The methoxatin semiquinone: a pulse radiolysis study

Methoxatin is a novel o-quinone found in bacterial dehydrogenases and mammalian plasma amine oxidase. This is the first report of the redox potential and spectrum of the 1-electron reduced methoxatin semiquinone obtained by the method of pulse radiolysis in aqueous solution.     

Optical spectra and electronic structure of flavine mononucleotide in flavodoxin crystals.

The polarized single-crystal absorption spectra of the oxidized and semiquinone forms of flavodoxin from Clostridium MP have been measured with a double beam recording microspectrophotometer. The spectra establish that the radical species in the crystal is the neutral (blue) falvine semiquinone. Combination of the spectra reported here with polarization data from previous fluorescence and stretched-film studies provides transition moment directions for the first two phi-phi transitions of the oxidized form. Predictions of molecular orbital theory are in good agreement with these experimental directions. The crystal spectra of the semiquinone indicate that the two lowest frequency transitions have the same detailed orbital origin as the corresponding transitions of the oxidized form; in the semiquinone these transitions appear at lower frequency, are closer together, and, as predicted from detailed considerations of transition probabilities, exhibit approximately half the absorption intensity. Our hypothesis of a common orbital origin suggests that semiquinone formation takes place by the addition of an electron to the lowest empty phi orbital of the oxidized form without any gross electronic rearrangement.     

Amino acid residues interacting with both the bound quinone and coenzyme, pyrroloquinoline quinone, in Escherichia coli membrane-bound glucose dehydrogenase

The Escherichia coli membrane-bound glucose dehydrogenase (mGDH) as the primary component of the respiratory chain possesses a tightly bound ubiquinone (UQ) flanking pyrroloquinoline quinone (PQQ) as a coenzyme. Several mutants for Asp-354, Asp-466, and Lys-493, located close to PQQ, that were constructed by site-specific mutagenesis were characterized by enzymatic, pulse radiolysis, and EPR analyses. These mutants retained almost no dehydrogenase activity or ability of PQQ reduction. CD and high pressure liquid chromatography analyses revealed that K493A, D466N, and D466E mutants showed no significant difference in molecular structure from that of the wild-type mGDH but showed remarkably reduced content of bound UQ. A radiolytically generated hydrated electron (e(aq)(-)) reacted with the bound UQ of the wild enzyme and K493R mutant to form a UQ neutral semiquinone with an absorption maximum at 420 nm. Subsequently, intramolecular electron transfer from the bound UQ semiquinone to PQQ occurred. In K493R, the rate of UQ to PQQ electron transfer is about 4-fold slower than that of the wild enzyme. With D354N and D466N mutants, on the other hand, transient species with an absorption maximum at 440 nm, a characteristic of the formation of a UQ anion radical, appeared in the reaction of e(aq)(-), although the subsequent intramolecular electron transfer was hardly affected. This indicates that D354N and D466N are prevented from protonation of the UQ semiquinone radical. Moreover, EPR spectra showed that mutations on Asp-466 or Lys-493 residues changed the semiquinone state of bound UQ. Taken together, we reported here for the first time the existence of a semiquinone radical of bound UQ in purified mGDH and the difference in protonation of ubisemiquinone radical because of mutations in two different amino acid residues, located around PQQ. Furthermore, based on the present results and the spatial arrangement around PQQ, Asp-466 and Lys-493 are suggested to interact both with the bound UQ and PQQ in mGDH.     

Vectorial redox reactions of physiological quinones. II. A study of transient semiquinone formation.

Transient absorption changes during reduction of quinone in liposomes by external dithionite, in the absence and presence of initially trapped ferricyanide, were matched with absorption spectra of semiquinone and quinone in the blue region. Plastoquinone, ubiquinone-9 and phylloquinone, each having an isoprenoid side chain were compared with trimethyl-p-benzoquinone, ubiquinone-9 and menadione, which lack a long side chain. Semiquinone transients could only be observed by our spectroscopic technique during reduction of quinones lacking the chain. If Triton X-100 was added to the liposomes preparation semiquinone transients were also observed with the isoprenoid quinones. This result is consistent with the view that isoprenoid quinones build domains in the membranes, in which the life time of the semiquinone might be decreased by fast disproportionation, and to which dithionite has limited access.     

Vectorial redox reactions of physiological quinones. II. A study of transient semiquinone formation

Transient absorption changes during reduction of quinone in liposomes by external dithionite, in the absence and presence of initially trapped ferricyanide, were matched with absorption spectra of semiquinone and quinone in the blue region. Plastoquinone, ubiquinone-9 and phylloquinone, each having an isoprenoid side chain were compared with trimethyl-p-benzoquinone, ubiquinone-9 and menadione, which lack a long side chain.Semiquinone transients could only be observed by our spectroscopic technique during reduction of quinones lacking the chain. If Triton X-100 was added to the liposomes preparation semiquinone transients were also observed with the isoprenoid quinones. This result is consistent with the view that isoprenoid quinones build domains in the membranes, in which the life time of the semiquinone might be decreased by fast disproportionation, and to which dithionite has limited access.     

Crystallization of a derivative of a new coenzyme,methoxatin

A new compound, derived from a parent compound to which we have given the trivial name, methoxatin, has been isolated from a methanol-oxidizing bacterium, and crystallized. Its chemical structure was determined by X-ray crystallography. Methoxatin is implicated as a coenzyme in the oxidation of substrate alcohols. This report describes the purification and crystallization of the derivative, acetonyl methoxatin.     

Resonance Raman spectra of flavin semiquinones stabilized by N5 methylation

Resonance Raman spectra are reported for the semiquinone of N5-methyl derivatives of FMN (flavin mononucleotide) in H2O and 2H2O, 8-chloro FMN and FAD (flavin adenine dinucleotide) with 647.1 nm excitation, in the first pi-pi absorption band, using KI to quench fluorescence. The spectral pattern is similar to that of oxidized flavin, in its first absorption band, but with appreciable shifts, up to approx. 50 cm-1, in corresponding frequencies. There are also significant shifts with respect to the previously reported resonance Raman spectrum of flavodoxin semiquinone, reflecting the substitution of CH3 for H at N5. The N5-methyl FAD semiquinone spectrum is also reported for 514.5 nm excitation, in resonance with the second pi-pi transition. The intensity pattern is quite different, the spectrum being dominated by a band at 1611 cm-1, assigned to a mode localized primarily on the central pyrazine ring.     

Replacement of methoxatin by 4,7-phenanthroline-5,6-dione and the inability of other phenanthroline quinones, as well as 7,9-di-decarboxy methoxatin, to serve as cofactors for the methoxatin-requiring glucose dehydrogenase of Acinetobacter calcoaceticus

Glucose dehydrogenase from A. calcoaceticus has been dissociated into apoenzyme and methoxatin coenzyme, and enzyme activity restored by replacing coenzyme with 4,7-phenanthroline-5,6-dione but not with 1,10- nor 1,7-phenanthroline-5,6-diones nor with 7,9-decarboxy methoxatin.     

Aromatic amine dehydrogenase, a second tryptophan tryptophylquinone enzyme.

Aromatic amine dehydrogenase (AADH) catalyzes the oxidative deamination of aromatic amines including tyramine and dopamine. AADH is structurally similar to methylamine dehydrogenase (MADH) and possesses the same tryptophan tryptophylquinone (TTQ) prosthetic group. AADH exhibits an alpha 2 beta 2 structure with subunit molecular weights of 39,000 and 18,000 and with a quinone covalently attached to each beta subunit. Neither subunit cross-reacted immunologically with antibodies to the corresponding subunits of MADH, and the N-terminal amino acid sequence of the beta subunit of AADH exhibited no homology with the highly conserved beta subunits of MADH. The absorption spectra for the oxidized, semiquinone, and reduced forms of AADH have been characterized, and extinction coefficients for the absorption maxima of each redox form have been determined. These spectra are very similar to those for MADH, indicating the likelihood of a TTQ cofactor. This was verified by the near identity of the vibrational frequencies and intensities in the resonance Raman spectra for the oxidized forms of AADH and MADH. A stable semiquinone of AADH could be observed during a reductive titration with dithionite, whereas titration with tyramine proceeded directly from the oxidized to the reduced form. AADH was very stable against denaturation by heat and exposure to guanidine. The individual subunits could be separated by gel filtration after incubation in guanidine hydrochloride, and partial reconstitution of activity was observed on recombination of the subunits. Steady-state kinetic analysis of AADH yielded a Vmax of 17 mumol/min/mg and a Km for tyramine of 5.4 microM. Substrate inhibition by tyramine was observed. AADH was irreversibly inhibited by hydrazine, phenylhydrazine, hydroxylamine, semicarbazide, and aminoguanidine. Isonicotinic acid hydrazide (isoniazid) and isonicotinic acid 2-isopropyl hydrazide (iproniazid) were reversible noncompetitive inhibitors of AADH and exhibited K(i) values of 8 and 186 microM, respectively. The similarities and differences between AADH and other amine oxidizing enzymes are also discussed.     

Spectroscopic studies on the photoreaction of choline oxidase, a flavoprotein, with covalently bound flavin

Formation of the anionic flavosemiquinone was observed spectrophotometrically during the anaerobic photo-irradiation of Alcaligenes sp. choline oxidase in the presence of EDTA. Further irradiation slowly converted the semiquinone form into the fully reduced state. The presence of a catalytic amount of riboflavin greatly enhances the photoreduction rate not only to the semiquinone state but also to the fully reduced state. This semiquinone species has low reactivity toward the substrate, choline or betaine aldehyde, as well as toward oxygen. This low reactivity toward oxygen is unique to the semiquinone form of a flavoprotein oxidase. The oxidized enzyme forms a complex with betaine, the product of the enzymatic reaction of choline oxidase. The dissociation constant for this complex was found to be 17 mM by spectroscopic titration. Anaerobic photo-irradiation of the enzyme with a saturating amount of betaine in the absence of EDTA produces, with no detectable semiquinone formation, an absorption spectrum which resembles (but significantly differs from) that of the fully reduced form. This species was found to comprise two flavin species. One of them is rapidly oxidized to the oxidized form by oxygen and is thus assigned as the fully reduced state. The other is converted slowly to the oxidized form upon aerobic standing in the dark. We tentatively assigned this latter species as a C(4a)-adduct. Formaldehyde was detected as a product of this photoreaction. The amount of formaldehyde formed coincided with that of the fully reduced enzyme. On the basis of the results obtained we propose a mechanism of the photoreaction of the enzyme in the presence of betaine where a C(4a)-adduct and the fully reduced enzyme via an N(5)-adduct are formed. Betaine also affects the dithionite reduction. In the dithionite reduction of the oxidized enzyme, the semiquinone species is an intermediate in the conversion of the oxidized to the fully reduced form, while the reduction of the oxidized enzyme-betaine complex with dithionite produces the fully reduced form without any significant formation of the semiquinone species.     

Pulse radiolysis study of daunorubicin redox reactions: Redox cycles or glycosidic cleavage?

Two aspects of daunorubicin reactivity were investigated by pulse radiolysis. (i) The reactions of O₂ and O₂⁻ with the semiquinone and the hydroquinone transients of daunorubicin were determined and their rate constants measured. Although O₂⁻ can reduce the drug and its semiquinone form, it is a more powerful oxident towards the two reduced transients. (ii) The hydroquinone daunorubicin glycosidic cleavage in aqueous solution was studied. Three intermediates were seen and characterized by their absorption spectra, their formation and decay kinetics.The competition beween these two main processes was evaluated in the conditions of pulse radiolysis. Even under low O₂ partial pressures the redox cycles are much more rapid than the glycosidic cleavage and a relatively high O₂⁻ steady state is settled. Biological implications are discussed.     

Differences between the reactivities of two pyridine nucleotides in the rapid reduction process and the reoxidation process of adrenodoxin reductase.

The reaction process of adrenodoxin reductase with NADPH and NADH were investigated. The appearance of new intermediate with a broad absorption band at around 520 nm has been detected by rapid-scan stopped-flow spectrophotometry. Although the formation of this intermediate is more rapid with NADPH than with NADH, the rates of the subsequent decay to the fully reduced state are almost identical (Kobs values were 20.5 and 16.0s-1). These results indicate that the new intermediate is the complex formed between the oxidized enzyme and reduced pyridine nucleotide (enzyme-substrate complex), and that subsequent decay of the intermidiate is caused by a two-electron transfer process from the reduced pyridine nucleotide to the enzyme flavin. On the other hand, spectral and kinetic properties in the steady state of the reoxidation reaction of the enzyme reduced with NADPH and NADH were somewhat different. The rate of reoxidation of the enzyme under aerobic conditions from the reduced state to the oxidized state was 6.5 times faster when a 10-fold molar excess of NADH was used than when NADPH of the same concentration was used. This result is consistent with the fact that the NADH-dependent oxidase activity was 6.4 times greater than that dependent on NADPH. During reoxidation of the reduced enzyme under aerobic conditions in the presence of an excess of NADPH or NADH, the EPR spectra indicated the formation of the flavin semiquinone radical species. Similarly, the formation of semiquinone was observed in the absorption spectrum with either NADPH or NADH under the same conditions as in the EPR measurement. The intensity of the semiquinone signal on EPR was considerably smaller with NADH than with NADPH. These results suggest that NADP+ complex with the enzyme semiquinone protects the radical from oxidation by oxygen to a greater extent than NAD+, and consequently the semiquinone is easier to detect with NADPH than with NADH.     

Thermodynamic basis of electron transfer in dihydroorotate dehydrogenase B from Lactococcus lactis: analysis by potentiometry, EPR spectroscopy, and ENDOR spectroscopy

Dihydroorotate dehydrogenase B (DHODB) is a complex iron-sulfur flavoprotein that catalyzes the conversion of dihydroorotate to orotate and the reduction of NAD(+). The enzyme is a dimer of heterodimers containing an FMN, an FAD, and a 2Fe-2S center. UV-visible, EPR, and ENDOR spectroscopies have been used to determine the reduction potentials of the flavins and the 2Fe-2S center and to characterize radicals and their interactions. Reductive titration using dithionite indicates a five-electron capacity for DHODB. The midpoint reduction potential of the 2Fe-2S center (-212 +/- 3 mV) was determined from analysis of absorption data at 540 nm, where absorption contributions from the two flavins are small. The midpoint reduction potentials of the oxidized/semiquinone (E(1)) and semiquinone/hydroquinone (E(2)) couples for the FMN (E(1) = -301 +/- 6 mV; E(2) = -252 +/- 8 mV) and FAD (E(1) = -312 +/- 6 mV; E(2) = -297 +/- 5 mV) were determined from analysis of spectral changes at 630 nm. Corresponding values for the midpoint reduction potentials for FMN (E(1) = -298 +/- 4 mV; E(2) = -259 +/- 5 mV) in the isolated catalytic subunit (subunit D, which lacks the 2Fe-2S center and FAD) are consistent with the values determined for the FMN couples in DHODB. During reductive titration of DHODB, small amounts of the neutral blue semiquinone are observed at approximately 630 nm, consistent with the measured midpoint reduction potentials of the flavins. An ENDOR spectrum of substrate-reduced DHODB identifies hyperfine couplings to proton nuclei similar to those recorded for the blue semiquinone of free flavins in aqueous solution, thus confirming the presence of this species in DHODB. Spectral features observed during EPR spectroscopy of dithionite-reduced DHODB are consistent with the midpoint reduction potentials determined using UV-visible spectroscopy and further identify an unusual EPR signal with very small rhombic anisotropy and g values of 2.02, 1.99, and 1.96. This unusual signal is assigned to the formation of a spin interacting state between the FMN semiquinone species and the reduced 2Fe-2S center. Reduction of DHODB using an excess of NADH or dihydroorotate produces EPR spectra that are distinct from those produced by dithionite. From potentiometric studies, the reduction of the 2Fe-2S center and the reduction of the FMN occur concomitantly. The study provides a detailed thermodynamic framework for electron transfer in this complex iron-sulfur flavoprotein.     

Bis-semiquinone (bi-radical) formation by photoinduced proton coupled electron transfer in covalently linked catechol-quinone systems: Aviram's hemiquinones revisited

The structure and reactivity of a covalently linked catechol-ortho-benzoquinone (hemiquinone) is studied by UV-Vis and IR absorption spectroscopy. Nanosecond transient absorption spectroscopy of the hemiquinone reveals the formation of bi-radical state consisting of two semiquinone units. It is a long-lived state resulting from proton coupled electron transfer (PCET).     

PQQ, the elusive coenzyme

The recently discovered redox coenzyme, PQQ (methoxatin), is widely distributed. Quantitation of protein-bound PQQ has been difficult, but unique redox cycling reactions, which reflect its striking biological properties, reveal trace amounts. PQQ is a potential target for drugs.     

Identification of the reduced primary electron acceptor of Photosystem II as a bound semiquinone anion

The complete absorption difference spectrum of the primary electron acceptor of Photosystem II has been measured at room temperature in subchloroplast fragments prepared with deoxycholate. The shape and amplitude of the spectrum indicate that the primary reaction involves the reduction of one bound plastoquinone molecule per reaction center to its semiquinone anion. In addition two small absorbance band shifts occur near 545 (C550) and 685 nm, which may be due to an influence of the semiquinone on the absorption spectrum of a reaction center pigment.     

Tyrosinase-catalyzed oxidation of dopa and related catechol(amine)s: a kinetic electron spin resonance investigation using spin-stabilization and spin label oximetry

The oxidation of four catechol(amine)s by tyrosinase has been studied by electron spin resonance and optical methods. Rates of oxygen consumption and of dopaquinone and dopachrome formation during the oxidation of dopa have been measured, and compared with rates of dopasemiquinone production measured using spin-stabilization procedures. In the presence of spin-stabilizing metal ions, production of semiquinone is approximately quantitative. Time-dependent ESR spectra obtained from dopa and dopamine show a slow regeneration of semiquinone, suggesting that a semiquinone precursor is slowly reformed. In contrast, time-dependent spectra for 4-methylcatechol and N-acetyldopamine show decay of the primary semiquinone together with buildup of a secondary semiquinone apparently derived from the corresponding 6-hydroxy-catechol(amine). Thus, catecholamines that give rise to a cyclizable quinone show a pattern of behavior that differs from those that produce a non-cyclizable quinone. These results are discussed in terms of their possible significance to melanogenesis and the toxicity of catechol(amine)s, which has been attributed to production of semiquinones and/or other oxygen radicals.     

Absorbance changes due to the charge-accumulating species in System 2 of photosynthesis

Absorbance changes are reported associated with Photosystem II and showing a periodicity of two and four as a function of flash number.

The absorbance changes showing a periodicity of two were found to occur in the presence of artificial electron donors as well and are presumably caused by the secondary electron acceptor R of Photosystem II. The absorbance difference spectra suggest that R is a plastoquinone molecule, which is reduced to its semiquinone anion after an uneven number of flashes. After an even number of flashes, the semiquinone is reoxidized. The absorbance changes showing a periodicity of four are tentatively ascribed to the charge accumulating donor complex of Photosystem II.     

Semiquinone and ascorbyl radicals in the gut fluids of caterpillars measured with EPR spectrometry

The biological activity of phenolic compounds ingested by caterpillars is commonly believed to result from their oxidation, although the products of oxidation have been well-characterized in only a few cases. The initial oxidation products of phenols (semiquinone or phenoxyl radicals) can be measured with electron paramagnetic resonance (EPR) spectrometry. In this study semiquinone radicals formed from tannic acid and gallic acid in the gut fluids of two species of caterpillars were measured. In Orgyia leucostigma, in which ingested phenols are not oxidized, semiquinone radicals were absent or at very low intensities. By contrast, in Malacosoma disstria, in which ingested phenols are oxidized, high semiquinone radical intensities were measured. In the absence of detectable levels of semiquinone radicals, ascorbyl radicals were detected in the EPR spectra instead. High molar ratios of ascorbate to phenols in an artificial diet produced ascorbyl radicals in the midgut fluids of both species, while diets containing low molar ratios produced semiquinone radicals. Similar results were obtained in M. disstria fed the leaves of red oak or sugar maple. The results of this study provide further evidence that ascorbate is an essential antioxidant that prevents the oxidation of phenols in the gut fluids of caterpillars, and demonstrate that EPR spectrometry is a valuable method for determining the degree of oxidative activation of phenols ingested by herbivorous insects.     

Kinetic and thermodynamic characterization of the common polymorphic variants of human methionine synthase reductase

Human methionine synthase reductase (MSR) is a protein containing both FAD and FMN, and it reactivates methionine synthase that has lost activity due to oxidation of cob(I)alamin to cob(II)alamin. In this study, anaerobic redox titrations were employed to determine the midpoint reduction potentials for the flavin cofactors in two highly prevalent polymorphic variants of MSR, I22/L175 and M22/S175. The latter is a genetic determinant of plasma homocysteine levels and has been linked to premature coronary artery disease, Down's syndrome, and neural tube defects. The I22/L175 polymorphism has been described in a homocystinuric patient. Interestingly, this polymorphism is in the extended linker region between the two flavin domains, which may mediate or facilitate interaction with methionine synthase. In MSR I22/L175, the FMN potentials are -103 mV (oxidized/semiquinone) and -175 mV (semiquinone/hydroquinone) at pH 7.0 and 25 degrees C, and the corresponding FAD potentials are -252 and -285 mV, respectively. For the M22/S175 variants, the values of the four midpoint potentials are -114 mV (FMN oxidized/semiquinone), -212 mV (FMN semiquinone/hydroquinone), -236 mV (FAD oxidized/semiquinone), and -264 mV (FAD semiquinone/hydroquinone). The midpoint potential values in the two variants are generally comparable to those originally determined for the MSR I22/S175 variant [Wolthers, K. R. (2003) Biochemistry 42, 3911-3920], with relatively minor variations in the different redox couples. In each case, blue neutral flavin semiquinone species are stabilized on both flavins, and are characterized by a broad absorption band in the long wavelength region. In addition, stopped-flow absorption and fluorescence spectroscopy were used to study the pre-steady state reduction kinetics by NADPH of the two polymorphic variants. The reversible kinetic model proposed for wild-type MSR was validated for the I22/L175 and M22/S175 variants. Thus, the biochemical penalties associated with these polymorphisms, which result in less effective methionine synthase activation, do not appear to result from differences in their reduction kinetics. It is likely that differences in their relative affinities for the redox partner, methionine synthase, underlie the differences in the relative efficiencies of reductive activation exhibited by the variants.