Chemical modification of NADPH-cytochrome P-450 reductase. Presence of a lysine residue in the rat hepatic enzyme as the recognition site of 2'-phosphate moiety of the cofactor

Chemical modification of rat hepatic NADPH-cytochrome P-450 reductase by sodium 2,4,6-trinitrobenzenesulfonate (TNBS) resulted in a time-dependent loss of the reducing activity for cytochrome c. The inactivation exhibited pseudo-first-order kinetics with a reaction order approximately one, and a second-order constant of 4.8 min-1 X M-1. The reducing activities for 2,6-dichloroindophenol and K3Fe(CN)6 were also decreased by TNBS. Almost complete protection of the NADPH-cytochrome P-450 reductase from inactivation by TNBS was achieved by NADP(H), while partial protection was obtained with a high concentration of NADH. NAD, FAD and FMN showed no effect against the inactivation. 3-Acetylpyridine-adenine dinucleotide phosphate, adenosine 2',5'-bisphosphate and 2'AMP protected the enzyme against the chemical modification. Stoichiometric studies showed that the complete inactivation was caused by modification of three lysine residues per molecule of the enzyme. But, under the conditions where the inactivation was almost protected by NADPH, two lysine residues were modified. From those results, we propose that one residue of lysine is located at the binding site of the 2'-phosphate group on the adenosine ribose of NADP(H), and plays an essential role in the catalytic function of the NADPH-cytochrome P-450 reductase.     

Modification of histidine 56 in adrenodoxin with diethyl pyrocarbonate inhibited the interaction with cytochrome P-450scc and adrenodoxin reductase

Three histidine residues of bovine adrenodoxin, His-10, His-56, and His-62, were modified with diethyl pyrocarbonate. The order of the modification among the three histidines were monitored by measuring the proton NMR spectra. The modified adrenodoxin exhibited reduced affinity for adrenodoxin reductase as determined in cytochrome c reductase activity. In the presence of cholesterol, the modified adrenodoxin induced a high spin form of cytochrome P-450scc on complex formation in the same manner as native adrenodoxin. The spectral titration showed that adrenodoxin modified with diethyl pyrocarbonate exhibited a 5-fold higher Kd value than that of native adrenodoxin. These effects of the modification of adrenodoxin on the affinities for the redox partners were not proportional to the number of modified histidines determined by the optical absorbance change at 240 nm. Modification of adrenodoxin up to 2 histidine residues did not affect the affinity for the redox partners, but further modification on the third one resulted in an increase of apparent Km in cytochrome c reductase activity by 2-fold and of Kd for cytochrome P-450scc by 5-fold. The 1H NMR spectra of the modified adrenodoxin unequivocally demonstrated that histidine residues at His-10 and His-62 reacted more readily with diethyl pyrocarbonate than His-56 did, indicating that modification of His-56 was responsible for the reduction of binding affinities of adrenodoxin for redox partners. These results are consistent with the proposal that the residue of His-56 in adrenodoxin has an essential role in the electron transfer mechanism where adrenodoxin functions as a mobile shuttle.     

Chemical modification of cyclomaltodextrin glucanotransferase from Bacillus circulans var. alkalophilus.

Counting of integral numbers of cysteine residues of the reduced and denaturated form of cyclomaltodextrin glucanotransferase (CGTase) from Bacillus circulans var. alkalophilus (ATCC 21783) showed two cysteine residues per enzyme molecule. Titrations of the enzyme with 5,5'-dithiobis-(2-nitrobenzoic acid) led to the same result. No free SH-group was detected in denatured form of CGTase, indicating that the two cysteine residues are linked by one disulfide bridge. Cyclizing activity of the GdmCl-denaturated and reduced enzyme was 13% of that of the native one. Incubation of CGTase with diethylpyrocarbonate (DEP) showed a pseudo-first-order inhibition with second-order rate constant of 3.2 M-1 s-1. Reaction with hydroxylamine and spectroscopic studies implied that inactivation of CGTase by DEP is due to modification of one histidine residue concomitantly with a 50% decrease in the cyclizing activity (t1/2 = 10.8 min). The inhibition was partially reversible. CGTase was protected against inactivation by alpha- and beta-cyclodextrins suggesting that the modified histidine residue is at or near the active site. Conversion of starch with DEP-modified enzyme resulted in a decreased formation of cyclodextrins while the relative amount of reducing sugars increased. Preliminary results on modification of CGTase with other reagents, e.g., Woodward's reagent K, 2,3-butanedione and carbodiimide are included.     

Chemical modifications of tyrosyl residue(s) and action of human-fibroblast interferon

Partially purified and purified human fibroblastoid interferon were iodinated and nitrated under experimental conditions in which the most likely amino acyl residue modified was tyrosine(s). The modification resulted in a loss of human interferon activity suggesting that tyrosyl residue(s) is associated with the antiviral action of human interferon.     

Modification of API-2c and Its Reactive Site

The inhibitory activity of API-2c was reduced by carboxymethylation of methionine residues but not by chemical modifications of lysine and arginine residues. This indicates that API-2c requires methionine residue for inhibitory activity. Dissociation of API-2c-subtilisin BPN′ complex under mild conditions (pH-gradient dialysis) resulted in the conversion of API-2c to modified form (API-2C*).

The amino acid composition of API-2c did not change upon enzymatic modification. However, modified API-2c had two NH₂-terminal sequences (Asp-Ser-Pro- and Ile-Tyr-Asp-) and two COOH-termini (Phe and Met), and gave two bands on SDS-polyacrylamide gel disc electrophoresis after reduction of disulfide bonds by 2-mercaptoethanol. From these results, it is concluded that the Met-Ile bond located within a disulfide bridge in API-2c molecule is the reactive site for inhibition of subtilisin BPN′.     

NAD-, NMN-, and NADP-dependent modification of dinitrogenase reductases from Rhodospirillum rubrum and Azotobacter vinelandii

Nitrogenase activity in the photosynthetic bacterium Rhodospirillum rubrum is reversibly regulated by ADP-ribosylation of a specific arginine residue of dinitrogenase reductase based on the cellular nitrogen or energy status. In this paper, we have investigated the ability of nicotinamide adenine dinucleotide, NAD (the physiological ADP-ribose donor), and its analogs to support covalent modification of dinitrogenase reductase in vitro. R. rubrum dinitrogenase reductase can be modified by DRAT in the presence of 2 mM NAD, but not with 2 mM nicotinamide mononucleotide (NMN) or nicotinamide adenine dinucleotide phosphate (NADP). We also found that the apo- and the all-ferrous forms of R. rubrum dinitrogenase reductase are not substrates for covalent modification. In contrast, Azotobacter vinelandii dinitrogenase reductase can be modified by the dinitrogenase reductase ADP-ribosyl transferase (DRAT) in vitro in the presence of either 2 mM NAD, NMN or NADP as nucleotide donors. We found that: (1) a simple ribose sugar in the modification site of the A. vinelandii dinitrogenase reductase is sufficient to inactivate the enzyme, (2) phosphoADP-ribose is the modifying unit in the NADP-modified enzyme, and (3) the NMN-modified enzyme carries two ribose-phosphate units in one modification site. This is the first report of NADP- or NMN-dependent modification of a target protein by an ADP-ribosyl transferase.     

Tyrosyl Residue at or Near the Active Site of Maize NADP-malic Enzyme

Incubation of maize NADP-malic enzyme with tetranitromethane (TNM) resulted in a total loss of enzyme activity. The loss of enzyme activity was not observed at pH 6.3 but at pH 8.0. NADP-malic enzyme was inactivated to almost 90 % by incubation with an 80-fold molar excess of TNM for 5 min at 30 °C. The substrate malate or Mg²⁺ alone gave no protection, while NADP provided considerable protection. NADP in the presence of malate and Mg²⁺ totally protected the enzyme activity, suggesting that tyrosine residue may be located at or near the active site of maize NADP-malic enzyme. The spectral analysis of the modified enzyme indicated that modification of at least one tyrosine residue per subunit resulted in complete loss of the enzyme activity. The fluorescence study of unmodified and modified enzymes postulated that essential tyrosine residue at maize NADP-malic enzyme is possibly involved in malate binding. This revised version was published online in September 2006 with corrections to the Cover Date.     

Computational, spectroscopic, and resonant mirror biosensor analysis of the interaction of adrenodoxin with native and tryptophan-modified NADPH-adrenodoxin reductase

In steroid hydroxylation system in adrenal cortex mitochondria, NADPH-adrenodoxin reductase (AR) and adrenodoxin (Adx) form a short electron-transport chain that transfers electrons from NADPH to cytochromes P-450 through FAD in AR and [2Fe-2S] cluster in Adx. The formation of [AR/Adx] complex is essential for the electron transfer mechanism in which previous studies suggested that AR tryptophan (Trp) residue(s) might be implicated. In this study, we modified AR Trps by N-bromosuccinimide (NBS) and studied AR binding to Adx by a resonant mirror biosensor. Chemical modification of tryptophans caused inhibition of electron transport. The modified protein (AR*) retained the native secondary structure but showed a lower affinity towards Adx with respect to AR. Activity measurements and fluorescence data indicated that one Trp residue of AR may be involved in the electron transferring activity of the protein. Computational analysis of AR and [AR/Adx] complex structures suggested that Trp193 and Trp420 are the residues with the highest probability to undergo NBS-modification. In particular, the modification of Trp420 hampers the correct reorientation of AR* molecule necessary to form the native [AR/Adx] complex that is catalytically essential for electron transfer from FAD in AR to [2Fe-2S] cluster in Adx. The data support an incorrect assembly of [AR*/Adx] complex as the cause of electron transport inhibition.     

Mixed disulfide with glutathione as an intermediate in the reaction catalyzed by glutathione reductase from yeast and as a major form of the enzyme in the cell

Glutathione reductase catalyzes the reduction of glutathione disulfide by NADPH. The FAD of the reductase is reduced by NADPH, and reducing equivalents are passed to a redox-active disulfide to complete the first half-reaction. The nascent dithiol of two-electron reduced enzyme (EH(2)) interchanges with glutathione disulfide forming two molecules of glutathione in the second half-reaction. It has long been assumed that a mixed disulfide (MDS) between one of the nascent thiols and glutathione is an intermediate in this reaction. In addition to the nascent dithiol composed of Cys(45) and Cys(50), the enzyme contains an acid catalyst, His(456), having a pK(a) of 9.2 that protonates the first glutathione (residue numbers refer to the yeast enzyme sequence). Reduction of yeast glutathione reductase by glutathione and reoxidation of EH(2) by glutathione disulfide indicate that the mixed disulfide accumulates, in particular, at low pH. The reaction of glutathione disulfide with EH(2) is stoichiometric in the absence of an excess of glutathione. The equilibrium position among E(ox), MDS, and EH(2) is determined by the glutathione concentration and is not markedly influenced by pH between 6.2 and 8.5. The mixed disulfide is the principal product in the reaction of glutathione with oxidized enzyme (E(ox)) at pH 6. 2. Its spectrum can be distinguished from that of EH(2) by a slightly lower thiolate (Cys(50))-FAD charge-transfer absorbance at 540 nm. The high GSH/GSSG ratio in the cytoplasm dictates that the mixed disulfide will be the major enzyme species.     

Modification of lactate oxidase with diethyl pyrocarbonate. Evidence for an active-site histidine residue

1. Diethyl pyrocarbonate inactivated l-lactate oxidase from Mycobacterium smegmatis. 2. Two histidine residues underwent ethoxycarbonylation when the enzyme was treated with sufficient reagent to abolish more than 90% of the enzyme activity, but analyses of the inactivation showed that the modification of one histidine residue was sufficient to cause the loss of enzyme activity. The rates of enzyme inactivation and histidine modification were the same. 3. Substrate and competitive inhibitors decreased the maximum extent of inactivation to a 50% loss of enzyme activity and modification was decreased from 1.9 to 0.75–1.2 histidine residues modified/molecule of FMN. 4. Treatment of the enzyme with diethyl [¹⁴C]pyrocarbonate (labelled in the carbonyl groups) confirmed that only histidine residues were modified under the conditions used and that deacylation of the ethoxycarbonylhistidine residues by hydroxylamine was concomitant with the removal of the ¹⁴C label and the re-activation of the enzyme. 5. No evidence was found for modification of tryptophan, tyrosine or cysteine residues, and no difference was detected between the conformation and subunit structure of the modified and native enzyme. 6. Modification of the enzyme with diethyl pyrocarbonate did not alter the following properties: the binding of competitive inhibitors, bisulphite and substrate or the chemical reduction of the flavin group to the semiquinone or fully reduced states. The normal reduction of the flavin by lactate was, however, abolished.     

Studies on nitrotyrosine-82 and aminotyrosine-82 derivatives of adrenodoxin. Effects of chemical modification on the complex formation with adrenodoxin reductase.

The coordination structure of the iron-sulfur center of the nitrotyrosine and the aminotyrosine derivates of bovine adrenodoxin was investigated by electron paramagnetic resonance spectroscopy. The reduced form of both modified samples exhibited signals identical with those for the native protein at g= 1.94 and g=2.01. From these results together with optical absorption and chemical analyses, it was concluded that the coordination structure of the iron-sulfur chromophore for both the derivatives was identical with the binuclear tetrahedral structure of native adrenodoxin. The configuration of the iron-binding area in nitro- and amino-adrenodoxin was studied by ovserving the circular dichroism spectra between 350 and 600 nm. The maxima for the nitro or amino derivatives were all identical with those for the native protein but different in the magnitude of their molar ellipticity. The molar ellipticities at 440 nm were 45.8 X 10(3), 14.5 X 10(3), and 9.5 X 10(6) deg cm2 per mol of iron for native adrenodoxin, nitro or amino derivative, respectively. These results suggest that the chemical modification of the tyrosine residue causes a conformational change in the iron-binding area. We have previously reported that the enzymatic activities of these reconstituted nitro and amino derivatives toware cytochrome c reduction in the presence of adrenodoxin reductase and reduced nicotinamide adenine dinucleotide phosphate were 19 and 7% of native adrenodoxin, respectively. The cytochrome c reductase activities of nitro- and aminoadrenodixin were drastically affected by the ionic strength of the assay medium, as found in native adrenodoxin. Fluorometric titration of the reductase with aminoadrenodoxin revealed that aminoadrenodoxin forms a 1:1 molar complex with the reductase. These results suggest that both the nitro and amino derivatives form a complex with the reductase. The dissociation constants of nitro- and aminoadrenodoxin for the reductase were 6.1 X 10(-7)M and 3.3 X 10(-7) M at mu = 0.04 and 1.9 X 10(-6) M and 2.0 X 10(-6) M at mu = 0.20, respectively. Comparison of these values with those of native adrenodoxin (approximately 10(-9) M at mu = 0.04 and 2.2 X 10(-7) M at mu = 0.20) suggests that an increase in the dissociation constant for the reductase is responsible for the decreased electron transferring activity of the modified adrenodoxins.     

Chemical modification studies of beef-heart mitochondrial b-c1 complex. Effect of modification by ethoxyformic anhydride

The effect of the histidine-modifier ethoxyformic anhydride (EFA) on the enzymatic properties of the mitochondrial b-c1 complex (ubiquinol-cytochrome c reductase) has been investigated. Chemical modification by EFA inhibited to the same extent the reductase and the proton translocating activity of the complex. In particular EFA modification of the complex resulted in: strong inhibition of the antimycin-insensitive reduction of b cytochromes; inhibition of the antimycin-promoted oxidant-induced reduction of b cytochromes and inhibition of oxidation of pre-reduced b cytochromes. Analysis of the absorbance at 238 nm, indicative of N-(ethoxyformyl)histidine derivative, of the various polypeptide subunits separated by high-pressure liquid chromatography procedure, showed that EFA modified residues in core proteins and in the low-molecular-mass proteins. Both the inhibition of the redox and the protonmotive activity of the complex and the absorbance increase at 238 nm of the core protein fraction were readily reversed by hydroxylamine, indicating that modification of histidine residue(s) in core protein(s) is critical for the activity of the complex. This was supported by the finding that modification of the reductase with EFA prevented binding of fluorescein isothiocyanate to histidine residue(s) in core protein II. EFA modification of the reductase was without effect on the binding of N-(7-dimethylamino-4-methylcoumarinyl)maleimide to the various polypeptides of the complex except for the binding to the Fe-S protein which was greatly potentiated. Thus primary chemical modification of histidine residue(s) in core protein (II) appears to cause, in turn, a conformational change in the Rieske Fe-S protein.     

Histidine and lysine residues and the activity of phospholipase A2 from the venom of Bitis gabonica.

Chemical modification of phospholipase A2 (phosphatide 2-acyl-hydrolase, EC 3.1.1.4) from the venom of gaboon adder (Bitis gabonica) showed that histidine and lysine residues are essential for enzyme activity. Treatment with p-bromophenacyl bromide or pyridoxal 5'-phosphate resulted in the specific covalent modification of one histidine or a total of one lysine residue per molecule of enzyme, respectively, with a concomitant loss of enzyme activity. Competitive protection against modification and inactivation was afforded by the presence of Ca2+ and/or micellar concentrations of substrate analogue, lysophosphatidylcholine. Neither modification caused any significant conformational change, as judged from circular dichroic properties. Amino acid analyses and the alignment of peptides from cyanogen bromide and proteolytic cleavage of modified enzyme preparations delineated His-45 as the only residue modified by p-bromophenacyl bromide. However, pyridoxal 5'-phosphate was shown to have reacted not with a single lysine but with four different ones (residues 11, 33, 58 and 111) in such a manner that an overall stoichiometry of one modified lysine residue/molecule enzyme resulted. Apparently, the essential function of lysine could be fulfilled by any one out of these four residues.     

Modulation of bovine serum amine oxidase activity by hydrogen peroxide

Bovine serum amine oxidase (BSAO), reduced by excess amine under limited turnover conditions, was over 80% inactivated by H(2)O(2) upon oxygen exhaustion. The UV-Vis spectrum and the reduced reactivity with carbonyl reagents showed that the cofactor topaquinone (TPQ) was stabilized in reduced form. The protein large M(r) (170 kDa) prevented the identification of modified residues by amino acid analyses. Minor changes of the Cu(2+) EPR signal and the formation of a radical at g = 2.001, with intensity a few percent of that of the Cu(2+) signal, unaffected by a temperature increase, suggest that Cu(2+)-bound histidines were not oxidized and the radical was not the Cu(+)-semiquinolamine in equilibrium with Cu(2+)-aminoquinol. It may derive from the modification of a conserved residue in proximity of the active site, possibly the tyrosine at hydrogen-bonding distance of TPQ C-4 ionized hydroxyl. The inactivation reaction appears to be a general feature of copper-containing amine oxidases. It may be part of an autoregulatory process in vivo, possibly relevant to cell adhesion and redox signaling.     

Chemical modification of tryptophan residues in Escherichia coli succinyl-CoA synthetase. Effect on structure and enzyme activity

Succinyl-CoA synthetase of Escherichia coli is an alpha 2 beta 2 protein containing active sites at the interfaces between alpha- and beta-subunits. The alpha-subunit contains a histidine residue that is phosphorylated during the reaction. The beta-subunit binds coenzyme A and probably succinate [see Nishimura, J. S. (1986) Adv. Enzymol. Relat. Areas Mol. Biol. 58, 141-172]. Chemical modification studies have been conducted in order to more clearly define functions of each subunit. Tryptophan residues of the enzyme were modified by treatment with N-bromosuccinimide at pH 7. There was a linear relationship between loss of enzyme activity and tryptophan modified. At one tryptophan residue modified per beta-subunit, 100% of the enzyme activity was lost. In this enzyme sample, one methionine residue in each alpha- and beta-subunit was oxidized to methionine sulfoxide, although loss of enzyme activity could not be related in a linear manner to the formation of this residue. Subunits were prepared from enzyme that was inactivated 50% by N-bromosuccinimide with 0.5 tryptophan modified per beta-subunit but with insignificant modification of methionine residues in either subunit. Small decreases in the tyrosine and histidine content were observed in the alpha-subunit but not in the beta-subunit. In this case, modified beta-subunit when mixed with unmodified alpha-subunit gave a population of molecules that was 50% as active as the refolded, unmodified control but was only slightly changed with respect to phosphorylation capacity and unchanged with respect to rate of phosphorylation.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Enhanced activity of an immobilized lipase promoted by site-directed chemical modification with polymers

The activity of a lipase from Geobacillus thermocatenulatus (BTL2) can be greatly improved by site-directed chemical modification of a single external Cys64. This residue is placed in the proximity of the region where the lid is allocated when the lipase exhibits its open and active form. Thiol group of Cys64 was modified by thiol-disulfide exchange with pyridyldisulfide poly-aminated-dextrans or mono-carboxylated-polyethyleneglycol. The modification was performed on the covalently immobilized lipase on CNBr-agarose or glyoxyl-agarose. The activity of modified derivatives was strongly dependent on the immobilized preparation, the polymer used and the substrate assayed. For example, the modification with PEG-COOH of BTL2 immobilized on glyoxyl-agarose increased 5-fold the enzyme activity towards the hydrolysis of 2-O-butyryl-2-phenylacetic acid. However, the modification with 3-(2-pyridyldithio)-propionyl-dextran-NH₂ reduced the activity to 40%.The fact that the modified enzymes can be inhibited by an irreversible inhibitor much more rapidly than the unmodified ones suggested that the main effect of the modification is to somehow stabilize the open form of the lipase.     

Reaction of (Na-K)ATPase with 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole: evidence for an essential tyrosine at the active site.

The reaction of 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole [NBD-Cl] with purified eel electrophax Na+ and K+ stimulated adenosine triphosphatase [(Na-K)ATPase] has been monitored by changes in the (Na-K)ATPase activity, the K+ stimulated p-nitrophenyl phosphatase [PNPase] activity, and the protein ultraviolet absorption spectrum. The NBD-Cl reacts with two tyrosine residues per mol of enzyme (approximately 6-7 nmol/mg of protein), as judged by changes in protein absorption spectra and incorporation of [14C]NBD-Cl. The modified tyrosine groups are located on the Mr = 95 000 polypeptide chain and react at different rates. Only one tyrosine modification is necessary for complete inhibition of (Na-K)ATPase activity, although both must be modified for complete inhibition of PNPase activity. Reversal of these modifications by 2-mercaptoethanol restores 65% of both activities. Na+ increases the rate of tyrosine modification, K+ decreases the rate, and ATP affords the more reactive tyrosine group complete protection. NBD-Cl modification of approximately 6-7 nmol of tyrosine groups/mg of protein results in a large decrease in ATP affinity as judged by equilibrium binding. These results are compared with similar results obtained from NBD-Cl modification of the coupling factors of oxidative phosphorylation and photophosphorylation. A model is presented suggesting an asymmetric arrangement of two 95 000 polypeptide chains with a single tyrosine residue at the ATP site.     

Modification of swine pepsin and pepsinogen by p-nitrophenyldiazonium chloride

It was found that at pH 5.2 and 40-fold excess of p-nitrophenyldiazonium chloride the inhibitor incorporation into the porcine pepsin molecule involves 1.9 residues, one residue being bound to tyrosine 189. Besides, tyrosines 44, 113, 154 and 174 enter the reaction. Modified pepsin retains 25% of the native enzyme activity. In the pepsinogen molecule the degree of tyrosine 189 modification diminishes 5 times; of 1.5 inhibitor molecules incorporated into the protein 0.78 residues are bound to tyrosine 113. The potential proteolytic activity of modified pepsinogen towards haemoglobin cleavage makes up to 60% of the original one. It is concluded that the activation peptide in the pepsinogen molecule masks the substrate binding site bearing tyrosine 189, thus preventing its modification with p-nitrophenyldiazonium chloride. The activation peptide in the pepsinogen molecule is presumably located in the vicinity of the wide loop bend carrying tyrosine residue 113, which may be the reason for the decreased pKa value of this residue and of its increased reactivity in the azocoupling reaction.     

Vitamin K2 (menaquinone) biosynthesis in Escherichia coli: evidence for the presence of an essential histidine residue in o-succinylbenzoyl coenzyme A synthetase.

o-Succinylbenzoyl coenzyme A (OSB-CoA) synthetase, when treated with diethylpyrocarbonate (DEP), showed a time-dependent loss of enzyme activity. The inactivation follows pseudo-first-order kinetics with a second-order rate constant of 9.2 x 10(-4) +/- 1.4 x 10(-4) microM(-1) min(-1). The difference spectrum of the modified enzyme versus the native enzyme showed an increase in A242 that is characteristic of N-carbethoxyhistidine and was reversed by treatment with hydroxylamine. Inactivation due to nonspecific secondary structural changes in the protein and modification of tyrosine, lysine, or cysteine residues was ruled out. Kinetics of enzyme inactivation and the stoichiometry of histidine modification indicate that of the eight histidine residues modified per subunit of the enzyme, a single residue is responsible for the enzyme activity. A plot of the log reciprocal of the half-time of inactivation against the log DEP concentration further suggests that one histidine residue is involved in the catalysis. Further, the enzyme was partially protected from inactivation by either o-succinylbenzoic acid (OSB), ATP, or ATP plus Mg2+ while inactivation was completely prevented by the presence of the combination of OSB, ATP, and Mg2+. Thus, it appears that a histidine residue located at or near the active site of the enzyme is essential for activity. When His341 present in the previously identified ATP binding motif was mutated to Ala, the enzyme lost 65% of its activity and the Km for ATP increased 5.4-fold. Thus, His341 of OSB-CoA synthetase plays an important role in catalysis since it is probably involved in the binding of ATP to the enzyme.