Free thiols of platelet thrombospondin. Evidence for disulfide isomerization

The free thiols of platelet thrombospondin (TSP) were derivatized with labeled N-ethylmaleimide (NEM) or iodoacetamide (IAM). When Ca2+ was chelated with EDTA, 2.9 mol of NEM or 2.6 mol of IAM reacted/mol of native TSP. No additional thiols were found after denaturation with urea. Since TSP has three apparently identical polypeptide chains, this suggests one free thiol/polypeptide chain. Ca2+ protected all of the thiols from reaction with IAM. In Ca2+ about half the thiols reacted normally with NEM and the others were unreactive, indicating that the thiols of TSP are not identical. The number of reactive thiols as a function of [Ca2+] revealed a sigmoidal curve with a transition midpoint of 207 microM. The ability of analogs of NEM to compete for derivatization of the thiols with labeled NEM was greater with larger, more hydrophobic agents. Gel electrophoretic separation of labeled TSP that had been partially digested with thrombin and trypsin indicated that some of the label was in the C-terminal tryptic fragment but that most was in the adjacent trypsin-sensitive region. After cyanogen bromide cleavage of the labeled and reduced protein, four labeled fractions were obtained from a gel filtration column. With subsequent combinations of tryptic digestion and reversed-phase high performance liquid chromatography, labeled peptides were purified from these four fractions, and the amino acid sequences were determined. Twelve labeled cysteines were identified, each with a specific radioactivity less than that of the thiol labeling reagent, indicating that only a fraction of that cysteine in a population of TSP molecules was a free thiol at the time of derivatization. While 2 labeled cysteines are in the non-repeating C-terminal portion of the molecule, the other 10 labeled cysteines are in the adjacent trypsin-sensitive type 3 repeats proposed (Lawler, J., and Hynes, R. O. (1986) J. Cell. Biol. 103, 1635-1648) as the calcium-binding region of the molecule. The disulfide bonds most sensitive to reduction by dithioerythritol were also stabilized by Ca2+, implying location in the Ca2(+)-sensitive part of the molecule. It is proposed that one equivalent of free thiol/polypeptide chain is distributed among 12 different cysteine residues through an intramolecular thioldisulfide isomerization.     

Molecular basis of superreactivity of cysteine residues 31 and 32 of seminal ribonuclease

The molecular basis of the high reactivity toward reducing agents of intersubunit disulfides at positions 31 and 32 of dimeric bovine seminal ribonuclease was investigated by studying in the monomeric enzyme the fast reaction kinetics with disulfides of the adjacent cysteine-31 and -32, exposed by selective reduction of the intersubunit disulfides. Negatively charged and neutral disulfide reagents were used for measuring the thiol reaction rates at neutral pH. The kinetics studied as a function of pH permitted us to define pK values for the thiols of interest and indicated the possibility of determining pK values of SH groups in proteins indirectly by measuring the kinetics of reactivity of the SH groups with a disulfide reagent. The results were compared with those obtained under identical conditions with synthetic thiol peptides and model compounds. The data indicate that the superreactivity of intersubunit disulfides of seminal ribonuclease is matched by the high reactivity at neutral pH of adjacent cysteine residues 31 and 32, as compared to all small thiol compounds tested. The synthetic hexapeptide segment of seminal ribonuclease Ac-Met-Cys-Cys-Arg-Lys-Met-OH, which includes the two cysteine residues of interest, was even more reactive. These data, and the other results reported in this paper, led to the conclusion that the superreactivity at neutral pH of cysteine residues at positions 31 and 32 of bovine seminal ribonuclease is primarily dependent on the nearby presence of positively charged groups, particularly the epsilon-NH2 of lysine-34, and is influenced by the adjacency of the two thiols and by the protein tertiary structure.     

Reaction of ribosomal sulfhydryl groups with 5,5'-dithiobis(2-nitrobenzoic acid)

The number of sulfhydryl groups in the Escherichia coli ribosome has been measured by titration with 5,5′-dithiobis(2-nitrobenzoic acid). Under denaturing conditions, there are 38.8 ± 1.0 titratable thiols per 70 S ribosome and 22.8 ± 0.3 and 12.9 ± 0.3 titratable thiols per 50 S and 30 S subunits, respectively. Three categories of thiol groups can be distinguished in the native 70 S ribosome, a “fast reacting” class of about 3 residues, a “slow reacting” class of about 10 residues and a “buried” class including about 26 residues. The addition of polyuridylic acid to reaction mixtures protects a fast-reacting thiol in the 30 S subunit belonging to protein S1.The addition of urea to ribosome solutions makes the buried residues titratable. Denaturation occurs as a sharp transition at a urea concentration between 4 and 4.5 m. Urea does not fully dissociate the ribosome into RNA and protein. Instead, in the case of the 30 S subunit, a slowly sedimenting particle forms in the presence of urea, containing roughly 65% of the normal amount of protein.     

Thiol groups of Escherichia coli citrate synthase and their influence on activity and regulation.

The modification of Escherichia coli citrate synthase (citrate oxaloacetatelyase(pro-3S-CH2.COO- leads to acetyl-CoA, EC 4.1.3.7) with 5,5'-dithiobis-(2-nitrobenzoic acid) has been investigated. (1) In low ionic strength (20 mM Tris.HCl, pH 8.0): (A) Eight thiol groups per tetramer of the native enzyme reacted with Nbs2. (b) Two of the eight accessible thiols were modified rapidly with the loss of 26% enzyme activity but with no change in the NADH inhibition. The remaining six were modified more slowly, resulting in a further 60% loss of activity and complete densensitization to NADH. (c) The 2nd-order rate constant for the modification of the rapidly reacting thiols is 2.5.10(4) M-1.min-1. At the reagent concentrations used (0.1 to 0.2 mM) the modification of the six thiols in the slow kinetic set appeared to be 1st-order; at 0.1 mM dithionitrobenzoic acid their rate of modification was approximately 30 times slower than the thiols in the fast kinetic set. (2) In high ionic strength (20 mM Tris.HCl, pH 8.0, 0.1 M KCl): (a) Four thiol groups were modified in a single kinetic set and it appeared that these thiols are four of the six slowly modified in the absence of KCl. (b) The modification resulted in 70% loss of enzyme activity and complete loss of NADH inhibition. (3) From the kinetic analysis it is proposed that the four thiol groups accessible to dithionitrobenzoic acid in the absence and presence of 0.1 M KCl are those involved in the response of NADH. Modification of any one of these four groups produced no reduction in the inhibition; instead, loss of NADH sensitivity was coincident with the appearance of tetrameric protein possessing three substituted thiols, whereas enzyme with one or two modified groups was still fully inhibited by NADH.     

Effect of pH and KCl on aggregation state and sulphydryl groups reactivity of rat skeletal muscle AMP deaminase

The effects of pH and KCl on sedimentation properties and SH groups reactivity of rat skeletal muscle AMP deaminase have been investigated. The values obtained for apparent molecular weight are consistent with an association of AMP deaminase subunits in response to increasing KCl concentration. Increasing pH value from 6.0 to 8.0 causes a reduction in the apparent molecular weight of the enzyme at high KCl concentration, which can be interpreted as due to a deprotonation-induced isomerization process. Removal of Zn2+ from AMP deaminase has effect similar to alkalinization in modifying the sedimentation properties of the enzyme. In the native enzyme at high K+ concentration about 7, 9 and 12 SH groups can be titrated with Nbs2, approximately 1, 2 and 4 SH groups reacting as fast sets, at pH 6.0, 7.0 and 8.0, respectively. Substitution of the 12 SH groups reactive with Nbs2 at pH 8.0 has no effect on the pH-dependent allosteric behaviour of the enzyme. Removal of K+ causes considerable changes in the reactivity of AMP deaminase towards Nbs2, unmasking a class of additional SH groups, so that the total number of titratable SH groups approaches that of 30 determined in denaturing conditions. In the enzyme previously treated with N-ethylmaleimide to alkylate the fast reacting class of SH groups, the class of additional SH groups are substituted by Nbs2 at basic pH, but not at acidic pH, with a concomitant reduction of the enzyme activity.     

The phosphate group of 3-phosphoglycerate accounts for conformational changes occurring on binding to 3-phosphoglycerate kinase. Enzyme inhibition and thiol reactivity studies

Steady-state kinetic study of the inhibition of 3-phosphoglycerate kinase reaction by the substrate analogues D-glycerol 3-phosphate, 2-phosphoglycolate, tartronate and malonate revealed competition with respect to 3-phosphoglycerate. D-Glycerate had no detectable inhibitory effect. The data indicate that (a) the phosphate of 3-phosphoglycerate plays an essential role in the formation of its complex with the enzyme and, taking into account the relatively strong binding of 3-phosphoglycerate, (b) the two charged groups of the substrate might cause a synergic interaction with the protein. The carboxyl-lacking D-glycerol 3-phosphate is a non-competitive inhibitor with respect to MgATP, while all the investigated carboxyl-containing inhibitors compete for MgATP binding. The inhibitory analogues of 3-phosphoglycerate reduce the reactivity of both the two fast-reacting and the five slow-reacting thiol groups of the enzyme molecule. In the case of the fast-reacting thiols the effect is specifically associated with the presence of a ligand's phosphate group. Similarly mainly the phosphate-containing nucleotides and analogues slow down significantly the reaction rate of the fast-reacting thiols, while adenosine is less effective and the competitive inhibitor adenine has no effect at all. MgADP has an especially dramatic effect as compared to MgATP, in line with the known X-ray structural data. The fast-reacting thiols are of particular interest, since their reactivity is possibly controlled by ligand-induced conformational changes. This is shown by the similar ligand protection against alkylation irrespective of the reagent's electrostatic charge (iodoacetamide or iodoacetate) and also by the similar substrate-binding properties of carboxamidomethylated and the unmodified enzyme.     

Phosphorylase b covalently bound to glycogen: properties of the complex

Rabbit skeletal muscle glycogen phosphorylase b was covalently bound to oyster glycogen by means of cyanogen bromide. Removal of the unbound enzyme was achieved, using DEAE-Sephadex A-50 chromatography. Glycogen-bound phosphorylase b showed a higher affinity toward glucose 1-phosphate but a lower homotropic cooperativity, with respect to AMP activation, than the native enzyme. However, at low AMP concentrations conjugated phosphorylase b was as efficient as the free enzyme. It is of interest that glycogen-bound phosphorylase b exhibited catalytic activity upon its polysaccharide carrier. Kinetics of heat and cold inactivation indicated that the bound enzyme was considerably more resistant toward heat inactivation but less stable upon exposure to cold. It was shown also that both conjugated and native enzymes had identical pH optima, similar activity/temperature dependencies and the same resistance against trypsin inactivation.     

Defining the "fast-reacting" thiols of myosin by reaction with 1, 5 IAEDANS.

The specificity of the fluorescent reagent N-iodoacetyl-N-(5-sulfo-1-naphthyl)ethylenediamine (1,5 IAEDANS) for a specific thiol group of myosin has been characterized by a comparison with iodoacetamide (IAA) and by observing maximal enhancement of the Ca²⁺-ATPase activity and inhibition of the K⁺-EDTA-ATPase activity of myosin. The stoichiometry of the [³H]1,5 IAEDANS bound to myosin indicates the presence of two fast-reacting thiols which correspond to the “SH₁” groups responsible for the catalytic properties of myosin. Moreover, it has been unequivocally demonstrated by gel electrophoresis that the fast-reacting thiol is located on the myosin heavy chain. A single radioactivity-labeled thiol peptide obtained from tryptic digests of myosin labeled with [³H]1,5 IAEDANS or iodo[1-¹⁴C]acetamide indicates strongly that the identical thiol was labeled by both reagents.     

The presence of reactive SH groups in the enzymatically active dicyano derivative of creatine kinase

It has been shown that the active dicyano derivative of creatine kinase (ATP:creatine N-phosphotransferase) obtained by cyanolysis of the 5,5'-dithiobis(2-nitrobenzoic acid)-modified and inactivated enzyme contains, as does the native enzyme, two reactive SH groups. Modification of these two SH groups leads to complete inactivation of the dicyano enzyme. Reaction with 4-iodoacetamido-1-naphthol introduces fluorescent labels at these reactive SH groups of the native and the dicyano enzymes. Following tryptic digestion, the respective fluorescent-labelled peptides have been separated by HPLC and the amino acid composition analysis of these peptides has shown that they are consistent with the sequence of the peptide segment containing the active-site SH of Cys-282 of creatine kinase for both the native and the dicyano enzymes, showing that the active SH groups are free in the dicyano enzyme. Upon mild denaturation in 3 M urea, it can be shown that two of the SH groups partially buried in the native enzyme have been cyanylated in the dicyano enzyme. The two reactive SH groups are therefore essential for the activity of creatine kinase and the two cyanylated SH groups are internal groups which probably contributes partially to the stabilization of an active conformation of the enzyme molecule.     

The two fast-reacting thiols of 3-phosphoglycerate kinase are structurally juxtaposed. Chemical modification with bifunctional reagents

The two fast-reacting thiol groups of pig muscle 3-phosphoglycerate kinase can be simultaneously blocked by one mole equivalent of bifunctional reagent: either mercuric chloride (HgCl2) or 1,4-bis(bromomercuri)butane. The reactions are accompanied by an enzyme activity loss of about 50-70% and 60-80% with mercuric chloride and 1,4-bis(bromomercuri)butane respectively. Removal of either of the reagents with excess cysteine leads to the recovery of at least 70-90% of the original enzymic activity. Gel chromatographic analysis revealed no change in the molecular mass of the enzyme modified with mercuric chloride, while an increase of about 30% of the apparent molecular mass was observed after the reaction with 1,4-bis(bromomercuri)butane. Since no dimer formation could be detected by independent crosslinking, the increase of the apparent molecular mass is probably due to modification causing protein conformational change. The results strongly suggest that the fast-reacting thiols are intramolecularly connected by either of the above bifunctional reagents. In the light of the known structural data on the enzyme, it may follow that the two fast-reacting thiols belong to the two sequentially neighbouring cysteinyl residues.     

Histidine decarboxylase of Lactobacillus 30a: function and reactivity of sulfhydryl groups.

Two classes of sulfhydryl groups in histidine decarboxylase from Lactobacillus 30 a can be differentiated by their reaction with 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB). Five cysteinyl residues (class I) of the native enzyme are titrated by DTNB as the pH of the reaction medium is increased from 6.5 to 7.5; the pH-rate profile for their reaction is described by a pKa of 9.2. An additional five thiol groups (class II) are titrated only when denaturing agents are added above neutral pH. Histidine decarboxylase is completely inactivated by DTNB in a kinetically second-order process (Kapp = 660 +/- 20 M-1 min-1 at pH 7.6 and 25 degrees C) which occurs coincident with and at the same rate as modification of the five class-I SH groups of the enzyme, i.e., one thiol group per pyruvoyl prosthetic group. The competitive inhibitors, histamine and imidazole, markedly enhanced the reactivity of these cysteinyl residues toward DTNB; this enhancement is accompanied by a concomitant increase in the rate of inactivation. A single SH group in each of the five catalytic units of histidine decarboxylase is thus implicated as being critical for the expression of enzymatic activity.     

Thiol- and pH-modulated slow conformational changes and cooperativity of phenol-binding sites in phenol hydroxylase

Spectrophotometric titration of phenol hydroxylase (EC 1.14.13.7) with phenol indicated interacting sites for phenol binding. In the absence of added thiol, the cooperativity was positive up to a pH around 8.0 but negative at higher pH values. With added thiol-ethylenediaminetetraacetate, the cooperativity was negative at all investigated pH values. Conversely, a corresponding titration of an enzyme preparation that had been selectively modified in its two most reactive SH groups indicated positive cooperativity at all studied pH values. This selective modification affects the activity of the enzyme to a very minor degree, in contrast to more extensive SH blocking, which displaces flavin adenine dinucleotide with a corresponding loss of activity [Neujahr, H. Y., & Gaal, A. (1975) Eur. J. Biochem. 58, 351-357]. The reactivity of SH groups in the enzyme was significantly decreased after turnover. Thiol treatment restored it to that of the native enzyme. Adding phenol prior to reduced nicotinamide adenine dinucleotide phosphate (NADPH) in the assay of phenol hydroxylase gave immediate linearity and higher initial rates than when NADPH was added first. In the absence of added thiol, there was then a shift of the pH optimum. The results indicate slow conformational changes limiting the rate of the overall reaction. The two most reactive SH groups of phenol hydroxylase, though not participating in any obvious redox reactions, are important for these slow conformational changes and for the cooperativity of phenol-binding sites, wherein the anionic S- forms may be involved (pKa for cysteine is 8.35).     

Characterisation in vivo of the reactive thiol groups of the lactose permease from Escherichia coli and a mutant; exposure, reactivity and the effects of substrate binding

The reactivity and accessibility of the reactive thiol groups of the native lactose permease and a mutant have been studied in a number of circumstances and with a number of reagents, in particular using the specific thiol-disulphide exchange reaction. Seven different reactive states of the thiol in the native protein have been characterised by their different second-order rate constants. Interconversion between these states is dependent on the magnitude of the protonmotive force, pH and substrate binding. In the absence of galactoside, reactivity is controlled by an ionisation with apparent pKa 9.3. This pKa is not affected by the protonmotive force, but it is lowered in the presence of external galactoside. The conformation adopted by the permease when in equilibrium with saturating galactoside appears to be different from that of the intermediate that accumulates during net turnover. In the former state, the reactivity of the thiol group is depressed, whereas in the latter state it is enhanced. The thiol group of the native protein is buried in a hydrophobic environment that has a dielectric constant considerably lower than that of water. The environment is not greatly perturbed by changes in the magnitude of the protonmotive force, but it is affected by the binding of galactoside. In a strain which carries the YUN mutation (Wilson, T.H. and Kusch, M. (1972) Biochim. Biophys. Acta 255, 786-797), two reactive thiols were characterised. The more reactive of the two is more exposed than the thiol group of the native molecule and is in an environment that has a dielectric constant close to that of water. The less reactive thiol appears to be more deeply buried than that of the native protein. Thus the mutation appears to produce a conformation change in the central portion of the polypeptide chain that results in greater exposure of the reactive thiol to the aqueous environment.     

Identification of the essential cysteine residue in Klebsiella aerogenes urease.

During reaction with [14C]iodoacetamide at pH 6.3, radioactivity was incorporated primarily into a single Klebsiella aerogenes urease peptide concomitant with activity loss. This peptide was protected from modification at pH 6.3 by inclusion of phosphate, a competitive inhibitor of urease, which also protected the enzyme from inactivation. At pH 8.5, several peptides were alkylated; however, modification of one peptide, identical to that modified at pH 6.3, paralleled activity loss. The N-terminal amino acid sequence and composition of the peptide containing the essential thiol was determined. Previous enzyme inactivation studies of K. aerogenes urease could not distinguish whether one or two essential thiols were present per active site (Todd, M. J., and Hausinger, R. P. (1991) J. Biol. Chem. 266, 10260-10267); we conclude that there is a single essential thiol present and identify this residue as Cys319 in the large subunit of the heteropolymeric enzyme.     

Effects of cyclic nucleotides on the conformational states of the alpha core of the cyclic AMP receptor protein.

The alpha core gragment produced by limited proteolysis contains the cyclic AMP binding domain and the two buried sulfhydryl groups of the cyclic AMP receptor protein. The buried sulfhydryl groups of the alpha core react with 5,5'-dithio-bis(2-nitrobenzoic acid) after denaturation by 3 M urea or digestion with subtilisin. The rate of sulfhydryl modification in the presence of 3 M urea or subtilisin is markedly decreased in the presence of cyclic nucleotides which are proposed to tighten the conformation of the alpha core. Incubation of the alpha core in 3 M urea or dithionitrobenzoic acid does not affect cyclic AMP binding while dithionitrobenzoic acid plus 3 M urea inhibits cyclic AMP binding suggesting a role for the buried sulfhydryls in cyclic AMP binding or their proximity to the cyclic AMP binding domain of the alpha core. The data are consistent with a ligand-induced conformational change in the alpha region of the native cyclic AMP receptor protein that is required for DNA binding.     

Modification of alpha-crystallin subunit chains and formation of alpha-neoprotein molecules: role of SH groups

Immunoadsorbents with bound antibodies restricted to determinants dependent on alpha-crystallin's quaternary structure permitted the fractionation of the population of 125I-labeled alpha-crystallin molecules, treated by iodoacetic acid, into molecules in which the native structure was still preserved and molecules with a completely different quaternary structure than the native protein. Parallel experiments with [14C]iodoacetic acid yielded information on the percentage of blocked SH groups in each of the above two fractions. The presence of molecules formed by A with B-chain association was established by sequential binding first to an immunoadsorbent with antibodies restricted to determinants located on alpha-crystallin's A-subunit chains as ligand and second, after desorption, to an immunoadsorbent with antibodies to B chains as ligand. With the aid of these techniques, it was established that (i) The modified alpha-crystallin molecules with quaternary determinants of the native protein contained a maximum of 23% blocked SH groups, indicating that the carboxymethylation involved only the fast-reacting surface SH groups. (ii) The modified alpha-crystallin molecules without the native protein's quaternary structure were built by a different association between A and B subunits than in alpha-crystallin, indicating formation of alpha-neoprotein molecules. (iii) Monomeric A chains with all SH groups carboxymethylated, and monomeric B chains in a ratio of 1A:5B, 2A:1B, and 5A:1B in urea solution, associate on dialysis, forming alpha-neoprotein molecules.     

Partial amino acid sequences around sulfhydryl groups of soybean beta-amylase

Sulfhydryl (SH) groups of soybean beta-amylase were modified with 5-(iodoaceto-amidoethyl)aminonaphthalene-1-sulfonate (IAEDANS) and the SH-containing peptides exhibiting fluorescence were purified after chymotryptic digestion of the modified enzyme. The sequence analysis of the peptides derived from the modification of all SH groups in the denatured enzyme revealed the existence of six SH groups, in contrast to five reported previously. One of them was found to have extremely low reactivity toward SH-reagents without reduction. In the native state, IAEDANS reacted with 2 mol of SH groups per mol of the enzyme (SH1 and SH2) accompanied with inactivation of the enzyme owing to the modification of SH2 located near the active site of this enzyme. The selective modification of SH2 with IAEDANS was attained after the blocking of SH1 with 5,5'-dithiobis-(2-nitrobenzoic acid). The amino acid sequences of the peptides containing SH1 and SH2 were determined to be Cys-Ala-Asn-Pro-Gln and His-Gln-Cys-Gly-Gly-Asn-Val-Gly-Asp-Ile-Val-Asn-Ile-Pro-Ile-Pro-Gln-Trp, respectively.     

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 free sulfhydryl groups and disulfide bonds in Na+,K+-ATPase

The content of free SH groups and disulfide bonds in the purified pig kidney Na+,K+-ATPase was determined by ammetric titration with silver nitrate. In the native enzyme, most of the free SH groups are masked due to their location in the polypeptide chain regions poorly accessible to SH reagents. Denaturation with 5% SDS and 8 M urea makes these regions accessible thus revealing 22 free SH groups/mol of the protein. After complete blocking of free SH groups with silver ions, 8 SH groups/mol of the protein are being released upon sulfitolysis which indicates the presence of four disulfide bonds in the enzyme. At least one disulfide bridge is located in the alpha-subunit whereas the beta-subunit contains three disulfide bonds.     

The non-flavin redox center of the streptococcal NADH peroxidase. I. Thiol reactivity and redox behavior in the presence of urea

Unlike the 2-electron-reduced (EH2) forms of the flavoprotein disulfide reductases and mercuric reductase, the native EH2 form of the streptococcal NADH peroxidase is quite refractile toward chemical modification with thiol-specific reagents. In the presence of 1.3 M urea, however, the single thiol of the reduced enzyme reacts with phenylmercuric acetate with a t1/2 of 3 min. This modification abolishes the charge-transfer absorbance band at 540 nm and inactivates the enzyme; the latter effect is shown to be reversed with dithiothreitol. Alkylation of the streptococcal peroxidase with iodo[1-14C]acetamide under reducing conditions in the presence of 8 M guanidine hydrochloride allows the isolation of a single labeled tryptic peptide with the sequence: Gly-Asp-Phe-Ile-Ser-Phe-Leu-Ser-C*ys-Gly-Met-Gln-Leu-Tyr-Leu- Glu-Gly-Lys. This sequence is identical to that previously reported (Poole, L. B., and Claiborne, A. (1988) Biochem. Biophys. Res. Commun. 153, 261-266) for the cysteinyl peptide isolated from the NADH peroxidase labeled metabolically with [35S]cysteine. Careful examination of the physical properties of the streptococcal peroxidase in the presence of 1.3 M urea shows that, while catalytic activity and native structural features are largely retained, the relative potentials of flavin and non-flavin redox centers are dramatically affected. We propose that low concentrations of urea stabilize an intermediate state in the transition between native and denatured forms, which is responsible for the observed changes in both active-site thiol reactivity and in redox properties.