Structure of Dihydromethanopterin Reductase,a Cubic Protein Cage for Redox Transfer

Dihydromethanopterin reductase (Dmr) is a redox enzyme that plays a key role in generating tetrahydromethanopterin (H₄MPT) for use in one-carbon metabolism by archaea and some bacteria. DmrB is a bacterial enzyme understood to reduce dihydromethanopterin (H₂MPT) to H₄MPT using flavins as the source of reducing equivalents, but the mechanistic details have not been elucidated previously. Here we report the crystal structure of DmrB from Burkholderia xenovorans at a resolution of 1.9 Å. Unexpectedly, the biological unit is a 24-mer composed of eight homotrimers located at the corners of a cubic cage-like structure. Within a homotrimer, each monomer-monomer interface exhibits an active site with two adjacently bound flavin mononucleotide (FMN) ligands, one deeply buried and tightly bound and one more peripheral, for a total of 48 ligands in the biological unit. Computational docking suggested that the peripheral site could bind either the observed FMN (the electron donor for the overall reaction) or the pterin, H₂MPT (the electron acceptor for the overall reaction), in configurations ideal for electron transfer to and from the tightly bound FMN. On this basis, we propose that DmrB uses a ping-pong mechanism to transfer reducing equivalents from FMN to the pterin substrate. Sequence comparisons suggested that the catalytic mechanism is conserved among the bacterial homologs of DmrB and partially conserved in archaeal homologs, where an alternate electron donor is likely used. In addition to the mechanistic revelations, the structure of DmrB could help guide the development of anti-obesity drugs based on modification of the ecology of the human gut.     

Functions of flavin reductase and quinone reductase in 2,4,6-trichlorophenol degradation by Cupriavidus necator JMP134

The tcpRXABCYD operon of Cupriavidus necator JMP134 is involved in the degradation of 2,4,6-trichlorophenol (2,4,6-TCP), a toxic pollutant. TcpA is a reduced flavin adenine dinucleotide (FADH₂)-dependent monooxygenase that converts 2,4,6-TCP to 6-chlorohydroxyquinone. It has been implied via genetic analysis that TcpX acts as an FAD reductase to supply TcpA with FADH₂, whereas the function of TcpB in 2,4,6-TCP degradation is still unclear. In order to provide direct biochemical evidence for the functions of TcpX and TcpB, the two corresponding genes (tcpX and tcpB) were cloned, overexpressed, and purified in Escherichia coli. TcpX was purified as a C-terminal His tag fusion (TcpX_H) and found to possess NADH:flavin oxidoreductase activity capable of reducing either FAD or flavin mononucleotide (FMN) with NADH as the reductant. TcpX_H had no activity toward NADPH or riboflavin. Coupling of TcpX_H and TcpA demonstrated that TcpX_H provided FADH₂ for TcpA catalysis. Among several substrates tested, TcpB showed the best activity for quinone reduction, with FMN or FAD as the cofactor and NADH as the reductant. TcpB could not replace TcpX_H in a coupled assay with TcpA for 2,4,6-TCP metabolism, but TcpB could enhance TcpA activity. Further, we showed that TcpB was more effective in reducing 6-chlorohydroxyquinone than chemical reduction alone, using a thiol conjugation assay to probe transitory accumulation of the quinone. Thus, TcpB was acting as a quinone reductase for 6-chlorohydroxyquinone reduction during 2,4,6-TCP degradation.     

Insights into electron flux through manipulation of fermentation conditions and assessment of protein expression profiles in Clostridium thermocellum

While annotation of the genome sequence of Clostridium thermocellum has allowed predictions of pathways catabolizing cellobiose to end products, ambiguities have persisted with respect to the role of various proteins involved in electron transfer reactions. A combination of growth studies modulating carbon and electron flow and multiple reaction monitoring (MRM) mass spectrometry measurements of proteins involved in central metabolism and electron transfer was used to determine the key enzymes involved in channeling electrons toward fermentation end products. Specifically, peptides belonging to subunits of ferredoxin-dependent hydrogenase and NADH:ferredoxin oxidoreductase (NFOR) were low or below MRM detection limits when compared to most central metabolic proteins measured. The significant increase in H₂ versus ethanol synthesis in response to either co-metabolism of pyruvate and cellobiose or hypophosphite mediated pyruvate:formate lyase inhibition, in conjunction with low levels of ferredoxin-dependent hydrogenase and NFOR, suggest that highly expressed putative bifurcating hydrogenases play a substantial role in reoxidizing both reduced ferredoxin and NADH simultaneously. However, product balances also suggest that some of the additional reduced ferredoxin generated through increased flux through pyruvate:ferredoxin oxidoreductase must be ultimately converted into NAD(P)H either directly via NADH-dependent reduced ferredoxin:NADP⁺ oxidoreductase (NfnAB) or indirectly via NADPH-dependent hydrogenase. While inhibition of hydrogenases with carbon monoxide decreased H₂ production 6-fold and redirected flux from pyruvate:ferredoxin oxidoreductase to pyruvate:formate lyase, the decrease in CO₂ was only 20 % of that of the decrease in H₂, further suggesting that an alternative redox system coupling ferredoxin and NAD(P)H is active in C. thermocellum in lieu of poorly expressed ferredoxin-dependent hydrogenase and NFOR.     

Flavodoxin cofactor binding induces structural changes that are required for protein–protein interactions with NADP+ oxidoreductase and pyruvate formate-lyase activating enzyme

Flavodoxin (Fld) conformational changes, thermal stability, and cofactor binding were studied using circular dichroism (CD), isothermal titration calorimetry (ITC), and limited proteolysis. Thermodynamics of apo and holo-Fld folding were examined to discern the features of this important electron transfer protein and to provide data on apo-Fld. With the exception of fluorescence and UV–vis binding experiments with its cofactor flavin mononucleotide (FMN), apo-Fld is almost completely uncharacterized in Escherichia coli. Fld is more structured when the FMN cofactor is bound; the association is tight and driven by enthalpy of binding. Surface plasmon resonance binding experiments were carried out under anaerobic conditions for both apo- and holo-Fld and demonstrate the importance of structure and conformation for the interaction with binding partners. Holo-Fld is capable of associating with NADP⁺-dependent flavodoxin oxidoreductase (FNR) and pyruvate formate-lyase activating enzyme (PFL-AE) whereas there is no detectable interaction between apo-Fld and either protein. Limited proteolysis experiments were analyzed by LC-MS to identify the regions in Fld that are involved in conformation changes upon cofactor binding. Docking software was used to model the Fld/PFL-AE complex to understand the interactions between these two proteins and gain insight into electron transfer reactions from Fld to PFL-AE.     

Location of lysyl residues at the allosteric site of fructose 1,6-bisphosphatase

Various flavin analogs were used as alternate substrates or competitive inhibitors to characterize the FMN binding sites of the NADH- and NADPH-specific FMN oxidoreductases from Beneckea harveyi. Several polyhydroxyl compounds were found to be poor competitive inhibitors for the FMN sites of these enzymes. The FMN binding sites of the two enzymes were found to be quite similar. The NADH:FMN oxidoreductase binds FMN exclusively through the isoalloxazine ring. The methyl groups at positions 7 and 8 contribute significantly to this binding. Utilizing lumichrome as a competitive inhibitor of the FMN binding site and AMP as a competitive inhibitor of the NADH binding site, we were able to determine that the NADH:FMN oxidoreductase forms an active ternary complex with NADH binding first in an ordered mechanism. The NADPH oxidoreductase also binds FMN primarily through the isoalloxazine ring. Unlike their participation in reaction with the NADH-specfic enzyme, the methyl groups at positions 7 and 8 are not involved in binding. There was no significant binding of the ribityl phosphate moiety with either enzyme. Both enzymes have lower K_m values for lumiflavin than FMN.     

Metabolism in hyperthermophilic microorganisms

Hyperthermophilic microorganisms grow at temperatures of 90 °C and above and are a recent discovery in the microbial world. They are considered to be the most ancient of all extant life forms, and have been isolated mainly from near shallow and deep sea hydrothermal vents. All but two of the nearly twenty known genera are classified asArchaea (formerly archaebacteria). Virtually all of them are strict anaerobes. The majority are obligate heterotrophs that utilize proteinaceous materials as carbon and energy sources, although a few species are also saccharolytic. Most also depend on the reduction of elemental sulfur to hydrogen sulfide (H₂S) for significant growth. Peptide fermentation involves transaminases and glutamate dehydrogenase, together with several unusual ferredoxin-linked oxidoreductases not found in mesophilic organisms. Similarly, a novel pathway based on a partially non-phosphorylated Entner-Doudoroff scheme has been postulated to convert carbohydrates to acetate, H₂ and CO₂, although a more conventional Embden-Meyerhof pathway has also been identified in one saccharolytic species. The few hyperthermophiles known that can assimilate CO₂ do so via a reductive citric acid cycle. Two S^o-reducing enzymes termed sulfhydrogenase and sulfide dehydrogenase have been purified from the cytoplasm of a hyperthermophile that is able to grow either with or without S^o. A scheme for electron flow during the oxidation of carbohydrates and peptides and the reduction of S^o has been proposed. However, the mechanisms by which S^o reduction is coupled to energy conservation in this organism and in obligate S^o-reducing hyperthermophiles is not known.Abbreviations ADH alcohol dehydrogenase (ADH) - AOR aldehyde ferredoxin oxidoreductase - FMOR formate ferredoxin oxidoreductase - FOR formaldehyde ferredoxin oxidoreductase - GAPDH glyceraldehyde-3-phosphate dehydrogenase - GDH glutamate dehydrogenase - GluOR glucose ferredoxin oxidoreductase - KGOR 2-ketoglutarate ferredoxin oxidoreductase - IOR indolepyruvate ferredoxin oxidoreductase - LDH lactate dehydrogenase - MPT molybopterin - POR pyruvate ferredoxin oxidoreductase - PLP pyridoxal-phosphate - PS polysulfide - TPP thiamin pyrophosphate - S^o elemental sulfur - VOR isovalerate ferredoxin oxidoreductase     

H2O2 Production in Species of the Lactobacillus acidophilus Group: a Central Role for a Novel NADH-Dependent Flavin Reductase

Hydrogen peroxide production is a well-known trait of many bacterial species associated with the human body. In the presence of oxygen, the probiotic lactic acid bacterium Lactobacillus johnsonii NCC 533 excretes up to 1 mM H₂O₂, inducing growth stagnation and cell death. Disruption of genes commonly assumed to be involved in H₂O₂ production (e.g., pyruvate oxidase, NADH oxidase, and lactate oxidase) did not affect this. Here we describe the purification of a novel NADH-dependent flavin reductase encoded by two highly similar genes (LJ_0548 and LJ_0549) that are conserved in lactobacilli belonging to the Lactobacillus acidophilus group. The genes are predicted to encode two 20-kDa proteins containing flavin mononucleotide (FMN) reductase conserved domains. Reductase activity requires FMN, flavin adenine dinucleotide (FAD), or riboflavin and is specific for NADH and not NADPH. The K_m for FMN is 30 ± 8 μM, in accordance with its proposed in vivo role in H₂O₂ production. Deletion of the encoding genes in L. johnsonii led to a 40-fold reduction of hydrogen peroxide formation. H₂O₂ production in this mutant could only be restored by in trans complementation of both genes. Our work identifies a novel, conserved NADH-dependent flavin reductase that is prominently involved in H₂O₂ production in L. johnsonii.     

Identification of a 14mer RNA that recognizes and binds flavin mononucleotide with high affinity

Aptamers are nucleic acids developed by in vitro evolution techniques that bind to specific ligands with high affinity and selectivity. Despite such high affinity and selectivity, however, in vitro evolution does not necessarily reveal the minimum structure of the nucleic acid required for selective ligand binding. Here, we show that a 35mer RNA aptamer for the cofactor flavin mononucleotide (FMN) identified by in vitro evolution can be computationally evolved to a mere 14mer structure containing the original binding pocket and eight scaffolding nucleotides while maintaining its ability to bind in vitro selectively to FMN. Using experimental and computational methodologies, we found that the 14mer binds with higher affinity to FMN (K_D ~ 4 µM) than to flavin adenine dinucleotide (K_D ~ 12 µM) or to riboflavin (K_D ~ 13 µM),despite the negative charge of FMN. Different hydrogen-bond strengths resulting from differing ring-system electron densities associated with the aliphatic-chain charges appear to contribute to the selectivity observed for the binding of the 14mer to FMN and riboflavin. Our results suggest that high affinity and selectivity in ligand binding is not restricted to large RNAs, but can also be a property of extraordinarily short RNAs.     

Hydrogenase Activity and the H2-Fumarate Electron Transport System in Bacteroides fragilis

Hydrogenase activity and the H₂-fumarate electron transport system in a carbohydrate-fermenting obligate anaerobe, Bacteroides fragilis, were investigated. In both whole cells and cell extracts, hydrogenase activity was demonstrated with methylene blue, benzyl viologen, flavin mononucleotide, or flavin adenine dinucleotide as the electron acceptor. A catalytic quantity of benzyl viologen or ferredoxin from Clostridium pasteurianum was required to reduce nicotinamide adenine dinucleotide or nicotinamide adenine dinucleotide phosphate with H₂. Much of the hydrogenase activity appeared to be associated with the soluble fraction of the cell. Fumarate reduction to succinate by H₂ was demonstrable in cell extracts only in the presence of a catalytic quantity of benzyl viologen, flavin mononucleotide, flavin adenine dinucleotide, or ferredoxin from C. pasteurianum. Sulfhydryl compounds were not required for fumarate reduction by H₂, but mercaptoethanol and dithiothreitol appeared to stimulate this activity by 59 and 61%, respectively. Inhibition of fumarate reduction by acriflavin, rotenone, 2-heptyl-4-hydroxyquinoline-N-oxide, and antimycin A suggest the involvement of a flavoprotein, a quinone, and cytochrome b in the reduction of fumarate to succinate. The involvement of a quinone in fumarate reduction is also apparent from the inhibition of fumarate reduction by H₂ when cell extracts were irradiated with ultraviolet light. Based on the evidence obtained, a possible scheme for the flow of electrons from H₂ to fumarate in B. fragilis is proposed.     

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.     

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.     

Purification and Characterization of a Ferredoxin-NADP Oxidoreductase-Like Enzyme from Radish Root Tissues

An enzyme able to reduce cytochrome c via ferredoxin in the presence of NADPH, was isolated, purified from radish (Raphanus sativus var acanthiformis cultivar miyashige) roots and characterized. The enzyme was purified by DEAE-cellulose, Blue-Cellulofine, Ferredoxin-Sepharose 4B, and Sephadex G-100 column chromatography. Molecular mass of the enzyme was estimated to be 33,000 and 35,000 daltons by Sephadex G-100 gel filtration and SDS-PAGE, respectively. Its absorption spectrum suggested that the enzyme contains flavin as a prosthetic group. The K_m values for NADPH and ferredoxin were calculated to be 9.2 and 1.2 micromolar, respectively. The enzyme required NADPH and did not use NADH as an electron donor. The optimal pH was 8.4. The enzyme also catalyzed the photoreduction of NADP⁺ in the spinach leaf thylakoid membranes depleted of ferredoxin and ferredoxin-NADP⁺ oxidoreductase. The effect of NaCl and MgCl₂ concentration on the activity and amino acid composition of the enzyme were demonstrated. The results suggest that the enzyme is similar to ferredoxin-NADP⁺ oxidoreductase from chloroplasts and cyanobacteria and is the key enzyme catalyzing the electron transport between NADPH, generated by the pentose phosphate pathway, and ferredoxin in plastids of plant heterotrophic tissues.     

Isolation and characterization of the transient,luciferase-bound flavin-4a-hydroxide in the bacterial luciferase reaction

Procedures and conditions have been established such that the unstable enzyme-bound flavin intermediate produced in the bacterial luciferase reaction can be isolated as approximately 70% of the flavin product, the remaining being the final product, FMN. The structure of the intermediate is proposed to be that of a luciferase-bound 4a,5-dihydroflavin-4a-hydroxide. The intermediate has a half-life of 33 min at 2°C and decays spontaneously to give H₂O and luciferase-bound FMN with an activation enthalpy of about 120 kJ/mol. It has an absorption spectrum (λ_max = 360 nm) that is consistent with the proposed structure, and a fluorescence emission (λ_max = 485 nm) that matches the bioluminescence emission closely.     

NAD(P)H:Flavin Mononucleotide Oxidoreductase Inactivation during 2,4,6-Trinitrotoluene Reduction

Bacteria readily transform 2,4,6-trinitrotoluene (TNT), a contaminant frequently found at military bases and munitions production facilities, by reduction of the nitro group substituents. In this work, the kinetics of nitroreduction were investigated by using a model nitroreductase, NAD(P)H:flavin mononucleotide (FMN) oxidoreductase. Under mediation by NAD(P)H:FMN oxidoreductase, TNT rapidly reacted with NADH to form 2-hydroxylamino-4,6-dinitrotoluene and 4-hydroxylamino-2,6-dinitrotoluene, whereas 2-amino-4,6-dinitrotoluene and 4-amino-2,6-dinitrotoluene were not produced. Progressive loss of activity was observed during TNT reduction, indicating inactivation of the enzyme during transformation. It is likely that a nitrosodinitrotoluene intermediate reacted with the NAD(P)H:FMN oxidoreductase, leading to enzyme inactivation. A half-maximum constant with respect to NADH, K_N, of 394 μM was measured, indicating possible NADH limitation under typical cellular conditions. A mathematical model that describes the inactivation process and NADH limitation provided a good fit to TNT reduction profiles. This work represents the first step in developing a comprehensive enzyme level understanding of nitroarene biotransformation.     

Ferredoxin:NADP+ oxidoreductase as a target of Cd2+ inhibitory action--biochemical studies

The ferredoxin:NADP+ oxidoreductase (FNR) catalyses the ferredoxin-dependent reduction of NADP+ to NADPH in linear photosynthetic electron transport. The enzyme also transfers electrons from reduced ferredoxin (Fd) or NADPH to the cytochrome b₆f complex in cyclic electron transport. In vitro, the enzyme catalyses the NADPH-dependent reduction of various substrates, including ferredoxin, the analogue of its redox centre - ferricyanide, and the analogue of quinones, which is dibromothymoquinone. This paper presents results on the cadmium-induced inhibition of FNR. The K_i value calculated for research condition was 1.72 mM.FNR molecule can bind a large number of cadmium ions, as shown by the application of cadmium-selective electrode, but just one ion remains bound after dialysis. The effect of cadmium binding is significant disturbance in the electron transfer process from flavin adenine dinucleotide (FAD) to dibromothymoqinone, but less interference with the reduction of ferricyanide. However, it caused a strong inhibition of Fd reduction, indicating that Cd-induced changes in the FNR structure disrupt Fd binding. Additionally, the protonation of the thiol groups is shown to be of great importance in the inhibition process. A mechanism for cadmium-caused inhibition is proposed and discussed with respect to the in vitro and in vivo situation.     

Flavin mononucleotide-binding flavoprotein family in the domain Archaea

The protein (AfpA, for archaeoflavoprotein) encoded by AF1518 in the genome of Archaeoglobus fulgidus was produced in Escherichia coli and characterized. AfpA was found to be a homodimer with a native molecular mass of 43 kDa and containing two noncovalently bound flavin mononucleotides (FMNs). The cell extract of A. fulgidus catalyzed the CO-dependent reduction of AfpA that was stimulated by the addition of ferredoxin. Ferredoxin was found to be a direct electron donor to purified AfpA, whereas rubredoxin was unable to substitute. Neither NADH nor NADPH was an electron donor. Ferricyanide, 2,6-dichlorophenolindophenol, several quinones, ferric citrate, bovine cytochrome c, and O(2) accepted electrons from reduced AfpA, whereas coenzyme F(420) did not. The rate of cytochrome c reduction was enhanced in the presence of O(2) suggesting that superoxide is a product of the interaction of reduced AfpA with O(2). Although AF1518 was previously annotated as encoding a decarboxylase involved in coenzyme A biosynthesis, the results establish that AfpA is an electron carrier protein with ferredoxin as the physiological electron donor. The genomes of several diverse Archaea contained afpA homologs clustered with open reading frames annotated as homologs of genes encoding reductases involved in the oxidative stress response of anaerobes from the domain BACTERIA: A potential role for AfpA in coupling electron flow from ferredoxin to the putative reductases is discussed. A search of the databases suggests that AfpA is the prototype of a previously unrecognized flavoprotein family unique to the domain Archaea for which the name archaeoflavoprotein is proposed.     

The pyruvate: Ferredoxin oxidoreductase in heterocysts of the cyanobacteriuim Anabaena cylindrica

Heterocyst preparations have been obtained which actively perform nitrogen fixation (C₂H₂ reduction) and contain the enzymes of glycolysis and some of the tricarboxylic acid cycle. Pyruvate: ferredoxin oxidereductase has been unambiguously demonstrated in extracts from heterocysts by the formation of acetylcoenzyme A, CO₂ and reduced methyl viologen (ferredoxi) from pyruvate, coenzyme A and oxidized methyl viologen (ferredoxin) as well as by the synthesis of pyruvate from CO₂, acetylcoenzyme A and reduced methyl viologen. Pyruvate supports C₂H₂ reduction by isolated heterocysts, however, with lower activity than Na₂S₂O₄ and H₂. α-Ketoglutarate: ferredoxin oxidoreductase is absent in Anabaena cylindrica, confirming that the organism has an incomplete tricarboxylic acid cycle.     

LuxG is a functioning flavin reductase for bacterial luminescence

The luxG gene is part of the lux operon of marine luminous bacteria. luxG has been proposed to be a flavin reductase that supplies reduced flavin mononucleotide (FMN) for bacterial luminescence. However, this role has never been established because the gene product has not been successfully expressed and characterized. In this study, luxG from Photobacterium leiognathi TH1 was cloned and expressed in Escherichia coli in both native and C-terminal His₆-tagged forms. Sequence analysis indicates that the protein consists of 237 amino acids, corresponding to a subunit molecular mass of 26.3 kDa. Both expressed forms of LuxG were purified to homogeneity, and their biochemical properties were characterized. Purified LuxG is homodimeric and has no bound prosthetic group. The enzyme can catalyze oxidation of NADH in the presence of free flavin, indicating that it can function as a flavin reductase in luminous bacteria. NADPH can also be used as a reducing substrate for the LuxG reaction, but with much less efficiency than NADH. With NADH and FMN as substrates, a Lineweaver-Burk plot revealed a series of convergent lines characteristic of a ternary-complex kinetic model. From steady-state kinetics data at 4°C pH 8.0, K_m for NADH, K_m for FMN, and k_cat were calculated to be 15.1 μM, 2.7 μM, and 1.7 s⁻¹, respectively. Coupled assays between LuxG and luciferases from P. leiognathi TH1 and Vibrio campbellii also showed that LuxG could supply FMNH⁻ for light emission in vitro. A luxG gene knockout mutant of P. leiognathi TH1 exhibited a much dimmer luminescent phenotype compared to the native P. leiognathi TH1, implying that LuxG is the most significant source of FMNH⁻ for the luminescence reaction in vivo.     

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.