The oxygenated complexes of the two catalytically active oxidation-reduction states of L-tryptophan-2,3-dioxygenase.

The oxygenated complexes of the two catalytically active forms of pseudomonad and rat liver L-tryptophan-2,3-dioxygenase (EC 1.13.11.11) have been studied. As was previously reported (ISHIMURA, Y., NORZAKI, M., HAYAISHI, O., TAMURA, M., AND YAMAZAK-I I. (1970) J. Biol. Chem. 245, 3593-3602), we observe that the fully reduced form of pseudomonad tryptophan oxygenase during steady state catalysis exists predominantly as the L-tryptophan ferroheme-O2 enzyme complex (lambdamax = 415 nm, 540 nm, 570 nm). However, during steady state catalysis by a half-reduced form of both the pseudomonad and hepatic enzymes, the predominant species present manifest absorption spectra indicative of ternary complexes in which all the heme exists as ferriheme (Soret, 407 nm), there being no trace of a ferroheme-O2 complex. Carbon monoxide is a competitive inhibitor with respect to molecular oxygen of catalysis by either the half-reduced or fully reduced forms of pseudomonad tryptophan oxygenase. During steady state catalysis in the presence of CO, the fully reduced form of the enzyme exists as a mixture of the oxyferroheme (Soret = 415 nm) and carboxyferroheme (Soret = 421 nm) enzyme complexes. However, if the same experiment is repeated with the half-reduced form of the pseudomonad enzyme, all of the enzyme is in the ferriheme state, even though CO is inhibiting this form of the enzyme to the same degree as it does the fully reduced form. We conclude that for the half-reduced form of pseudomonad tryptophan oxygenase the substrate, O2, and the inhibitor, CO, are not binding to the heme moieties, but are bound elsewhere, presumably to the Cu(I) moieties. Examination of the kinetic mechanisms of the half-reduced and fully reduced forms of pseudomonad tryptophan oxygenase using the inhibitors carbon monoxide and 5-fluorotryptophan confirmed that the fully reduced enzyme binds L-tryptophan before O2 (FORMAN, H., AND FEIGELSON, P. (1971) Biochemistry 10, 760-763) and that for the half-reduced enzyme O2 binds first. In the presence of 5-fluorotryptophan a relatively stable oxyferroheme enzyme complex was generated with the fully reduced form of pseudomonad tryptophan oxygenase. Thus, saturation of the catalytic site alone either with the substrate, L-tryptophan, or the competitive inhibitor, 5-fluorotryptophan, enhances binding of O2 to the ferroheme moieties of the enzyme. The resistance of this complex to photolysis indicates that the bound molecular oxygen is predominantly present as superoxide, O2-minus.     

Preparation and properties of ferrous chloroperoxidase complexes with dioxygen, nitric oxide, and an alkyl isocyanide. Spectroscopic dissimilarities between the oxygenated forms of chloroperoxidase and cytochrome P-450

Extensive spectroscopic investigations of chloroperoxidase and cytochrome P-450 have consistently revealed close similarities between these two functionally distinct enzymes. Although the CO-bound ferrous states were the first to display such resemblance, additional comparisons have focused on the native ferric and ferrous and the ligand-bound ferric derivatives of the enzymes. In order to test the extent to which the spectral properties of the two enzymes match each other, we have prepared the NO, alkyl isocyanide, and O2 adducts of ferrous chloroperoxidase, the latter two for the first time. As expected, the NO adducts of the two proteins have similar UV-visible absorption and magnetic circular dichroism spectra; the same behavior is observed for the alkyl isocyanide complexes. Unexpectedly, the dioxygen adduct of ferrous chloroperoxidase (i.e. Compound III), generated in cryogenic solvents at -30 degrees C by bubbling with O2, is spectrally distinct from oxy-P-450-CAM. Identification of this derivative as oxygenated chloroperoxidase is based on the following criteria: It is EPR-silent at 77 K. The bound O2 is dissociable as judged by the uniform conversion to the CO-bound form. Oxy-chloroperoxidase autoxidizes to form the native ferric enzyme without detectable intermediates at a rate comparable to that determined for oxy-P-450-CAM. Oxy-chloroperoxidase exhibits optical absorption (lambda nm (epsilon mM) = 354 (41), 430 (94), 554 (16.5), 587 (12.5)) and magnetic circular dichroism spectra that are clearly distinct from those of histidine-ligated heme proteins such as oxy-myoglobin or oxy-horseradish peroxidase. Surprisingly, several of its spectral properties, namely the red-shifted Soret peak and discrete alpha peak, are also unlike those of oxy-P-450-CAM. Since considerable evidence has accumulated supporting the ligation of an endogenous thiolate to the heme iron of chloroperoxidase, as has been established for the P-450 enzyme, the observed dissimilarities suggest that the electronic properties of the two dioxygen adducts are quite sensitive to differences in their active site heme environment. This, in turn may be related to the functional differences between the two enzymes.     

Effects of heme ligand mutations including a pathogenic variant, H65R, on the properties of human cystathionine beta-synthase

Human cystathionine beta-synthase is a hemeprotein that catalyzes a pyridoxal phosphate (PLP)-dependent condensation of serine and homocysteine into cystathionine. Biophysical characterization of this enzyme has led to the assignment of the heme ligands as histidine and cysteinate, respectively, which has recently been confirmed by crystal structure determination of the catalytic core of the protein. Using site-directed mutagenesis, we confirm that C52 and H65 represent the thiolate and histidine ligands to the heme. Conversion of C52 to alanine or serine results in spectral properties of the resulting hemeprotein that are consistent with the loss of a thiolate ligand. Thus, the Soret peak blue-shifts from 428 to 415 and 417 nm in the ferric forms of the C52S and C52A mutants, respectively, and from 450 to 423 nm in the ferrous states of both mutants. Addition of CO to the dithionite-reduced ferrous C52 mutants results in spectra with Soret peaks at 420 nm. EPR spectroscopy of the ferric C52 variants reveals the predominance of a high-spin species. The H65R mutant, a variant described in a homocystinuric patient, has Soret peaks at 424, 421, and 420 nm in the ferric, ferrous, and ferrous CO states, respectively. EPR spectroscopy reveals predominance of the low-spin species. Both C52A and C52S mutations lead to protein with substoichiometric heme (19% with respect to wild type); however, the PLP content is comparable to that of wild-type enzyme. The heme and PLP contents of the H65R mutant are 40% and 75% that of wild-type enzyme. These results indicate that heme saturation does not dictate PLP saturation in these mutant enzymes. Both H65 and C52 variants display low catalytic activity, revealing that changes in the heme binding domain modulate activity, consistent with a regulatory role for this cofactor.     

Stereoelectronic control of bond formation in Escherichia coli tryptophan synthase: substrate specificity and enzymatic synthesis of the novel amino acid dihydroisotryptophan

The reactions of the indole analogues indoline and aniline with the Escherichia coli tryptophan synthase alpha-aminoacrylate Schiff base intermediate have been characterized by UV-visible and 1H NMR absorption spectroscopy and compared with the interactions of indole and the potent inhibitor benzimidazole. Indole, via the enamine functionality of the pyrrole ring, reacts with the alpha-aminoacrylate intermediate, forming a transient quinonoid species with lambda max 476 nm as the new C-C bond is synthesized. Conversion of this quinonoid to L-tryptophan is the rate-limiting step in catalysis [Lane, A., & Kirschner, K. (1981) Eur. J. Biochem. 120, 379-398]. Both aniline and indoline undergo rapid N-C bond formation with the alpha-aminoacrylate to form quinonoid intermediates; benzimidazole binds rapidly and tightly to the alpha-aminoacrylate but does not undergo covalent bond formation. The indoline and aniline quinonoids (lambda max 464 and 466 nm, respectively) are formed via nucleophilic attack on the electrophilic C-beta of the alpha-aminoacrylate. The indoline quinonoid decays slowly, yielding a novel, new amino acid, dihydroisotryptophan. The aniline quinonoid is quasi-stable, and no new amino acid product was detected. We conclude that nucleophilic attack requires the precise alignment of bonding orbitals between nucleophile and the alpha-aminoacrylate intermediate. The constraints imposed by the geometry of the indole subsite force the aromatic rings of indoline, aniline, and benzimidazole to bind in the same plane as indole; thus nucleophilic attack occurs with the N-1 atoms of indoline and aniline.(ABSTRACT TRUNCATED AT 250 WORDS)     

Spectroscopic and kinetic characterization of nonenzymic and aldose reductase mediated covalent NADP-glycolaldehyde adduct formation

Reaction of glycolaldehyde with the binary E-NADP complex of bovine kidney aldose reductase (ALR2) produces an enzyme-bound chromophore whose absorbance (lambd max 341 nm) and fluorescence (lambda ex max 341 nm; lambda emit max 421 nm) properties are distinct from those of NADPH or E.NADPH yet are consistent with the proposed covalent adduct structure [1,4-dihydro-4-(1-hydroxy-2-oxoethyl)nicotinamide adenine dinucleotide phosphate]. The kinetics of adduct formation, both in solution and at the enzyme active site, support a mechanism involving rate-determining enolization of glycolaldehyde at high [NADP+] or [E.NADP]. At low [NADP+] or [E.NADP] the reaction is second-order overall, but the ALR2-mediated reaction displays saturation by glycolaldehyde due to competition of the aldehyde (plus hydrate) and enol for E.NADP. Measurement of the pre-steady-state burst of E-adduct formation confirms that glycolaldehyde enol is the reactive species and gives a value of 1.3 x 10(-6) for Kenol = [enol]/[( aldehyde] + [hydrate]), similar to that determined by trapping the enol with I3-. At the ALR2 active site, the rate of adduct formation is enhanced 79,000-fold and the adduct is stabilized greater than or equal to 13,000-fold relative to the reaction with NADP+ in solution. A portion of this enhancement is ascribed to specific interaction of NADP+ with the enzyme since the 3-acetylpyridine analogue, (AP)ADP+, gives values that are 15-200-fold lower. Additional evidence for strong interaction of ALR2 with both NADP+ and NADPH is reported. Yet, because dissociation of adduct is slow, catalysis of the overall adduct formation reaction by ALR2 is less than or equal to 67-fold.     

Interaction of bd-type quinol oxidase from Escherichia coli and carbon monoxide: Heme d binds CO with high affinity

Comparative studies on the interaction of the membrane-bound and detergent-solubilized forms of the enzyme in the fully reduced state with carbon monoxide at room temperature have been carried out. CO brings about a bathochromic shift of the heme d band with a maximum at 644 nm and a minimum at 624 nm, and a peak at 540 nm. In the Soret band, CO binding to cytochrome bd results in absorption decrease and minima at 430 and 445 nm. Absorption perturbations in the Soret band and at 540 nm occur in parallel with the changes at 630 nm and reach saturation at 3-5 microM CO. The peak at 540 nm is probably either beta-band of the heme d-CO complex or part of its split alpha-band. In both forms of cytochrome bd, CO reacts predominantly with heme d. Addition of high CO concentrations to the solubilized cytochrome bd results in additional spectral changes in the gamma-band attributable to the reaction of the ligand with 10-15% of low-spin heme b558. High-spin heme b595 does not bind CO even at high concentrations of the ligand. The apparent dissociation constant values for the heme d-CO complex of the membrane-bound and detergent-solubilized forms of the fully reduced enzyme are about 70 and 80 nM, respectively.     

Structural characterization of n-butyl-isocyanide complexes of cytochromes P450nor and P450cam

Alkyl-isocyanides are able to bind to both ferric and ferrous iron of the heme in cytochrome P450, and the resulting complexes exhibit characteristic optical absorption spectra. While the ferric complex gives a single Soret band at 430 nm, the ferrous complex shows double Soret bands at 430 and 450 nm. The ratio of intensities of the double Soret bands in the ferrous isocyanide complex of P450 varies, as a function of pH, ionic strength, and the origin of the enzyme. To understand the structural origin of these characteristic spectral features, we examined the crystallographic and spectrophotometric properties of the isocyanide complexes of Pseudomonas putida cytochrome P450cam and Fusarium oxysporum cytochorme P450nor, since ferrous isocyanide complex of P450cam gives a single Soret band at 453 nm, while that of P450nor gives one at 427 nm. Corresponding to the optical spectra, we observed C-N stretching of a ferrous iron-bound isocyanide at 2145 and 2116 cm(-1) for P450nor and P450cam, respectively. The crystal structures of the ferric and ferrous n-butyl isocyanide complexes of P450cam and P450nor were determined. The coordination structure of the fifth Cys thiolate was indistinguishable for the two P450s, but the coordination geometry of the isocyanide was different for the case of P450cam [d(Fe-C) = 1.86 A, angleFe-C-N = 159 degrees ] versus P450nor [d(Fe-C) = 1.85 A, angleFe-C-N = 175 degrees ]. Another difference in the structures was the chemical environment of the heme pocket. In the case of P450cam, the iron-bound isocyanide is surrounded by some hydrophobic side chains, while, for P450nor, it is surrounded by polar groups including several water molecules. On the basis of these observations, we proposed that the steric factors and/or the polarity of the environment surrounding the iron-bound isocyanide significantly effect on the resonance structure of the heme(Fe)-isocyanide moiety and that differences in these two factors are responsible for the spectral characteristics for P450s.     

Carbon monoxide complex of cytochrome b(5) at acidic pH

CO complex of cyt b(5) generated at acidic pH is investigated by absorption, resonance Raman (RR), and far UV CD measurements. The Soret maximum wavelength blue-shifted to 420 nm with other absorption bands observed around 540 and 570 nm for reduced cyt b(5) upon interaction with CO at acidic pH (pH 3.1-3.5). Under this condition, the iron-carbon stretching RR band was observed at 529 cm(-1) (520 cm(-1) for C(18)O), which indicated formation of a heme&bond;CO adduct with a histidine as an axial ligand. Heme dissociated from the reduced cyt b(5) protein at pH approximately 3.5, whereas its rate decreased under CO atmosphere compared with N(2) atmosphere, due to formation of a heme&bond;CO adduct with a histidine as an axial ligand.     

Indole protects tryptophan indole-lyase, but not tryptophan synthase, from inactivation by trifluoroalanine.

Trifluoroalanine is a mechanism-based inactivator of Escherichia coli tryptophan indole-lyase (tryptophanase) and E. coli tryptophan synthase (R. B. Silverman and R. H. Abeles, 1976, Biochemistry 15, 4718-4723). We have found that indole is able to prevent inactivation of tryptophan indole-lyase by trifluoroalanine. The protection of tryptophan indole-lyase by indole exhibits saturation kinetics, with a KD of 0.03 mM, which is comparable to the KI for inhibition of pyruvate ion formation (0.01 mM) and the Km for L-tryptophan synthesis. Fluoride electrode measurements indicate the formation of 28 mol of fluoride ion per mole of enzyme during inactivation of tryptophan indole-lyase, and 121 mol of fluoride ion are formed per mole of enzyme in the presence of 2 mM indole during the same incubation period. 19F NMR spectra of reaction mixtures of tryptophan indole-lyase and trifluoroalanine showed evidence only for fluoride ion formation, in either the absence or the presence of indole, and difluoropyruvic acid was not detected. The partition ratio, kcat/kinact, is estimated to be 9. Tryptophan indole-lyase in the presence of trifluoroalanine exhibits visible absorption peaks at 446 and 478 nm, which decay at the same rate as inactivation. However, in the presence of 1 mM indole and trifluoralanine, tryptophan indole-lyase exhibits a peak only at 420 nm, and the spectra show a gradual increase at 300-310 nm with incubation. In contrast, tryptophan synthase is not protected by indole from inactivation by trifluoroalanine, and the absorption peak at 408 nm for the tryptophan synthase-trifluoroalanine complex is unaffected by indole. These results demonstrate that inactivation of tryptophan indole-lyase occurs via a catalytically competent species, probably the beta,beta-difluoro-alpha-aminoacrylate intermediate, which can be partitioned from inactivation to products by a reactive aromatic nucleophile, indole.     

The ferrous dioxygen complex of the oxygenase domain of neuronal nitric-oxide synthase

The mechanisms by which nitric-oxide synthases (NOSs) bind and activate oxygen at their P450-type heme active site in order to synthesize nitric oxide from the substrate L-arginine are mostly unknown. To obtain information concerning the structure and properties of the first oxygenated intermediate of the enzymatic cycle, we have used a rapid continuous flow mixer and resonance Raman spectroscopy to generate and identify the ferrous dioxygen complex of the oxygenase domain of nNOS (Fe(2+)O(2) nNOSoxy). We detect a line at 1135 cm(-1) in the resonance Raman spectrum of the intermediate formed from 0.6 to 3.0 ms after the rapid mixing of the ferrous enzyme with oxygen that is shifted to 1068 cm(-1) with (18)O(2). This line is assigned as the O-O stretching mode (nu(O-O)) of the oxygenated complex of nNOSoxy. Rapid mixing experiments performed with nNOSoxy saturated with L-arginine or N(omega)-hydroxy-L-arginine, in the presence or absence of (6R)-5,6, 7,8-tetrahydro-L-biopterin, reveal that the nu(O-O) line is insensitive to the presence of the substrate and the pterin. The optical spectrum of this ferrous dioxygen species, with a Soret band wavelength maximum at 430 nm, confirms the identification of the previously reported oxygenated complexes generated by stopped flow techniques.     

Binding of pyrimidin-2-one ribonucleoside by cytidine deaminase as the transition-state analogue 3,4-dihydrouridine and the contribution of the 4-hydroxyl group to its binding affinity

Cytidine deaminase, purified to homogeneity from constitutive mutants of Escherichia coli, was found to bind the competitive inhibitors pyrimidin-2-one ribonucleoside (apparent Ki = 3.6 x 10(-7) M) and 5-fluoropyrimidin-2-one ribonucleoside (apparent Ki = 3.5 x 10(-8) M). Enzyme binding resulted in a change of the lambda max of pyrimidin-2-one ribonucleoside from 303 nm for the free species to 239 nm for the bound species. The value for the bound species was identical with that of an oxygen adduct formed by combination of hydroxide ion with 1,3-dimethyl-2-oxopyrimidinium (239 nm), but lower than that of a sulfur adduct formed by combination of the thiolate anion of N-acetylcysteamine with 1,3-dimethyl-2-oxopyrimidinium (259 nm). The results suggest that pyrimidin-2-one ribonucleoside is bound by cytidine deaminase as an oxygen adduct, probably the covalent hydrate 3,4-dihydrouridine, rather than intact or as an adduct involving a thiol group of the enzyme. In dilute solution at 25 degrees C, the equilibrium constant for formation of a single diastereomer of 3,4-dihydrouridine from pyrimidin-2-one ribonucleoside was estimated as approximately 4.7 x 10(-6), from equilibria of dissociation of water, protonation of 1-methylpyrimidin-2-one, and combination of the 1,3-dimethylpyrimidinium cation with the hydroxide ion.(ABSTRACT TRUNCATED AT 250 WORDS)     

Active site rearrangement of the 2-hydrazinopyridine adduct in Escherichia coli amine oxidase to an azo copper(II) chelate form: a key role for tyrosine 369 in controlling the mobility of the TPQ-2HP adduct

Adduct I (lambda(max) at approximately 430 nm) formed in the reaction of 2-hydrazinopyridine (2HP) and the TPQ cofactor of wild-type Escherichia coli copper amine oxidase (WT-ECAO) is stable at neutral pH, 25 degrees C, but slowly converts to another spectroscopically distinct species with a lambda(max) at approximately 530 nm (adduct II) at pH 9.1. The conversion was accelerated either by incubation of the reaction mixture at 60 degrees C or by increasing the pH (>13). The active site base mutant forms of ECAO (D383N and D383E) showed spectral changes similar to WT when incubated at 60 degrees C. By contrast, in the Y369F mutant adduct I was not stable at pH 7, 25 degrees C, and gradually converted to adduct II, and this rate of conversion was faster at pH 9. To identify the nature of adduct II, we have studied the effects of pH and divalent cations on the UV-vis and resonance Raman spectroscopic properties of the model compound of adduct I (2). Strikingly, it was found that addition of Cu2+ to 2 at pH 7 gave a product (3) that exhibited almost identical spectroscopic signatures to adduct II. The X-ray crystal structure of 3 shows that it is the copper-coordinated form of 2, where the +2 charge of copper is neutralized by a double deprotonation of 2. These results led to the proposal that adduct II in the enzyme is TPQ-2HP that has migrated onto the active site Cu2+. The X-ray crystal structure of Y369F adduct II confirmed this assignment. Resonance Raman and EPR spectroscopy showed that adduct II in WT-ECAO is identical to that seen in Y369F. This study clearly demonstrates that the hydrogen-bonding interaction between O4 of TPQ and the conserved Tyr (Y369) is important in controlling the position and orientation of TPQ in the catalytic cycle, including optimal orientation for reactivity with substrate amines.     

Oxygen binding to dithionite-reduced chloroperoxidase

Both the kinetics of ferric chloroperoxidase reduction by dithionite and the binding of molecular oxygen to ferrous chloroperoxidase have been studied. The oxyferrous chloroperoxidase decays spontaneously to the ferric enzyme. In addition the corresponding rapid-scan spectra have been recorded. The reduction reaction is caused by SO-.2 with a rate constant of (7.7 +/- 1.0) X 10(4) M-1 S-1. Oxygen binding occurs with a rate constant of (5.5 +/- 1.0) X 10(5) M-1 S-1 over the pH range 3.5-6. Oxyferrous chloroperoxidase has a Soret absorption peak at 428 nm and two partially resolved peaks at 555 nm and 588 nm. Isosbestic points occur at the following wavelengths: between ferrous and oxyferrous chloroperoxidase at 419, 545, 555 and 580 nm; between oxyferrous and ferric chloroperoxidase at 419, 487, 540, 609 and 682 nm.     

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.     

Spectroscopic detection of transient thiamin diphosphate-bound intermediates on benzoylformate decarboxylase

Thiamin diphosphate (ThDP)-dependent enzymes catalyze a range of transformations, such as decarboxylation and ligation. We report a novel spectroscopic assay for detection of some of the ThDP-bound intermediates produced on benzoylformate decarboxylase. Benzoylformate decarboxylase was mixed with its alternate substrate p-nitrobenzoylformic acid on a rapid-scan stopped-flow instrument, resulting in formation of three absorbing species (lambda(max) in parentheses): I(1) (a transient at 620 nm), I(2) (a transient at 400 nm), and I(3) (a stable absorbance with lambda(max) > 730 nm). Analysis of the kinetics of the two transient species supports a model in which a noncovalent complex of the substrate and the enzyme is converted to the first covalent intermediate I(1); the absorbance corresponding to I(1) is probably a charge-transfer band arising from the interaction of the thiamin diphosphate-p-nitrobenzoylformic acid covalent adduct (2-p-nitromandelylThDP) and the enzyme. The rate of disappearance of I(1) parallels the rate of formation of I(2). Chemical models suggest the lambda(max) of I(2) (near 400 nm) to be appropriate to the enamine, a key intermediate in ThDP-dependent reactions resulting from the decarboxylation of the thiamin diphosphate-p-nitrobenzoylformic acid covalent adduct. Therefore, the rate of disappearance of I(1) and/or the appearance of I(2) directly measure the rate of decarboxylation. A relaxation kinetic treatment of the pre-steady-state kinetic data also revealed a hitherto unreported facet of the mechanism, alternating active-sites reactivity. Parallel studies of the His70Ala BFD active-site variant indicate that it cannot form the complex reported by the charge-transfer band (I(1)) at the level of the wild-type protein.     

Role of the interactions between the active site base and the substrate Schiff base in amine oxidase catalysis. Evidence from structural and spectroscopic studies of the 2-hydrazinopyridine adduct of Escherichia coli amine oxidase

2-Hydrazinopyridine (2HP) is an irreversible inhibitor of copper amine oxidases (CAOs). 2HP reacts directly at the C5 position of the TPQ cofactor, yielding an intense chromophore with lambda(max) approximately 430 nm (adduct I) in Escherichia coli amine oxidase (ECAO). The adduct I form of wild type (WT-ECAO) was assigned as a hydrazone on the basis of the X-ray crystal structure. The hydrazone adduct appears to be stabilized by two key hydrogen-bonding interactions between the TPQ-2HP moiety and two active site residues: the catalytic base (D383) and the conserved tyrosine residue (Y369). In this work, we have synthesized a model compound (2) for adduct I from the reaction of a TPQ model compound (1) and 2HP. NMR spectroscopy and X-ray crystallography show that 2 exists predominantly as the azo form (lambda(max) at 414 nm). Comparison of the UV-vis and resonance Raman spectra of 2 with adduct I in WT, D383E, D383N, and Y369F forms of ECAO revealed that adduct I in WT and D383N is a tautomeric mixture where the hydrazone form is favored. In D383E adduct I, the equilibrium is further shifted in favor of the hydrazone form. UV-vis spectroscopic pH titrations of adduct I in WT, D383N, D383E, and 2 confirmed that D383 in WT adduct I is protonated at pH 7 and stabilizes the hydrazone tautomer by a short hydrogen-bonding interaction. The deprotonation of D383 (pKa approximately 9.7) in adduct I resulted in conversion of adduct I to the azo tautomer with a blue shift of the lambda(max) to 420 nm, close to that of 2. In contrast, adduct I in D383N and D383E is stable and did not show any pH-dependent spectral changes. In Y369F, adduct I was not stable and gradually converted into a new species with lambda(max) at approximately 530 nm (adduct II). A detailed mechanism for the adduct I formation in WT has been proposed that is consistent with the mechanism proposed for the oxidation of substrate by CAOs but addresses some key differences in the active site chemistry of hydrazine inhibitors and substrate amines.     

Resonance Raman investigations of chloroperoxidase, horseradish peroxidase, and cytochrome c using Soret band laser excitation.

Resonance Raman spectra of the heme protein chloroperoxidase in its native and reduced forms and complexed with various small ions are obtained by using laser excitation in the Soret region (350-450 nm). Additionally, Raman spectra of horseradish peroxidase, cytochrome P-450cam, and cytochrome c, taken with Soret excitation, are presented and discussed. The data support previous findings that indicate a strong analogy between the active site environments of chloroperoxidase and cytochrome P-450cam. The Raman spectra of native chloroperoxidase are found to be sensitive to temperature and imply that a high leads to low spin transition of the heme iron atom takes place as the temperature is lowered. Unusual peak positions are also found for native and reduced chloroperoxidase and indicate a weakening of porphyrin ring bond strengths due to the presence of a strongly electron-donating axial ligand. Enormous selective enhancements of vibrational modes at 1360 and 674 cm-1 are also observed in some low-spin ferrous forms of the enzyme. These vibrational frequencies are assigned to primary normal modes of expansion of the prophyrin macrocycle upon electronic excitation.     

Characterization of two low Em forms of cytochrome a3 and their carbon monoxide complexes in mammalian cytochrome c oxidase.

Evidence is presented for the existence of two forms of low-potential cytochrome a3. One appears to be similar to the low-spin form reported by Nicholls, P., and V. Hildebrandt (1978 Biochem. J. 173:65-72) and Wrigglesworth, J. M., J. Elsden, A. Chapman, N. Van der Water, and M. F. Grahn (1988. Biochim. Biophys. Acta. 936:452-464). It has a reduced Soret peak near 428 nm and a prominent alpha peak near 602 nm. This form is seen when the enzyme is either supplemented with lipoprotein or incorporated into a liposomal membrane, preexposed to a voltage greater than 400 mV for at least 30 min, and titrated in the presence of approximately 1 mM K3Fe(CN)6. The other form has a reduced Soret peak near 446 nm, and no prominent alpha peak. The 428-nm form has an Em near 175 mV and forms a CO complex with an Em near 225 mV. The 446-nm form has an Em near 200 mV and forms a CO complex with an Em near 335 mV.     

The resonance Raman frequencies of the Fe-CO stretching and bending modes in the CO complex of cytochrome P-450cam

Resonance Raman spectra of the ferrous CO complex of cytochrome P-450cam have been observed both in its camphor-bound and free states. Upon excitation at 457.9 nm, near the absorption maximum of the Soret band, the ferrous CO complex of the camphor-bound enzyme showed an anomalously intense Raman line at 481 cm-1 besides the strong Raman lines at 1366 and 674 cm-1 for the porphyrin vibrations. The Raman line at 481 cm-1 (of the 12C16O complex) shifted to 478 cm-1 upon the substitution by 13C16O and to 473 cm-1 by 12C18O without any detectable shift in porphyrin Raman lines. This shows that the line at 481 cm-1 is assignable to Fe-CO stretching vibration. By the excitation at 457.9 nm, a weak Raman line was also observed at 558 cm-1, which was assigned to the Fe-C-O bending vibration, because it was found to shift by -14 cm-1 on 13C16O substitution while only -3 cm-1 on 12C18O substitution. These stretching and bending vibrations of the Fe-CO bond were not detected with the excitation at 413.1 nm, though the porphyrin Raman lines at 1366 and 674 cm-1 were clearly observed. When the substrate, camphor, was removed from the enzyme, the Fe-CO stretching vibration was found to shift to 464 cm-1 from 481 cm-1, while no detectable changes were found in porphyrin Raman lines. This means that the bound substrate interacts predominantly with the Fe-CO portion of the enzyme molecule.