The role of thiol groups in the structure and mechanism of action of arginine kinase

1. A detailed study of the reaction of iodoacetamide with arginine kinase has been carried out. 2. The enzyme contains five reactive thiol groups per 37000g. of protein, all of which can be alkylated. 3. Below pH8.5 loss of activity is substantially independent of pH and can be correlated with the alkylation of a single pH-independent thiol. 4. One catalytic site per enzyme molecule is inferred. 5. The progress curves of the alkylation reaction are polyphasic and reveal a pH-and time-dependent sequential release of thiols which is dependent upon the alkylation of the first pH-independent thiol. This is supported by electrophoretic investigations. 6. Comparison of alkylation rate and rate of loss of activity suggests that two thiol groups are not essential for catalytic activity. Variability in enzyme preparations with respect to alkylation rate appears to be associated with these two groups. 7. A complex protection pattern is revealed by the effects of various substrate combinations on rates of alkylation and of loss of activity. It is inferred that two thiol groups participate in conformational changes and nucleotide interactions. 8. Comparison with creatine kinase suggests a fundamentally similar catalytic mechanism, although for arginine kinase certain additional restrictions are necessary because of the protection observed with nucleotide substrates.     

Fluorescence labeling of the human erythrocyte anion transport system.

The anion transport system of human red cells was isolated in vesicles containing the original membrane lipids and the 95 000 dalton polypeptides (band 3) by the method of Wolosin et al. (J. Biol. Chem. (1977) 252, 2419--2427). The vesicles have a functional anion transprot system since they display sulfate transport that is inhibited by the fluorescent probe 8-anilinonaphthalene 1-sulfonate (ANS) with similar potency as in red cells. The vesicles were labeled with the SH-specific probe fluorescein mercuric acetate (FMA). Labeling lowers FMA fluorescence, and is prevented or reversed by dithiothreitol, suggesting that the reaction is with a thiol group on the protein. Fluorescnece titrations show a maximum labeling stoichiometry of 1.3 +/- 0.4 mol FMA/mol 95 000 dalton polypeptide. The polarization of bound FMA fluorescence is high indicating that the probe is highly immobilized. Pretreatment with Cu2+ + o-phenanthroline under conditions that crosslink band 3 in ghosts decreases FMA labeling 50%. Differences in kinetics of FMA labeling in sealed and leaky vesicles suggest that the reactive SH group is located in the intravesicular portion of the protein (corresponding to the cytoplasmic surface of the red cell) and that FMA can cross the membrane. Inhibitors of anion transport have no effect on FMA labeling kinetics suggesting it is not transported via the anion transport system. Sulfate transport in the labeled vesicles remains fully functional. We detected self-energy transfer between bound FMA molecules by fluorescence depolarization. With excitation at 450--50 nm P decreases from 0.4, when less than half of the proteins are labeled, to 0.1 at saturation. This depolarization is not observed with red edge excitation (510--530 nm). Addition of 0.1% sodium dodecyl sulfate (SDS) changes P to 0.32, regardless of the excitation wavelength or degree of saturation with FMA. These results indicate that the band 3 proteins are close enough to allow energy transfer between fluorophores(Ro = 37.4 A), which does not occur upon red edge excitation or when the proteins are separated by SDS. We conclude that the functional anion transport system exists as a dimer or higher oligomer of band 3 proteins in these membranes, confirming previous suggestions derived using other methods. Future applications are discussed.     

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.     

Reactivity of the essential thiol group of lactate dehydrogenase and substrate binding

1. The preparation of a derivative of pig heart lactate dehydrogenase in which the essential thiol group has been converted into an S-sulpho group is described. The derivative has unchanged s(20,w) and is catalytically inactive. 2. The rate of reaction of the essential thiol group is controlled by a system with a pK>9. 3. The essential thiol group is protected by NADH against reaction with maleimide. 4. Lactate dehydrogenase in which the essential thiol group has been converted into an S-sulpho group or alkylated with maleimide still binds one molecule of NADH/subunit but with a three- to four-fold diminished affinity. 5. The inhibited enzymes also bind one molecule of NAD(+)-sulphite complex/subunit but with affinity decreased 10(3)-10(4)-fold. 6. The inhibited enzymes fail to bind C(2) and C(3) molecules to give the ternary complexes enzyme-NAD(+)-pyruvate, enzyme-NADH-oxamate and enzyme-NADH-oxalate. The 1:1:1 stoicheiometry of the last-mentioned complex with the native enzyme was established by gel filtration. 7. Structures that account for these results are discussed.     

4-Chloroacetylpyridine adenine dinucleotide. A highly reactive and chromophoric affinity label of glyceraldehyde-3-phosphate dehydrogenase from sturgeon

The analogue of NAD+, 4-chloroacetylpyridine-adenine dinucleotide (clac4PdAD+), inactivated the glyceraldehyde-3-phosphate dehydrogenase from sturgeon at a high rate. An affinity labeling was shown to occur with clac4PdAD+. The mononucleotide 4-chloroacetylpyridine 1-beta-D-ribose 5'-phosphate (clac4PdMN+) reacted with the enzyme in a second-order reaction whose rate was much smaller than that calculated for clac4PdAD+ taken as a second-order rate reagent. The rate of the reaction of clac4PdAD+ with the enzyme was determined by stopped flow, using as a probe the long-wavelength absorption maximum (430 nm) formed concomitantly with inactivation of the enzyme. Computer-assisted graphic simulation showed that the clac4PdAD+ analogue could bind to the active site of the enzyme from Bacillus stearothermophilus in a similar manner to that of NAD+, and that the reactive carbon and the reactive thiolate of Cys-149 were within bonding distance. The absorption at 430 nm was linearly proportional to the substoichiometric concentration of clac4PdAD+/mole subunit. Thiol titration suggested the modification of one thiol residue per subunit. The modified thiol was identified by degradation as Cys-149. In contrast to the absorption band generated during the reaction of the 3-chloroacetylpyridine-adenine dinucleotide (clac3PdAD+) with the same enzyme [Eur. J. Biochem. (1982) 127, 519-524; 129, 437-446], enzyme inactivated with clac4PdAD+ and clac4PdMN+ exhibited an absorption maximum at long wavelength which was still present after denaturation. The chromophore is proposed to be the enol form of the alpha-thioether ketone produced by alkylation of the thiolate of Cys-149 by the chloroacetyl group.     

Radioactive labeling and location of specific thiol groups in myosin from fast, slow and cardiac muscles.

1. Based on incorporation of radioactively labeled N-ethylmaleimide, the readily reactive thiol groups of isolated myosin (EC 3.6.1.3) from fast, slow and cardiac muscles could be classified into 3 types. All 3 myosins contain 2 thiol-1, 2 thiol-2 and a variable number of thiol-3 groups per molecule. Both thiol-1 and thiol-2 groups which are essential for functioning of the K+-stimulated ATPase, are located in the heavy chains in all 3 myosin types. 2. The variation in the incorporation pattern of N-ethylmaleimide over the 3 thiol group classes under steady-state conditions of Mg(2+) - ATP hydrolysis allowed different conformations of some reaction intermediates to be characterized. In all 3 types of myosin the hydrolytic cycle of Mg(2+) - ATP was found to be controlled by the same step at 25 degrees C. In all three cases, this rate-limiting step is changed in the same way by lowereing temperature. 3. Using the chemically determined molecular weights for myosin light chains, their stoichiometry was found on the basis of sodium dodecyl sulfate electrophoresis to be 1.2 : 2.1 : 0.8 for light chain-1: light chain-2:light chain-3 per molecule of fast myosin, 2.0 : 1.9 for light chain-1:light chain-2 per molecule of slow myosin and 1.9 : 1.9 for light chain-1:light chain-2 per molecule of cardiac myosin. This qualitative difference in light subunit composition between the fast and the two types of slow myosin is not reflected in the small variations of the characteristics exhibited by the isolated myosins, but rather seems to be connected with their respective myofibrillar ATPase activities.     

Thiol modification as a probe of conformational forms of the F1 ATPase of Escherichia coli and of the structural asymmetry of its beta subunits

The sulfhydryl groups of soluble and membrane-bound F1 adenosine triphosphatase of Escherichia coli were modified by reaction with the fluorescent thiol reagents 5-iodoacetamidofluorescein, 2-[(4'-iodoacetamido)anilino]naphthalene-6-sulfonic acid 4-[N-(iodoacetoxy)ethyl-N-methyl]amino-7-nitrobenzo-2-oxa-1,3-d iaz ole and 2-[(4'-maleimidyl)anilino]naphthalene-6-sulfonic acid. Whereas gamma and delta subunits were always labeled by these reagents, the beta subunit reacted preferentially in the soluble enzyme, and the alpha subunit in the membrane-bound enzyme. This suggests that the soluble enzyme undergoes a conformational change on binding to the membrane. The three beta subunits of the soluble ATPase did not react with chemical reagents in a similar manner. One beta subunit was cross-linked to the epsilon subunit on treatment of the ATPase with 1-ethyl-3-[3-(dimethyl-amino)propyl]carbodiimide, as observed previously by L?tscher et al. [Biochemistry (1984) 23, 4134-4140]. A second beta subunit, which did not cross-link to the epsilon subunit, was modified preferentially by the fluorescent thiol reagents and by 4-chloro-7-nitrobenzo-2-oxa-1,3-diazole. The third beta subunit was less chemically reactive than the others. Both alpha and beta subunits of the soluble 4-chloro-7-nitrobenzo-2-oxa-1,3-diazole-modified enzyme were labeled by the fluorescent thiol reagents. Thus, the modified enzyme, which is inactive, probably has a different conformation from the native soluble ATPase.     

Characterization of 73 kDa thiol protease from Serratia marcescens and its effect on plasma proteins

The 73-kDa protease (73K protease) was purified from a clinical isolate of Serratia marcescens kums 3958. The purified protease appeared homogeneous by sodium dodecyl sulfate polyacrylamide gel electrophoresis in the presence or absence of 2-mercaptoethanol. The protease is active in a broad pH range with maximum activity at pH 7.5-8.0. The protease appeared to be a thiol protease, since it was inhibited by sulfhydryl reactive compounds such as p-chloromercuribenzoic acid, fluorescein mercuric acetate (FMA), iodoacetamide, and N-ethylmaleimide, and the protease activity was enhanced by various reducing agents such as cysteine, glutathione, 2-mercaptoethanol, and dithiothreitol. The protease contained 2 mol of free sulfhydryl residues per mol of protease. When the protease was reacted with FMA, a maximum of 2 mol of FMA per mol of enzyme was found reacted, based on fluorescence quenching in which the enzyme inactivation was paralleled linearly with the loss of both SH groups. This indicates possible equal involvement of the two thiol groups for the enzyme activity. The inactivation of the protease by FMA was partially restored by a dialysis in the presence of cysteine or dithiothreitol. The protease was not inhibited by high molecular weight kininogen but was inhibited by alpha 2-macroglobulin. The protease bound stoichiometrically to alpha 2-macroglobulin with 1:1 molar ratio and 25% activity remained constant even after the addition of 4 molar excess of alpha 2-macroglobulin. The protease extensively degraded IgG, IgA, fibronectin, fibrinogen, and alpha 1-protease inhibitor.(ABSTRACT TRUNCATED AT 250 WORDS)     

Reaction of fluorescein bimercuric acetate with a molybdenum center of xanthine oxidase from milk

Inhibition of milk xanthine oxidase by fluorescein bimercuriacetate (FMA) allows for the classification of S-containing groups according to their localization and role in the catalytic activity of the enzyme. The enzyme (E) complexes with FMA (E--FMA I and E--FMA II) differing in their activity, stoichiometry and spectral properties were studied at various experimental conditions, reaction time and FMA concentrations. The enzyme molecule contains 5 groups that are reactive towards FMA (E--FMA I) and are localized outside the active center. That these groups have no concern with activity and are subjected to modification irrespective of whether or not the xanthine oxidase molecule has an intact Mo-center. The formation of an inactive E--FMA II complex is associated with an additional (in comparison with E--FMA I) binding of two FMA molecules per molecule of the active enzyme. The stoichiometry of the E--FMA II complex was determined by the X-ray fluorescent method from the amount of the Hg in enzyme. A kinetic scheme of xanthine oxidase inhibition by FMA is proposed, according to which the inhibition is a result of modification of two groups in the enzyme active center, of which only one is essential for the enzyme activity. This scheme also postulates the role of reversible E--FMA complexes in the course of irreversible inhibition. Xanthine oxidase is protected against FMA by the substrate (xanthine), competitive inhibitors (azaxanthine and allopurinol) and acceptor (2,6-dichlorophenolindophenol), i. e., compounds which interact with the Mo-center of the enzyme. The EPR spectra of the dithionite-reduced E--FMA II complex were found to contain a "slow" signal, Mo(V), typical of the Mo-center devoid of labile sulphur. It was assumed that the essential group interacting with FMA in the active center of xanthine oxidase as a terminal sulphur which is a component of the coordination region of Mo.     

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.     

Nuclear-membrane-associated protein kinase and substrates. The effect of growth state on activity and specificity.

Reaction of rat muscle AMP deaminase with low molar excess of tetranitromethane results in a rapid loss of free thiol groups and a concomitant decrease in enzyme activity at high, but not at low, AMP concentration. This modification appears to be limited to the same non-essential thiol groups reactive towards specific reagents in non-denaturing conditions. On incubation with higher molar excess of tetranitromethane, a loss of enzyme activity is observed, which correlates with nitration of tyrosine residues. By amino acid analysis, approximately there tyrosine residues per subunit are estimated to be nitrated in the completely inactivated enzyme. The kinetic properties of the partially inactivated AMP deaminase reveal a negative co-operatively behaviour at approximately half saturation. This suggests that modification of tyrosine residues is also responsible for alteration of the binding properties of the hypothesized activating site of AMP deaminase.     

Preferential cross-linking of the small subunit of the electron-transfer flavoprotein to general acyl-CoA dehydrogenase.

The interaction between pig liver mitochondrial electron-transfer flavoprotein (ETF) and general acyl-CoA dehydrogenase (GAD) was investigated by means of the heterobifunctional reagent N-succinimidyl 3-(2-pyridyldithio)propionate. Neither ETF or GAD contained reactive thiol groups. The substitution of 9.4 lysine residues/FAD group in GAD with pyridyl disulphide structures did not affect the catalytic activity of the enzyme. Thiol groups were introduced into ETF by thiolation with methyl 4-mercaptobutyrimidate. ETF containing 10.5 reactive thiol groups/FAD group showed undiminished electron-acceptor activity with respect to GAD. The reaction of thiolated ETF and GAD containing pyridyl disulphide structures resulted in a decreased staining intensity of the small subunit of ETF on SDS/polyacrylamide-gel electrophoresis. Preferential cross-linking of the smaller subunit of ETF to GAD did not take place when ETF was first treated with SDS, but was unaffected by reduction of GAD by octanoyl-CoA.     

A convenient method of preparation of high-activity urease from Canavalia ensiformis by covalent chromatography and an investigation of its thiol groups with 2,2''-dipyridyl disulphide as a thiol titrant and reactivity probe.

1. A convenient method of preparation of jack-bean urease (EC3.5.1.5) involving covalent chromatography by thiol-disulphide interchange is described. 2. Urease thus prepared has specific activity comparable with the highest value yet reported (44.5 +/- 1.47 kat/kg, Km = 3.32 +/- 0.05 mM; kcat. = 2.15 X 10(4) +/- 0.05 X 10(4)s-1 at pH7.0 and 38 degrees C). 3. Titration of the urease thiol groups with 2,2'-dipyridyl disulphide (2-Py-S-S-2-Py) and application of the method of Tsou Chen-Lu [(1962) Sci. Sin. 11, 1535-1558] suggests that the urease molecule (assumed to have mol.wt. 483000 and epsilon280 = 2.84 X 10(5) litre-mol-1-cm-1) contains 24 inessential thiol groups of relatively high reactivity (class-I), six 'essential' thiol groups of low reactivity (class-II) and 54 buried thiol groups (class-III) which are exposed in 6M-guanidinium chloride. 4. The reaction of the class-I thiol groups with 2-Py-S-S-2-Py was studied in the pH range 6-11 at 25 degrees C(I = 0.1 mol/l) by stopped-flow spectrophotometry, and the analogous reaction of the class-II thiol groups by conventional spectrophotometry. 5. The class-I thiol groups consist of at least two sub-classes whose reactions with 2-Py-S-S-2-Py are characterized by (a) pKa = 9.1, k = 1.56 X 10(4)M-1-s-1 and (b) pKa = 8.1, k = 8.05 X 10(2)M-1-s-1 respectively. The reaction of the class-II thiol groups is characterized by pKa = 9.15 and k = 1.60 X 10(2)M-1-s-1. 6. At pH values 7-8 the class-I thiol groups consist of approx. 50% class-Ia groups and 50% class-Ib groups. The ratio class Ia/class Ib decreases an or equal to approx. 9.5, and at high pH the class-I thiol groups consist of at most 25% class-Ia groups and at least 75% class-Ib groups. 7. The reactivity of the class-II thiol groups towards 2-Py-S-S-2-Py is insensitive to the nature of the group used to block the class-I thiols. 8. All the 'essential' thiol groups in urease appear to be eeactive only as uncomplicated thiolate ions. The implications of this for the active-centre chemistry of urease relative to that of the thiol proteinases are discussed.     

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.     

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.     

Fluorescence labeling of the human erythrocyte anion transport system. Subunit structure studied with energy transfer

The anion transport system of human red cells was isolated in vesicles containing the original membrane lipids and the 95 000 dalton polypeptides (band 3) by the method of Wolosin et al. (J. Biol. Chem. (1977) 252, 2419–2427). The vesicles have a functional anion transport system since they display sulfate transport that is inhibited by the fluorescent probe 8-anilinonaphthalene 1-sulfonate (ANS) with similar potency as in red cells. The vesicles were labeled with the SH-specific probe fluorescein mercuric acetate (FMA). Labeling lowers FMA fluorescence, and is prevented or reversed by dithiothreitol, suggesting that the reaction is with a thiol group on the protein. Fluorescence titrations show a maximum labeling stoichiometry of 1.3 ± 0.4 mol FMA/mol 95 000 dalton polypeptide. The polarization of bound FMA fluorescence is high indicating that the probe is highly immobilized. Pretreatment with Cu²⁺ + o-phenanthroline under conditions that crosslink band 3 in ghosts decreases FMA labeling 50%. Differences in kinetics of FMA labeling in sealed and leaky vesicles suggest that the reactive SH group is located in the intravesicular portion of the protein (corresponding to the cytoplasmic surface of the red cell) and that FMA can cross the membrane. Inhibitors of anion transport have no effect on FMA labeling kinetics suggesting it is not transported via the anion     

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.     

Active-site modification of native and mutant forms of inosine 5′-monophosphate dehydrogenase from Escherichia coli K12

IMP dehydrogenase of Escherichia coli was irreversibly inactivated by Cl-IMP (6-chloro-9-beta-d-ribofuranosylpurine 5'-phosphate, 6-chloropurine ribotide). The inactivation reaction showed saturation kinetics. 6-Chloropurine riboside did not inactivate the enzyme. Inactivation by Cl-IMP was retarded by ligands that bind at the IMP-binding site. Their effectiveness was IMP>XMP>GMP>AMP. NAD(+) did not protect the enzyme from modification. Inactivation of IMP dehydrogenase was accompanied by a change in lambda(max.) of Cl-IMP from 263 to 290nm, indicating formation of a 6-alkylmercaptopurine nucleotide. The spectrum of 6-chloropurine riboside was not changed by IMP dehydrogenase. With excess Cl-IMP the increase in A(290) with time was first-order. Thus it appears that Cl-IMP reacts with only one species of thiol at the IMP-binding site of the enzyme: 2-3mol of Cl-IMP were bound per mol of IMP dehydrogenase tetramer. Of ten mutant enzymes from guaB strains, six reacted with Cl-IMP at a rate similar to that for the native enzyme. The interaction was retarded by IMP. None of the mutant enzymes reacted with 6-chloropurine riboside. 5,5'-Dithiobis-(2-nitrobenzoic acid), iodoacetate, iodoacetamide and methyl methanethiosulphonate also inactivated IMP dehydrogenase. Reduced glutathione re-activated the methanethiolated enzyme, and 2-mercaptoethanol re-activated the enzyme modified by Cl-IMP. IMP did not affect the rate of re-activation of methanethiolated enzyme. Protective modification indicates that Cl-IMP, methyl methanethiosulphonate and iodoacetamide react with the same thiol groups in the enzyme. This is also suggested by the low incorporation of iodo[(14)C]acetamide into Cl-IMP-modified enzyme. Hydrolysis of enzyme inactivated by iodo[(14)C]acetamide revealed radioactivity only in S-carboxymethylcysteine. The use of Cl-IMP as a probe for the IMP-binding site of enzymes from guaB mutants is discussed, together with the possible function of the essential thiol groups.     

Dihydroorotase from Escherichia coli. Sulfhydryl group-metal ion interactions

We have obtained 53 mg of 99% pure dihydroorotase from 10.9 g of frozen Escherichia coli pyrC plasmid-containing E. coli cells using a 4-step 16-fold purification procedure, a yield of 60%. We characterize the enzyme by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (a dimer of subunit molecular weight 38,300 +/- 2,900), high performance liquid chromatography gel sieving, amino acid analysis, amino terminus determination (blocked), and specific activity. The isolated enzyme contains 1 tightly bound essential zinc atom/subunit, and readily but loosely binds 2 additional Zn(II) or Co(II) ions/subunit which modulate catalytic activity; treatment of crude extracts with weak chelators suggests that the enzyme contains 3 zinc atoms/subunit in vivo. Two of the 6 thiol groups/subunit react rapidly with 5,5'-dithiobis(2-nitrobenzoate) when 1 Zn/subunit enzyme is used, but slowly when 3 Zn/subunit enzyme is used. The 2 weakly bound Zn(II) ions/subunit protect against the reversible air oxidation which lowers the specific activity of the enzyme and renders it unreactive with 5,5'-dithiobis(2-nitrobenzoate). The dilution activation observed in the presence of substrate, the dilution inactivation observed in the absence of substrate, and the transient activation by the metal chelator oxalate are interpreted as evidence for an unstable, hyperactive monomer.