An essential residue at the active site of aspartate transcarbamylase.

Reaction of phenylglyoxal with aspartate transcarbamylase and its isolated catalytic subunit results in complete loss of enzymatic activity. This modification reaction is markedly influenced by pH and is partially reversible upon dialysis. Carbamyl phosphate or carbamyl phosphate with succinate partially protect the catalytic subunit and the native enzyme from inactivation by phenylglyoxal. In the native enzyme complete protection from inactivation is afforded by N-(phosphonacetyl)-L-aspartate. The decrease in enzymatic activity correlates with the modification of 6 arginine residues on each aspartate transcarbamylase molecule, i.e. 1 arginine per catalytic site. The data suggest that the essential arginine is involved in the binding of carbamyl phosphate to the enzyme. Reaction of the single thiol on the catalytic chain with 2-chloromercuri-4-nitrophenol does not prevent subsequent reaction with phenylglyoxal. If N-(phosphonacetyl)-L-aspartate is used to protect the active site we find that phenylglyoxal also causes the loss of activation of ATP and inhibition by CTP. The rate of loss of heterotropic effects is exactly the same for both nucleotides indicating that the two opposite regulatory effects originate at the same location on the enzyme, or are transmitted by the same mechanism between the subunits, or both.     

Properties and reaction with iodoacetamide of adenosine 5′-triphosphate–creatinine phosphotransferase from human skeletal muscle. Further evidence about the role of the essential thiol group in relation to the mechanism of action

1. The purification of creatine kinase from human and monkey skeletal muscle by horizontal electrophoresis on Sephadex blocks is described. 2. The purified enzymes are shown to have similar chemical and kinetic properties to the rabbit muscle enzyme and a common mechanism is inferred. 3. Iodoacetamide has a similar apparent second-order inhibition constant with the human and rabbit enzymes, but the inhibition does not go to completion with the former. This is even more marked with the monkey enzyme, which has more reactive thiol groups, but inhibition is only about 50%. 4. Single substrates have little effect on the inhibition by iodoacetamide, but with the primate enzymes, in contrast with the rabbit enzyme, high concentrations of ADP-Mg(2+) plus creatine convert the essential thiol group from being pH-independent into one with a normal ionization. Low concentrations of ADP-Mg(2+) plus creatine first enhance the rate of inactivation, but cause protection as the reaction proceeds. These results are interpreted to indicate an activation of the thiol group on the subunit to which the substrates bind and a co-operatively induced decrease in the activity of the thiol group on the other subunit which lacks substrates. 5. The effects of a substrate equilibrium mixture on the rate of inhibition are essentially those of ADP-Mg(2+) plus creatine. 6. Since no substrate combination affords significant protection to the thiol group associated with the catalytic site to which the substrates are bound, it is concluded that any mechanism involving the thiol group in a direct participation in the transition-state complex of the catalytic reaction must be abandoned unless the transition state is only a small part of the time taken for one catalytic cycle.     

Identification of the amino acid residues essential for the activity and the interconversion of the molecular forms of biliverdin reductase

Biliverdin reductase (molecular form 1, EC 1.3.1.24, bilirubin:NAD(P)+ oxidoreductase) carries three thiol residues. Only one of them could be alkylated when a ratio N-ethylmaleimide (NEM)/mol enzyme's SH = 90 was used. The alkylation of this thiol group inhibited the conversion of molecular form 1 to its dimer, molecular form 3; however, it did not inhibit the enzymatic activity. At a ratio of NEM/enzyme's SH = 300, two thiol residues were alkylated and the activity of the enzyme was totally inhibited. The third thiol group could not be alkylated either by NEM or by iodoacetamide. Biliverdin as well as the co-substrate NADPH protected the thiol residue essential for the enzymatic activity from alkylation. Spectroscopic evidence was obtained that this thiol group binds covalently to the C-10 of biliverdin to form a rubinoid adduct. The presence of a lysine residue, which is also essential for the enzymatic activity, could be inferred from the fact that by reduction of the Schiff base formed by the enzyme with pyridoxal phosphate the catalytic activity was irreversibly abolished. The location of a lysine residue in the vicinity of the thiol group involved in the catalytic activity was evident when the enzyme was treated with o-phthalaldehyde. The inactivation of the enzymatic activity was coincident with the formation of the fluorescent isoindole derivative which originates when the thiol and epsilon-NH2 groups are located about 3 A apart. The presence of a positively charged ammonium ion in the vicinity of the NADPH binding site was inferred from the shifts in the UVmax of NADPH from 340 nm to 327 nm and of 3-acetyl NADPH from 360 nm to 348 nm when the pyridine nucleotides bind to the reductase. The involvement of arginine residues in the enzymatic activity was established by inhibition of the latter after reaction with butanedione. This inhibition was totally protected by NADPH but not by biliverdin. The similarity of the structural features of biliverdin reductase with those of several dehydrogenases is discussed.     

Studies of glutamate dehydrogenase. Methionine-169: the preferentially carboxymethylated residue.

In phosphate buffer at pH 7.0, 5,5'-dithio-bis(2-nitrobenzoic acid), N-ethylmaleimide or iodoacetamide do not alter the activity of beef liver glutamate dehydrogenase. Iodoacetate, however, inactivities the enzyme irreversibility by alkylation. Combined addition of the coenzyme NADH and the substrate 2-oxoglutarate or the effector GTP protects against this inactivation. The alkylation reaction is independent of pH between pH 6-9 indicating that amino, imidazole or phenolic groups are probably not involved in this reaction. Titration of the thiol groups, after denaturation of the enzyme, revealed the loss of approximately one group per polypeptide chain. However, this is not due to the exclusive alkylation of a cysteine residue, since alkylation with iodo-[2-14C]acetic acid also labels a methionine residue. 50% of the label is incorporated into methionine-169 and only 7% into cysteine-115, the remaining radioactivity is distributed in minor quantities (4%) in several unidentified residues. A probable cause of the erroneous thiol groups titration is discussed.     

Arginine-specific modification of rabbit muscle phosphoglucose isomerase: Differences in the inactivation by phenylglyoxal and butanedione and in the protection by substrate analogs

Rabbit muscle phosphoglucose isomerase was modified with phenylglyoxal or 2,3-butanedione, the reaction with either reagent resulting in loss of enzymatic activity in a biphasic mode. At slightly alkaline pH butanedione was found to be approximately six times as effective as phenylglyoxal. The inactivation process could not be significantly reversed by removal of the modifier. Competitive inhibitors of the enzyme protected partially against loss of enzyme activity by either modification. The only kind of amino acid residue affected was arginine. However, more than one arginine residue per enzyme subunit was found to be susceptible to modification by the dicarbonyl reagents. From protection experiments it was concluded (i) that both modifiers react specifically with an arginine in the phosphoglucose isomerase active site and nonspecifically with one or more arginine residues elsewhere in the enzyme molecule, (ii) that modification at either loci causes loss of catalytic activity, and (iii) that butanedione has a higher preference for active site arginine than for arginine residues outside of the catalytic center whereas the opposite is true for phenylglyoxal.     

Evidence for an essential arginine residue at the active site of Escherichia coli acetate kinase

Escherichia coli acetate kinase (ATP: acetate phosphotransferase, EC 2.7.2.1.) was inactivated in the presence of either 2,3-butanedione in borate buffer or phenylglyoxal in triethanolamine buffer. When incubated with 9.4 mM phenylglyoxal or 5.1 mM butanedione, the enzyme lost its activity with an apparent rate constant of inactivation of 0.079 min-1, respectively. The loss of enzymatic activity was concomitant with the loss of an arginine residue per active site. Phosphorylated substrates of acetate kinase, ATP, ADP and acetylphosphate as well as AMP markedly decreased the rate of inactivation by both phenylglyoxal and butanedione. Acetate neither provided any protection nor affected the protection rendered by the adenine nucleotides. However, it interfered with the protection afforded by acetylphosphate. These data suggest that an arginine residue is located at the active site of acetate kinase and is essential for its catalytic activity, probably as a binding site for the negatively charged phosphate group of the substrates.     

Pyrroloquinoline quinone (coenzyme PQQ) and the oxidation of SH residues in proteins.

Pyrroloquinoline quinone (PQQ) catalyzes the oxidation of cysteamine at neutral pH with a second order rate constant K2 = 0.45 M-1 s-1. The reduction of PQQ was monitored by absorption and fluorescence spectroscopy, whereas the oxidation of cysteamine to cystamine was followed by titration with 5,5'-dithiobis(2-nitrobenzoic acid). PQQ also catalyzes the oxidation of thiol groups critically connected with the function of two proteins, i.e. thioredoxin and phosphoribulose kinase. The reaction of PQQ with reduced thioredoxin brings about the oxidation of two thiol groups of the oxireductase, whereas the enzyme phosphoribulose kinase is inactivated at 25 degrees C. The oxidized disulfide bond of phosphoribulose kinase is reduced by dithiothreitol and the enzyme recovers catalytic activity. The ability of PQQ to catalyze the oxidation of vicinal cysteinyl residues to generate disulfide bonds under mild experimental conditions can be exploited to define the precise role of modified thiol residues in either catalysis or stabilization of protein structure.     

Chemical modification of Escherichia coli succinyl-CoA synthetase with the adenine nucleotide analogue 5''-p-fluorosulphonylbenzoyladenosine.

Escherichia coli succinyl-CoA synthetase (EC 6.2.1.5) was irreversibly inactivated on incubation with the adenine nucleotide analogue 5'-p-fluorosulphonylbenzoyladenosine (5'-FSBA). Optimal inactivation by 5'-FSBA took place in 40% (v/v) dimethylformamide. ATP and ADP protected the enzyme against inactivation by 5'-FSBA, whereas desulpho-CoA, an analogue of CoA, did not. Inactivation of succinyl-CoA synthetase by 5'-FSBA resulted in total loss of almost four thiol groups per alpha beta-dimer, of which two groups appeared to be essential for catalytic activity. 5'-FSBA at the first instance appeared to interact non-specifically with non-essential thiol groups, followed by a more specific reaction with essential thiol groups in the ATP(ADP)-binding region. Plots of the data according to the method of Tsou [(1962) Sci. Sin. 11, 1535-1558] revealed that, of the two slower-reacting thiol groups, only one was essential for catalytic activity. When succinyl-CoA synthetase that had been totally inactivated by 5'-FSBA was unfolded in acidic urea and then refolded in the presence of 100 mM-dithiothreitol, 85% of the activity, in comparison with the appropriate control, was restored. These data are interpreted to indicate that inactivation of succinyl-CoA synthetase by 5'-FSBA involves the formation of a disulphide bond between two cysteine residues. Disulphide bond formation likely proceeds via a thiosulphonate intermediate between 5'-p-sulphonylbenzoyladenosine and one of the reactive thiol groups of the enzyme.     

Use of methanethiolation to investigate the catalytic role of sulphydryl groups in rabbit skeletal muscle pyruvate kinase.

Incubation of rabbit skeletal muscle pyruvate kinase (ATP:pyruvate 2-O-phosphotransferase, EC 2.7.1.40) with methyl methanethiosulphonate resulted in the time- and inhibitor concentration-dependent loss of enzyme activity. Substrates or products of the catalytic reaction prevented the loss of activity caused by methanethiolation. Their effectiveness as protecting agents was placed in the order ADP greater than ATP greater than Mg2+ greater than phosphoenolpyruvate greater than pyruvate. The essential catalytic cation, K+, had no effect on the methanethiolation reaction. [Me-3H]Methanethiosulphonate modified all the available cysteine thiol groups which correlated to the incorporation of four SC3H3 groups per protomer. Four radioactive peptides were obtained on tryptic peptide mapping. When methanethiolation was carried out in the presence of Mg2+ alone or with Mg2+ and ATP together, then only three SC3H3 groups were incorporated into each subunit. If MgATP protected methanethiolated pyruvate kinase was reacted with iodo[2-3H]acetic acid then 1.37 +/- 0.2 groups per protomer were carboxymethylated. 70% of the radioactivity was located in a single peptide on tryptic peptide mapping. This peptide was isolated and contained the segment carboxymethyl cysteine (Glx, Asx, Ser) Arg. Collectively these data indicate that although all thiol groups are equally accessible to methyl methanethiosulphonate, only a single thiol group participates in the catalytic event. An additional role in the maintenance of structure for this thiol group was also shown in studied of reduction and thermal denaturation of the enzyme.     

Evidence for a close similarity in the catalytic sites of papain and ficin in near-neutral media despite differences in acidic and alkaline media. Kinetics of the reactions of papain and ficin with chloroacetate.

1. The pH-dependences of the second-order rate constants (k) for the alkylation by chloroacetate of the active-centre thiol groups of papain (EC 3.4.22.2) and ficin (EC 3.4.22.3) were determined over a wide range of pH at 25 degrees C at I 0.1. 2. The main feature of both pH-k profiles is a striking rate maximum at pH6 (characterizing parameters in both cases pKI approx. 3.5, pKII approx. 8.4 and pH-independent rate constant approximately kXH 2.5-3.0 M-1 . s-1). 3. The profile for the ficin reaction contains a plateau at high pH, with approximately kX 0.10 M-1 . s-1; if an analogous plateau exists in the papain reaction, approximately kX ix much lower, less than 0.02 M-1 . s-1. 4. Both enzymes appear to contain closely similar thiolate-imidazolium interactive systems at pH6, but differences in their behaviour in more-acidic media and in alkaline media suggest differences in interaction with the postulated carboxylate component of the putative catalytic triad.     

Involvement of arginine residues in catalysis by rat brain hexokinase

Inactivation of rat brain hexokinase (ATP:d-hexose 6-phosphotransferase, EC 2.7.1.1) by the arginine-specific reagent, phenylglyoxal, has been studied. Inactivation did not follow pseudo-first-order kinetics, suggesting the involvement of two or more arginine residues in catalytic function. Using [¹⁴C]phenylglyoxal, it was found that 5 of the 55 arginines per molecule of hexokinase react with this reagent, with an accompanying loss of over 90% of the catalytic activity. Virtually all of the activity loss occurs during derivatization of four relatively slower reacting arginines, with essentially no activity loss during derivatization of one rapidly reacting arginine. Inactivation by phenylglyoxal was not due to reaction with critical sulfhydryl groups in brain hexokinase since reactivity of the enzyme with the sulfhydryl reagent, 5,5′-dithiobis(2-nitrobenzoic acid) was not affected by prior treatment with phenylglyoxal. Comparison of amino acid composition, before and after reaction with phenylglyoxal, indicated that only the arginine content had been affected by phenylglyoxal treatment. The decrease in arginine content, measured by amino acid analysis, and the incorporation of phenylglyoxal, measured with [¹⁴C]phenylglyoxal, was consistent with the phenylglyoxal:arginine stoichiometry of 2:1 originally reported by K. Takahashi (1968, J. Biol. Chem.243, 6171–6179). Several ligands were tested and found to provide varying degrees of protection of hexokinase activity against phenylglyoxal. ATP and ADP alone provided only slight protection, but were highly effective in the presence of N-acetylglucosamine which itself gave only moderate protection. Glucose 6-phosphate and 1,5-anhydroglucitol 6-phosphate, both good inhibitors of brain hexokinase, were very effective while poorly inhibitory hexose 6-phosphates were not. Glucose was very effective, with protection afforded by other hexoses being correlated with their ability to serve as substrates (i.e., poor substrates also provided little protection against phenylglyoxal). The effectiveness of hexose 6-phosphates and hexoses in protecting the enzyme against inactivation by phenylglyoxal was related to their ability to induce conformational change in the enzyme. None of the ligands tested appreciably affected the reactivity of the rapidly reacting arginine residue. There was no correlation between the inhibition observed in the presence of various ligands and the number of arginines reacted with phenylglyoxal. The results were interpreted as indicating the involvement of two to four arginine residues in the catalytic function of brain hexokinase, possibly in the binding of anionic ligands such as ATP, ADP, or glucose 6-phosphate.     

Evidence for a reactive cysteine at the nucleotide binding site of spinach ribulose-5-phosphate kinase

Ribulose-5-phosphate kinase from spinach was rapidly inactivated by N-bromoacetylethanolamine phosphate in a bimolecular fashion with a k2 of 2.0 M-1 S-1 at 2 degrees C and pH 8.0. Ribulose 5-phosphate had little effect on the rate of inactivation, whereas complete protection was afforded by ADP or ATP. The extent of incorporation as determined with 14C-labeled reagent was about 1 molar equivalent per subunit in the presence of ATP with full retention of enzymatic activity, and about 2 molar equivalents per subunit in the completely inactivated enzyme. Amino acid analyses of enzyme derivatized with 14C-labeled reagent reveal that all of the covalently incorporated reagent was associated with cysteinyl residues. Hence two sulfhydryls are reactive, but the inactivation correlates with alkylation of one cysteinyl residue at or near the enzyme's nucleotide binding site. The kinase was also extremely sensitive to the sulfhydryl reagents 5,5'-dithiobis(2-nitrobenzoic acid) and N-ethyl-maleimide. The reactive sulfhydryl groups are likely those generated by reduction of a disulfide during activation.     

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.     

The reaction of horse-liver alcohol dehydrogenase with glyoxal.

Horse liver alcohol dehydrogenase was reacted with glyoxal at different pH values ranging from 6.0 to 9.0. At pH 9.0 the enzyme undergoes a rapid activation over the first minutes of reaction, followed by a decline of activity, which reaches 10% of that of the native enzyme. Chemical analysis of the inactivated enzyme after sodium borohydride reduction shows that 11 argi-ine and 11 lysine residues per mole are modified. At pH 7.7 the enzyme activity increases during the first hour of the reaction with glyoxal and then decreases slowly. Chemical analysis shows that 4 arginine and 3 lysine residues per mole are modified in the enzyme at the maximum of activation. At pH 7.0 the enzyme undergoes a 4-fold activation. Chemical analysis shows that in this activated enzyme 3 lysine and no arginine residues per mole have been modified. Steady-state kinetic analysis suggests that the activated enzyme is not subjected to substrate inhibition and that its Michaelis constant for ethanol is three times larger than that of the native enzyme. The possible role of arginine and lysine residues in the catalytic function of liver alcohol dehydrogenase is discussed.     

The reaction of N-ethylmaleimide at the active site of succinate dehydrogenase.

Since 1938 mammalian succinate dehydrogenase has been thought to contain thiol groups at the active site. This hypothesis was questioned recently, because irreversible inhibition by bromopyruvate and N-ethylmaleimide appeared not to satisfy the requisite criteria for reaction at the active site. These recent observations of incomplete inactivation of succinate dehydrogenase by N-ethylmaleimide and incomplete protection by substrates can, however, be explained adequately by the presence of oxalacetate and other strong competitors of the inactivation process in the enzyme used in these studies. Substrates, competitive inhibitors, and anions which activate succinate dehydrogenase protect the enzyme from inhibition by N-ethylmaleimide. Inhibition of succinate dehydrogenase by N-ethylmaleimide involves at least two second order reactions which are pH dependent, with pKa values of 8.0 to 8.2. This pH dependence, the known reactivity of N-ethylmaleimide toward thiols, and the protection by substrate and competitive inhibitors indicate that sulfhydryl residues are required for catalytic activity and perform an essential, not secondary, role in the catalysis. Just as the presence of tightly bound oxalacetate prevents inhibition by N-ethylmaleimide, alkylation of the sulfhydryl residue(s) at the active site prevents the binding of [14C]oxalacetate. Thus, these thiol groups at the active site also may be the site of tight binding of oxalacetate during the activation-deactivation cycle.     

Electron paramagnetic resonance identification of a highly reactive thiol group in the proximity of the catalytic site of human placenta glutathione transferase.

The reaction of the glutathione transferase from human placenta with a maleimide spin label derivative has been followed by EPR. Incubation of the enzyme at pH 7.0 with 50-fold molar excess of the spin label reagent gives rise to an immobilized nitroxyl EPR spectrum indicative of two reacting thiol groups per dimer of enzyme as evaluated by double integration of the EPR spectrum; the activity is lost in parallel. The same type of spectrum can be obtained simply by adding 2 eq of the spin label reagent to the enzyme. The binding is completed after less than 1 min at pH 8.0; it requires 2 min at pH 7.0 and more than 10 min at pH 6.0. These data indicate that the maleimide derivative reacts, in each subunit, with a thiol group which plays a crucial role for the maintenance of the catalytic activity and is characterized by a low pK. Inactivation of the enzyme at pH 7.0 in the presence of 2 eq of spin label reagent per mol of enzyme requires 15 min, suggesting the occurrence of a structural rearrangement after the binding of the thiol blocking agent. The same binding in the presence of S-methylglutathione or protoporphyrin IX shows a decreased reaction rate with respect to the reaction in the absence of inhibitors, indicating that the thiols are in proximity of both the glutathione and the porphyrin binding sites. For this latter case, this is unambiguously demonstrated by the titration of spin-labeled enzyme with hemin, which produces a decrease of the EPR signal amplitude from which an interspin distance of about 10 A can be evaluated.     

The reactivity of thiol groups and the subunit structure of aldolase

1. Seven unique carboxymethylcysteine-containing peptides have been isolated from tryptic digests of rabbit muscle aldolase carboxymethylated with iodo[2-(14)C]acetic acid in 8m-urea. These peptides have been characterized by amino acid and end-group analysis and their location within the cyanogen bromide cleavage fragments of the enzyme has been determined. 2. Reaction of native aldolase with 5,5'-dithiobis-(2-nitrobenzoic acid), iodoacetamide and N-ethylmaleimide showed that a total of three cysteine residues per subunit of mol.wt. 40000 were reactive towards these reagents, and that the modification of these residues was accompanied by loss in enzymic activity. Chemical analysis of the modified enzymes demonstrated that the same three thiol groups are involved in the reaction with all these reagents but that the observed reactivity of a given thiol group varies with the reagent used. 3. One reactive thiol group per subunit could be protected when the modification of the enzyme was carried out in the presence of substrate, fructose 1,6-diphosphate, under which conditions enzymic activity was retained. This thiol group has been identified chemically and is possibly at or near the active site. Limiting the exposure of the native enzyme to iodoacetamide also served to restrict alkylation to two thiol groups and left the enzymic activity unimpaired. The thiol group left unmodified is the same as that protected by substrate during more rigorous alkylation, although it is now more reactive towards 5,5'-dithiobis-(2-nitrobenzoic acid) than in the native enzyme. 4. Conversely, prolonged incubation of the enzyme with fructose 1,6-diphosphate, which was subsequently removed by dialysis, caused an irreversible fall in enzymic activity and in thiol group reactivity measured with 5,5'-dithiobis-(2-nitrobenzoic acid). 5. It is concluded that the aldolase tetramer contains at least 28 cysteine residues. Each subunit appears to be identical with respect to number, location and reactivity of thiol groups.     

Enzyme deactivation due to metal-ion dissociation during turnover of the cobalt-beta-lactamase catalyzed hydrolysis of beta-lactams

Metallo-beta-lactamases are native zinc enzymes that catalyze the hydrolysis of beta-lactam antibiotics but are also able to function with cobalt (II) and require one or two metal ions for catalytic activity. The kinetics of the hydrolysis of benzylpenicillin catalyzed by cobalt substituted beta-lactamase from Bacillus cereus (BcII) are biphasic. The dependence of enzyme activity on pH and metal-ion concentration indicates that only the di-cobalt enzyme is catalytically active. A mono-cobalt enzyme species is formed during the catalytic cycle, which is virtually inactive and requires the association of another cobalt ion for turnover. Two intermediates with different metal to enzyme stoichiometries are formed on a branched reaction pathway. The di-cobalt enzyme intermediate is responsible for the direct catalytic route, which is pH-independent between 5.5 and 9.5 but is also able to slowly lose one bound cobalt ion via the branching route to give the mono-cobalt inactive enzyme intermediate. This inactivation pathway of metal-ion dissociation occurs by both an acid catalyzed and a pH-independent reaction, which is dependent on the presence of an enzyme residue of pK(a) = 8.9 +/- 0.1 in its protonated form and shows a large kinetic solvent isotope effect (H(2)O/D(2)O) of 5.2 +/- 0.5, indicative of a rate-limiting proton transfer. The pseudo first-order rate constant to regenerate the di-cobalt beta-lactamase from the mono-cobalt enzyme intermediate has a first-order dependence on cobalt-ion concentration in the pH range 5.5-9.5. The second-order rate constant for metal-ion association is dependent on two groups of pK(a) 6.32 +/- 0.1 and 7.47 +/- 0.1 being in their deprotonated basic forms and one group of pK(a) 9.48 +/- 0.1 being in its protonated form.     

Rat liver 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase. Identification of essential sulfhydryl residues in the primary sequence of the enzyme

The kinase and sugar phosphate exchange reactions of rat liver 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase were inactivated by treatment with 5'-p-fluorosulfonylbenzoyladenosine or 8-azido-ATP, but activity could be restored by the addition of dithiothreitol. This inactivation was accompanied by incorporation of 5'-p-sulfonylbenzoyl[8-14C]adenosine into the enzyme that was not released by the addition of dithiothreitol. The lack of effect of ATP analogs on the ATP/ADP exchange or on bisphosphatase activity and reversal of their effects on the kinase and sugar phosphate reactions by dithiothreitol suggest that 1) they reacted with sulfhydryl groups important for sugar phosphate binding in the kinase reaction, and 2) the inactivation of the kinase by these analogs involves a specific reaction that is not related to their general mechanism of attacking nucleotide-binding sites. In addition, alkylation of the enzymes' sulfhydryls with iodoacetamide prevented inactivation by 5'-p-fluorosulfonylbenzoyladenosine, suggesting that the same thiols were involved. o-Iodosobenzoate inactivated the kinase and sugar phosphate exchange; the inactivation was reversed by dithiothreitol; but there was no effect on the bisphosphatase or nucleotide exchange, indicating that oxidation occurred at the same sulfhydryl that are associated with sugar phosphate binding. ATP or ADP, but not fructose 6-phosphate, protected these groups from modification by 5'-p-fluorosulfonylbenzoyladenosine, 8-azido-ATP, and o-iodosobenzoate. ATP also induced dramatic changes in the circular dichroism spectrum of the enzyme, suggesting that adenine nucleotide protection of thiol groups resulted from changes in enzyme secondary structure. Analysis of cyanogen bromide fragments of 14C-carboxamidomethylated enzyme showed that all radioactivity was associated with cysteinyl residues in a single cyanogen bromide fragment. Three of these cysteinyl residues are clustered in a 38-residue region, which probably plays a role in maintaining the conformation of the kinase sugar phosphate-binding site.     

Histidine in the nucleotide-binding site of NADP-linked isocitrate dehydrogenase from pig heart.

Incubation of pig heart NADP-dependent isocitrate dehydrogenase with ethoxyformic anhydride (diethylpyrocarbonate) at pH 6.2 results in a 9-fold greater rate of loss of dehydrogenase than of oxalosuccinate decarboxylase activity. The rate constants for loss of dehydrogenase and decarboxylase activities depend on the basic form of ionizable groups with pK values of 5.67 and 7.05, respectively, suggesting that inactivation of the two catalytic functions results from reaction with different amino acid residues. The rate of loss of dehydrogenase activity is decreased only slightly in the presence of manganous isocitrate, but is reduced up to 10-fold by addition of the coenzymes or coenzyme analogues, such as 2'-phosphoadenosine 5'-diphosphoribose (Rib-P2-Ado-P). Enzyme modified at pH 5.8 fails to bind NADPH, but exhibits manganese-enhanced isocitrate binding typical of native enzyme, indicating that reaction takes place in the region of the nucleotide binding site. Dissociation constants for enzyme . coenzyme-analogue complexes have been calculated from the decrease in the rate of inactivation as a function of analogue concentration. In the presence of isocitrate, activating metals (Mn2+, Mg2+, Zn2+) decrease the Kd value for enzyme . Rib-P2-Ado-P, while the inhibitor Ca2+ increases Kd. The strengthened binding of nucleotide produced by activating metal-isocitrate complexes may be essential for the catalytic reaction, reflecting an optimal orientation of NADP+ to facilitate hydride transfer. Measurements of ethoxyformyl-histidine formation at 240 nm and of incorporation of [14C]ethoxy groups in the presence and absence of Rib-P2-Ado-P indicate that loss of activity may be related to modification of approximately one histidine. The critical histidine appears to be located in the nucleotide binding site in a region distal from the substrate binding site.