2-Chloro-2-phenylethylamine as a mechanistic probe and active site-directed inhibitor of monoamine oxidase from bovine liver mitochondria

The reaction of 2-chloro-2-phenylethylamine with monoamine oxidase B was investigated to study the mechanism of this enzyme and its inactivation by this compound. 2-Chloro-2-phenylethylamine is a substrate with a Km of 30 microM and a turnover number of 80 min-1 at pH 6.5 at 30 degrees C. Incubation of 2-chloro-2-phenylethylamine with the enzyme led to the normal oxidation product, 2-chloro-2-phenylacetaldehyde, but only traces (0.25 mol%) of 2-phenylacetaldehyde, the product anticipated if the oxidation of substrate involved a stabilized carbanion at C-1 and elimination of chloride ion. These data suggest that a carbanion is not a likely intermediate in the oxidation of amines by monoamine oxidase. During the mechanistic studies we noted time-dependent inactivation of monoamine oxidase B by 2-chloro-2-phenylethylamine under both aerobic and anaerobic conditions. Inactivation was not reversible. Aerobically 2-chloro-2-phenylethylamine is oxidized to 2-chloro-2-phenylacetaldehyde which covalently modifies the enzyme (tau 1/2 = 40 min). Benzyl alcohol, a substrate analog, gives substantial protection against inactivation under aerobic conditions (tau 1/2 = 320 min), suggesting that an active site residue is modified. Anaerobic reaction of 2-chloro-2-phenylethylamine with monoamine oxidase B probably proceeds by direct alkylation of an enzyme residue (tau 1/2 = 140 min). Reduction with [3H]NaBH4 of the inactivated enzyme gave from 0 to 0.7 and from 4.5 to 5.6 mol of hydride incorporation for enzyme inactivated anaerobically and aerobically, respectively. The latter results are in agreement with inactivation by unmodified inhibitor and inactivation by oxidized inhibitor for the anaerobic and aerobic reactions, respectively. It is suggested that 2-chloro-2-phenylethylamine or its oxidation product 2-chloro-2-phenylacetaldehyde may serve as an active site affinity reagent for monoamine oxidase.     

Lysozyme inactivation and aggregation in stirred-reactor

Mechanisms of enzyme inactivation and aggregation are still poorly understood. In this work, we are considering the characterisation of both inactivation and aggregation in stirred tank reactor, with lysozyme as the model enzyme.

The inactivation kinetics are first order. For stirring speeds in the range of 0–700 rpm, the kinetic constant is found to be proportional to the power brought by the impeller. It suggests that inactivation depends on collisions between enzyme molecules. Efficient collisions between native and inactive molecules induce native molecules to turn into inactive molecules and lead to lysozyme aggregation.

During inactivation, enzymes are found to aggregate as shown by light scattering measurements. The structure of aggregates was studied on samples treated for chemical denaturation and reduction. The aggregates are supramolecular edifices, mainly made up of inactivated enzymes linked by weak forces. But aggregates are also made up of dimers and trimers of lysozyme, linked by disulfide bridges. Dimers and trimers are 18% and 5%, respectively, of the total amount of lysozyme aggregates.

Whatever the stage of aggregate formation and the initial enzyme concentration are, these aggregates are irreversibly inactivated. Enzyme activity is definitely lost even if stirring is stopped and/or temperature decreased.

This study points out the importance of hydrodynamics in bioreactors and highlights the nature of the aggregates resulting from the interactions between native and inactive enzymes.     

Kinetic modeling of cellulose hydrolysis with first order inactivation of adsorbed cellulase

Enzymatic hydrolysis involves complex interaction between enzyme, substrate, and the reaction environment, and the complete mechanism is still unknown. Further, glucose release slows significantly as the reaction proceeds. A model based on Langmuir binding kinetics that incorporates inactivation of adsorbed cellulase was developed that predicts product formation within 10% of experimental results for two substrates. A key premise of the model, with experimental validation, suggests that V(max) decreases as a function of time due to loss of total available enzyme as adsorbed cellulases become inactivated. Rate constants for product formation and enzyme inactivation were comparable to values reported elsewhere. A value of k(2)/K(m) that is several orders of magnitude lower than the rate constant for the diffusion-controlled encounter of enzyme and substrate, along with similar parameter values between substrates, implies a common but undefined rate-limiting step associated with loss of enzyme activity likely exists in the pathway of cellulose hydrolysis.     

Inactivation of o-diphenoloxidase in the pyrocatechol oxidation reaction

The inactivation kinetics of o-diphenoloxidase isolated from potato tubers was studied in the process of pyrocatechol oxidation. The enzyme when saturated with the substrate is inactivated with the inactivation rate constant kin = 0.5-1.0 min-1; kin depends on the initial concentration of pyrocatechol. The ultimate yield of the enzymic reaction product increases linearly with the initial concentration of the enzyme. Introduction of ethylene-diaminosulphate, a substance which condenses with o-quinones, does not increase the operation stability of o-diphenoloxidase. The data obtained evidence for inactivation of o-diphenoloxidase either at the level of the enzyme-substrate complex or due to bimolecular reaction with the substrate.     

Inhibition of the broad spectrum nonmetallocarbapenamase of class A (NMC-A) beta-lactamase from Enterobacter cloacae by monocyclic beta-lactams.

beta-Lactamases hydrolyze beta-lactam antibiotics, a reaction that destroys their antibacterial activity. These enzymes, of which four classes are known, are the primary cause of resistance to beta-lactam antibiotics. The class A beta-lactamases form the largest group. A novel class A beta-lactamase, named the nonmetallocarbapenamase of class A (NMC-A) beta-lactamase, has been discovered recently that has a broad substrate profile that included carbapenem antibiotics. This is a serious development, since carbapenems have been relatively immune to the action of these resistance enzymes. Inhibitors for this enzyme are sought. We describe herein that a type of monobactam molecule of our design inactivates the NMC-A beta-lactamase rapidly, efficiently, and irreversibly. The mechanism of inactivation was investigated by solving the x-ray structure of the inhibited NMC-A enzyme to 1.95 A resolution. The structure shed light on the nature of the fragmentation of the inhibitor on enzyme acylation and indicated that there are two acyl-enzyme species that account for enzyme inhibition. Each of these inhibited enzyme species is trapped in a distinct local energy minimum that does not predispose the inhibitor species for deacylation, accounting for the irreversible mode of enzyme inhibition. Molecular dynamics simulations provided evidence in favor of a dynamic motion for the acyl-enzyme species, which samples a considerable conformational space prior to the entrapment of the two stable acyl-enzyme species in the local energy minima. A discussion of the likelihood of such dynamic motion for turnover of substrates during the normal catalytic processes of the enzyme is presented.     

Enzyme deactivation

Enzyme deactivation kinetics is often first-order. Different examples of first-order deactivation kinetics exhibited by different enzymes under a wide variety of conditions are presented. Examples of both soluble and immobilized enzymes are presented. The influence of different parameters, chemical modification of specific residues, inhibitors, inactivators, protecting agents, induced conformational changes by external agents, enzyme concentration, and different substrates on the first-order inactivation kinetics of different enzymes is analyzed. The different examples presented from a variety of different areas provides a judicious framework and collection demonstrating the wide applicability of first-order deactivation kinetics. Examples of reversible first-order deactivation kinetics and deactivation-disguise kinetics are also presented.Different mechanisms are also presented to model complex enzyme deactivations. The non-series type mechanisms are emphasized and these involve the substrate and chemical modifiers. Substrate-dependent deactivation rate expressions that are of "separable" and "non-separable" type are presented. Rate expressions involving time-dependent rate constants along with their corresponding mechanisms are presented. Examples of enzymes that exhibit a deactivation-free grace period are also given. An interesting case of enzyme inactivation is the loss of activity in the presence of an auto-decaying reagent. The method is presented by which the intrinsic inactivation rate constants may be obtained. Examples of pH-dependent enzyme inactivation are presented that may be modelled by a five-step (or a simplified two-step) mechanism, and also by a single-step mechanism involving residual activity for the final state. Appropriate examples of enzyme inactivation are presented in each case to highlight the different mechanisms involved.     

Irreversible inactivation of pyruvate decarboxylase in the presence of substrate and an oxidant. An example of paracatalytic enzyme inactivation.

Pyruvate decarboxylase from yeast is progressively inactivated in the presence of pyruvate and an extrinsic oxidant such as 2,6-dichloroindophenol or hexacyanoferrate(III). The inactivation is linked to the oxidation of the hydroxyethylthiamine diphosphate intermediate to acetate. Removal of low-molecular compounds by gel filtration does not reactivate the enzyme. The rate of inactivation obeys saturation kinetics with respect to substrate concentration and is independent of enzyme concentration. In analogy to the paracatalytic inactivation of other enzymes forming oxidizable carbanion intermediates [Christen, P. (1977) Methods Enzymol.46, 48--54], the oxidation of enzyme-bound hydroxyethylthiamine diphosphate is thought to generate a transiently reactive intermediate which, without being released from the enzyme, covalently modifies a group at or near the active site. Reconstitution experiments indicate that the protein rather than the coenzyme moiety is modified.     

The effect of mixed-function oxidation of enzymes on their susceptibility to degradation by a nonlysosomal cysteine proteinase

Mixed-function oxidation of Escherichia coli glutamine synthetase by ascorbate, oxygen, and iron has previously been shown to cause inactivation of the enzyme and enhanced susceptibility to proteolytic attack by a variety of proteases. One of these proteases, from rat liver, is a high molecular weight cysteine proteinase which does not degrade native glutamine synthetase at neutral pH. Although inactive, the oxidized glutamine synthetase preparations used in this study were only partially degraded by this proteinase. Some of the subunits were degraded to acid soluble products with no detectable intermediates; the remaining subunits had not become susceptible to proteolytic attack during the limited exposure to the ascorbate mixed-function oxidation system. Several mammalian enzymes which are known to be inactivated by mixed-function oxidation were tested as substrates for the proteinase. Native rabbit muscle enolase and pyruvate kinase were resistant to degradation, but their oxidatively inactivated forms were degraded. Oxidized phosphoglycerate kinase and creatine kinase were also preferentially degraded. Moreover, trypsin degraded oxidized preparations of all of these enzymes faster than control preparations. Oxidative inactivation of superoxide dismutase by hydrogen peroxide caused a slight increase in susceptibility to proteolytic attack, but the enzyme was still relatively resistant to degradation both by the cysteine proteinase and by trypsin. Although oxidation conditions may not have been optimal for demonstrating enhanced proteolytic susceptibility, the results do indicate that mixed-function oxidation can render some mammalian enzymes, as well as bacterial glutamine synthetase, susceptible to degradation. Mixed-function oxidation of these proteins may be a mechanism of marking them for intracellular turnover.     

Mechanism of inhibition of dopamine beta-monooxygenase by quinol and phenol derivatives, as determined by solvent and substrate deuterium isotope effects.

The mechanism of interaction of quinols and phenols with dopamine beta-monooxygenase (D beta M) has been investigated. The ratio of quinone formation (from catechol) to oxygen consumption rises from a value of 1 in the presence of phenethylamine substrate to 2 in the absence of substrate. These results implicate quinol oxidation at both the reductant- and substrate-binding sites of D beta M. In the presence of saturating ascorbate, catechol and p-hydroquinol behave as mechanism-based inhibitors of D beta M, with partitioning ratios of turnover to inactivation of 21:1 and 41:1, respectively. Phenol is found to inactivate the enzyme in a manner similar to p-cresol, suggesting that the methyl group of p-cresol is not an essential component of enzyme inhibition. Solvent isotope effects on inactivation and turnover have been measured for various inactivators. Although the majority of these inhibitors, including catechol, p-hydroquinol, aniline, phenethylenediamine, and benzylhydrazine, are characterized by relatively small solvent isotope effects (1.5-2.5) on the inactivation rate constant (ki), solvent isotope effects on ki for phenol and p-cresol are 5.7 and 7.4, respectively. By contrast, solvent isotope effects on the turnover of p-cresol are almost unity. Using p-cresol-d7 as substrate, we observe D(kcat) = 5.2 and D(kcat/Km) = 3.1, while isotope effects on inactivation are D(ki) = 0.95 and D(ki/Ki) = 0.59. These results lead us to propose that inhibitors fall into two mechanistic classes, involving either one-electron oxidation to form radical cation intermediates (quinols) or hydrogen atom abstraction (phenols).(ABSTRACT TRUNCATED AT 250 WORDS)     

Burst kinetics and redox transformations of the active site manganese ion in oxalate oxidase: implications for the catalytic mechanism

Oxalate oxidase (EC 1.2.3.4) catalyzes the oxidative cleavage of oxalate to carbon dioxide and hydrogen peroxide. In this study, unusual nonstoichiometric burst kinetics of the steady state reaction were observed and analyzed in detail, revealing that a reversible inactivation process occurs during turnover, associated with a slow isomerization of the substrate complex. We have investigated the underlying molecular mechanism of this kinetic behavior by preparing recombinant barley oxalate oxidase in three distinct oxidation states (Mn(II), Mn(III), and Mn(IV)) and producing a nonglycosylated variant for detailed biochemical and spectroscopic characterization. Surprisingly, the fully reduced Mn(II) form, which represents the majority of the as-isolated native enzyme, lacks oxalate oxidase activity, but the activity is restored by oxidation of the metal center to either Mn(III) or Mn(IV) forms. All three oxidation states appear to interconvert under turnover conditions, and the steady state activity of the enzyme is determined by a balance between activation and inactivation processes. In O(2)-saturated buffer, a turnover-based redox modification of the enzyme forms a novel superoxidized mononuclear Mn(IV) biological complex. An oxalate activation role for the catalytic metal ion is proposed based on these results.     

Origin of initial burst in activity for Trichoderma reesei endo-glucanases hydrolyzing insoluble cellulose

The kinetics of cellulose hydrolysis have long been described by an initial fast hydrolysis rate, tapering rapidly off, leading to a process that takes days rather than hours to complete. This behavior has been mainly attributed to the action of cellobiohydrolases and often linked to the processive mechanism of this exo-acting group of enzymes. The initial kinetics of endo-glucanases (EGs) is far less investigated, partly due to a limited availability of quantitative assay technologies. We have used isothermal calorimetry to monitor the early time course of the hydrolysis of insoluble cellulose by the three main EGs from Trichoderma reesei (Tr): TrCel7B (formerly EG I), TrCel5A (EG II), and TrCel12A (EG III). These endo-glucanases show a distinctive initial burst with a maximal rate that is about 5-fold higher than the rate after 5 min of hydrolysis. The burst is particularly conspicuous for TrCel7B, which reaches a maximal turnover of about 20 s(-1) at 30 °C and conducts about 1200 catalytic cycles per enzyme molecule in the initial fast phase. For TrCel5A and TrCel12A the extent of the burst is 2-300 cycles per enzyme molecule. The availability of continuous data on EG activity allows an analysis of the mechanisms underlying the initial kinetics, and it is suggested that the slowdown is linked to transient inactivation of enzyme on the cellulose surface. We propose, therefore, that the frequency of structures on the substrate surface that cause transient inactivation determine the extent of the burst phase.     

Catalytic Properties of the 3-Chlorocatechol-Oxidizing 2,3-Dihydroxybiphenyl 1,2-Dioxygenase from Sphingomonas sp. Strain BN6

The 2,3-dihydroxybiphenyl dioxygenase from Sphingomonas sp. strain BN6 (BphC1-BN6) differs from most other extradiol dioxygenases by its ability to oxidize 3-chlorocatechol to 3-chloro-2-hydroxymuconic semialdehyde by a distal cleavage mechanism. The turnover of different substrates and the effects of various inhibitors on BphC1-BN6 were compared with those of another 2,3-dihydroxybiphenyl dioxygenase from the same strain (BphC2-BN6) as well as with those of the archetypical catechol 2,3-dioxygenase (C23O-mt2) encoded by the TOL plasmid. Cell extracts containing C23O-mt2 or BphC2-BN6 converted the relevant substrates with an almost constant rate for at least 10 min, whereas BphC1-BN6 was inactivated significantly within the first minutes during the turnover of all substrates tested. Furthermore, BphC1-BN6 was much more sensitive than the other two enzymes to inactivation by the Fe(II) ion-chelating compound o-phenanthroline. The reason for inactivation of BphC1-BN6 appeared to be the loss of the weakly bound ferrous ion, which is the cofactor in the catalytic center. A mutant enzyme of BphC1-BN6 constructed by site-directed mutagenesis showed a higher stability to inactivation by o-phenanthroline and an increased catalytic efficiency for the conversion of 2,3-dihydroxybiphenyl and 3-methylcatechol but was still inactivated during substrate oxidation.     

Essential residues in lysolecithin:lysolecithin acyltransferase from rabbit lung: assessment by chemical modification

The inhibition of lysolecithin:lysolecithin acyltransferase by several specific reagents was studied. Diisopropyl fluorophosphate (DFP) completely inhibited both activities at a concentration of 4 mM. Activity was not protected by substrate and the enzyme showed a change in circular dichroism spectrum upon treatment with inhibitor. Phenylmethanesulfonyl fluoride, another serine-specific reagent, did not inhibit either hydrolysis or transacylation. Therefore, we suggest that DFP does not modify an active serine in the catalytic site. p-Hydroxymercury benzoate and N-ethylmaleimide (NEM) abolished both activities of the enzyme. The presence of substrate partially protected against inactivation. Far-uv CD spectrum of NEM-modified enzyme revealed no changes in protein structure. The existence of two classes of essential cysteine residues was deduced from kinetics of NEM inactivation. Both classes differ in NEM reactivity and also in their participation in the catalytic mechanism. A tyrosine-specific reagent, tetranitromethane, also inhibited hydrolysis and transacylation, following first-order kinetics. The partial protection by substrate suggested the possible existence of essential tyrosines near the active site. At pH 5.0 N-ethoxycarbonyl-2-ethoxy-1,2-dihydroquinoline inactivated hydrolysis but not transacylation. However, both of them remained unchanged at pH 6.5. The substrate prevented the loss of hydrolytic ability. Therefore, a carboxyl residue participating just in the catalytic mechanism of hydrolysis is proposed.     

Biotinylation, a post-translational modification controlled by the rate of protein-protein association

Biotin protein ligases catalyze specific covalent linkage of the coenzyme biotin to biotin-dependent carboxylases. The reaction proceeds in two steps, including synthesis of an adenylated intermediate followed by biotin transfer to the carboxylase substrate. In this work specificity in the transfer reaction was investigated using single turnover stopped-flow and quench-flow assays. Cognate and noncognate reactions were measured using the enzymes and minimal biotin acceptor substrates from Escherichia coli, Pyrococcus horikoshii, and Homo sapiens. The kinetic analysis demonstrates that for all enzyme-substrate pairs the bimolecular rate of association of enzyme with substrate limits post-translational biotinylation. In addition, in noncognate reactions the three enzymes displayed a range of selectivities. These results highlight the importance of protein-protein binding kinetics for specific biotin addition to carboxylases and provide one mechanism for determining biotin distribution in metabolism.     

Inactivation of bacterial D-amino acid transaminases by the olefinic amino acid D-vinylglycine.

D-Vinylglycine (2-amino-3-butenoate) functions as a transamination substrate and irreversible inactivator of the homogeneous pyridoxal phosphate-dependent D-amino acid transaminases from Bacillus subtilis and Bacillus sphaericus. In the absence of alpha-ketoglutarate as co-substrate, vinyl-glycine causes little if any inactivation of either enzyme; in the presence of excess alpha-ketoglutarate, both enzymes are inactivated with pseudo-first order kinetics. The limiting rate constant for inactivation of the B. sphaericus enzyme is 1.9 min-1, for the B. subilis enzyme it is 0.36 min-1. The number of catalytic events before inactivation is about 450 for the B. sphaericus enzyme and about 800 for the B. subtilis enzyme; that is, about 0.2% inactivation in each catalytic cycle for the former enzyme and 0.15% for the latter. Comparisons are made with the L-aspartate amino-transferase from pig heart which is inactivated completely in one catalytic cycle and the L-alanine aminotransferase which is not inactivated in many cycles. Comparisons are also made between the likely mode of D-transaminase inactivation produced by vinylglycine and the mode of inactivation induced by beta-chloro-D-alanine.     

Understanding the Broad Substrate Repertoire of Nitroreductase Based on Its Kinetic Mechanism

The oxygen-insensitive nitroreductase from Enterobacter cloacae (NR) catalyzes two-electron reduction of nitroaromatics to the corresponding nitroso compounds and, subsequently, to hydroxylamine products. NR has an unusually broad substrate repertoire, which may be related to protein dynamics (flexibility) and/or a simple non-selective kinetic mechanism. To investigate the possible role of mechanism in the broad substrate repertoire of NR, the kinetics of oxidation of NR by para-nitrobenzoic acid (p-NBA) were investigated using stopped-flow techniques at 4 °C. The results revealed a hyperbolic dependence on the p-NBA concentration with a limiting rate of 1.90 ± 0.09 s⁻¹, indicating one-step binding before the flavin oxidation step. There is no evidence for a distinct binding step in which specificity might be enforced. The reduction of p-NBA is rate-limiting in steady-state turnover (1.7 ± 0.3 s⁻¹). The pre-steady-state reduction kinetics of NR by NADH indicate that NADH reduces the enzyme with a rate constant of 700 ± 20 s⁻¹ and a dissociation constant of 0.51 ± 0.04 mm. Thus, we demonstrate simple transient kinetics in both the reductive and oxidative half-reactions that help to explain the broad substrate repertoire of NR. Finally, we tested the ability of NR to reduce para-hydroxylaminobenzoic acid, demonstrating that the corresponding amine does not accumulate to significant levels even under anaerobic conditions. Thus E. cloacae NR is not a good candidate for enzymatic production of aromatic amines.     

A cysteine residue (cysteine-116) in the histidinol binding site of histidinol dehydrogenase

Salmonella typhimurium L-histidinol dehydrogenase (EC 1.1.1.23), a four-electron dehydrogenase, was inactivated by an active-site-directed modification reagent, 7-chloro-4-nitro-2,1,3-benzoxadiazole (NBD-Cl). The inactivation followed pseudo-first-order kinetics and was prevented by low concentrations of the substrate L-histidinol or by the competitive inhibitors histamine and imidazole. The observed rate saturation kinetics for inactivation suggest that NBD-Cl binds to the enzyme noncovalently before covalent inactivation occurs. The UV spectrum of the inactivated enzyme showed a peak at 420 nm, indicative of sulfhydryl modification. Stoichiometry experiments indicated that full inactivation was correlated with modification of 1.5 sulfhydryl groups per subunit of enzyme. By use of a substrate protection scheme, it was shown that 0.5 sulfhydryl per enzyme subunit was neither protected against NBD-Cl modification by L-histidinol nor essential for activity. Modification of the additional 1.0 sulfhydryl caused complete loss of enzyme activity and was prevented by L-histidinol. Pepsin digestion of NBD-modified enzyme was used to prepare labeled peptides under conditions that prevented migration of the NBD group. HPLC purification of the peptides was monitored at 420 nm, which is highly selective for NBD-labeled cysteine residues. By amino acid sequencing of the major peptides, it was shown that the reagent modified primarily Cys-116 and Cys-377 and that the presence of L-histidinol gave significant protection of Cys-116. The presence of a cysteine residue in the histidinol binding site is consistent with models in which formation and subsequent oxidation of a thiohemiacetal occurs as an intermediate step in the overall reaction.     

Kinetics of inactivation of green crab (Scylla Serrata) alkaline phosphatase during removal of zinc ions by ethylenediaminetetraacetic acid disodium

Green crab (Scylla Serrata) alkaline phosphatase (EC 3.1.3.1.) is a metalloenzyme, the each active site in which contains a tight cluster of two zinc ions and one magnesium ion. The kinetic theory of the substrate reaction during irreversible inhibition of enzyme activity previously described by Tsou has been applied to a study on the kinetics of the course of inactivation of the enzyme by ethylenediaminetetraacetic acid disodium (EDTA). The kinetics of the substrate reaction with different concentrations of the substrate p-nitrophenyl phosphate (PNPP) and inactivator EDTA suggested a complexing mechanism for inactivation by, and substrate competition with, EDTA at the active site. The inactivation kinetics are single phasic, showing the initial formation of an enzyme-EDTA complex is a relatively rapid reaction, followed a slow inactivation step that probably involves a conformational change of the enzyme. Zinc ions are finally removed from the enzyme. The presence of metal ions apparently stabilizes an active-site conformation required for enzyme activity.     

Stereospecific alkylation of cis-3-chloroacrylic acid dehalogenase by (R)-oxirane-2-carboxylate: analysis and mechanistic implications

The enzymes trans-3-chloroacrylic acid dehalogenase (CaaD) and cis-3-chloroacrylic acid dehalogenase (cis-CaaD) represent the two major classes of bacterial, isomer-selective 3-chloroacrylic acid dehalogenases. They catalyze the hydrolytic dehalogenation of either trans- or cis-3-haloacrylates to yield malonate semialdehyde, presumably through unstable halohydrin intermediates. In view of a proposed general acid/base mechanism for these enzymes, (R)- and (S)-oxirane-2-carboxylate were investigated as potential irreversible inhibitors. Only cis-CaaD is irreversibly inhibited in a time- and concentration-dependent manner and only by the (R)-enantiomer of oxirane-2-carboxylate. The enzyme displays saturation kinetics and is protected from inactivation by the presence of substrate. These findings indicate that the inactivation process involves the initial formation of a reversibly bound enzyme-inhibitor complex at the active site followed by covalent modification. Mass spectral analysis of the inactivated cis-CaaD shows that Pro-1 is the site of modification. It has also been determined that Arg-70 and Arg-73 are required for covalent modification because incubation of either the R70A or R73A mutant with inhibitor does not result in enzyme alkylation. Studies of the pH dependence of the kinetic parameters of wild-type cis-CaaD reveal that a protonated group with a pK(a) of approximately 9.3 is essential for catalysis. The group is likely Pro-1, making it predominately a charged species under the conditions of the inactivation experiments. Two mechanisms could account for these observations. In one mechanism, the oxirane undergoes acid-catalyzed ring opening followed by alkylation of the conjugate base of Pro-1. Alternatively, the oxirane undergoes a nucleophilic substitution reaction where the conjugate base of Pro-1 functions as the nucleophile and an acid catalyst polarizes the carbon oxygen bond. The two arginine residues likely bind the carboxylate group and position the inhibitor in a favorable orientation for the alkylation reaction. These findings set the stage for a crystallographic analysis of the inactived enzyme to delineate further the roles of active site residues in both the inactivation process and the catalytic mechanism.     

Kinetic studies on the inactivation of L-lactate oxidase by [the acetylenic suicide substrate] 2-hydroxy-3-butynoate.

2-Hydroxy-3-butynoate is both a substrate and an irreversible inactivator of the flavoenzyme L-lactate oxidase. The partitioning between catalytic oxidation of 2-hydroxy-3-butynoate and inactivation of the enzyme is determined by the concentration of the second substrate, O2. Rapid reaction studies show the formation of an intermediate which is common to both the oxidation and inactivation pathways. This intermediate appears to be a charge-transfer complex between enzyme-reduced flavin and 2-keto-3-butynoate. It is characterized by a long-wavelength absorbing band (gamma(max) 600 nm) and lack of fluorescence, making it easily distinguished from the subsequently formed inactivated enzyme, which has no long wavelength absorption (gamma(max) 318, 368 nm) and which is strongly fluorescent. Inactivation is also accomplished by reaction of the reduced enzyme with 2-keto-3-butynoate. The absorbance and fluorescence characteristics of the inactivated enzyme are similar to those of a model compound, C(4a), N(5)-propano-bridged FMN bound to apolactate oxidase. That the modified chromophore of the inactivated enzyme is an adduct involving both the C(4a) and N5 positions is further supported by the spectral and fluorescence changes resulting from treatment of the inactivated enzyme with borohydride.