Adrenodoxin reductase and adrenodoxin. Mechanisms of reduction of ferricyanide and cytochrome c.

Adrenodoxin reductase, the flavoprotein moiety of the adrenal cortex mitochondrial steroid hydroxylating system, participates in adrenodoxin-dependent cytochrome c and adrenodoxin-independent ferricyanide reduction, with NADPH as electron donor for both of these 1-electron reductions. For ferricyanide reduction, adrenodoxin reductase cycles between oxidized and 2-electron-reduced forms, reoxidation proceeding via the neutral flavin (FAD) semiquinone form (Fig. 9). Addition of adrenodoxin has no effect upon the kinetic parameters of flavoprotein-catalyzed ferricyanide reduction. For cytochrome c reduction, the adrenodoxin reductase-adrenodoxin 1:1 complex has been shown to be the catalytically active species (Lambeth, J. D., McCaslin, D. R., and Kamin, H. (1976) J. Biol. Chem. 251, 7545-7550). Present studies, using stopped flow techniques, have shown that the 2-electron-reduced form of the complex (produced by reaction with 1 eq of NADPH) reacts rapidly with 1 eq of cytochrome c (k approximately or equal to 4.6 s-1), but only slowly with a second cytochrome c (k = 0.1 to 0.3 s-1). However, when a second NADPH is included, two more equivalents of cytochrome are reduced rapidly. Thus, the adrenodoxin reductase-adrenodoxin complex appears to cycle between 1- and 3-electron reduced states, via an intermediate 2-electron-containing form produced by reoxidation by cytochrome (Fig. 10). For ferricyanide reduction by adrenodoxin reductase, the fully reduced and semiquinone forms of flavin each transfer 1 electron at oxidation-reduction potentials which differ by approximately 130 mV. However, adrenodoxin in a complex with adrenodoxin reductase allows electrons of constant potential to be delivered from flavin to cytochrome c via the iron sulfur center...     

Electron transfer in human methionine synthase reductase studied by stopped-flow spectrophotometry

Human methionine synthase reductase (MSR) is a key enzyme in folate and methionine metabolism as it reactivates the catalytically inert cob(II)alamin form of methionine synthase (MS). Electron transfer from MSR to the cob(II)alamin cofactor coupled with methyl transfer from S-adenosyl methionine returns MS to the active methylcob(III)alamin state. MSR contains stoichiometric amounts of FAD and FMN, which shuttle NADPH-derived electrons to the MS cob(II)alamin cofactor. Herein, we have investigated the pre-steady state kinetic behavior of the reductive half-reaction of MSR by anaerobic stopped-flow absorbance and fluorescence spectroscopy. Photodiode array and single-wavelength spectroscopy performed on both full-length MSR and the isolated FAD domain enabled assignment of observed kinetic phases to mechanistic steps in reduction of the flavins. Under single turnover conditions, reduction of the isolated FAD domain by NADPH occurs in two kinetically resolved steps: a rapid (120 s(-1)) phase, characterized by the formation of a charge-transfer complex between oxidized FAD and NADPH, is followed by a slower (20 s(-1)) phase involving flavin reduction. These two kinetic phases are also observed for reduction of full-length MSR by NADPH, and are followed by two slower and additional kinetic phases (0.2 and 0.016 s(-1)) involving electron transfer between FAD and FMN (thus yielding the disemiquinoid form of MSR) and further reduction of MSR by a second molecule of NADPH. The observed rate constants associated with flavin reduction are dependent hyperbolically on NADPH and [4(R)-2H]NADPH concentration, and the observed primary kinetic isotope effect on this step is 2.2 and 1.7 for the isolated FAD domain and full-length MSR, respectively. Both full-length MSR and the separated FAD domain that have been reduced with dithionite catalyze the reduction of NADP+. The observed rate constant of reverse hydride transfer increases hyperbolically with NADP+ concentration with the FAD domain. The stopped-flow kinetic data, in conjunction with the reported redox potentials of the flavin cofactors for MSR [Wolthers, K. R., Basran, J., Munro, A. W., and Scrutton, N. S. (2003) Biochemistry, 42, 3911-3920], are used to define the mechanism of electron transfer for the reductive half-reaction of MSR. Comparisons are made with similar stopped-flow kinetic studies of the structurally related enzymes cytochrome P450 reductase and nitric oxide synthase.     

Preparation and characterization of FAD-dependent NADPH-cytochrome P-450 reductase

NADPH-cytochrome P-450 reductase releases FAD upon dilution into slightly acidic potassium bromide. Chromatography on high performance hydroxylapatite resolved the FAD-dependent reductase from holoreductase. The FAD dependence was matched by a low FAD content, with the ratio of FAD to FMN as low as 0.015. The aporeductase had negligible activity toward cytochrome c, ferricyanide, menadione, dichlorophenolindophenol, nitro blue tetrazolium, and an analogue of NADP, acetylpyridine adenine dinucleotide phosphate. A 4-min incubation in FAD reconstituted from one-half to all of the enzyme activity, as compared to the untreated reductase, depending upon the substrate. After a 2-h reconstitution, the reductase eluted from hydroxylapatite at the same location in the elution profile as did the untreated holoreductase. The reconstituted reductase had little flavin dependence, was nearly equimolar in FMN and FAD, and had close to the specific activity, per mol of flavin, of untreated reductase. The dependence upon FAD implies that FMN is not a competent electron acceptor from NADPH. Thus, the FAD site must be the only point of electron uptake from NADPH.     

Determination of the redox potentials and electron transfer properties of the FAD- and FMN-binding domains of the human oxidoreductase NR1.

Human novel reductase 1 (NR1) is an NADPH dependent diflavin oxidoreductase related to cytochrome P450 reductase (CPR). The FAD/NADPH- and FMN-binding domains of NR1 have been expressed and purified and their redox properties studied by stopped-flow and steady-state kinetic methods, and by potentiometry. The midpoint reduction potentials of the oxidized/semiquinone (-315 +/- 5 mV) and semiquinone/dihydroquinone (-365 +/- 15 mV) couples of the FAD/NADPH domain are similar to those for the FAD/NADPH domain of human CPR, but the rate of hydride transfer from NADPH to the FAD/NADPH domain of NR1 is approximately 200-fold slower. Hydride transfer is rate-limiting in steady-state reactions of the FAD/NADPH domain with artificial redox acceptors. Stopped-flow studies indicate that hydride transfer from the FAD/NADPH domain of NR1 to NADP+ is faster than hydride transfer in the physiological direction (NADPH to FAD), consistent with the measured reduction potentials of the FAD couples [midpoint potential for FAD redox couples is -340 mV, cf-320 mV for NAD(P)H]. The midpoint reduction potentials for the flavin couples in the FMN domain are -146 +/- 5 mV (oxidized/semiquinone) and -305 +/- 5 mV (semiquinone/dihydroquinone). The FMN oxidized/semiquinone couple indicates stabilization of the FMN semiquinone, consistent with (a) a need to transfer electrons from the FAD/NADPH domain to the FMN domain, and (b) the thermodynamic properties of the FMN domain in CPR and nitric oxide synthase. Despite overall structural resemblance of NR1 and CPR, our studies reveal thermodynamic similarities but major kinetic differences in the electron transfer reactions catalysed by the flavin-binding domains.     

Oxidation-reduction potential studies on p-hydroxybenzoate hydroxylase from Pseudomonas fluorescens

The oxidation-reduction potential of p-hydroxybenzoate hydroxylase (4-hydroxybenzoate, NADPH: oxygen oxidoreductase (3-hydroxylating), EC 1.14.13.2) from Pseudomonas fluorescens has been measured in the presence and absence of p-hydroxybenzoate using spectrocoulometry. The native enzyme demonstrated a two-electron midpoint potential of -129 mV during the initial reductive titration. The midpoint potential observed during subsequent oxidative and reductive titrations was -152 mV. This marked hysteresis is proposed to arise from the oxidation and reduction of the known air-sensitive thiol group on the enzyme (Van Berkel, W.J.H. and Müller, F. (1987) Eur. J. Biochem. 167, 35-46). Redox titrations of the enzyme in the presence of substrate showed a two-electron midpoint potential of -177 mV. No spectral or electrochemical evidence for the thermodynamic stabilization of any flavin semiquinone was observed in the titrations performed. These data show that the affinity of the apoenzyme for the hydroquinone form of FAD is 150-fold greater than for the oxidized flavin and that the substrate is bound to the reduced enzyme with a 3-fold lower affinity than to the oxidized enzyme. These data are consistent with the view that the stimulatory effect of substrate binding on the rate of enzyme reduction by NADPH is due to the respective geometries of the bound FAD and NADPH rather than to a large perturbation of the oxidation-reduction potential of the bound flavin coenzyme.     

Kinetic isotope effects on the oxidation of reduced nicotinamide adenine dinucleotide phosphate by the flavoprotein methylenetetrahydrofolate reductase

Previous work from this laboratory has established that the NADPH-menadione oxidoreductase reaction catalyzed by methylenetetrahydrofolate reductase from pig liver proceeds by Ping Pong Bi Bi kinetics and that the reductive half-reaction is rate limiting in steady-state turnover. We have now shown that methylenetetrahydrofolate reductase stereo-specifically removes the pro-S hydrogen from the 4-position of NADPH. During the oxidation of [4(S)-3H]NADPH, we observed a kinetic isotope on V/KNADPH of 10.8 +/- 0.4. When comparing the rates of oxidation of [4(S)-2H]NADPH and [4(S)-1H]NADPH, we measure kinetic isotope effects on V of 4.78 +/- 0.15 and on V/KNADPH of 4.54 +/- 0.59. When oxidation of [4(R)-2H]NADPH and [4(R)-1H]NADPH is compared, the secondary kinetic isotope effect on V is 1.04 +/- 0.01. When the NADPH-menadione oxidoreductase reaction is catalyzed in tritiated water, no incorporation of solvent tritium into residual NADPH is observed. We conclude from these observations that the oxidation of NADPH is largely or entirely rate limiting in the reductive half-reaction and, hence, in NADPH-menadione oxidoreductase turnover at saturating menadione concentration. In the presence of saturating NADPH, the flavin reduction proceeds with a rate constant of 160 S-1, which is at least 29-fold slower than estimates of the lower limit for the diffusion-limited rate constant characterizing NADPH binding to the enzyme under physiological conditions. Albery & Knowles have defined criteria for perfection in enzyme catalysis [Albery, W. J., & Knowles, J.R. (1976) Biochemistry 15, 5631-5640].(ABSTRACT TRUNCATED AT 250 WORDS)     

The p67(phox) activation domain regulates electron flow from NADPH to flavin in flavocytochrome b(558).

An activation domain in p67(phox) (residues within 199-210) is essential for cytochrome b(558)-dependent activation of NADPH superoxide (O2(-.)) generation in a cell-free system (Han, C.-H., Freeman, J. L. R., Lee, T., Motalebi, S. A., and Lambeth, J. D. (1998) J. Biol. Chem. 273, 16663-16668). To determine the steady state reduction flavin in the presence of highly absorbing hemes, 8-nor-8-S-thioacetamido-FAD ("thioacetamido-FAD") was reconstituted into the flavocytochrome, and the fluorescence of its oxidized form was monitored. Thioacetamido-FAD-reconstituted cytochrome showed lower activity (7% versus 100%) and increased steady state flavin reduction (28 versus <5%) compared with the enzyme reconstituted with native FAD. Omission of p67(phox) decreased the percent steady state reduction of the flavin to 4%, but omission of p47(phox) had little effect. The activation domain on p67(phox) was critical for regulating flavin reduction, since mutations in this region that decreased O2(-.) generation also decreased the steady state reduction of flavin. Thus, the activation domain on p67(phox) regulates the reductive half-reaction for FAD. This reaction is comprised of the binding of NADPH followed by hydride transfer to the flavin. Kinetic deuterium isotope effects along with K(m) values permitted calculation of the K(d) for NADPH. (R)-NADPD but not (S)-NADPD showed kinetic deuterium isotope effects on V and V/K of about 1.9 and 1.5, respectively, demonstrating stereospecificity for the R hydride transfer. The calculated K(d) for NADPH was 40 microM in the presence of wild type p67(phox) and was approximately 55 microM using the weakly activating p67(phox)(V205A). Thus, the activation domain of p67(phox) regulates the reduction of FAD but has only a small effect on NADPH binding, consistent with a dominant effect on hydride/electron transfer from NADPH to FAD.     

Kinetics of adrenodoxin reductase oxidation by non-physiologic electron acceptors

The reactions of NADPH oxidation by quinones and inorganic complexes catalyzed by NADPH: adrenodoxin reductase were studied. The catalytic constant for the enzyme at pH 7.0 is 20-25 s-1; the oxidative constants for the quinones vary from 5 X 10(5) to 1.1 X 10(3) M-1 s-1 and show an increase with a rise in the one-electron acceptor reduction potential. The mode of adrenodoxin reductase interaction with oxyquinones differs from that of the enzyme interaction with alkyl-substituted quinones and inorganic complexes. NADPH competitively inhibits electron acceptors, whereas NADP+ is a competitive inhibitor of NADPH and a uncompetitive inhibitor of electron acceptors. (Ki = 25 microM). The depth of FAD incorporation into the enzyme molecule as calculated according to the outer sphere electron transfer theory is 6.1 A.     

Role of Asp1393 in catalysis, flavin reduction, NADP(H) binding, FAD thermodynamics, and regulation of the nNOS flavoprotein

Nitric oxide synthases (NOS) are flavoheme enzymes with important roles in biology. The reductase domain of neuronal NOS (nNOSr) contains a widely conserved acidic residue (Asp(1393)) that is thought to facilitate hydride transfer between NADPH and FAD. Previously we found that the D1393V and D1393N mutations lowered the NO synthesis activity and the rates of heme and flavin reduction in full-length nNOS. To examine the mechanisms for these results in greater detail, we incorporated D1393V and D1393N substitutions into nNOSr along with a truncated NADPH-FAD domain construct (FNR) and characterized the mutants. D1393V nNOSr had markedly lower (相似文献   

Redox potential and equilibria in the reductive half-reaction of Vibrio harveyi NADPH-FMN oxidoreductase

Vibrio harveyi NADPH:FMN oxidoreductase P (FRP(Vh)) is a homodimeric enzyme having a bound FMN per enzyme monomer. The bound FMN functions as a cofactor of FRP(Vh) in transferring reducing equivalents from NADPH to a flavin substrate in the absence of V. harveyi luciferase but as a substrate for FRP(Vh) in the luciferase-coupled bioluminescent reaction. As part of an integral plan to elucidate the regulation of functional coupling between FRP(Vh) and luciferase, this study was carried out to characterize the equilibrium bindings, reductive potential, and the reversibility of the reduction of the bound FMN in the reductive half-reaction of FRP(Vh). Results indicate that, in addition to NADPH binding, NADP(+) also bound to FRP(Vh) in either the oxidized (K(d) 180 microM) or reduced (K(d) 230 microM) form. By titrations with NADP(+) and NADPH and by an isotope exchange experiment, the reduction of the bound FMN by NADPH was found to be readily reversible (K(eq) = 0.8). Hence, the reduction of FRP(Vh)-bound FMN is not the committed step in coupling the NADPH oxidation to bioluminescence. To our knowledge, such an aspect of flavin reductase catalysis has only been clearly established for FRP(Vh). Although the reductive potentials and some other properties of a R203A variant of FRP(Vh) and an NADH/NADPH-utilizing flavin reductase from Vibrio fischeri are quite similar to that of the wild-type FRP(Vh), the reversal of the reduction of bound FMN was not detected for either of these two enzymes.     

Trp(359) regulates flavin thermodynamics and coenzyme selectivity in Mycobacterium tuberculosis FprA

Mtb (Mycobacterium tuberculosis) FprA (flavoprotein reductase A) is an NAD(P)H-dependent FAD-binding reductase that is structurally related to mammalian adrenodoxin reductase, and which supports the catalytic function of Mtb cytochrome P450s. Trp(359), proximal to the FAD, was investigated in light of its potential role in controlling coenzyme interactions, as observed for similarly located aromatic residues in diflavin reductases. Phylogenetic analysis indicated that a tryptophan residue corresponding to Trp(359) is conserved across FprA-type enzymes and in adrenodoxin reductases. W359A/H mutants of Mtb FprA were generated, expressed and the proteins characterized to define the role of Trp(359). W359A/H mutants exhibited perturbed UV-visible absorption/fluorescence properties. The FAD semiquinone formed in wild-type NADPH-reduced FprA was destabilized in the W359A/H mutants, which also had more positive FAD midpoint reduction potentials (-168/-181 mV respectively, versus the standard hydrogen electrode, compared with -230 mV for wild-type FprA). The W359A/H mutants had lower ferricyanide reductase k(cat) and NAD(P)H K(m) values, but this led to improvements in catalytic efficiency (k(cat)/K(m)) with NADH as reducing coenzyme (9.6/18.8 muM(-1).min(-1) respectively, compared with 5.7 muM(-1).min(-1) for wild-type FprA). Stopped-flow spectroscopy revealed NAD(P)H-dependent FAD reduction as rate-limiting in steady-state catalysis, and to be retarded in mutants (e.g. limiting rate constants for NADH-dependent FAD reduction were 25.4 s(-1) for wild-type FprA and 4.8 s(-1)/13.4 s(-1) for W359A/H mutants). Diminished mutant FAD content (particularly in W359H FprA) highlighted the importance of Trp(359) for flavin stability. The results demonstrate that the conserved Trp(359) is critical in regulating FprA FAD binding, thermodynamic properties, catalytic efficiency and coenzyme selectivity.     

Adrenodoxin reductase. Properties of the complexes of reduced enzyme with NADP+ and NADPH.

Anaerobic reduction of the flavoprotein adrenodoxin reductase with NADPH yields a spectrum with long wavelength absorbance, 750 nm and higher. No EPR signal is observed. This spectrum is produced by titration of oxidized adrenodoxin reductase with NADPH, or of dithionite-reduced adrenodoxin reductase with NADP+. Both titrations yield a sharp endpoint at 1 NADP(H) added per flavin. Reduction with other reductants, including dithionite, excess NADH, and catalytic NADP+ with an NADPH generating system, yields a typical fully reduced flavin spectrum, without long wavelength absorbance. The species formed on NADPH reduction appears to be a two-electron-containing complex, with a low dissociation constant, between reduced adrenodoxin reductase and NADP+, designated ARH2-NADP+. Titration of dithionite-reduced adrenodoxin reductase with NADPH also produces a distinctive spectrum, with a sharp endpoint at 1 NADPH added per reduced flavin, indicating formation of a four-electron-containing complex between reduced adrenodoxin reductase and NADPH. Titration of adrenodoxin reductase with NADH, instead of NADPH, provides a curved titration plot rather than the sharp break seen with NADPH, and permits calculation of a potential for the AR/ARH2 couple of -0.291 V, close to that of NAD(P)H (-0.316 V). Oxidized adrenodoxin reductase binds NADP+ much more weakly (Kdiss=1.4 X 10(-5) M) than does reduced adrenodoxin reductase, with a single binding site. The preferential binding of NADP+ to reduced enzyme permits prediction of a more positive oxidation-reduction potential of the flavoprotein in the presence of NADP+; a change of about + 0.1 V has been demonstrated by titration with safranine T. From this alteration in potential, a Kdiss of 1.0 X 10(-8) M for binding of NADP+ to reduced adrenodoxin reductase is calculated. It is concluded that the strong binding of NADP+ to reduced adrenodoxin reductase provides the thermodynamic driving force for formation of a fully reduced flavoprotein form under conditions wherein incomplete reduction would otherwise be expected. Stopped flow studies demonstrate that reduction of adrenodoxin reductase by equimolar NADPH to form the ARH2-NADP+ complex is first order (k=28 s-1). When a large excess of NADPH is used, a second apparently first order process is observed (k=4.25 s-1), which is interpreted as replacement of NADPH for NADP+ in the ARH2-NADP+ complex. Comparison of these rate constants to catalytic flavin turnover numbers for reduction of various oxidants by NADPH, suggests an ordered sequential mechanism in which reduction of oxidant is accomplished by the ARH2-NADP+ complex, followed by dissociation of NADP+. The absolute dependence of NADPH-cytochrome c reduction on both adrenodoxin reductase and adrenodoxin is confirmed...     

Kinetic studies of the reduction of yeast glutathione reductase by reduced nicotinamide hypoxanthine dinucleotide phosphate

The reduction of yeast glutathione reductase by reduced nicotinamide hypoxanthine dinucleotide phosphate (NHxDPH) has been examined by stopped-flow kinetic methods. Like reduced glutathione or NADPH, this pyridine nucleotide generates the catalytically active two-electron reduced form of the enzyme. This reductive half-reaction with NHxDPH has only one detectable kinetic step which shows saturation kinetics (Kd = 76 microM), and has a limiting rate constant of 56 s-1. Comparison of stopped-flow and steady-state turnover data indicates that the reductive half-reaction is rate-limiting in the overall catalytic reaction. No evidence was found for a preequilibrium charge-transfer complex between NHxDPH and the active site FAD, like that seen when NADPH is the electron donor.     

The role of a conserved serine residue within hydrogen bonding distance of FAD in redox properties and the modulation of catalysis by Ca2+/calmodulin of constitutive nitric-oxide synthases

The crystal structure of the neuronal nitric-oxide synthase (nNOS) NADPH/FAD binding domain indicated that Ser-1176 is within hydrogen bonding distance of Asp-1393 and the O4 atom of FAD and is also near the N5 atom of FAD (3.7 A). This serine residue is conserved in most of the ferredoxin-NADP+ reductase family of proteins and is important in electron transfer. In the present study, the homologous serines of both nNOS (Ser-1176) and endothelial nitric-oxide synthase (eNOS) (Ser-942) were mutated to threonine and alanine. Both substitutions yielded proteins that exhibited decreased rates of electron transfer through the flavin domains, in the presence and absence of Ca2+/CaM, as measured by reduction of potassium ferricyanide and cytochrome c. Rapid kinetics measurements of flavin reduction of all the mutants also showed a decrease in the rate of flavin reduction, in the absence and presence of Ca2+/CaM, as compared with the wild type proteins. The serine to alanine substitution caused both nNOS and eNOS to synthesize NO more slowly; however, the threonine mutants gave equal or slightly higher rates of NO production compared with the wild type enzymes. The midpoint redox potential measurements of all the redox centers revealed that wild type and threonine mutants of both nNOS and eNOS are very similar. However, the redox potentials of the FMN/FMNH* couple for alanine substitutions of both nNOS and eNOS are >100 mV higher than those of wild type proteins and are positive. These data presented here suggest that hydrogen bonding of the hydroxyl group of serine or threonine with the isoalloxazine ring of FAD and with the amino acids in its immediate milieu, particularly nNOS Asp-1393, affects the redox potentials of various flavin states, influencing the rate of electron transfer.     

Kinetics of proton-linked flavin conformational changes in p-hydroxybenzoate hydroxylase

p-Hydroxybenzoate hydroxylase (PHBH) is an FAD-dependent monooxygenase that catalyzes the hydroxylation of p-hydroxybenzoate (pOHB) to 3,4-dihydroxybenzoate in an NADPH-dependent reaction. Two structural features are coupled to control the reactivity of PHBH with NADPH: a proton-transfer network that allows protons to be passed between the sequestered active site and solvent and a flavin that adopts two positions: "in", where the flavin is near pOHB, and "out", where the flavin is near NADPH. PHBH uses the proton-transfer network to test for the presence of a suitable aromatic substrate before allowing the flavin to adopt the NADPH-accessible conformation. In this work, kinetic analysis of the His72Asn mutant, with a disrupted proton-transfer network, showed that flavin movement could occur in the presence or absence of NADPH but that NADPH stimulated movement to the reactive conformation required for hydride transfer. Substrate and solvent isotope effects on the transient kinetics of reduction of the His72Asn mutant showed that proton transfer was linked to flavin movement and that the conformational change occurred in a step separate from that of hydride transfer. Proton transfers during the reductive half-reaction were observed directly in the wild-type enzyme by performing experiments in the presence of a fluorescent pH-indicator dye in unbuffered solutions. NADPH binding caused rapid proton release from the enzyme, followed by proton uptake after flavin reduction. Solvent and substrate kinetic isotope effects showed that proton-coupled flavin movement and reduction also occurred in different steps in wild-type PHBH. These results allow a detailed kinetic scheme to be proposed for the reductive half-reaction of the wild-type enzyme. Three kinetic models considered for substrate-induced isomerization are analyzed in the Appendix.     

Rate enhancement of the electron transfer of the adrenodoxin-adrenodoxin reductase system by inorganic and nucleotide phosphates

Phosphate and pyrophosphate increased the rate of reduction of adrenodoxin by NADPH-adrenodoxin reductase and NADPH, pyrophosphate being one order more effective than the former. However, the cytochrome c reduction by the electron transport system was inhibited in the presence of inorganic (pyro)phosphate. On the other hand, ADP and ATP enhanced the rates of reduction of both adrenodoxin and cytochrome c through adrenodoxin by the electron transport system. GTP also enhanced the rate of reduction of cytochrome c by this system, whereas AMP showed no appreciable enhancement. These inorganic and nucleotide phosphates did not affect the rate of ferricyanide reduction by the reductase.     

Tryptophan 697 modulates hydride and interflavin electron transfer in human methionine synthase reductase

Human methionine synthase reductase (MSR), a diflavin oxidoreductase, plays a vital role in methionine and folate metabolism by sustaining methionine synthase (MS) activity. MSR catalyzes the oxidation of NADPH and shuttles electrons via its FAD and FMN cofactors to inactive MS-cob(II)alamin. A conserved aromatic residue (Trp697) positioned next to the FAD isoalloxazine ring controls nicotinamide binding and catalysis in related flavoproteins. We created four MSR mutants (W697S, W697H, S698Δ, and S698A) and studied their associated kinetic behavior. Multiwavelength stopped-flow analysis reveals that NADPH reduction of the C-terminal Ser698 mutants occurs in three resolvable kinetic steps encompassing transfer of a hydride ion to FAD, semiquinone formation (indicating FAD to FMN electron transfer), and slow flavin reduction by a second molecule of NADPH. Corresponding experiments with the W697 mutants show a two-step flavin reduction without an observable semiquinone intermediate, indicating that W697 supports FAD to FMN electron transfer. Accelerated rates of FAD reduction, steady-state cytochrome c(3+) turnover, and uncoupled NADPH oxidation in the S698Δ and W697H mutants may be attributed to a decrease in the energy barrier for displacement of W697 by NADPH. Binding of NADP(+), but not 2',5'-ADP, is tighter for all mutants than for native MSR. The combined studies demonstrate that while W697 attenuates hydride transfer, it ensures coenzyme selectivity and accelerates FAD to FMN electron transfer. Moreover, analysis of analogous cytochrome P450 reductase (CPR) variants points to key differences in the driving force for flavin reduction and suggests that the conserved FAD stacking tryptophan residue in CPR also promotes interflavin electron transfer.     

Monodehydroascorbate reductase from cucumber is a flavin adenine dinucleotide enzyme

Monodehydroascorbate reductase (EC 1.6.5.4) was purified from cucumber fruit to a homogeneous state as judged by polyacrylamide gel electrophoresis. The cucumber monodehydroascorbate reductase was a monomer with a molecular weight of 47,000. It contained 1 mol of FAD/mol of enzyme which was reduced by NAD(P)H and reoxidized by monodehydroascorbate. The enzyme had an exposed thiol group whose blockage with thiol reagents inhibited the electron transfer from NAD(P)H to the enzyme FAD. Both NADH and NADPH served as electron donors with Km values of 4.6 and 23 microM, respectively, and Vmax of 200 mol of NADH and 150 mol of NADPH oxidized mol of enzyme-1 s-1. The Km for monodehydroascorbate was 1.4 microM. The amino acid composition of the enzyme is presented. In addition to monodehydroascorbate, the enzyme catalyzed the reduction of ferricyanide and 2,6-dichloroindophenol but showed little reactivity with calf liver cytochrome b5 and horse heart cytochrome c. The kinetic data suggested a ping-pong mechanism for the monodehydroascorbate reductase-catalyzed reaction. Cucumber monodehydroascorbate reductase occurs in soluble form and can be distinguished from NADPH dehydrogenase, NADH dehydrogenase, DT diaphorase, microsome-bound NADH-cytochrome b5 reductase, and NADPH-cytochrome c reductase by its molecular weight, amino acid composition, and specificity of electron acceptors and donors.     

Use of a site-directed triple mutant to trap intermediates: demonstration that the flavin C(4a)-thiol adduct and reduced flavin are kinetically competent intermediates in mercuric ion reductase

A mutant form of mercuric reductase, which has three of its four catalytically essential cysteine residues replaced by alanines (ACAA: Ala135Cys140Ala558Ala559), has been constructed and used for mechanistic investigations. With disruption of the Hg(II) binding site, the mutant enzyme is devoid of Hg(II) reductase activity. However, it appears to fold properly since it binds FAD normally and exhibits very tight binding of pyridine nucleotides as is seen with the wild-type enzyme. This mutant enzyme allows quantitative accumulation of two species thought to function as intermediates in the catalytic sequence of the flavoprotein disulfide reductase family of enzymes. NADPH reduces the flavin in this mutant, and a stabilized E-FADH- form accumulates. The second intermediate is a flavin C(4a)-Cys140 thiol adduct, which is quantitatively accumulated by reaction of oxidized ACAA enzyme with NADP+. The conversion of the Cys135-Cys140 disulfide in wild-type enzyme to the monothiol Cys140 in ACAA and the elevated pKa of Cys140 (6.7 vs 5.0 in wild type) have permitted detection of these intermediates at low pH (5.0). The rates of formation of E-FADH- and the breakdown of the flavin C(4a)-thiol adduct have been measured and indicate that both intermediates are kinetically competent for both the reductive half-reaction and turnover by wild-type enzyme. These results validate the general proposal that electrons flow from NADPH to FADH- to C(4a)-thiol adduct to the FAD/dithiol form that accumulates as the EH2 form in the reductive half-reaction for this class of enzymes.