Kinetics of a two-component p-hydroxyphenylacetate hydroxylase explain how reduced flavin is transferred from the reductase to the oxygenase

p-Hydroxyphenylacetate hydroxylase (HPAH) from Acinetobacter baumannii catalyzes the hydroxylation of p-hydroxyphenylacetate (HPA) to form 3,4-dihydroxyphenylacetate (DHPA). HPAH is composed of two proteins: a flavin mononucleotide (FMN) reductase (C1) and an oxygenase (C2). C1 catalyzes the reduction of FMN by NADH to generate reduced FMN (FMNH-) for use by C2 in the hydroxylation reaction. C1 is unique among the flavin reductases in that the substrate HPA stimulates the rates of both the reduction of FMN and release of FMNH- from the enzyme. This study quantitatively shows the kinetics of how the C1-bound FMN can be reduced and released to be used efficiently as the substrate for the C2 reaction; additional FMN is not necessary. Reactions in which O2 is rapidly mixed with solutions containing C1-FMNH- and C2 are very similar to those in which solutions containing O2 are mixed with one containing the C2-FMNH- complex. This suggests that in a mixture of the two proteins FMNH- binds more tightly to C2 and has already been completely transferred to C2 before it reacts with oxygen. Rate constants for the transfer of FMNH- from C1 to C2 were found to be 0.35 and >or=74 s-1 in the absence and presence of HPA, respectively. The reduction of cytochrome c by FMNH- was also used to measure the dissociation rate of FMNH- from C1. In the absence of HPA, FMNH- dissociates from C1 at 0.35 s-1, while with HPA present it dissociates at 80 s-1; these are the same rates as those for the transfer from C1 to C2. Therefore, the dissociation of FMNH- from C1 is rate-limiting in the intermolecular transfer of FMNH- from C1 to C2, and this process is regulated by the presence of HPA. This regulation avoids the production of H2O2 in the absence of HPA. Our findings indicate that no protein-protein interactions between C1 and C2 are necessary for efficient transfer of FMNH- between the proteins; transfer can occur by a rapid-diffusion process, with the rate-limiting step being the release of FMNH- from C1.     

The reductase of p-hydroxyphenylacetate 3-hydroxylase from Acinetobacter baumannii requires p-hydroxyphenylacetate for effective catalysis

p-Hydroxyphenylacetate (HPA) hydroxylase (HPAH) from Acinetobacter baumannii catalyzes hydroxylation of HPA to form 3,4-dihydroxyphenylacetate. It is a two-protein system consisting of a smaller reductase component (C(1)) and a larger oxygenase component (C(2)). C(1) is a flavoprotein containing FMN, and its function is to provide reduced flavin for C(2) to hydroxylate HPA. We have shown here that HPA plays important roles in the reaction of C(1). The apoenzyme of C(1) binds to oxidized FMN tightly with a K(d) of 0.006 microM at 4 degrees C, but with a K(d) of 0.038 microM in the presence of HPA. Reduction of C(1) by NADH occurs in two phases with rate constants of 11.6 and 3.1 s(-)(1) and K(d) values for NADH binding of 2.1 and 1.5 mM, respectively. This result indicates that C(1) exists as a mixture of isoforms. However, in the presence of HPA, the reduction of C(1) by NADH occurred in a single phase at 300 s(-)(1) with a K(d) of 25 microM for NADH binding at 4 degrees C. Formation of the C(1)-HPA complex prior to binding of NADH was required for this stimulation. The redox potentials indicate that the rate enhancement is not due to thermodynamics (E degrees (m) of the C(1)-HPA complex is -245 mV compared to an E degrees (m) of C(1) of -236 mV). When the C(1)-HPA complex was reduced by 4(S)-NADH, the reduction rate was changed from 300 to 30 s(-)(1), giving a primary isotope effect of 10 and indicating that C(1) is specifically reduced by the pro-(S)-hydride. In the reaction of reduced C(1) with oxygen, the reoxidation reaction is also biphasic, consistent with reduced C(1) being a mixture of fast and slow reacting species. Rate constants for both phases were the same in the absence and presence of HPA, but in the presence of HPA, the equilibrium shifted toward the faster reacting species.     

A novel two-protein component flavoprotein hydroxylase.

p-Hydroxyphenylacetate (HPA) hydroxylase (HPAH) was purified from Acinetobacter baumannii and shown to be a two-protein component enzyme. The small component (C1) is the reductase enzyme with a subunit molecular mass of 32 kDa. C1 alone catalyses HPA-stimulated NADH oxidation without hydroxylation of HPA. C1 is a flavoprotein with FMN as a native cofactor but can also bind to FAD. The large component (C2) is the hydroxylase component that hydroxylates HPA in the presence of C1. C2 is a tetrameric enzyme with a subunit molecular mass of 50 kDa and apparently contains no redox centre. FMN, FAD, or riboflavin could be used as coenzymes for hydroxylase activity with FMN showing the highest activity. Our data demonstrated that C2 alone was capable of utilizing reduced FMN to form the product 3,4-dihydroxyphenylacetate. Mixing reduced flavin with C2 also resulted in the formation of a flavin intermediate that resembled a C(4a)-substituted flavin species indicating that the reaction mechanism of the enzyme proceeded via C(4a)-substituted flavin intermediates. Based on the available evidence, we conclude that the reaction mechanism of HPAH from A. baumannii is similar to that of bacterial luciferase. The enzyme uses a luciferase-like mechanism and reduced flavin (FMNH2, FADH2, or reduced riboflavin) to catalyse the hydroxylation of aromatic compounds, which are usually catalysed by FAD-associated aromatic hydroxylases.     

pH-dependent studies reveal an efficient hydroxylation mechanism of the oxygenase component of p-hydroxyphenylacetate 3-hydroxylase

p-Hydroxyphenylacetate (HPA) 3-hydroxylase (HPAH) catalyzes the hydroxylation of HPA at the ortho-position to yield 3,4-dihydroxyphenylacetate. The enzyme is a flavin-dependent two-component monooxygenase that consists of a reductase component and an oxygenase component (C(2)). C(2) catalyzes the hydroxylation of HPA using oxygen and reduced FMN as co-substrates. To date, the effects of pH on the oxygenation of the two-component monooxygenases have never been reported. Here, we report the reaction kinetics of C(2)·FMNH(-) with oxygen at various pH values investigated by stopped-flow and rapid quenched-flow techniques. In the absence of HPA, the rate constant for the formation of C4a-hydroperoxy-FMN (～1.1 × 10(6) m(-1)s(-1)) was unaffected at pH 6.2-9.9, which indicated that the pK(a) of the enzyme-bound reduced FMN was less than 6.2. The rate constant for the following H(2)O(2) elimination step increased with higher pH, which is consistent with a pK(a) of >9.4. In the presence of HPA, the rate constants for the formation of C4a-hydroperoxy-FMN (～4.8 × 10(4) m(-1)s(-1)) and the ensuing hydroxylation step (15-17 s(-1)) were not significantly affected by the pH. In contrast, the following steps of C4a-hydroxy-FMN dehydration to form oxidized FMN occurred through two pathways that were dependent on the pH of the reaction. One pathway, dominant at low pH, allowed the detection of a C4a-hydroxy-FMN intermediate, whereas the pathway dominant at high pH produced oxidized FMN without an apparent accumulation of the intermediate. However, both pathways efficiently catalyzed hydroxylation without generating significant amounts of wasteful H(2)O(2) at pH 6.2-9.9. The decreased accumulation of the intermediate at higher pH was due to the greater rates of C4a-hydroxy-FMN decay caused by the abolishment of substrate inhibition in the dehydration step at high pH.     

Catalytic importance of the substrate binding order for the FMNH2-dependent alkanesulfonate monooxygenase enzyme

The two-component alkanesulfonate monooxygenase system from Escherichia coli includes an FMN reductase (SsuE) and an FMNH2-dependent alkanesulfonate monooxygenase (SsuD) involved in the acquisition of sulfur from alkanesulfonates during sulfur starvation. The SsuD enzyme directly catalyzes the oxidation of alkanesulfonate to aldehyde and sulfite in the presence of O2 and FMNH2. The goal of these studies was to investigate the kinetic mechanism of SsuD through rapid reaction kinetics and substrate binding studies. The SsuD enzyme shows a clear preference for FMNH2 (Kd, 0.32 +/- 0.15 microM) compared to FMN (Kd, 10.2 +/- 0.4 microM) with a 1:1 binding stoichiometry for each form of the flavin. The kinetic trace of premixed SsuD and FMNH2 mixed with oxygenated buffer was best fit to a double exponential with no observed formation of the C4a-(hydro)peroxyflavin. However, when FMNH2 was mixed with SsuD and oxygenated buffer an initial fast phase (kobs, 12.9 s-1) was observed, suggesting that the mixing order is critical for the accumulation of the C4a-(hydro)peroxyflavin. Results from fluorimetric titrations with octanesulfonate imply that reduced flavin must bind first to promote octanesulfonate binding. When octanesulfonate was included in the kinetic studies the C4a-(hydro)peroxyflavin was observed at 370 nm when FMNH2 was not premixed with SsuD, which correlated with an increase in octanal product. There was a clear hyperbolic dependence on octanesulfonate binding, indicating that octanesulfonate binds in rapid equilibrium, and further results indicated there was a second isomerization step following binding. These results suggest that an ordered substrate binding mechanism is important in the desulfonation reaction by SsuD with reduced flavin binding first followed by either O2 or octanesulfonate.     

Determination of the redox properties of human NADPH-cytochrome P450 reductase

Midpoint reduction potentials for the flavin cofactors in human NADPH-cytochrome P450 oxidoreductase were determined by anaerobic redox titration of the diflavin (FAD and FMN) enzyme and by separate titrations of its isolated FAD/NADPH and FMN domains. Flavin reduction potentials are similar in the isolated domains (FAD domain E(1) [oxidized/semiquinone] = -286 +/- 6 mV, E(2) [semiquinone/reduced] = -371 +/- 7 mV; FMN domain E(1) = -43 +/- 7 mV, E(2) = -280 +/- 8 mV) and the soluble diflavin reductase (E(1) [FMN] = -66 +/- 8 mV, E(2) [FMN] = -269 +/- 10 mV; E(1) [FAD] = -283 +/- 5 mV, E(2) [FAD] = -382 +/- 8 mV). The lack of perturbation of the individual flavin potentials in the FAD and FMN domains indicates that the flavins are located in discrete environments and that these environments are not significantly disrupted by genetic dissection of the domains. Each flavin titrates through a blue semiquinone state, with the FMN semiquinone being most intense due to larger separation (approximately 200 mV) of its two couples. Both the FMN domain and the soluble reductase are purified in partially reduced, colored form from the Escherichia coli expression system, either as a green reductase or a gray-blue FMN domain. In both cases, large amounts of the higher potential FMN are in the semiquinone form. The redox properties of human cytochrome P450 reductase (CPR) are similar to those reported for rabbit CPR and the reductase domain of neuronal nitric oxide synthase. However, they differ markedly from those of yeast and bacterial CPRs, pointing to an important evolutionary difference in electronic regulation of these enzymes.     

Properties and catalytic function of the two nonequivalent flavins in sarcosine oxidase

Sarcosine oxidase from Corynebacterium sp. U-96 contains 1 mol of noncovalently bound flavin and 1 mol of covalently bound flavin per mole of enzyme. Anaerobic titrations of the enzyme with either sarcosine or dithionite show that both flavins are reducible and that two electrons per flavin are required for complete reduction. Absorption increases in the 510-650-nm region, attributed to the formation of a blue neutral flavin radical, are observed during titration of the enzyme with dithionite or substrate, during photochemical reduction of the enzyme, and during reoxidation of substrate-reduced enzyme. Fifty percent of the enzyme flavin forms a reversible, covalent complex with sulfite (Kd = 1.1 X 10(-4) M), accompanied by a complete loss of catalytic activity. Sulfite does not prevent reduction of the sulfite-unreactive flavin by sarcosine but does interfere with the reoxidation of reduced enzyme by oxygen. The stability of the sulfite complex is unaffected by excess acetate (an inhibitor competitive with sarcosine) or by removal of the noncovalent flavin to form a semiapoprotein preparation where 75% of the flavin reacts with sulfite (Kd = 9.4 X 10(-5) M) while only 3% remains reducible with sarcosine. The results indicate that oxygen and sulfite react with the covalently bound flavin and suggest that sarcosine is oxidized by the noncovalently bound flavin.     

Redox and flavin-binding properties of recombinant flavodoxin from Desulfovibrio vulgaris (Hildenborough).

Flavodoxin from Desulfovibrio vulgaris (Hildenborough) has been expressed at a high level (3-4% soluble protein) in Escherichia coli by subcloning a minimal insert carrying the gene behind the tac promoter of plasmid pDK6. The recombinant protein was readily isolated and its properties were shown to be identical to those of the wild-type protein obtained directly from D. vulgaris, with the exception that the recombinant protein lacks the N-terminal methionine residue. Detailed measurements of the redox potentials of this flavodoxin are reported for the first time. The redox potential, E2, for the couple oxidized flavodoxin/flavodoxin semiquinone at pH 7.0 is -143 mV (25 degrees C), while the value for the flavodoxin semiquinone/flavodoxin hydroquinone couple (E1) at the same pH is -440 mV. The effects of pH on the observed potentials were examined; E2 varies linearly with pH (slope = -59 mV), while E1 is independent of pH at high pH values, but below pH 7.5 the potential becomes less negative with decreasing pH, indicating a redox-linked protonation of the flavodoxin hydroquinone. D. vulgaris apoflavodoxin binds FMN very tightly, with a value of 0.24 nM for the dissociation constant (Kd) at pH 7.0 and 25 degrees C, similar to that observed with other flavodoxins. In addition, the apoflavodoxin readily binds riboflavin (Kd = 0.72 microM; 50 mM sodium phosphate, pH 7.0, 5 mM EDTA at 25 degrees C) and the complex is spectroscopically very similar to that formed with FMN. The redox potentials for the riboflavin complex were determined at pH 6.5 (E1 = -262 mV, E2 = -193 mV; 25 degrees C) and are discussed in the light of earlier proposals that charge/charge interactions between different parts of the flavin hydroquinone play a crucial role in determining E1 in flavodoxin.     

The C-terminal domain of 4-hydroxyphenylacetate 3-hydroxylase from Acinetobacter baumannii is an autoinhibitory domain

p-Hydroxyphenylacetate (HPA) 3-hydroxylase from Acinetobacter baumannii consists of a reductase component (C(1)) and an oxygenase component (C(2)). C(1) catalyzes the reduction of FMN by NADH to provide FMNH(-) as a substrate for C(2). The rate of reduction of flavin is enhanced ～20-fold by binding HPA. The N-terminal domain of C(1) is homologous to other flavin reductases, whereas the C-terminal domain (residues 192-315) is similar to MarR, a repressor protein involved in bacterial antibiotic resistance. In this study, three forms of truncated C(1) variants and single site mutation variants of residues Arg-21, Phe-216, Arg-217, Ile-246, and Arg-247 were constructed to investigate the role of the C-terminal domain in regulating C(1). In the absence of HPA, the C(1) variant in which residues 179-315 were removed (t178C(1)) was reduced by NADH and released FMNH(-) at the same rates as wild-type enzyme carries out these functions in the presence of HPA. In contrast, variants with residues 231-315 removed behaved similarly to the wild-type enzyme. Thus, residues 179-230 are involved in repressing the production of FMNH(-) in the absence of HPA. These results are consistent with the C-terminal domain in the wild-type enzyme being an autoinhibitory domain that upon binding the effector HPA undergoes conformational changes to allow faster flavin reduction and release. Most of the single site variants investigated had catalytic properties similar to those of the wild-type enzyme except for the F216A variant, which had a rate of reduction that was not stimulated by HPA. F216A could be involved with HPA binding or in the required conformational change for stimulation of flavin reduction by HPA.     

Resonance Raman study on complexes of medium-chain acyl-CoA dehydrogenase.

Resonance Raman (RR) spectra of the complex of pig kidney medium-chain acyl-CoA dehydrogenase with acetoacetyl-CoA and of the purple complex formed upon the addition of octanoyl-CoA to the dehydrogenase were obtained. RR spectra were also measured for the complexes prepared by using isotopically labeled compounds, i.e., [3-13C]-, [1,3-13C]-, and [2,4-13C2]acetoacetyl-CoA; [1-13C]octanoyl-CoA; the dehydrogenase reconstituted with [4a-13C]- and [4,10a-13C2]FAD. Both bands of oxidized flavin and acetoacetyl-CoA were resonance-enhanced in the 632.8 nm excited spectra of the acetoacetyl-CoA complex; this confirms that the broad long-wavelength absorption band is a charge-transfer absorption band between oxidized flavin and acetoacetyl-CoA. The 1,622 cm-1 band was assigned to the C(3)=O stretching mode coupling with the C(2)-H bending mode of the enolate form of acetoacetyl-CoA and the bands at 1,483 and 1,119 cm-1 were assigned to bands associated with the C(2)=C(1)-O- moiety. Both bands of fully reduced flavin and the substrate were resonance-enhanced in the 632.8 nm excited spectra of the purple complex. As the enzyme is already reduced, the substrate must be oxidized to octenoyl-CoA; the complex is a charge-transfer complex between the reduced enzyme and octenoyl-CoA. The low frequency value of the 1,577 cm-1 band, which is associated with the C(2)-C(1)=O moiety of the octenoyl-CoA, suggests that the enzyme-bound octenoyl-CoA has an appreciable contribution of C(2)=C(1)-O-.(ABSTRACT TRUNCATED AT 250 WORDS)     

Three-dimensional structure of the purple intermediate of porcine kidney D-amino acid oxidase. Optimization of the oxidative half-reaction through alignment of the product with reduced flavin

The three-dimensional structure of the purple intermediate of porcine kidney D-amino acid oxidase (DAO) was solved by cryo-X-ray crystallography; the purple intermediate is known to comprise a complex between the dehydrogenated product, an imino acid, and the reduced form of DAO. The crystalline purple intermediate was obtained by anaerobically soaking crystals of oxidized DAO in a buffer containing excess D-proline as the substrate. The dehydrogenated product, delta(1)-pyrrolidine-2-carboxylate (DPC), is found sandwiched between the phenol ring of Tyr 224 and the planar reduced flavin ring. The cationic protonated imino nitrogen is within hydrogen-bonding distance of the backbone carbonyl oxygen of Gly 313. The carboxyl group of DPC is recognized by the Arg 283 guanidino and Tyr 228 hydroxyl groups through ion-pairing and hydrogen-bonding, respectively. The (+)HN=C double bond of DPC overlaps the N(5)-C(4a) bond of reduced flavin. The electrostatic effect of the cationic nitrogen of DPC is suggested to shift the resonance hybridization of anionic reduced flavin toward a canonical form with a negative charge at C(4a), thereby augmenting the electron density at C(4a), from which electrons are transferred to molecular oxygen during reoxidation of reduced flavin. The reactivity of reduced flavin in the purple intermediate, therefore, is enhanced through the alignment of DPC with respect to reduced flavin.     

Influence of the protein environment on the redox potentials of flavodoxins from Clostridium beijerinckii

The flavin mononucleotide (FMN) quinones in flavodoxin have two characteristic redox potentials, namely, Em(FMNH./FMNH-) for the one-electron reduction of the protonated FMN (E1) and Em(FMN/FMNH.) for the proton-coupled one-electron reduction (E2). These redox potentials in native and mutant flavodoxins obtained from Clostridium beijerinckii were calculated by considering the protonation states of all titratable sites as well as the energy contributed at the pKa value of FMN during protonation at the N5 nitrogen (pKa(N5)). E1 is sensitive to the subtle differences in the protein environments in the proximity of FMN. The protein dielectric volume that prevents the solvation of charged FMN quinones is responsible for the downshift of 130-160 mV of the E1 values with respect to that in an aqueous solution. The influence of the negatively charged 5'-phosphate group of FMN quinone on E1 could result in a maximum shift of 90 mV. A dramatic difference of 130 mV in the calculated E2 values of FMN quinone of the native and G57T mutant flavodoxins is due to the difference in the pKa(N5) values. This is due to the difference in the influence exerted by the carbonyl group of the protein backbone at residue 57.     

A 31P-nuclear-magnetic-resonance study of NADPH-cytochrome-P-450 reductase and of the Azotobacter flavodoxin/ferredoxin-NADP+ reductase complex

31P-nuclear-magnetic-resonance spectroscopy has been employed to probe the structure of the detergent-solubilized form of liver microsomal NADPH--cytochrome-P-450 reductase. In addition to the resonances due to the FMN and FAD coenzymes, additional phosphorus resonances are observed and are assigned to the tightly bound adenosine 2'-phosphate (2'-AMP) and to phospholipids. The phospholipid content was found to vary with the preparation; however, the 2'-AMP resonance was observed in all preparations tested. In agreement with published results [Otvos et al. (1986) Biochemistry 25, 7220-7228] for the protease-solubilized enzyme, the addition of Mn(II) to the oxidized enzyme did not result in any observable line-broadening of the FMN and FAD phosphorus resonances. The phospholipid resonances, however, were extensively broadened and the line width of the phosphorus resonance assigned to the bound 2'-AMP was broadened by approximately 70 Hz. The data show that only the phosphorus moieties of the phospholipids and the 2'-AMP, but not the flavin coenzymes are exposed to the bulk solvent. Removal of the FMN moiety from the enzyme substantially alters the 31P-NMR spectrum as compared with the native enzyme. The 2'-AMP is removed from the enzyme during the FMN-depletion procedure and the pyrophosphate resonances of the bound FAD are significantly altered. Reconstitution of the FMN-depleted protein with FMN results in the restoration of the coenzyme spectral properties. Reduction of FMN to its air-stable paramagnetic semiquinone form results in broadening of the FMN and 2'-AMP resonances in the detergent-solubilized enzyme. In agreement with previous results. FMN semiquinone formation had little or no effect on the line width of the FMN phosphorus resonance for the proteolytically solubilized enzyme. 31P-NMR experiments with Azotobacter flavodoxin semiquinone, both in its free form and in a complex with spinach ferredoxin-NADP+ reductase, mimic the differential paramagnetic effects of the flavin semiquinone on the line width of the FMN phosphorus resonance, observed by comparison of the detergent-solubilized and protease-solubilized forms of the reductase. The data demonstrate that assignment of the site of flavin semiquinone formation to a particular flavin coenzyme may not always be possible by 31P-NMR experiments in multi-flavin containing enzymes.     

Mechanism of flavin reduction in the alkanesulfonate monooxygenase system

The alkanesulfonate monooxygenase system from Escherichia coli is involved in scavenging sulfur from alkanesulfonates under sulfur starvation. An FMN reductase (SsuE) catalyzes the reduction of FMN by NADPH, and the reduced flavin is transferred to the monooxygenase (SsuD). Rapid reaction kinetic analyses were performed to define the microscopic steps involved in SsuE catalyzed flavin reduction. Results from single-wavelength analyses at 450 and 550 nm showed that reduction of FMN occurs in three distinct phases. Following a possible rapid equilibrium binding of FMN and NADPH to SsuE (MC-1) that occurs before the first detectable step, an initial fast phase (241 s(-1)) corresponds to the interaction of NADPH with FMN (CT-1). The second phase is a slow conversion (11 s(-1)) to form a charge-transfer complex of reduced FMNH(2) with NADP(+) (CT-2), and represents electron transfer from the pyridine nucleotide to the flavin. The third step (19 s(-1)) is the decay of the charge-transfer complex to SsuE with bound products (MC-2) or product release from the CT-2 complex. Results from isotope studies with [(4R)-(2)H]NADPH demonstrates a rate-limiting step in electron transfer from NADPH to FMN, and may imply a partial rate-limiting step from CT-2 to MC-2 or the direct release of products from CT-2. While the utilization of flavin as a substrate by the alkanesulfonate monooxygenase system is novel, the mechanism for flavin reduction follows an analogous reaction path as standard flavoproteins.     

Acryloyl-CoA reductase from Clostridium propionicum. An enzyme complex of propionyl-CoA dehydrogenase and electron-transferring flavoprotein.

Acryloyl-CoA reductase from Clostridium propionicum catalyses the irreversible NADH-dependent formation of propionyl-CoA from acryloyl-CoA. Purification yielded a heterohexadecameric yellow-greenish enzyme complex [(alpha2betagamma)4; molecular mass 600 +/- 50 kDa] composed of a propionyl-CoA dehydrogenase (alpha2, 2 x 40 kDa) and an electron-transferring flavoprotein (ETF; beta, 38 kDa; gamma, 29 kDa). A flavin content (90% FAD and 10% FMN) of 2.4 mol per alpha2betagamma subcomplex (149 kDa) was determined. A substrate alternative to acryloyl-CoA (Km = 2 +/- 1 microm; kcat = 4.5 s-1 at 100 microm NADH) is 3-buten-2-one (methyl vinyl ketone; Km = 1800 microm; kcat = 29 s-1 at 300 microm NADH). The enzyme complex exhibits acyl-CoA dehydrogenase activity with propionyl-CoA (Km = 50 microm; kcat = 2.0 s-1) or butyryl-CoA (Km = 100 microm; kcat = 3.5 s-1) as electron donor and 200 microm ferricenium hexafluorophosphate as acceptor. The enzyme also catalysed the oxidation of NADH by iodonitrosotetrazolium chloride (diaphorase activity) or by air, which led to the formation of H2O2 (NADH oxidase activity). The N-terminus of the dimeric propionyl-CoA dehydrogenase subunit is similar to those of butyryl-CoA dehydrogenases from several clostridia and related anaerobes (up to 55% sequence identity). The N-termini of the beta and gamma subunits share 40% and 35% sequence identities with those of the A and B subunits of the ETF from Megasphaera elsdenii, respectively, and up to 60% with those of putative ETFs from other anaerobes. Acryloyl-CoA reductase from C. propionicum has been characterized as a soluble enzyme, with kinetic properties perfectly adapted to the requirements of the organism. The enzyme appears not to be involved in anaerobic respiration with NADH or reduced ferredoxin as electron donors. There is no relationship to the trans-2-enoyl-CoA reductases from various organisms or the recently described acryloyl-CoA reductase activity of propionyl-CoA synthase from Chloroflexus aurantiacus.     

Catalytic mechanism of 2-hydroxybiphenyl 3-monooxygenase, a flavoprotein from Pseudomonas azelaica HBP1

2-Hydroxybiphenyl 3-monooxygenase (EC 1.14.13.44) from Pseudomonas azelaica HBP1 is an FAD-dependent aromatic hydroxylase that catalyzes the conversion of 2-hydroxybiphenyl to 2, 3-dihydroxybiphenyl in the presence of NADH and oxygen. The catalytic mechanism of this three-substrate reaction was investigated at 7 degrees C by stopped-flow absorption spectroscopy. Various individual steps associated with catalysis were readily observed at pH 7.5, the optimum pH for enzyme turnover. Anaerobic reduction of the free enzyme by NADH is a biphasic process, most likely reflecting the presence of two distinct enzyme forms. Binding of 2-hydroxybiphenyl stimulated the rate of enzyme reduction by NADH by 2 orders of magnitude. The anaerobic reduction of the enzyme-substrate complex involved the formation of a transient charge-transfer complex between the reduced flavin and NAD(+). A similar transient intermediate was formed when the enzyme was complexed with the substrate analog 2-sec-butylphenol or with the non-substrate effector 2,3-dihydroxybiphenyl. Excess NAD(+) strongly stabilized the charge-transfer complexes but did not give rise to the appearance of any intermediate during the reduction of uncomplexed enzyme. Free reduced 2-hydroxybiphenyl 3-monooxygenase reacted rapidly with oxygen to form oxidized enzyme with no appearance of intermediates during this reaction. In the presence of 2-hydroxybiphenyl, two consecutive spectral intermediates were observed which were assigned to the flavin C(4a)-hydroperoxide and the flavin C(4a)-hydroxide, respectively. No oxygenated flavin intermediates were observed when the enzyme was in complex with 2, 3-dihydroxybiphenyl. Monovalent anions retarded the dehydration of the flavin C(4a)-hydroxide without stabilization of additional intermediates. The kinetic data for 2-hydroxybiphenyl 3-monooxygenase are consistent with a ternary complex mechanism in which the aromatic substrate has strict control in both the reductive and oxidative half-reaction in a way that reactions leading to substrate hydroxylation are favored over those leading to the futile formation of hydrogen peroxide. NAD(+) release from the reduced enzyme-substrate complex is the slowest step in catalysis.     

Electronic transitions in the isoalloxazine ring and orientation of flavins in model membranes studied by polarized light spectroscopy.

The orientation of flavin mononucleotide (FMN) in model membranes and the directions of the transition moments of the first three bands in the electronic absorption spectrum of the oxidized form of the isoalloxazine ring have been determined by means of linear dichroism and polarized fluorescence spectroscopy. Measured counterclockwise relative to the axis connecting the two nitrogens in the central ring (considered positive when going in the direction from -CN less than to greater than or equal to N), these angles are 58 +/- 4 degrees (450-nm band), 97 +/- 3 degrees (350-nm band), and 119 +/- 2 degrees (260-nm band).     

The flavoprotein subcomplex of complex I (NADH:ubiquinone oxidoreductase) from bovine heart mitochondria: insights into the mechanisms of NADH oxidation and NAD+ reduction from protein film voltammetry

Complex I (NADH:ubiquinone oxidoreductase) from bovine heart mitochondria contains 45 different subunits and nine redox cofactors. NADH is oxidized by a noncovalently bound flavin mononucleotide (FMN), then seven iron-sulfur clusters transfer the two electrons to quinone, and four protons are pumped across the inner mitochondrial membrane. Here, we use protein film voltammetry to investigate the mechanisms of NADH oxidation and NAD+ reduction in the simplest catalytically active subcomplex of complex I, the flavoprotein (Fp) subcomplex. The Fp subcomplex was prepared using chromatography and contained the 51 and 24 kDa subunits, the FMN, one [4Fe-4S] cluster, and one [2Fe-2S] cluster. The reduction potential of the FMN in the enzyme's active site is lower than that of free FMN (thus, the oxidized state of the FMN is most strongly bound) and close to the reduction potential of NAD+. Consequently, the catalytic transformation is reversible. Electrocatalytic NADH oxidation by subcomplex Fp can be explained by a model comprising substrate mass transport, the Michaelis-Menten equation, and interfacial electron transfer kinetics. The difference between the "catalytic" potential and the FMN potential suggests that the flavin is reoxidized before NAD+ is released or that intramolecular electron transfer from the flavin to the [4Fe-4S] cluster influences the catalytic rate. NAD+ reduction displays a marked activity maximum, below which the catalytic rate decreases sharply as the driving force increases. Two possible models reproduce the observed catalytic waveshapes: one describing an effect from reducing the proximal [2Fe-2S] cluster and the other the enhanced catalytic ability of the semiflavin state.     

Determination of the midpoint potential of the FAD and FMN flavin cofactors and of the 3Fe-4S cluster of glutamate synthase

Glutamate synthase is a complex iron-sulfur flavoprotein that catalyzes the reductive transfer of the L-glutamine amide group to C(2) of 2-oxoglutarate, forming two molecules of L-glutamate. The bacterial enzyme is an alphabeta protomer, which contains one FAD (on the beta subunit, approximately 50 kDa), one FMN (on the alpha subunit, approximately 150 kDa), and three different Fe-S clusters (one 3Fe-4S center on the alpha subunit and two 4Fe-4S clusters at an unknown location). To address the problem of the intramolecular electron pathway, we have measured the midpoint potential values of the flavin cofactors and of the 3Fe-4S cluster of glutamate synthase in the isolated alpha and beta subunits and in the alphabeta holoenzyme. No detectable amounts of flavin semiquinones were observed during reductive titrations of the enzyme, indicating that the midpoint potential value of each flavin(ox)/flavin(sq) couple is, in all cases, significantly more negative than that of the corresponding flavin(sq)/flavin(hq) couple. Association of the two subunits to form the alphabeta protomer does not alter significantly the midpoint potential value of the FMN cofactor and of the 3Fe-4S cluster (approximately -240 and -270 mV, respectively), but it makes that of FAD some 40 mV less negative (approximately -340 mV for the beta subunit and -300 mV for FAD bound to the holoenzyme). Binding of the nonreducible NADP(+) analogue, 3-aminopyridine adenine dinucleotide phosphate, made the measured midpoint potential value of the FAD cofactor approximately 30-40 mV less negative in the isolated beta subunit, but had no effect on the redox properties of the alphabeta holoenzyme. This result correlates with the formation of a stable charge-transfer complex between the reduced flavin and the oxidized pyridine nucleotide in the isolated beta subunit, but not in the alphabeta holoenzyme. Binding of L-methionine sulfone, a glutamine analogue, had no significant effect on the redox properties of the enzyme cofactors. On the contrary, 2-oxoglutarate made the measured midpoint potential value of the 3Fe-4S cluster approximately 20 mV more negative in the isolated alpha subunit, but up to 100 mV less negative in the alphabeta holoenzyme as compared to the values of the corresponding free enzyme forms. These findings are consistent with electron transfer from the entry site (FAD) to the exit site (FMN) through the 3Fe-4S center of the enzyme and the involvement of at least one of the two low-potential 4Fe-4S centers, which are present in the glutamate synthase holoenzyme, but not in the isolated subunits. Furthermore, the data demonstrate a specific role of 2-oxoglutarate in promoting electron transfer from FAD to the 3Fe-4S cluster of the glutamate synthase holoenzyme. The modulatory role of 2-oxoglutarate is indeed consistent with the recently determined three-dimensional structure of the glutamate synthase alpha subunit, in which several polypeptide stretches are suitably positioned to mediate communication between substrate binding sites and the enzyme redox centers (FMN and the 3Fe-4S cluster) to tightly control and coordinate the individual reaction steps [Binda, C., et al. (2000) Structure 8, 1299-1308].     

pH-dependent spectroscopic changes associated with the hydroquinone of FMN in flavodoxins

Photoreduction with a 5-deazaflavin as the catalyst was used to convert flavodoxins from Desulfovibrio vulgaris, Megasphaera elsdenii, Anabaena PCC 7119, and Azotobacter vinelandii to their hydroquinone forms. The optical spectra of the fully reduced flavodoxins were found to vary with pH in the pH range of 5.0-8.5. The changes correspond to apparent pKa values of 6.5 and 5.8 for flavodoxins from D. vulgaris and M. elsdenii, respectively, values that are similar to the apparent pKa values reported earlier from the effects of pH on the redox potential for the semiquinone-hydroquinone couples of these two proteins (7 and 5.8, respectively). The changes in the spectra resemble those occurring with the free two-electron-reduced flavin for which the pKa is 6.7, but they are red-shifted compared with those of the free flavin. The optical changes occurring with flavodoxins from D. vulgaris and A. vinelandii flavodoxins are larger than those of free reduced FMN. The absorbance of the free and bound flavin increases in the region of 370-390 nm (Delta epsilon = 1-1.8 mM-1 cm-1) with increases of pH. Qualitatively similar pH-dependent changes occur when FMN in D. vulgaris flavodoxin is replaced by iso-FMN, and in the following mutants of D. vulgaris flavodoxin in which the residues mutated are close to the isoalloxazine of the bound flavin: D95A, D95E, D95A/D127A, W60A, Y98S, W60M/Y98W, S96R, and G61A. The 13C NMR spectrum of reduced D. vulgaris [2,4a-13C2]FMN flavodoxin shows two peaks. The peak due to C(4a) is unaffected by pH, but the peak due to C(2) broadens with decreasing pH; the apparent pKa for the change is 6.2. It is concluded that a decrease in pH induces a change in the electronic structure of the reduced flavin due to a change in the ionization state of the flavin, a change in the polarization of the flavin environment, a change in the hydrogen-bonding network around the flavin, and/or possibly a change in the bend along the N(5)-N(10) axis of the flavin. A change in the ionization state of the flavin is the simplest explanation, with the site of protonation differing from that of free FMNH-. The pH effect is unlikely to result from protonation of D95 or D127, the negatively charged amino acids closest to the flavin of D. vulgaris flavodoxin, because the optical changes observed with alanine mutants at these positions are similar to those occurring with the wild-type protein.