode) for 26‐meric cycloamylose (CA26) and a covalent intermediate for acarbose. Our study revealed that the acarbose and CA26 reactions catalyzed by potato D‐enzyme involve the formation of a covalent intermediate with the donor substrate. HPAEC of reaction substrates and products revealed the activity of the potato D‐enzyme on acarbose and CA26 as donor substrates. The structural and chromatography analyses provide insight into the mechanism of the coupling reaction of CA and glucose catalyzed by the potato D‐enzyme. The enzymatic reaction mechanism does not involve residual hydrolysis. This could be particularly useful in preventing unnecessary starch degradation leading to reduced crop productivity. Optimization of this mechanism would be important for improvements of starch storage and productivity in crops.     

Conversion of the aminocrotonate intermediate limits the rate of gamma-elimination reaction catalyzed by L-cystathionine gamma-lyase of the yeast Saccharomyces cerevisiae

L-Cystathionine gamma-lyase [EC 4.4.1.1] of Saccharomyces cerevisiae was shown to bind cofactor pyridoxal 5'-phosphate, up to 2 molecules/subunit. The association constants of the enzyme for the cofactor were estimated to be 3.67 x 10(5) M(-1) and 9.05 x 10(3) M(-1). However, the latter value was too small for the binding to play a catalytic role. Changes in the absorption spectra of the enzyme in gamma-elimination reaction mixtures with various amino acids as substrates were observed at 10 degrees C to elucidate the reaction mechanism of the enzyme. The enzyme formed a chromophore exhibiting absorption at approximately 480 nm, which is characteristic of an aminocrotonate intermediate with O-succinyl-L-homoserine, L-cystathionine, L-homoserine, or O-acetyl-L-homoserine, at rates in this order. The intermediate was consumed at much lower rates than those of formation. The order of the rates of consumption was the same as the order of the formation rates and the order of the gamma-elimination activity of the enzyme with the above-mentioned substrates. These results strongly suggested that the intermediate was essential for gamma-elimination and that the reaction was rate-limited by its conversion into the product alpha-ketobutyrate. L-Cysteine sensitively inhibited the alpha, gamma-elimination activity of the enzyme, and also retarded the formation of the chromophore when it was provided to the enzyme together with a substrate. The reason for these phenomena is discussed.     

Regulation of mitochondrial and cytosolic malic enzymes from cultured rat brain astrocytes

Malate has a number of key roles in the brain, including its function as a tricarboxylic acid (TCA) cycle intermediate, and as a participant in the malate-aspartate shuttle. In addition, malate is converted to pyruvate and CO₂ via malic enzyme and may participate in metabolic trafficking between astrocytes and neurons. We have previously demonstrated that malate is metabolized in at least two compartments of TCA cycle activity in astrocytes. Since malic enzyme contributes to the overall regulation of malate metabolism, we determined the activity and kinetics of the mitochondrial and cytosolic forms of this enzyme from cultured astrocytes. Malic enzyme activity measured at 37°C in the presence of 0.5 mM malate was 4.15±0.47 and 11.61±0.98 nmol/min/mg protein, in mitochondria and cytosol, respectively (mean±SEM, n=18–19). Malic enzyme activity was also measured in the presence of several endogenous compounds, which have been shown to alter intracellular malate metabolism in astrocytes, to determine if these compounds affected malic enzyme activity. Lactate inhibited cytosolic malic enzyme by a noncompetitive mechanism, but had no effect on the mitochondrial enzyme. -Ketoglutarate inhibited both cytosolic and mitochondrial malic enzymes by a partial noncompetitive mechanism. Citrate inhibited cytosolic malic enzyme competitively and inhibited mitochondrial malic enzyme noncompetitively at low concentrations of malate, but competitively at high concentrations of malate. Both glutamate and aspartate decreased the activity of mitochondrial malic enzyme, but also increased the affinity of the enzyme for malate. The results demonstrate that mitochondrial and cytosolic malic enzymes have different kinetic parameters and are regulated differently by endogenous compounds previously shown to alter malate metabolism in astrocytes. We propose that malic enzyme in brain has an important role in the complete oxidation of anaplerotic compounds for energy.These data were presented in part at the meeting of the American Society for Neurochemistry in Richmond, Virginia, March 1993     

Covalent heterogeneity of the human enzyme galactose-1-phosphate uridylyltransferase

Galactose-1-phosphate uridylyltransferase (GALT) acts by a double displacement mechanism, catalyzing the second step in the Leloir pathway of galactose metabolism. Impairment of this enzyme results in the potentially lethal disorder, galactosemia. Although the microheterogeneity of native human GALT has long been recognized, the biochemical basis for this heterogeneity has remained obscure. We have explored the possibility of covalent GALT heterogeneity using denaturing two-dimensional gel electrophoresis and Western blot analysis to fractionate and visualize hemolysate hGALT, as well as the human enzyme expressed in yeast. In both contexts, two predominant GALT species were observed. To define the contribution of uridylylated enzyme intermediate to the two-spot pattern, we exploited the null allele, H186G-hGALT. The Escherichia coli counterpart of this mutant protein (H166G-eGALT) has previously been demonstrated to fold properly, although it cannot form covalent intermediate. Analysis of the H186G-hGALT protein demonstrated a single predominant species, implicating covalent intermediate as the basis for the second spot in the wild-type pattern. In contrast, three naturally occurring mutations, N314D, Q188R, and S135L-hGALT, all demonstrated the two-spot pattern. Together, these data suggest that uridylylated hGALT comprises a significant fraction of the total GALT enzyme pool in normal human cells and that three of the most common patient mutations do not disrupt this distribution.     

Mechanism of action of adenosylcobalamin: hydrogen transfer in the inactivation of diol dehydratase by glycerol

We have investigated the kinetic characteristics of the inactivation of the adenosylcobalamin-dependent enzyme propanediol dehydratase by glycerol, (RS)-1,1-dideuterioglycerol, (R)-1,1-dideuterioglycerol, and perdeuterioglycerol in the presence of 1,2-propanediol and 1,1-dideuterio-1,2-propanediol. The results imply that hydrogen (or deuterium) attached to C-1 of 1,2-propanediol participates in the inactivation process and contributes to the expression of a kinetic isotope effect on the rate of inactivation. The mechanism for this inactivation must involve the cofactor as an intermediate hydrogen carrier, presumably in the form of 5'-deoxyadenosine. Moreover, a mechanism involving a rate-determining transfer of hydrogen from an intermediate containing three equivalent hydrogens quantitatively accounts for all of the results. When diol dehydratase holoenzyme is inactivated by [1-3H]glycerol, 5'-deoxyadenosine which is enriched in tritium by a factor of 2.1 over that in glycerol can be isolated from the reaction mixture.     

Permeable membrane/mass spectrometric measurement of solvent 1H/2H, 12C/13C, and 16O/18O kinetic isotope effects associated with alpha-chymotrypsin deacylation: evidence for reaction mechanism plasticity

We have measured, by permeable membrane/mass spectrometry, the 16O/18O, 12C/13C, and solvent H2O/D2O kinetic isotope effects (kie) associated with acyl-alpha-chymotrypsin hydrolysis and transesterification. The hydrolysis of alpha-chymotrypsinyl 2-furoate has a 12C/13C kie of approximately 1.06. Transesterification of the same acyl enzyme shows 16O/18O, 12C/13C, and solvent H2O/D2O kinetic isotope effects of 1.015 (0.003), 1.01-1.02, and 2.226 (0.007), respectively. From the temperature independence of the 16O/18O transesterification kinetic isotope effect and kinetic data reported elsewhere [Wang, C.-L. A., Calvo, K. C., & Klapper, M. H. (1981) Biochemistry 20, 1401-1408], we conclude that there are two active forms of acylchymotrypsin. We also propose that formation of the tetrahedral intermediate is the rate-limiting step in both hydrolysis and transesterification and that the position of the transition state in the transesterification is closer to the starting enzyme ester while that for the hydrolytic reaction is closer to the tetrahedral intermediate. These results are discussed in terms of reaction mechanism plasticity.     

Site-directed mutagenesis studies on the recombinant thioesterase domain of chicken fatty acid synthase expressed in Escherichia coli

The animal fatty acid synthase is a multifunctional protein with a subunit molecular weight of 260,000. We recently reported the expression and characterization of the acyl carrier protein and thioesterase domains of the chicken liver fatty acid synthase in Escherichia coli. In order to gain insight into the mechanism of action of the thioesterase domain, we have replaced the putative active site serine 101 with alanine and cysteine and the conserved histidine 274 with alanine by site-directed mutagenesis. While both the Ser101----Ala and His274----Ala mutant proteins were inactive, the Ser101----Cys mutant enzyme (thiol-thioesterase) retained considerable activity, but the properties of the enzyme were changed from an active serine esterase to an active cysteine esterase, providing strong evidence for the role of Ser101 as the active site nucleophile. In order to further probe into the role of His274, a double mutant was constructed containing both the Ser101----Cys and the His274----Ala mutations. The double-mutant protein was inactive and exhibited diminished reactivity of the Cys-SH to iodoacetamide as compared to that of the Ser101----Cys-thioesterase, suggesting a role of His274 as a general base in withdrawing the proton from the Cys-SH in the thiol-thioesterase or Ser101 in the wild-type enzyme. Incubation of the recombinant thioesterases with [1-14C] palmitoyl-CoA resulted in the incorporation of [1-14C] palmitoyl into the enzyme only in the double mutant, suggesting that Cys-SH of the double mutant is reactive enough to form the palmitoyl-S-enzyme intermediate. This intermediate is not hydrolyzed because of the lack of His274, which is required for the attack of H2O on the acyl enzyme. These results suggest that the catalytic mechanism of the thioesterases may be similar to that of the serine proteases and lipases, which employ a serine-histidine-aspartic acid catalytic triad as part of their catalytic mechanism.