Kinetic mechanism and quaternary structure of Aminobacter aminovorans NADH:flavin oxidoreductase: an unusual flavin reductase with bound flavin

The homodimeric NADH:flavin oxidoreductase from Aminobacter aminovorans is an NADH-specific flavin reductase herein designated FRD(Aa). FRD(Aa) was characterized with respect to purification yields, thermal stability, isoelectric point, molar absorption coefficient, and effects of phosphate buffer strength and pH on activity. Evidence from this work favors the classification of FRD(Aa) as a flavin cofactor-utilizing class I flavin reductase. The isolated native FRD(Aa) contained about 0.5 bound riboflavin-5'-phosphate (FMN) per enzyme monomer, but one bound flavin cofactor per monomer was obtainable in the presence of excess FMN or riboflavin. In addition, FRD(Aa) holoenzyme also utilized FMN, riboflavin, or FAD as a substrate. Steady-state kinetic results of substrate titrations, dead-end inhibition by AMP and lumichrome, and product inhibition by NAD(+) indicated an ordered sequential mechanism with NADH as the first binding substrate and reduced FMN as the first leaving product. This is contrary to the ping-pong mechanism shown by other class I flavin reductases. The FMN bound to the native FRD(Aa) can be fully reduced by NADH and subsequently reoxidized by oxygen. No NADH binding was detected using 90 microM FRD(Aa) apoenzyme and 300 microM NADH. All results favor the interpretation that the bound FMN was a cofactor rather than a substrate. It is highly unusual that a flavin reductase using a sequential mechanism would require a flavin cofactor to facilitate redox exchange between NADH and a flavin substrate. FRD(Aa) exhibited a monomer-dimer equilibrium with a K(d) of 2.7 microM. Similarities and differences between FRD(Aa) and certain flavin reductases are discussed.     

Studies on the biosynthesis of cytochrome P-450 in rat liver--a probe with phenobarbital.

The reaction of NAD(P)H:flavin oxidoreductase (flavin reductase) from Photobacterium fischeri is proposed to follow a ping-pong bisubstrate-biproduct mechanism. This is based on a steady-state kinetic analysis of initial velocities and patterns of inhibition by NAD⁺ and AMP. The double reciprocal plots of initial velocities versus concentrations of FMN or NADH show, in both cases, a series of parallel lines. The Michaelis constants for NADH (FMN saturating) and FMN (NADH saturating) are 2.2 and 1.2 × 10^?4m, respectively. The product NAD⁺ has been found to be an inhibitor competitive with FMN but non-competitive with NADH. Using AMP as an inhibitor, noncompetitive inhibition patterns were observed with respect to both NADH and FMN as the varied substrate. In addition, the reductase was not inactivated by treatment with N-ethylmaleimide either alone or in the presence of FMN, but the enzyme was inactivated by N-ethylmaleimide in the presence of NADH. These findings suggest that flavin reductase shuttles between disulfide- and sulfhydryl-containing forms during catalysis.     

Mechanism and substrate specificity of the flavin reductase ActVB from Streptomyces coelicolor

ActVB is the NADH:flavin oxidoreductase participating in the last step of actinorhodin synthesis in Streptomyces coelicolor. It is the prototype of a whole class of flavin reductases with both sequence and functional similarities. The mechanism of reduction of free flavins by ActVB has been studied. Although ActVB was isolated with FMN bound, we have demonstrated that it is not a flavoprotein. Instead, ActVB contains only one flavin binding site, suitable for the flavin reductase activity and with a high affinity for FMN. In addition, ActVB proceeds by an ordered sequential mechanism, where NADH is the first substrate. Whereas ActVB is highly specific for NADH, it is able to catalyze the reduction of a great variety of natural and synthetic flavins, but with K(m) values ranging from 1 microm (FMN) to 69 microm (lumiflavin). We show that both the ribitol-phosphate chain and the isoalloxazine ring contribute to the protein-flavin interaction. Such properties are unique and set the ActVB family apart from the well characterized Fre flavin reductase family.     

Flavin mononucleotide reductase of luminous bacteria

NAD(P)H: FMN oxidoreductase (flavin reductase) couples in vitro to bacterial luciferase. This reductase, which is also postulated to supply reduced flavin mononucleotide in vivo as a substrate for the bioluminescent reaction, has been partially purified and characterized from two species of luminous bacterial. From Photobacterium fischeri the enzyme has a M. W. determined by Sephadex gel filtration, of 43,000 and may have a subunit structure. The turnover number at 20 degrees C, based on a purity estimate of 20 percent, is 1.7 times 10-4 moles of NADH oxidized per min per mole of reductase. The reductase isolated from Beneckea harveyi has an apparent molecular weight of 23,000; its purity was too low to permit estimation of specific activity. Using a spectrophotometric assay at 340 nm with the P. fischeri reductase, both NADH (Km, 8 times 10-5 M) and NADPH (Km, 4 times 10-4 M) were enzymatically oxidized, the Vmax with NADH being approximately twice that of NADPH. Of the flavins tested in this assay, only FMN (Km, 7.3 times 10-5 M) and FAD (Km, 1.4 times 10-4 M) were effective, FMN having a Vmax three times that of FAD. In the coupled assay, i.e., measuring the bioluminescence intensity of the reaction with added luciferase, the optimum FMN concentration was nearly 100 times less than in the spectrophotometric assay. The studies reported suggest the existence of a functional reductase-luciferase complex.     

The dissociation of flavin coenzymes from trypsin-solubilized NADPH/Cytochrome c (P-450) reductase of pig-liver microsomes.

The change in fluorescence emission at 520 nm after excitation at 365 nm was used to investigate the effect of pH and ionic strength on the dissociation of flavin cofactors from microsomal NADPH/cytochrome c (P-450) reductase. In the unmodified enzyme both the FAD and FMN moieties appeared to dissociate at a similar rate and followed first-order kinetics. The rate constant for the dissociation was increased by low pH and high ionic strength, particularly in the range pH 4.4-3.8 (0.02 M acetate buffer) where the rate constants increased 80-fold. Modification of the enzyme by treatment with p-chloromercuribenzoate enhanced the rate of flavin dissociation and, in the region of pH 4, resulted in a biphasic increase in fluorescence consistent with two simultaneous parallel first-order dissociations. It was concluded that p-chloromercuribenzoate treatment modified the protein so that the two flavin cofactors dissociated at different rates. Using the measured rate constants for the dissociations, and the known variation in fluorescence of flavin nucleotides with pH, an analogue computer simulation of the dissociation as well as a manual curve-fitting procedure showed that the biphasic response could be explained as a simultaneous rapid dissociation of FAD and a slower loss of FMN from the protein.     

Structural prototypes for an extended family of flavoprotein reductases: Comparison of phthalate dioxygenase reductase with ferredoxin reductase and ferredoxin

The structure of phthalate dioxygenase reductase (PDR), a monomeric iron-sulfur flavoprotein that delivers electrons from NADH to phthalate dioxygenase, is compared to ferredoxin-NADP⁺ reductase (FNR) and ferredoxin, the proteins that reduce NADP⁺ in the final reaction of photosystem I. The folding patterns of the domains that bind flavin, NAD(P), and [2Fe-2S] are very similar in the two systems. Alignment of the X-ray structures of PDR and FNR substantiates the assignment of features that characterize a family of flavoprotein reductases whose members include cytochrome P-450 reductase, sulfite and nitrate reductases, and nitric oxide synthase. Hallmarks of this subfamily of flavoproteins, here termed the FNR family, are an antiparallel β-barrel that binds the flavin prosthetic group, and a characteristic variant of the classic pyridine nucleotide-binding fold. Despite the similarities between FNR and PDR, attempts to model the structure of a dissociable FNR:ferredoxin complex by analogy with PDR reveal features that are at odds with chemical crosslinking studies (Zanetti, G., Morelli, D., Ronchi, S., Negri, A., Aliverti, A., & Curti, B., 1988, Biochemistry 27, 3753–3759). Differences in the binding sites for flavin and pyridine nucleotides determine the nucleotide specificities of FNR and PDR. The specificity of FNR for NADP⁺ arises primarily from substitutions in FNR that favor interactions with the 2′ phosphate of NADP⁺. Variations in the conformation and sequences of the loop adjoining the flavin phosphate affect the selectivity for FAD versus FMN. The midpoint potentials for reduction of the flavin and [2Fe–2S] groups in PDR are higher than their counterparts in FNR and spinach ferredoxin, by about 120 mV and 260 mV, respectively. Comparisons of the structure of PDR with spinach FNR and with ferredoxin from Anabaena 7120, along with calculations of electrostatic potentials, suggest that local interactions, including hydrogen bonds, are the dominant contributors to these differences in potential.     

X-ray crystal structure of benzoate 1,2-dioxygenase reductase from Acinetobacter sp. strain ADP1

One of the major processes for aerobic biodegradation of aromatic compounds is initiated by Rieske dioxygenases. Benzoate dioxygenase contains a reductase component, BenC, that is responsible for the two-electron transfer from NADH via FAD and an iron-sulfur cluster to the terminal oxygenase component. Here, we present the structure of BenC from Acinetobacter sp. strain ADP1 at 1.5 A resolution. BenC contains three domains, each binding a redox cofactor: iron-sulfur, FAD and NADH, respectively. The [2Fe-2S] domain is similar to that of plant ferredoxins, and the FAD and NADH domains are similar to members of the ferredoxin:NADPH reductase superfamily. In phthalate dioxygenase reductase, the only other Rieske dioxygenase reductase for which a crystal structure is available, the ferredoxin-like and flavin binding domains are sequentially reversed compared to BenC. The BenC structure shows significant differences in the location of the ferredoxin domain relative to the other domains, compared to phthalate dioxygenase reductase and other known systems containing these three domains. In BenC, the ferredoxin domain interacts with both the flavin and NAD(P)H domains. The iron-sulfur center and the flavin are about 9 A apart, which allows a fast electron transfer. The BenC structure is the first determined for a reductase from the class IB Rieske dioxygenases, whose reductases transfer electrons directly to their oxygenase components. Based on sequence similarities, a very similar structure was modeled for the class III naphthalene dioxygenase reductase, which transfers electrons to an intermediary ferredoxin, rather than the oxygenase component.     

Flavin reductase coupling with two monooxygenases involved in dibenzothiophene desulfurization: purification and characterization from a non-desulfurizing bacterium,Paenibacillus polymyxa A-1

The dibenzothiophene (DBT) desulfurizing bacterium metabolizes DBT to form 2-hydroxybiphenyl without breaking the carbon skeleton. Of the DBT desulfurization enzymes, DszC and DszA catalyze monooxygenation reactions, both requiring flavin reductase. We searched for non-DBT-desulfurizing microorganisms producing a flavin reductase that couples more efficiently with DszC than that produced by the DBT desulfurizing bacterium Rhodococcus erythropolis D-1, and found Paenibacillus polymyxa A-1 to be a promising strain. The enzyme was purified to complete homogeneity. K(m) values for FMN and NADH were 2.1 microM and 0.57 mM, respectively. Flavin compounds were good substrates, some nitroaromatic compounds were also active, and regarding the electron donor, the activity for NADPH was about 1.5 times that for NADH. In the coupling assay with DszC, only FMN or riboflavin acted as the electron acceptor. The coupling reactions of P. polymyxa A-1 flavin reductase with DszC and DszA proceeded more efficiently (3.5- and 5-fold, respectively) than those of R. erythropolis D-1 flavin reductase when identical enzyme activities of each flavin reductase were added to the reaction mixture. The result of the coupling reaction suggested that, in the microbial DBT desulfurization, flavin reductase from the non-DBT-desulfurizing bacterium was superior to that from the DBT-desulfurizing bacterium.     

Aminobacter aminovorans NADH:flavin oxidoreductase His140: a highly conserved residue critical for NADH binding and utilization

Homodimeric FRD(Aa) Class I is an NADH:flavin oxidoreductase from Aminobacter aminovorans. It is unusual because it contains an FMN cofactor but utilizes a sequential-ordered kinetic mechanism. Because little is known about NADH-specific flavin reductases in general and FRD(Aa) in particular, this study aimed to further explore FRD(Aa) by identifying the functionalities of a key residue. A sequence alignment of FRD(Aa) with several known and hypothetical flavoproteins in the same subfamily reveals within the flavin reductase active-site domain a conserved GDH motif, which is believed to be responsible for the enzyme and NADH interaction. Mutation of the His140 in this GDH motif to alanine reduced FRD(Aa) activity to <3%. An ultrafiltration assay and fluorescence quenching demonstrated that H140A FRD(Aa) binds FMN in the same 1:1 stoichiometric ratio as the wild-type enzyme, but with slightly weakened affinity (K(d) = 0.9 microM). Anaerobic stopped-flow studies were carried out using both the native and mutated FRD(Aa). Similar to the native enzyme, H140A FRD(Aa) was also able to reduce the FMN cofactor by NADH although much less efficiently. Kinetic analysis of anaerobic reduction measurements indicated that the His140 residue of FRD(Aa) was essential to NADH binding, as well as important for the reduction of the FMN cofactor. For the native enzyme, the cofactor reduction was followed by at least one slower step in the catalytic pathway.     

Activity coupling and complex formation between bacterial luciferase and flavin reductases.

Luminous bacteria contain several species of flavin reductases, which catalyze the reduction of FMN using NADH and/or NADPH as a reductant. The reduced FMN (i.e. FMNH(2)) so generated is utilized along with a long-chain aliphatic aldehyde and molecular oxygen by luciferase as substrates for the bioluminescence reaction. In this report, the general properties of luciferases and reductases from luminous bacteria are briefly summarized. Earlier and more recent studies demonstrating the direct transfer of FMNH(2) from reductases to luciferase are surveyed. Using reductases and luciferases from Vibrio harveyi and Vibrio fischeri, two mechanisms were uncovered for the direct transfer of reduced flavin cofactor and reduced flavin product of reductase to luciferase. A complex of an NADPH-specific reductase (FRP(Vh)) and luciferase from V. harveyi has been detected in vitro and in vivo. Both constituent enzymes in such a complex are catalytically active. The reduction of FRP(Vh)-bound FMN cofactor by NADPH is reversible, allowing the cellular contents of NADP(+) and NADPH as a factor for the regulation of the production of FMNH(2) by FRP(Vh) for luciferase bioluminescence. Other regulations of the activity coupling between reductase and luciferase are also discussed.     

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.     

Crystal structure of enoyl-acyl carrier protein reductase (FabK) from Streptococcus pneumoniae reveals the binding mode of an inhibitor

Enoyl-acyl carrier protein (ACP) reductases are critical for bacterial type II fatty acid biosynthesis and thus are attractive targets for developing novel antibiotics. We determined the crystal structure of enoyl-ACP reductase (FabK) from Streptococcus pneumoniae at 1.7 A resolution. There was one dimer per asymmetric unit. Each subunit formed a triose phosphate isomerase (TIM) barrel structure, and flavin mononucleotide (FMN) was bound as a cofactor in the active site. The overall structure was similar to the enoyl-ACP reductase (ER) of fungal fatty acid synthase and to 2-nitropropane dioxygenase (2-ND) from Pseudomonas aeruginosa, although there were some differences among these structures. We determined the crystal structure of FabK in complex with a phenylimidazole derivative inhibitor to envision the binding site interactions. The crystal structure reveals that the inhibitor binds to a hydrophobic pocket in the active site of FabK, and this is accompanied by induced-fit movements of two loop regions. The thiazole ring and part of the ureido moiety of the inhibitor are involved in a face-to-face pi-pi stacking interaction with the isoalloxazine ring of FMN. The side-chain conformation of the proposed catalytic residue, His144, changes upon complex formation. Lineweaver-Burk plots indicate that the inhibitor binds competitively with respect to NADH, and uncompetitively with respect to crotonoyl coenzyme A. We propose that the primary basis of the inhibitory activity is competition with NADH for binding to FabK, which is the first step of the two-step ping-pong catalytic mechanism.     

Fourier transform infrared spectroscopic study on the conformational reorganization in Escherichia coli complex I due to redox-driven proton translocation

The proton-pumping NADH:ubiquinone oxidoreductase (complex I) couples the transfer of electrons from NADH to ubiquinone with the translocation of protons across the membrane. Electron transfer is accomplished by flavin mononucleotide (FMN) and a series of iron-sulfur (Fe/S) clusters. A novel mechanism has been proposed wherein the electron transfer reaction induces conformational changes that subsequently lead to the translocation of protons. Redox-induced Fourier transform infrared difference spectra have been obtained, showing strong conformational changes in the amide I region. The amplitude of the signal is pH dependent, as expected for an energy coupling step in the enzymes reaction. Furthermore, pH-dependent protonation events and quinone binding were detected.     

Purification and characterization of NADPH-dependent flavin reductase. An enzyme required for the activation of chorismate synthase in Bacillus subtilis.

NADPH-dependent flavin reductase (required for the activation of chorismate synthase) was purified to homogeneity from cell-free extracts of Bacillus subtilis. The enzyme has a molecular weight of 13,000 as determined by sodium dodecyl sulfate-gel electrophoresis, is specific for NADPH, and requires a divalent metal ion and either FMN or FAD for maximal rates of NADPH oxidation. The enzyme is able to reduce 2,6-dichlorophenolindophenol (DCIP) in the presence of NADPH and a divalent metal ion. Both catalytic activities were completely inhibited by EDTA. The Km for FMN is 1.25 X 10(-5) M and for NADPH 7.8 X 10(-5) M with oxygen as the final electron acceptor, and 3.85 X 10(-4) M with DCIP as the final electron acceptor. The enzyme was also isolated in association with chorismate synthase and dehydroquinate synthase. The enzyme associated with the complex has the same catalytic properties as the dissociated enzyme except that it requires both a divalent metal ion and FMN for DCIP reduction. Maximal enzyme activity was observed when the enzyme was preincubated with FMN and the divalent metal ion. The enzyme complex is easily dissociable and the dissociation of the enzyme complex resulted in the failure of NADPH-dependent flavin reductase to adsorb to phosphocellulose.     

NAD(P)H:flavin oxidoreductase of Escherichia coli. A ferric iron reductase participating in the generation of the free radical of ribonucleotide reductase

The active form of one subunit of Escherichia coli ribonucleotide reductase (protein B2) contains an organic free radical localized to tyrosine 122 of its polypeptide chain. When this radical is scavenged, e.g. by treatment with hydroxyurea, the enzyme is inactivated (protein B2/HU). E. coli contains an enzyme system consisting of at least three proteins that in the presence of NADPH, FMN, dithiothreitol, and oxygen introduce the tyrosyl radical into B2/HU (Eliasson, R., J?rnvall, H., and Reichard, P. (1986) Proc. Natl. Acad. Sci. U. S. A. 83, 2373-2377). One of the three proteins was identified as superoxide dismutase. We now identify a second protein, previously provisionally named Fraction c, as an NAD(P)H:flavin oxidoreductase (flavin reductase). After 4,000-fold purification the protein moved as a single band on sodium dodecyl sulfate gel electrophoresis with a molecular weight of 28,000-29,000. The enzyme contained no flavin but reduced riboflavin, FMN, and FAD by NADH, or riboflavin and FMN by NADPH. It is a powerful ferric iron reductase. We propose that its complementing activity during radical generation involves participation in the reduction of the ferric iron center of protein B2/HU. Radical formation is then linked to the reoxidation of iron by oxygen. The flavin reductase may also participate in other aspects of iron metabolism of E. coli.     

Characterization of FMN-dependent NADH-quinone reductase induced by menadione in Escherichia coli

It was found that when Escherichia coli is grown in the presence of 0.2-0.3 mM menadione (2-methyl-1,4-naphthoquinone), an FMN-dependent NADH-quinone reductase increases more than 20-fold in the cytoplasmic fraction. The menadione-induced quinone reductase was isolated from the cytoplasmic fraction of induced cells. The purified enzyme had an Mr of 24 kDa on SDS-polyacrylamide gel electrophoresis. The enzyme required flavin as a cofactor and a half-maximum activity was obtained with 0.54 microM FMN or 16.5 microM FAD. The enzyme had a broad pH optimum at pH 7.0-8.0 and reacted with NADH, but not with NADPH. The reaction followed a ping-pong mechanism and the intrinsic Km values for NADH and menadione were estimated to be 132 microM and 2.0 microM, respectively. Dicoumarol was a simple competitive inhibitor with respect to NADH with a Ki value of 0.22 microM. The electron acceptor specificity of this enzyme was very similar to that of NAD(P)H: (quinone acceptor) oxidoreductase (EC 1.6.99.2, DT-diaphorase) from rat liver. Since menadione is reduced by the two-electron reduction pathway to menadiol, the induction of this enzyme is likely to be an adaptive response of E. coli to partially alleviate the toxicity of menadione.     

The Structural and Functional Basis of Catalysis Mediated by NAD(P)H:acceptor Oxidoreductase (FerB) of Paracoccus denitrificans

FerB from Paracoccus denitrificans is a soluble cytoplasmic flavoprotein that accepts redox equivalents from NADH or NADPH and transfers them to various acceptors such as quinones, ferric complexes and chromate. The crystal structure and small-angle X-ray scattering measurements in solution reported here reveal a head-to-tail dimer with two flavin mononucleotide groups bound at the opposite sides of the subunit interface. The dimers tend to self-associate to a tetrameric form at higher protein concentrations. Amino acid residues important for the binding of FMN and NADH and for the catalytic activity are identified and verified by site-directed mutagenesis. In particular, we show that Glu77 anchors a conserved water molecule in close proximity to the O2 of FMN, with the probable role of facilitating flavin reduction. Hydride transfer is shown to occur from the 4-pro-S position of NADH to the solvent-accessible si side of the flavin ring. When using deuterated NADH, this process exhibits a kinetic isotope effect of about 6 just as does the NADH-dependent quinone reductase activity of FerB; the first, reductive half-reaction of flavin cofactor is thus rate-limiting. Replacing the bulky Arg95 in the vicinity of the active site with alanine substantially enhances the activity towards external flavins that obeys the standard bi-bi ping-pong reaction mechanism. The new evidence for a cryptic flavin reductase activity of FerB justifies the previous inclusion of this enzyme in the protein family of NADPH-dependent FMN reductases.     

Purification, characterization, and overexpression of flavin reductase involved in dibenzothiophene desulfurization by Rhodococcus erythropolis D-1

The dibenzothiophene (DBT)-desulfurizing bacterium, Rhodococcus erythropolis D-1, removes sulfur from DBT to form 2-hydroxybiphenyl using four enzymes, DszC, DszA, DszB, and flavin reductase. In this study, we purified and characterized the flavin reductase from R. erythropolis D-1 grown in a medium containing DBT as the sole source of sulfur. It is conceivable that the enzyme is essential for two monooxygenase (DszC and DszA) reactions in vivo. The purified flavin reductase contains no chromogenic cofactors and was found to have a molecular mass of 86 kDa and four identical 22-kDa subunits. The enzyme catalyzed NADH-dependent reduction of flavin mononucleotide (FMN), and the K(m) values for NADH and FMN were 208 and 10.8 microM, respectively. Flavin adenine dinucleotide was a poor substrate, and NADPH was inert. The enzyme did not catalyze reduction of any nitroaromatic compound. The optimal temperature and optimal pH for enzyme activity were 35 degrees C and 6.0, respectively, and the enzyme retained 30% of its activity after heat treatment at 80 degrees C for 30 min. The N-terminal amino acid sequence of the purified flavin reductase was identical to that of DszD of R. erythropolis IGTS8 (K. A. Gray, O. S. Pogrebinsky, G. T. Mrachko, L. Xi, D. J. Monticello, and C. H. Squires, Nat. Biotechnol. 14:1705-1709, 1996). The flavin reductase gene was amplified with primers designed by using dszD of R. erythropolis IGTS8, and the enzyme was overexpressed in Escherichia coli. The specific activity in crude extracts of the overexpressed strain was about 275-fold that of the wild-type strain.     

Release of flavin from the mitochondrial NADH-dehydrogenase complex

The conditions leading to the release of flavin mononucleotide from the NADH-dehydrogenase Complex I of the mitochondrial respiratory chain were studied. Upon incubation of a mitochondrial suspension for 1-4 h, a spontaneous release of flavin mononucleotide to the aqueous phase was observed. The release abruptly increased even at insignificant damage of mitochondria (by heating, very small quantities of detergents or washings, NaHCO3, and acidic or alkaline pH). This was detected by the enhancement in the intensity of flavin fluorescence and the degree of its depolarization. The loss of flavin mononucleotide leads to the loss of the NADH:ubiquinone reductase activity (but not the NADH: ferricyanide reductase activity). It is suggested that the loss of flavin mononucleotide from Complex I by the action of temperature, detergents, alkali and other agents can be a cause of many mitochondrial diseases.     

Effect of inorganic phosphate on FMN binding and loop flexibility in Desulfovibrio desulfuricans apo-flavodoxin

The complex between flavin mononucleotide (FMN) and apo-flavodoxin is dominated by isoalloxazine-stacking interactions and 5'-phosphate hydrogen bonds. We show here that FMN binding to Desulfovibrio desulfuricans apo-flavodoxin is faster and the affinity is higher in the presence of inorganic phosphate as compared to in its absence (I=110 mM, pH 7, 20 degrees C). The transition-state of complex formation was investigated by phi-value analysis using Trp60Ala and Tyr98Ala apo-flavodoxin variants. We find that Tyr98 is highly involved in the FMN/protein transition state independent of inorganic phosphate, whereas the participation of Trp60 is modulated by inorganic phosphate. The phi-value for Trp60 is higher without phosphate, implying that at this condition stronger binding of Trp60 is required in the transition state to assure successful complex formation. Consistent with the experimental data, all-atom molecular dynamic simulations reveal that the presence of an anion in the phosphate subsite restricts the mobility of the Trp60-containing loop in terms of both backbone and side-chain movements, but has no effect on the Tyr98-containing loop. The overall thermodynamic stability of apo-flavodoxin is higher in the presence of inorganic phosphate as compared to in its absence (I=110 mM, pH 7, 20 degrees C). Kinetic experiments reveal that the additional stability originates in slower unfolding. The combined experimental and computational observations demonstrate that phosphate has an ordering effect on the Trp60-containing loop, which positions Trp60 favorably for FMN binding and increases the barrier for protein unfolding.