The role of pH in the melanin biosynthesis pathway

Having oxidized 3,4-dihydroxyphenylalanine (dopa) with sodium periodate or mushroom tyrosinase in a pH range from 3.5 to 6.0, it has been possible to detect spectrophotometrically 4-(2-carboxy-2-aminoethyl)-1,2-benzoquinone with the amino group protonated (o-dopaquinone-H+), a postulated intermediate in the melanogenesis pathway. When the pH value was greater than 4, the final product obtained was 2-carboxy-2,3-dihydroindole-5,6-quinone (dopachrome); however, for pH values lower than 4, two different products were identified by means of cyclic voltammetry: 5-(2-carboxy-2-aminoethyl)-2-hydroxy-1,4-benzoquinone and dopachrome. These products appeared when oxidation was achieved with the enzyme as well as with periodate. This suggests that two chemical pathways can arise from alpha-dopaquinone-H+, whose relative importance is determined by the pH. The steps of these pathways would be dopa leads to o-dopaquinone-H+ leads to o-dopaquinone leads to leukodopachrome leads to dopachrome, for the first one, and dopa leads to o-dopaquinone-H+ leads to 2,4,5-trihydroxyphenylalanine leads to 5-(2-carboxy-2-aminoethyl)-2-hydroxy-1,4-benzoquinone very slowly leads to intermediate compound leads to dopachrome, for the second one. The stoichiometry for the conversion of dopaquinone-H+ into dopachrome for pH values greater than 4 followed equation of 2 o-dopaquinone-H+ leads to dopa + dopachrome. No participation of oxygen was detected in the conversion of leukodopachrome (2,3-dihydro-5,6-dihydroxyindole-2-carboxylate) into dopachrome.     

Effect of pH on the oxidation pathway of dopamine catalyzed by tyrosinase

The oxidation of 3,4-dihydroxyphenylethylamine (dopamine) by O2 catalyzed by tyrosinase yields 4-(2-aminoethyl)-1, 2-benzoquinone (o-dopaminequinone), which evolves nonenzymatically through two branches or sequences of reactions, whose respective operations are determined by the pH of the medium. The cyclization branch of o-dopaminequinone takes place in the entire range of pH and is the only significant branch at pH greater than or equal to 6. The hydroxylation branch of o-dopaminequinone only operates significantly at pH less than 6, and involves the accumulation of 2,4,5-trihydroxyphenylethylamine (6-hydroxydopamine) and 5-(2-aminoethyl)-2-hydroxy-1,4-benzoquinone (p-topaminequinone), identified from cyclic voltammetry assays. The kinetic characterization of the hydroxylation branch of o-dopaminequinone has been carried out by spectrophotometric and oxymetric assays. The successful fitting of data to the kinetic behavior predicted by the kinetic analysis at both pH greater than or equal to 6 and pH less than 6 confirms the overall oxidation pathway proposed for the dopamine oxidation catalyzed by tyrosinase. The antitumoral power of dopamine is possibly enhanced by the high cytotoxicity of 6-hydroxydopamine and p-topaminequinone, accumulated at the acidic pH characteristic of melanosomes and melanome cells.     

Oxidation of 6-hydroxydopamine catalyzed by tyrosinase

• 1.1. The oxidation of 3,4-dihydroxyphenylethylamine (dopamine) by O₂ catalyzed by tyrosinase yields 4-(2-aminoethyl)-1,2-benzoquinone, with its amino group protonated (o-dopaminequinone-H⁺, which evolves non-enzymatically through two branches or sequences of reactions, whose respective operations are determined by the pH of the medium.
• 2.2. The cyclization branch of o-dopaminequinone-H⁺ takes place in the entire range of pH and is the only significant branch at pH ⩾ 6.
• 3.3. The hydroxylation branch of o-dopaminequinone-H⁺ only operates significantly at pH < 6, and involves the accumulation of 2,4,5-trihydroxyphenylethylamine (6-hydroxydopamine), identified by high performance liquid chromatography (HPLC).
• 4.4. 6-hydroxydopamine is also a substrate of tyrosinase. The identification and evolution of the oxidation products of 6-hydroxydopamine has been carried out by spectrophotometry and HPLC assays.

     

The role of 2,4,5-trihydroxyphenylalanine in melanin biosynthesis.

Both 3,4-dihydroxyphenylalanine and 2,4,5-trihydroxyphenylalanine were oxidized with periodate and mushroom tyrosinase to determine whether the latter compound is an intermediate in melanin biosynthesis. Matrix analysis of the spectra obtained with a rapid scan spectrophotometer and comparison of the spectra of quinone intermediates with model quinones disclosed that, although 2,4,5-trihydroxyphenylalanine can be oxidized to 2-carboxy-2,3-dihydroindole-5,6-quinone (dopachrome), this oxidation proceeds through a stable intermediate, 5-(2-carboxy-2-aminoethyl)-2-hydroxy-1,4-benzoquinone, which does not appear in the oxidation of 3,4-dihydroxyphenylalanine to dopachrome. Thus, these studies are in agreement with the original postulate, that 4-(2-carboxy-2-aminoethyl)-1,2-benzoquinone and leukodopachrome are the intermediates in the major pathway for dopachrome synthesis.     

Inhibition of adrenodoxin reductase by NADP+ and NADPH

Adrenodoxin reductase (EC 1.18.1.2) catalyzes the oxidation of NADPH by 1.4-benzoquinone. The catalytic constant of this reaction at pH 7.0 is equal to 25-28 s-1. NADP+ acts as the mixed-type nonlinear inhibitor of enzyme increasing Km of NADPH and decreasing catalytic constant. NADP+ and NADPH act as mutually exclusive inhibitors relative to reduced adrenodoxin reductase. The patterns of 2',5'-ADP inhibition are analogous to that of NADP+. These data support the conclusion about the existence of second nicotinamide coenzyme binding centre in adrenodoxin reductase.     

2-Aryl-1,3-thiazolidines as masked sulfhydryl agents for inhibition of melanogenesis

As a part of an ongoing project aimed at developing new skin depigmenting agents, the ability of variously substituted 2-aryl-1,3-thiazolidines to inhibit melanogenesis in vitro was investigated. At 0.2 mM concentration 2-(2'-hydroxyphenyl)-1,3-thiazolidine-4-carboxylic acid (Th2), as well as the descarboxy analog (Th1) and, to a lower extent, the 4'-hydroxy isomer (Th3) all proved capable of preventing the tyrosinase catalyzed conversion of 0.2 mM L-tyrosine to melanin. Spectrophotometric monitoring of the reaction course in the presence of Th2 showed the initial formation of a yellow chromophore (lambda max 400 nm) which slowly decayed, being eventually replaced by a new absorption maximum centered at 305 nm. HPLC analysis of the final incubation mixture revealed the presence of a major product (lambda max 306 nm), ninhydrin and ferric chloride positive, which was isolated by gel filtration on Sephadex G-10 and was identified as beta-[7-(3-carboxy-5-hydroxy-3,4-dihydro-2H-1,4-benzothiazinyl)]al anine (DBA) by 1H-NMR spectroscopy. Attempts to isolate the intermediate with lambda max 400 nm were hampered by its marked instability under the usual chromatographic conditions. However, the nature of the chromophore, coupled with mechanistic considerations, suggested for the compound the Schiff base-containing structure 3,4-dihydroxy-5-S-(N-salicylidenecysteinyl)phenylalanine (salcysdopa). This was substantiated by: (i) the formation of a zinc complex (lambda max 349 nm) analogous to that observed with the model Schiff base N-salicylidene leucine; and (ii) detection by 1H-NMR of a Schiff base resonance at delta 8.1 during the yellow chromophoric phase of the reaction. It was concluded that 1,3-thiazolidines inhibit melanin formation by a mechanism that involves the trapping of enzymically generated dopaquinone by the -SH containing Schiff base arising by cleavage of the thiazolidine ring. The salcysdopa adduct thus formed undergoes hydrolysis and subsequent ring closure to give eventually the colorless DBA.     

Inactivation of fructose-1,6-bisphosphatase by o-phthalaldehyde

Rabbit liver fructose-1,6-bisphosphatase, a tetramer of identical subunits was rapidly and irreversibly inactivated by o-phthalaldehyde at 25 degrees C (pH 7.3). The second-order rate constant for the inactivation was 30 M-1s-1. Fructose-1,6-bisphosphatase was completely protected from inactivation by the substrate--fructose-1,6-diphosphate but not by the allosteric effector--adenosine monophosphate. The absorption spectrum (lambda max 337 nm) and, fluorescence excitation (lambda max 360 nm) and fluorescence emission spectra (lambda max 405 nm) were consistent with the formation of an isoindole derivative in the subunit between a cysteine and a lysine residue about 3A apart. About 4 isoindole groups per mol of the bisphosphatase were formed following complete loss of the phosphatase activity. This suggests that the amino acid residues of the biphosphatase participating in reaction with o-phthalaldehyde more likely reside at or near the active site instead of allosteric site. The molar transition energy of fructose-1,6-bisphosphatase--o-phthalaldehyde adduct was estimated 121 kJ/mol and compares favorably with 127 kJ/mol for the synthetic isoindole, 1-[(beta-hydroxyethyl)thio]-2-(beta-hydroxyethyl) isoindole in hexane. It is, thus, concluded that the cysteine and lysine residues participating in isoindole formation in reaction between fructose-1,6-bisphosphatase and o-phthalaldehyde are located in a hydrophobic environment.     

Synthesis and characterization of 1-substituted 5-alkylphenazine derivatives carrying functional groups

The following 1-substituted derivatives of 5-methylphenazine and 5-ethylphenazine were synthesized: 1-(3-carboxypropyloxy)-5-methylphenazine (1B), 1-(3-carboxypropyloxy)-5-ethylphenazine (2B), 1-(3-ethoxycarbonylpropyloxy)-5-ethylphenazine (2C) and 1-[N-(2-aminoethyl)carbamoylpropyloxy]-5-ethylphenazine (2D); their spectra, stability and reactivity as electron mediators were investigated, together with those of 5-methylphenazine (1A) and 5-ethylphenazine (2A). The 1-substituted derivatives are all insensitive to light and the derivatives of 5-ethylphenazine are more stable than those of 5-methylphenazine under neutral and alkaline conditions; 2B is the most stable of all the derivatives. The spectral properties of the decomposed compounds showed that photodecomposition of 1A and 2A is associated with hydroxylation at position 1, alkali decomposition of 1A and 1B with elimination of the 5-methyl group and alkali decomposition of 2A, 2B, and 2D with a ring-opening reaction. The second-order rate constant k1 for the reaction of the phenazine derivatives with NADH was measured under steady-state conditions. The k1 values vary depending on the substituents at positions 1 and 5: the values for 1A, 1B, 2A, 2B, 2C and 2D are 1.83 mM-1 s-1, 3.33 mM-1 s-1, 0.75 mM-1 s-1, 1.42 mM-1 s-1, 1.68 mM-1 s-1 and 2.03 mM-1 s-1, respectively. The rate constants, k2 and k3, for the reactions of the reduced form of 2B with oxygen and with 3-(4',5'-dimethylthiazole-2-yl)-2,5-diphenyltetrazolium ion, respectively, were k2 = 1.21 mM-1 s-1 and k3 = 91 mM-1 s-1. These phenazine derivatives have potential applications in the biochemical field.     

Melanin accelerates the tyrosinase-catalyzed oxygenation of p-hydroxyanisole (MMEH)

Although pigment melanin has long been though of as "inert," recent work has attested to its chemical reactivity. In this communication, we report that either commercial synthetic melanin prepared by persulfate oxidation of tyrosine ("Sigma melanin") or sepia melanin extracted from cuttlefish markedly accelerates the in vitro oxygenation of p-hydroxyanisole (MMEH), catalyzed by mushroom or B-16 melanoma tyrosinase. Kinetics of 4-methoxy-1,2-benzoquinone formation (lambda max = 413 nm) or of molecular O2 uptake were biphasic, with an initial slow rate ("lag time") followed by a fast linear increase. The biphasic response reflects an initial slow hydroxylation followed by a fast dehydrogenation. Added melanin markedly decreased the lag time but had little effect on subsequent dehydrogenation. Similar effects were observed for tyrosine itself. A complex between MMEH and melanin appears to be the "active" species in these reactions. The results indicate that melanin acts as an electron conduit, which accepts electrons from the substrate and transfers them to tyrosinase. The magnitude of the effect depends on the type of melanin as well as on its oxidation state. Kinetic analysis indicates that both melanins are very efficient at transferring electron to tyrosinase, and that Sigma melanin is roughly threefold more efficient than sepia melanin. The qualitative similarity of reaction between the synthetic and "natural" melanins suggests that the former may serve as a first approximation to the in vivo situation. On the other hand, the observed quantitative differences and the sensitivity of these results to the chemical state of melanin suggests that this methodology might eventually be adapted as a non-destructive probe of melanin in situ.(ABSTRACT TRUNCATED AT 250 WORDS)     

Evidence for the formation of a quinone methide during the oxidation of the insect cuticular sclerotizing precursor 1,2-dehydro-N-acetyldopamine.

1,2-Dehydro-N-acetyldopamine (dehydro-NADA) is an important catecholamine derivative involved in the cross-linking of insect cuticular components during sclerotization. Since sclerotization is a vital process for the survival of insects, and is closely related to melanogenesis, it is of interest to unravel the chemical mechanisms participating in this process. The present paper reports on the mechanism by which dehydro-NADA is oxidatively activated to form reactive intermediate(s) as revealed by pulse radiolysis, electron spin resonance spectroscopy, high performance liquid chromatography, and ultraviolet-visible spectroscopic analysis. Pulse radiolytic one-electron oxidation of dehydro-NADA by N3. (k = 5.3 x 10(9) M-1 s-1) or Br2.- (k = 7.5 x 10(8) M-1 s-1) at pH6 resulted in the rapid generation of the corresponding semiquinone radical, lambda max 400 nm, epsilon = 20,700 M-1 cm-1. This semiquinone decayed to form a second transient intermediate, lambda max 485 nm, epsilon = 8000 M-1 cm-1, via a second order disproportionation process, k = 6.2 x 10(8) M-1 s-1. At pH 6 in the presence of azide, the first order decay of this second intermediate occurred over milliseconds; the rate decreases at higher pH. At pH 6 in the presence of bromide, the intermediate decayed much more slowly over seconds, k = 0.15 s-1. Under such conditions, the dependence of the first order decay constant upon parent dehydro-NADA concentration led to a second order rate constant of 8.5 x 10(2) M-1 s-1 for reaction of the intermediate with the parent, probably to form benzodioxan "dimers." (The term dimer is used for convenience; the products are strictly bisdehydrodimers of dehydro-NADA (see "Discussion" and Fig. 11)) Rate constants of 5.9 x 10(5), 4.5 x 10(5), 2.8 x 10(4) and 3.5 x 10(4) M-1 s-1 were also obtained for decay of the second intermediate in the presence of cysteine, cysteamine, o-phenylenediamine, and p-aminophenol, respectively. By comparison with the UV-visible spectroscopic properties of the two-electron oxidized species derived from dehydro-NADA and from 1,2-dehydro-N-acetyldopa methyl ester, it is concluded that the transient intermediate exhibiting absorbance at 485 nm is the quinone methide tautomer of the o-quinone of dehydro-NADA. Sclerotization of insect cuticle is discussed in the light of these findings.     

Kinetic study of the slow cyanide binding to Glycera dibranchiata monomer hemoglobin components III and IV

Compared to other monomeric heme proteins and the heme peroxidases, the Glycera dibranchiata monomer hemoglobin components III and IV exhibit very slow cyanide binding kinetics. This is agreement with the previously reported behavior of component II. Similar to component II, components III and IV have been studied under pseudo-first-order conditions at pH 6.0, 7.0, 8.0, and 9.0 by using a 100-250-fold excess of potassium cyanide at each pH. At 20 degrees C with micromolar protein concentrations, kobs for component III varies between 7.08 x 10(-5) s-1 at pH 6.0 and 100-fold cyanide excess and 1.06 x 10(-2) s-1 at pH 9.0 and 250-fold cyanide excess. For component IV, the values are 2.03 x 10(-4) s-1 for 100-fold cyanide excess at pH 6.0 and 4.13 x 10(-2) s-1 for 250-fold cyanide excess at pH 9.0. In comparison to other heme proteins, our analysis shows that the bimolecular rate constant (klapp) is small. For example, at pH 7.0, it is 3.02 x 10(-1) M-1 s-1 for component III and 1.82 M-1 s-1 for component IV, compared to 400 M-1 s-1 for sperm whale metmyoglobin, 692 M-1 s-1 for soybean metleghemoglobin a, 111 M-1 s-1 for guinea pig methemoglobin, and 1.1 x 10(5) M-1 s-1 for cytochrome c peroxidase. Our results also show that the dissociation rates (k-lapp) are extremely slow and no larger than 10(-6) s-1.(ABSTRACT TRUNCATED AT 250 WORDS)     

The reaction of superoxide radical with iron complexes of EDTA studied by pulse radiolysis.

The reactions of Fe3+-EDTA and Fe2+-EDTA with O2- and CO2- were investigated in the pH range 3.8--11.8. Around neutral pH O2- reduces Fe3+-EDTA with a rate constant which is pH dependent kpH 5.8--8.1 = 2 - 10(6)--5 - 10(5) M-1 - s-1. At higher pH values this reaction becomes much slower. The CO2- radical reduces Fe3+-EDTA with kpH 3.8--1- = 5 +/- 1 - 10(7) M-1 - s-1 independent of pH. At pH 9--11.8, Fe2+-EDTA forms a complex with O2- with kFe2+-EDTA + O2 = 2 - 10(6)--4 - 10(6) M-1 - s-1 which is pH dependent. We measured the spectrum of Fe2+-EDTA-O2- and calculated epsilon 290 over max = 6400 +/- 800 M-1 - cm-1 in air-saturated solutions. In O2-saturated solutions another species is formed with a rate constant of 7 +/- 2 s-1. This intermediate absorbs around 300 nm but we were not able to identify it.     

Synthesis of gamma-L-glutaminyl-[3,5-3H]4-hydroxybenzene and the study of reactions catalyzed by the tyrosinase of Agaricus bisporus.

gamma-L-Glutaminyl-[3,5-3H]4-hydroxybenzene was synthesized in order to study the kinetics of its hydroxylation by tyrosinase purified from Agaricus bisporus and to explore its role in the induction of the dormant state in the spores of this species. It was found to be unique among the monophenolic substrates for tyrosinase in that the lag period for the hydroxylation reaction decreased with increasing substrate concentration. Unlike previously studied compounds, this phenol appeared to function as an electron donor, allowing it to act as its own co-substrate in the hydroxylation reaction. Its catechol product, gamma-L-glutaminyl-3,4-dihydroxybenzene, was found to be a superior co-substrate, yielding its electrons more readily (oxidation peak potential +0.18 V as compared with +0.65 V for the phenol). In situ periodate oxidation of gamma-L-glutaminyl-3,4-dihydroxybenzene to gamma-L-glutaminyl-3,4-benzoquinone confirmed the co-substrate role of the catechol in the hydroxylation reaction. The tyrosinase-mediated oxidation of gamma-L-glutaminyl-3,4-dihydroxybenzene to gamma-L-glutaminyl-3,4-benzoquinone occurred with an apparent Km = 1.54 mM and Vmax = 0.36 mmol/min/mg of enzyme. gamma-L-Glutaminyl-4-hydroxybenzene acted as an inhibitor of the oxidation reaction.     

The pH dependence of kinetic parameters of Penicillium brevicompactum RNAase]

The effect of pH on the kinetic parameters (Km and Ki) for extracellular acid Penicillium brevicompactum RNAse (pH max 4.7+/-0.1), non-specific to the chemical nature of nucleic bases, was studied. The pKm--pH dependence curve showed bends within the following intervals of pH: 3.5--4.0 and 5.6--6.0 (upward side concavity) and 6.2--6.8 (downward side concavity). The pKi--pH dependence for adenosine-3'-monophosphate as an inhibitor is identical to the pH dependence on pKm for the substrate. On the other hand, the pKi--pH dependence curves obtained for the base-free inhibitors (ribose-5'-monophosphate, or phosphate (adenosine) show no bends within the pH intervals of 3.0--4.0 and 5.6--7.0 respectively. A possibility is discussed of the presence of a carboxylic (pK 3.58+/-0.1) and two imidazole groups (pK 6.42+/-0.1--a weakly protonated and 5.8+/-+/-0.1--a strongly protonated group) in the RNAse active site and their participation in the formation of the RNAse-nucleotide (RNAse-substrate) complex.     

4-Hydroxycinnamoyl-CoA: an ionizable probe of the active site of the medium chain acyl-CoA dehydrogenase

4-OH-Cinnamoyl-CoA has been synthesized as a probe of the active site in the medium chain acyl-CoA dehydrogenase. The protonated form of the free ligand (lambda(max) = 336 nm) yields the corresponding phenolate (lambda(max) = 388 nm) with a pK of 8.9. 4-OH-Cinnamoyl-CoA binds tightly (K(d) = 47 nM, pH 6) to the pig kidney dehydrogenase with a prominent new band at 388 nm, suggesting ionization of the bound ligand. However, this spectrum reflects polarization, not deprotonation, of the neutral form of the ligand. Thus, the 388 nm band is abolished as the pH is raised (not lowered), and analogous spectral and pH behavior is observed with the nonionizable analogue 4-methoxycinnamoyl-CoA. Studies with wild type, E99G, and E376Q mutants of the human medium chain acyl-CoA dehydrogenase showed that these two active site carboxylates strongly suppress ionization of the 4-OH ligand. Binding to the double mutant E99G/E376Q gives an intense new band as the pH is raised (pK = 7.8), with an absorbance maximum at 498 nm resembling the natural 4-OH-cinnamoyl-thioester chromophore of the photoactive yellow protein. Raman difference spectroscopy in water and D(2)O, using the free ligand and wild-type and double-mutant enzyme.ligand complexes, confirms that the 4-OH group of the thioester is ionized only when bound to the double mutant. These data demonstrate the strong electrostatic coupling between ligand and enzyme, and the critical role Glu376 plays in modulating thioester polarization in the medium chain acyl-CoA dehydrogenase.     

Aspartate aminotransferase with the pyridoxal-5'-phosphate-binding lysine residue replaced by histidine retains partial catalytic competence

The active site residue lysine 258 of chicken mitochondrial aspartate aminotransferase was replaced with a histidine residue by means of site-directed mutagenesis. The mutant protein was expressed in Escherichia coli and purified to homogeneity. Addition of 2-oxoglutarate to its pyridoxamine form changed the coenzyme absorption spectrum (lambda max = 330 nm) to that of the pyridoxal form (lambda max = 330/392 nm). The rate of this half-reaction of transamination (kcat = 4.0 x 10(-4)s-1) is five orders of magnitude slower than that of the wild-type enzyme. However, the reverse half-reaction, initiated by addition of aspartate or glutamate to the pyridoxal form of the mutant enzyme, is only three orders of magnitude slower than that of the wild-type enzyme, kmax of the observable rate-limiting elementary step, i.e. the conversion of the external aldimine to the pyridoxamine form, being 7.0 x 10(-2)s-1. Aspartate aminotransferase (Lys258----His) thus represents a pyridoxal-5'-phosphate-dependent enzyme with significant catalytic competence without an active site lysine residue. Apparently, covalent binding of the coenzyme, i.e. the internal aldimine linkage, is not essential for the enzymic transamination reaction, and a histidine residue can to some extent substitute for lysine 258 which is assumed to act as proton donor/acceptor in the aldimine-ketimine tautomerization.     

Hydroxylating activity of tyrosinase and its dependence on hydrogen peroxide

The aim of this work was to study the hydroxylation of N, N-dimethyltyramine (DMTA) by tyrosinase in the presence of hydrogen peroxide, a reaction that does not take place without the addition of the hydrogen peroxide. Some properties of this hydroxylating activity are analyzed. The kinetic parameters of mushroom tyrosinase toward hydrogen peroxide (K(m) = 0.5 mM, V(m) = 11 microM/min, V(m)/K(m) = 2.2 x 10(-2) min(-1)) and toward DMTA (K(m) = 0.3 mM, V(m) = 4.8 microM/min, V(m)/K(m) = 16 x 10(-2) min(-1)) were evaluated. There was a lag period, which was similar to the characteristic lag of monophenolase activity at the expense of molecular oxygen. The length of this lag phase decreased with increasing hydrogen peroxide concentration, and disappeared at approximately 0.5 mM H(2)O(2). However, the lag was longer with higher DMTA concentrations. The pH optimum range for this hydroxylating activity was 6.0 to 7.0. The lag also varied with pH, increasing at pH values higher than 6.7. The presence of hydrogen peroxide is necessary for the oxidation of DMTA, as is the presence of active enzyme since the reaction was completely inhibited when selective tyrosinase inhibitors were added.     

Inhibition of rabbit lung angiotensin-converting enzyme by N alpha-[(S)-1-carboxy-3-phenylpropyl]L-alanyl-L-proline and N alpha-[(S)-1-carboxy-3-phenylpropyl]L-lysyl-L-proline

Two novel peptide analogs, N alpha-[(S)-1-carboxy-3-phenylpropyl]L-alanyl-L-proline and the corresponding L-lysyl-L-proline derivative, have been demonstrated to be potent competitive inhibitors of purified rabbit lung angiotensin-converting enzyme: Ki = 2 and 1 X 10(-10) M, respectively, at pH 7.5, 25 degrees C, and 0.3 M chloride ion. Second-order rate constants for addition of these inhibitors to enzyme under the same conditions are in the range 1-2 X 10(6) M-1 s-1; first-order rate constants for dissociation of the EI complexes are in the range 1-4 X 10(-4) s-1. The association rate constants are similar to those measured for D-3-mercapto-2-methylpropanoyl-L-proline, captopril, but the dissociation rate constants are severalfold slower and account for the higher affinity of these inhibitors for the enzyme. The dissociation constant for the EI complex containing N alpha-[(S)-1-carboxy-3-phenylpropyl]L-alanyl-L-proline is pH-dependent, and reaches a minimum at approximately pH 6: Ki = 4 +/- 1 X 10(-11) M. The pH dependence is consistent either with a model for which the protonation state of the secondary nitrogen atom in the inhibitor determines binding affinity, or one for which ionizations on the enzyme alone influence affinity for these inhibitors. The affinity of this inhibitor for the zinc-free apoenzyme is 2 X 10(4) times less than for the zinc-free apoenzyme is 2 X 10(4) times less than that for the holoenzyme. If considered as a "collected product" inhibitor, N alpha-[(S)-1-carboxy-3-phenylpropyl]L-alanyl-L-proline appears to derive an additional factor of 375 M in its affinity for the enzyme compared to that of the two products of its hypothetical hydrolysis, a consequence of favorable entropy effects.     

Oxidation of dicyano-bis(1,10 phenanthroline) iron(II) by compounds I and II of cytochrome c peroxidase.

The apparent bimolecular rate constant for the oxidation of dicyano-bis(1,10 phenanthroline) iron(II) by compound II of cytochrome c peroxidase (ferrocytochrome c; hydrogen-peroxide oxidoreductase EC 1.11.1.5) has been measured over the pH range 2.5-11.0 at 0.1 M ionic strength, 25 degrees C, by the stopped-flow technique. An ionizable group in the enzyme, with a pKa of 4.5, strongly influences the electron transfer rate between the ferrous complex and the oxidized site in the enzyme. The electron transfer is fastest when the group is protonated, with a rate constant of 2.9 - 10-5 M--1 - s-1. The rate constantdecreases over three orders of magnitude when the proton dissociates. The apparent bimolecular rate constant for the oxidation of the ferrous complex by compound I of cytochrome c peroxidase was determined between pH 3.5 and 6. Under all conditions where this rate constant could be measured it was about three times larger than that for the oxidation by compound II.     

Kinetics and mechanism of the reduction of ferricytochrome c by the superoxide anion

The temperature and pH dependence of the reaction of the superoxide radical anion with ferricytochrome c have been measured using the pulse-radiolysis technique. The temperature dependence of the reaction at low ionic strength yields an activation energy of 31 +/- 5 kJ/mol as compared to 14 +/- 3 kJ/mol for the reaction of CO2.(-) under the same conditions. The pH dependence fits the single pK'a of ferricytochrome c of 9.1. The bimolecular rate constant for the reaction of the superoxide anion with ferricytochrome c at pH 7.8, 21 +/- 2 degrees C, in the presence of 50 mM phosphate and 0.1 mM EDTA is (2.6 +/- 0.1) X 10(5) M-1 s-1. Using this value, 1 unit of superoxide dismutase activity (McCord, J. M., and Fridovich, I. (1969) J. Biol. Chem. 244, 6049-6055) is calculated to be 3.6 +/- 0.3 pmol of enzyme if the assay is performed in a total volume of 3.0 ml. Copper ions reduce the yield of the reaction of ferricytochrome c with CO2.(-). The reactivities of native and singly modified 4-carboxy-2,4-dinitrophenyllysine cytochromes c towards the superoxide anion radical are in the order native greater than 4-carboxy-2,4-dinitrophenyllysine 60 greater than lysine 13 greater than lysine 87 greater than lysine 27 greater than lysine 86 greater than lysine 72, indicating that electron transfer takes place at or close to the solvent accessible heme edge. The mechanism of the reaction is discussed in terms of the approach of superoxide anion radicals to the heme edge and the available molecular orbitals of both heme and free radicals.