Kinetics of the reaction between 5,5′-dithiobis[2-nitrobenzoic acid] and the sulphydryl group in Zn-dependent β-lactamase II

The kinetics of the reaction of the thiol residue in Zn²⁺-dependent β-lactamase II with 5,5′-dithiobis[2-nitrobenzoic acid], and the concomitant inactivation revealed that both events take place at the same rate. The inactivation could not be reverted by incubation with Zn²⁺ or by using a substrate concentration about eight times the K_m of the enzyme. EDTA incubation also produced inactivation of the enzyme, although it was reverted by increasing the substrate concentration in the assay. A dual role is proposed for Zn²⁺ in β-lactamase. The kinetic analysis of the thiol modification and the concomitant inactivation is in agreement with previous reports on the implication of the metal ion in catalysis. A role in stabilizing the native structure of the enzyme is also suggested.     

Kinetics of modification of the mitochondrial succinate-ubiquinone reductase by 5,5′-dithiobis-(2-nitro-benzoic acid)

The kinetic theory of the substrate reaction during modification of enzyme activity previously described by Tsou [Tsou (1988),Adv. Enzymol. Relat. Areas Mol. Biol. 61, 381–436] has been applied to a study of the kinetics of the course of inactivation of the mitochondrial succinate-ubiquinone reductase by 5,5′-dithiobis-(2-nitro-benzoic acid) (DTNB). The results show that the inactivation of this enzyme by DTNB is a conformation-change-type inhibition which involves a conformational change of the enzyme before inactivation. The microscopic rate constants were determined for the reaction of the inactivator with the enzyme. The presence of the substrate provides marked protection of this enzyme against inactivation by DTNB. The modification reaction of the enzyme using DTNB was shown to follow a triphasic course by following the absorption at 412 nm. Among these reactive thiol groups, the fast-reaction thiol group is essential for the enzyme activity. The results suggest that the essential thiol group is situated at the succinate-binding site of the mitochondrial succinate-ubiquinone reductase.     

Inactivation of purified phenylalanine hydroxylase by dithiothreitol.

Purified rat liver phenylalanine hydroxylase is inactivated in vitro by ascorbate and thiol compounds, dithiothreitol being the most effective inhibitor, with a second order rate constant for the inactivation of 0.066 +/- 0.002 mM-1.min-1 at 20 degrees C and pH 7.2. Anaerobic conditions and catalase protected the enzyme from inactivation by dithiothreitol. This suggests that hydrogen peroxide, produced by oxidation of the thiol, is involved in the inactivation. The substrate, L-phenylalanine, also partially protected the enzyme from this inactivation. It is shown that incubation of the enzyme with dithiothreitol at aerobic conditions, followed by gel filtration, causes the release of iron from the active site. The inactivation by dithiothreitol was reversed by incubation of the iron-depleted enzyme with Fe(II).     

Inactivation of yeast hexokinase by 2-aminothiophenol. Evidence for a ''half-of-the-sites'' mechanism.

Yeast hexokinase is a homodimer consisting of two identical subunits. Yeast hexokinase was inactivated by 2-aminothiophenol at 25 degrees C (pH 9.1). The reaction followed pseudo-first-order kinetics until about 70% of the phosphotransferase activity was lost. About 0.65 mol of 2-aminothiophenol/mol of hexokinase was found to be bound after the 70% loss of the enzyme activity. Completely inactivated hexokinase showed a stoichiometry of about 1 mol of 2-aminothiophenol bound/mol of the enzyme. The evidence obtained from kinetic experiments, stoichiometry of the inactivation reaction and fluorescence emission measurements suggested site-site interaction (weak negative co-operativity) during the inactivation reaction. The approximate rate constants for the reversible binding of 2-aminothiophenol to the first subunit (KI) and for the rate of covalent bond formation with only one site occupied (k3) were 150 microM and 0.046 min-1 respectively. The inactivation reaction was pH-dependent. Dithiothreitol, 2-mercaptoethanol and cysteine restored the phosphotransferase activity of the hexokinase after inactivation by 2-aminothiophenol. Sugar substrates protected the enzyme from inactivation more than did the nucleotides. Thus it is concluded that the inactivation of the hexokinase by 2-aminothiophenol was a consequence of a covalent disulphide bond formation between the aminothiol and thiol function at or near the active site of the enzyme. Hexokinase that had been completely inactivated by 2-aminothiophenol reacted with o-phthalaldehyde. Fluorescence emission intensity of the incubation mixture containing 2-aminothiophenol-modified hexokinase and o-phthalaldehyde was one-half of that obtained from an incubation mixture containing hexokinase and o-phthalaldehyde under similar experimental conditions. The intensity and position of the fluorescence emission maximum of the 2-aminothiophenol-modified hexokinase were different from those of the native enzyme, indicating conformational change following modification. Whereas aliphatic aminothiols were completely ineffective, aromatic aminothiols were good inhibitors of the hexokinase. Cyclohexyl mercaptan weakly inhibited the enzyme. Inhibition of the hexokinase by heteroaromatic thiols was dependent on the nature of the heterocyclic ring and position of the thiol-thione equilibrium. The inhibitory function of a thiol is associated with the following structural characteristics: (a) the presence of an aromatic ring, (b) the presence of a free thiol function and (c) the presence of a free amino function in the close proximity of the thiol function.(ABSTRACT TRUNCATED AT 400 WORDS)     

Mechanism of action of adenosylcobalamin: glycerol and other substrate analogues as substrates and inactivators for propanediol dehydratase--kinetics, stereospecificity, and mechanism.

A number of vicinal diols were found to react with propanediol dehydratase, typically resulting in the conversion of enzyme-bound adenosylcobalamin to cob(II)alamin and formation of aldehyde or ketone derives from substrate. Moreover, all are capable of effecting the irreversible inactivation of the enzyme. The kinetics and mechanism of product formation and inactivation were investigated. Glycerol, found to be a very good substrate for diol dehydratase as well as a potent inactivator, atypically, did not induce cob(II)alamin formation to any detectable extent. With glycerol, the inactivation process was accompanied by conversion of enzyme-bound adenosylcobalamin to an alkyl or thiol cobalamin, probably by substitution of an amino acid chain near the active site for the 5'-deoxy-5'-adenosyl ligand on the cobalamin. The inactivation reaction with glycerol as the inactivator exhibits a deuterium isotope effect of 14, strongly implicating hydrogen transfer as an important step in the mechanism of inactivation. The isotope effect on the rate of product formation was found to be 8.0. Experiments with isotopically substituted glycerols indicate that diol dehydrase distinguishes between "R" and "S" binding conformations, the enzyme-(R)-glycerol complex being predominately responsible for the product-forming reaction, while the enzyme-(S)-glycerol complex results primarily in the activation reaction. Mechanistic implications are discussed. A method for removing enzyme-bound hydroxycobalamin that is nondestructive to the enzyme and a technique for measuring the binding constants of (R)- and (S)-1,2-propanediols are presented.     

Inactivation of Phycomyces isocitrate lyase by thiol-reactive reagents. Evidence for an essential thiol group.

Isocitrate lyase from the mycelium of Phycomyces blakesleeanus was inactivated with thiol-reactive reagents, 5,5'-dithiobis-(2-nitrobenzoic)acid, p-hydroxymercuribenzoic acid, N-ethylmaleimide or iodoacetate, at pH 6.8 and 25 degrees C. In all cases the inactivation is characterized by a biphasic kinetic profile. The rapid initial phase of inactivation does not increase linearly with increasing reagent concentration, but exhibits an apparent saturation effect, suggesting the formation of a reversible complex between the enzyme and the reagent prior to the inactivation step. Re-activation of the enzyme was observed under thiol excess treatment. The pH dependence of the initial phase of inactivation suggests that a group on the enzyme with pKa = 6.8 is being modified. The effect of ligands was tested on the inactivation reaction. Mg(2+)-Ds-isocitrate and Ds-isocitrate provided total protection, whereas Mg2+ ions, succinate and oxalate provided only partial protection of the enzyme against inactivation. On the basis of these results, we would suggest that the thiol-reactive reagents modify at least one thiol group crucial for the enzymatic activity and probably located in the interface between succinate and glyoxylate subsite.     

The inactivation of glucosamine synthetase from bacteria by anticapsin, the C-terminal epoxyamino acid of the antibiotic tetaine

Incubation of anticapsin with the purified glucosamine synthetase (2-amino-2-deoxy-D-glucose-6-phosphate ketol-isomerase, amino transferring, EC 5.3.1.19) from Escherichia coli, Pseudomonas aeruginosa, Arthrobacter aurescens and Bacillus thuringiensis led to the formation of an inactive enzyme irreversibly modified. The inactivation reaction followed pseudo-first-order kinetics. The rate of the inactivation reaction at various concentrations of anticapsin exhibited saturation kinetics, implying that anticapsin binds reversibly to the enzyme prior to inactivation. The determined Kinact is in the range of 10(-5) M (B. thuringiensis) and 10(-6) M (E. coli, P. aeruginosa, A. aurescens ). The addition of glutamine protected the amidotransferase from inactivation by anticapsin . The anticapsin was demonstrated to be a mixed type or competitive inhibitor with respect to glutamine with a Ki value of 10(-6) to 10(-7) M. Reaction of anticapsin with the enzyme exhibits the characteristics of affinity labelling of the glutamine binding site. Chemical modification of the enzyme thiol group with various reagents, 5,5'-dithiobis-(2-nitrobenzoic) acid, 6,6'- dithiodinicotinic acid, 1,1'- dithiodiformamidine , N-ethylmaleimide and iodoacetamide, resulted in an inactive enzyme.     

The molecular weight and thiol residues of acetyl-coenzyme A synthetase from ox heart mitochondria

1. A constant molecular weight of 57000 was obtained by gel filtration of highly purified acetyl-CoA synthetase over a 1000-fold range of enzyme concentrations. The amino acid analysis is reported. 2. With native enzyme at 20 degrees C the relatively rapid reaction of four thiol residues with p-hydroxymercuribenzoate caused an immediate inhibition reversible by either CoA or mercaptoethanol. Other substrates did not protect against this rapid inhibition. 3. The much slower reaction of the remaining four thiol residues was independent of the concentration of the mercurial, first-order with respect to enzyme, and had a large energy of activation (+136kJ/mol), suggesting that a conformation change in the protein was rate-limiting. This slow phase of the reaction was accompanied by an irreversible inactivation of the enzyme. 4. The effects of substrates on this irreversible inactivation at pH7.0 in 5 mm-MgCl(2) indicated strong binding of ATP and pyrophosphate by the enzyme (concentrations for half-maximal effects, K((1/2)), were <30mum and <10mum respectively) and weaker binding of acetyl-CoA (K((1/2)) about 1 mm), AMP (K((1/2)) about 2mm) and acetate. In the presence of acetate, MgCl(2) and p-hydroxymercuribenzoate, titration of the enzyme with ATP revealed at least two ATP binding sites/mol. 5. The experiments suggest that reaction of the thiol residues with mercurial causes loss of enzymic activity by altering the structure of the enzyme, rather than that the thiol residues play a direct role in the catalysis.     

Active sites of beta-lactamases from Bacillus cereus

There are two extracellular beta-lactamases produced by Bacillus cereus 569. One of these enzymes, beta-lactamase I, is inactivated by 6-beta-bromopenicillanic acid: the site of reaction is serine-44. This is a conserved amino acid residue in the other beta-lactamases whose structures have been determined, and it becomes a good candidate for an active-site group in these enzymes. The inactivation may involve a rearrangement leading to a dihydrothiazine. The other extracellular enzyme produced by B. cereus, beta-lactamase II, is exceptional in requiring metal ions for activity. The Zn II and Co II enzymes (the former is more active) have been studied by nuclear magnetic resonance, and by absorption spectroscopy. The groups that bind the metal ion required for activity are three histidine residues and the enzyme's sole thiol group.     

Studies on the thiol group of lactose synthetase A protein from human milk and on the binding of uridine diphosphate galactose to the enzyme

The lactose synthetase activity of A protein from human milk was much decreased but not abolished by reaction with thiol-group reagents. Protection experiments indicated that a free thiol group on the enzyme is situated near the UDP-galactose binding site and inactivation of the enzyme with p-hydroxymercuribenzoate was probably due to prevention of UDP-galactose binding. Affinity chromatography showed that the mercuribenzoate substituent also decreased the affinity of A protein for N-acetylglucosamine but complex-formation between A protein-N-acetylglucosamine and alpha-lactalbumin was relatively unaffected. UDP-galactose appears to be bound to the enzyme mainly through its pyrophosphate group with Mn(2+) ion and through the cis hydroxyls of ribose, whereas its hexose moiety has little if any affinity for the enzyme. Lactose synthetase activity remaining after the reaction with thiol-group reagents indicates that a free thiol group is not an essential part of the A protein active site.     

Thiolation of low-Mr phosphotyrosine protein phosphatase by thiol-disulfides

Thiol-disulfides cause a time- and a concentration-dependent inactivation of the low-M(r) phosphotyrosine protein phosphatase (PTP). We demonstrated that six of eight enzyme cysteines have similar reactivity against 5,5'-dithiobis(nitrobenzoic acid): Their thiolation is accompanied by enzyme inactivation. The inactivation of the enzyme by glutathione disulfide also is accompanied by the thiolation of six cysteine residues. Inorganic phosphate, a competitive enzyme inhibitor, protects the enzyme from inactivation, indicating that the inactivation results from thiolation of the essential active-site cysteine of the enzyme. The inactivation is reversed by dithiothreitol. Although all PTPs have three-dimensional active-site structures very similar to each other and also have identical reaction mechanisms, the thiol group contained in the active site of low-M(r) PTP seems to have lower reactivity than that of other PTPs in the protein thiolation reaction.     

Suicide inactivation of fructose-1,6-bisphosphate aldolase

2-Keto-4,4,4-trifluorobutyl phosphate (HTFP) was prepared from 3,3,3-trifluoropropionic acid. HTFP acts as an irreversible inhibitor of rabbit muscle aldolase: the loss of activity was time dependent and the inactivation followed a pseudo-first-order process. Values of 1.4 mM for the dissociation constant and 2.3 X 10(-2) s-1 for the reaction rate constant were determined. The kinetic constants do not depend on the enzyme concentration. No effect of thiols on the inactivation rate was detected. Only 1-2 mol of fluoride ions was liberated per inactivated subunit, indicative of a low partition ratio. Dihydroxyacetone phosphate protected the enzyme against the inactivation in a competitive manner, and glyceraldehyde 3-phosphate protected as if it formed a condensation product with HTPF. 5,5'-Dithiobis(2-nitrobenzoic acid) thiol titration showed the loss of one very reactive thiol group per enzyme subunit after inactivation. All those observations seem to agree with a suicide substrate inactivation of aldolase by HTPF.     

Unmasking of an essential thiol during function of the membrane-bound enzyme II of the phosphenolpyruvate beta-glucoside phosphotransferase system of Escherichia coli.

beta-Glucoside transport by phosphoenolpyruvate-hexose phosphotransferase system in Escherichia coli is inactivated in vivo by thiol reagents. This inactivation is strongly enhanced by the presence of transported substrates. In a system reconstituted from soluble and membrane-bound components, only the particulate component, the membrane-bound enzyme IIbgl appeared as the target of N-ethylmaleimide inaction. The same feature was found in the case of methyl-alpha-D-glucoside uptake via enzyme IIglc. It is shown that the sensitizing effect of substrates is specific and not generalized, methyl-alpha-D-glucoside only sensitizes enzyme IIglc and p-nitrophenyl-beta-D-glucoside only sensitizes enzyme IIbgl towards N-ethylmaleimide inactivation. The inactivation of enzyme IIbgl by thiol reagents is also promoted in vivo by fluoride inhibition of phosphoenolpyruvate synthesis. In toluene-treated bacteria, the presence of phosphoenolpyruvate protects against inactivation by thiol reagents of p-nitrophenyl-beta-D-glucoside phosphorylation. Both results suggest that the inactivator resistent form of enzyme IIbgl is an energized form of the enzyme.     

Inactivation of phosphoenolypyruvate carboxykinase (GTP) by liver extracts.

1. The inactivation of phosphoenolpyruvate carboxykinase (GTP) (EC 4.1.1.32) in liver extracts was catalysed by the microsomal fraction, and led to the enzyme becoming bound to the microsomal membranes. 2. Inactivation by microsomal fraction, typsin or heating at 48degreesC was accelerated by L-cystine, D-cystine and oxidized glutathione and decreased by dithiothreitol. 3. MnC1(2) and CoC1(2) protected the enzyme from inactivation by heat or microsomal fraction, but did not affect the inactivation caused by trypsin. 4. Several proteinase inhibitors had no effect on the microsomal inactivation reaction, suggesting that proteolysis was not involved. 5. It is argued that the initial step in the degradation of phosphoenolpyruvate carboxykinase (GTP) is an inactivation reaction, perhaps involving oxidized thiol compounds.     

Kinetics of inactivation of creatine kinase during modification of its thiol groups

Kinetics of inactivation and modification of the reactive thiol groups of creatine kinase by 5,5'-dithiobis(2-nitrobenzoic acid) or iodoacetamide have been compared, the former by following the substrate reaction in presence of the inactivator [Wang, Z.-X., & Tsou, C.-L. (1987) J. Theor. Biol. 127, 253]. The microscopic constants for the reaction of the inactivators with the free enzyme and with the enzyme-substrate complexes were determined. From the results obtained it appears that with respect to ATP both inactivators are noncompetitive whereas for creatine iodoacetamide is competitive but DTNB is not. The formation of the ternary complex protects against the inactivation by both DTNB and iodoacetamide. The inactivation kinetics is monophasic with both inactivators, but under similar conditions, the modification reactions in the presence of the transition-state analogue of creatine-ADP-Mg2+-nitrate show biphasic kinetics as also reported by Price and Hunter [Price, N.C., & Hunter, M.G. (1976) Biochim. Biophys. Acta 445, 364]. If the reactive ternary complex and the enzyme complexed with the transition-state analogue react in the same way with these reagents, the modification of one fast-reacting thiol group for each enzyme molecule leads to complete inactivation, indicating that the enzyme has to be in the dimeric state to be active.     

Deoxycytidylate hydroxymethylase: purification, properties, and the role of a thiol group in catalysis

Deoxycytidylate (dCMP) hydroxymethylase from Escherichia coli infected with a T-4 bacteriophage amber mutant has been purified to homogeneity. It is a dimer with a subunit molecular weight of 28,000. Chemical modification of the homogeneous enzyme with N-ethylmaleimide (NEM) and 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) leads to complete loss of enzyme activity. dCMP can protect the enzyme against NEM inactivation, but the dihydrofolate analogues methotrexate and aminopterin alone do not afford similar protection. Compared to dCMP alone, dCMP plus either methotrexate or aminopterin greatly enhances protection against NEM inactivation. DTNB inactivation is reversed by dithiothreitol. For both reagents, inactivation kinetics obey second-order kinetics. NEM inactivation is pH dependent with a pKa for a required thiol group of 9.15 +/- 0.11. Complete enzyme inactivation by both reagents involves the modification of one thiol group per mole of dimeric enzyme. There are two thiol groups in the totally denatured enzyme modified by either NEM or DTNB. Kinetic analysis of NEM inactivation cannot distinguish between these two groups; however, with DTNB kinetic analysis of 2-nitro-5-thiobenzoate release shows that enzyme inactivation is due to the modification of one fast-reacting thiol followed by the modification of a second group that reacts about 5-6-fold more slowly. In the presence of methotrexate, the stoichiometry of dCMP binding to the dimeric enzyme is 1:1 and depends upon a reduced thiol group. It appears that the two equally sized subunits are arranged asymmetrically, resulting in one thiol-containing active site per mole of dimeric enzyme.     

Analysis of function-related interactions of ATP, sodium and potassium ions with Na+- and K+-transporting ATPase studied with a thiol reagent as tool.

The paper describes the interaction of ATP, Na+ and K+ with (NaK)-ATPase exploiting the inactivation by reaction with NBD-chloride as an analytical tool for the evaluation of enzyme ligandation with the various effectors. 1. The inactivation of (NaK)-ATPase by reaction with NBD-chloride showing under all conditions studied a pseudo first-order rate rests on the alkylation of thiol groups in or near catalytic centre. ATP bound to catalytic centre prevents from enzyme inactivation by NDD-chloride through protection of these thiol groups from alkylation. Na+ and K+ affect the reactivity of the thiol groups towards NBD-chloride either indirectly via influencing ATP binding or more directly via changing the conformation of catalytic centre. Proceeding from these interrelations, the interaction of the various effectors with the enzyme was analyzed. 2. The K'D-values of various nucleotides determined by our approach correspond to the values obtained by independent methods. As shown for the first time, two catalytic centres per enzyme molecule exist. They exhibit high or low affinity to both ATP and ADP apparently caused by anticooperative interaction of the half-units of the enzyme through intersubunit communication ("half-of-the-sites reactivity"). 3. In the absence of ATP, Na+ or K+ ligandation of (NaK)-ATPase produce opposite effects on the reactivity of the thiol groups of catalytic centres reflecting different changes of their conformation. This corresponds to the well-known antagonistic effect of Na+ and K+ on some partial reactions of (NaK)-ATPase. The Na+ and K+ concentrations required to change thiol reactivity are rather high, i.e. the ionophoric centres for both Na+ and K+ are not readily accessible for cation complexation in the absence of enzyme complexation with ATP. 4. Na+ being without effect on ATP binding to the enzyme also does not influence the inactivating reaction with NBD-chloride while K+ by decreasing ATP binding dramatically decreases the protective effect of ATP. The K+ affinity of the enzyme-ATP complex is by more than two orders of magnitude higher than that of free enzyme. Na+ ligandation of the K+-liganded enzyme-ATP complex reverses the effect of K+ ligandation and produces a protective effect which distinctly surpasses that of the complexation of free enzyme with ATP. Hence, the enzyme molecule carries simultaneously ionophoric centres for both Na+ and K+. 5. The findings that per enzyme molecule ionophoric centres for Na+ and K+, and two catalytic centres with anticooperative interaction coexist corroborate the corresponding basic predictions of the flip-flop concept of (NaK)-ATPase pump mechanism, and explain some peculiar kinetic features of transport and enzyme activities of (NaK)-ATPase.     

Reactive thiol groups in rat liver acid phosphatase

Dimeric rat liver acid phosphatase P1 of Mr 92,000 is inactivated by p-chloromercuribenzoate and fluorescein mercuriacetate (FMA). The enzyme is protected against the mercurials by the substrate analogue Pi. The reaction with FMA is accompanied by changes in absorbance at 495 nm and in fluorescence emission at 520 nm that are characteristic of reaction of this compound with thiol groups. Titration of P1 with FMA monitored by spectrophotometry or by fluorimetry indicated that equivalence is reached at an FMA/P1 ratio of 3. Since FMA can act as a bifunctional reagent, it is likely that P1 contains either 3 or 6 reactive thiol groups per molecule. Analysis of FMA inactivation/modification data by a statistical method suggests that of 6 reactive thiol groups, 2 are essential so that there are probably 3 thiol groups per subunit, one of which is located at the active site. If the total thiol number is 3, analysis suggests 1 essential thiol per subunit.     

Effects of di-isopropyl phosphorofluoridate on rat liver microsomal and lysosomal beta-glucuronidase

N-Bromosuccinimide completely inactivated the cellulase, and titration experiments showed that oxidation of one tryptophan residue per cellulase molecule coincided with 100% inactivation. CM-cellulose protected the enzyme from inactivation by N-bromosuccinimide. The cellulase was inhibited by active benzyl halides, and reaction with 2-hydroxy-5-nitrobenzyl bromide resulted in the incorporation of 2.3 hydroxy-5-nitrobenzyl groups per enzyme molecule; one tryptophan residue was shown to be essential for activity. Diazocarbonyl compounds in the presence of Cu2+ ions inhibited the enzyme. The pH-dependence of inactivation was consistent with the reaction occurring with a protonated carboxyl group. Carbodi-imide inhibited the cellulase, and kinetic analysis indicated that there was an average of 1 mol of carbodi-imide binding to the cellulase during inactivation. Treatment of the cellulase with diethyl pyrocarbonate resulted in the modification of two out of the four histidine residues present in the cellulase. The modified enzyme retained 40% of its original activity. Inhibition of cellulase activity by the metal ions Ag+ and Hg2+ was ascribed to interaction with tryptophan residues, rather than with thiol groups.