Regulation of Riboflavin Biosynthesis in Bacillus subtilis Is Affected by the Activity of the Flavokinase/Flavin Adenine Dinucleotide Synthetase Encoded by ribC

This work shows that the ribC wild-type gene product has both flavokinase and flavin adenine dinucleotide synthetase (FAD-synthetase) activities. RibC plays an essential role in the flavin metabolism of Bacillus subtilis, as growth of a ribC deletion mutant strain was dependent on exogenous supply of FMN and the presence of a heterologous FAD-synthetase gene in its chromosome. Upon cultivation with growth-limiting amounts of FMN, this ribC deletion mutant strain overproduced riboflavin, while with elevated amounts of FMN in the culture medium, no riboflavin overproduction was observed. In a B. subtilis ribC820 mutant strain, the corresponding ribC820 gene product has reduced flavokinase/FAD-synthetase activity. In this strain, riboflavin overproduction was also repressed by exogenous FMN but not by riboflavin. Thus, flavin nucleotides, but not riboflavin, have an effector function for regulation of riboflavin biosynthesis in B. subtilis, and RibC seemingly is not directly involved in the riboflavin regulatory system. The mutation ribC820 leads to deregulation of riboflavin biosynthesis in B. subtilis, most likely by preventing the accumulation of the effector molecule FMN or FAD.     

Metaphosphate-dependent phosphorylation of riboflavin to FMN by Corynebacterium ammoniagenes

Using the bifunctional FAD synthetase from Corynebacterium ammoniagenes, which has the two sequential activities of flavokinase and FMN adenylyl-transferase in FAD biosynthesis, a method of production of the intermediate FMN without any accumulation of FAD was investigated. Various phosphate polymers having no adenylyl moiety were tested for their ability to phosphorylate riboflavin to FMN, using a crude enzyme from C. ammoniagenes/pKH46, which is an FAD-synthetase-gene-dosed strain. Only metaphosphate, other than ATP, could phosphorylate riboflavin to FMN, but FAD did not accumulate at all. The conditions for the conversion of riboflavin to FMN were optimized. The metaphosphate-dependent phosphorylation reaction required Mg²⁺ as the most effective divalent cation. The best concentrations were 10 mM for MgCl₂ and 3mg/ml for metaphosphate. The riboflavin added to the reaction mixture was almost completely converted into FMN after 6 h incubation in the presence of high concentrations of the enzyme preparation.     

Identity of aliphatic L- -hydroxyacid oxidase and glycolate oxidase from rat livers

l-α-Hydroxyacid oxidase and glycolate oxidase have been partially purified from rat livers and found to be identical, judging by substrate specificities, K_m values for certain substrates and coenzyme (FMN), activation energy, inhibition rates by various reagents and pH optimum. K_m values are as follows; glycolate, 2.4 × 10^?4m; l-α-hydroxyisocaproate, 1.26 × 10^?3; glyoxylate, 1.41 × 10^?4m; and FMN, 1.13 × 10^?6m. K_m values for glycolate and FMN are one-tenth and one-twentieth the literature values for hepatic glycolate oxidase. Sucrose density gradient centrifugation establishes that this enzyme is located in hepatic peroxisomes.     

Preparation and properties of immobilized flavokinase.

Flavokinase (ATP: riboflavin 5'-phosphotransferase, EC 2.7.1.26) purified from rat liver by affinity chromatography, has been immobilized by amide linkage to omega-aminoalkyl-agarose beads. The immobilized enzyme differs from the soluble enzyme in having greater stability, slightly higher Km for the substrates, riboflavin and ATP, a broader pH optimum, and a lower energy of activation. These results suggest that the immobilized enzyme is influenced by the microenvironment of the bead and is subject to some degree of internal diffusional limitation. A small (3 ml), continuous, plug-flow reactor prepared with immobilized flavokinase effects 50% conversion of riboflavin to riboflavin 5'-phosphate (FMN) with a flow rate of 0.16 ml/min, which corresponds to an output of 5 nmol FMN/min. Immobilized flavokinase is effective for phosphorylating riboflavin and numerous riboflavin analogs and provides a facile method for preparing exclusively, unlike other synthetic methods, the 5'-phosphates.     

Evaluation of the hydrogen bonding interactions and their effects on the oxidation-reduction potentials for the riboflavin complex of the Desulfovibrio vulgaris flavodoxin

The oxidation-reduction potentials for the riboflavin complex of the Desulfovibrio vulgaris flavodoxin are substantially different from those of the flavin mononucleotide (FMN) containing native protein, with the midpoint potential for the semiquinone-hydroquinone couple for the riboflavin complex being 180 mV less negative. This increase has been attributed to the absence in the riboflavin complex of unfavorable electrostatic effects of the dianionic 5'-phosphate of the FMN on the stability of the flavin hydroquinone anion. In this study, 15N and 1H-15N heteronuclear single-quantum coherence nuclear magnetic resonance spectroscopic studies demonstrate that when bound to the flavodoxin, (1) the N1 of the riboflavin hydroquinone remains anionic at pH 7.0 so the protonation of the hydroquinone is not responsible for this increase, (2) the N5 position is much more exposed and may be hydrogen bonded to solvent, and (3) that while the hydrogen bonding interaction at the N3H appears stronger, that at the N5H in the reduced riboflavin is substantially weaker than for the native FMN complex. Thus, the higher reduction potential of the riboflavin complex is primarily the consequence of altered interactions with the flavin ring that affect hydrogen bonding with the N5H that disproportionately destabilize the semiquinone state of the riboflavin rather than through the absence of the electrostatic effects of the 5'-phosphate on the hydroquinone state.     

A continuous fluorometric assay for flavokinase. Properties of flavokinase from Peptostreptococcus elsdenii.

A continuous fluorometric assay that utilizes apoflavodoxin as a trapping agent for riboflavin 5'-phosphate (FMN) has been developed for flavokinase (ATP:riboflavin 5'-phosphotransferase, EC 2.7.1.26). Use of this assay is illustrated in a procedure for the partial purification of flavokinase from the strict anaerobe Peptostreptococcus elsdenii. The purified enzyme catalyzed the formation of 8.3 nmol FMN - min-1 - mg-1 at 37 degrees C and had apparent Km values for riboflavin and ATP of 10 and 4.7 micronM, respectively. ATP could be replaced by ADP (22% of the rate observed with ATP) but not by GTP. The enzyme also phosphorylated 5-deaza- and 8-bromoriboflavin with activities of 15 and 70%, respectively, of that with riboflavin; it was inactive with iso riboflavin and deoxyriboflavin.     

Probable reaction mechanisms of flavokinase and FAD synthetase from rat liver

A steady-state kinetic analysis with evaluation of product inhibition was accomplished with purified rat liver flavokinase and FAD synthetase. For flavokinase, Km values were calculated as approximately 11 microM for riboflavin and 3.7 microM for ATP. Ki values were calculated for FMN as 6 microM against riboflavin and for ZnADP as 120 microM against riboflavin and 23 microM against ZnATP. From the inhibition pattern, the flavokinase reaction followed an ordered bi bi mechanism in which riboflavin binds first followed by ATP; ADP is released first followed by FMN. For FAD synthetase, Km values were calculated as 9.1 microM for FMN and 71 microM for MgATP. Ki values were calculated for FAD as 0.75 microM against FMN and 1.3 microM against MgATP and for pyrophosphate as 66 microM against FMN. The product inhibition pattern suggests the FAD synthetase reaction also followed an ordered bi bi mechanism in which ATP binds to enzyme prior to FMN, and pyrophosphate is released from enzyme before FAD. Comparison of Ki values with physiological concentrations of FMN and FAD suggests that the biosynthesis of FAD is most likely regulated by this coenzyme as product at the stage of the FAD synthetase reaction.     

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.     

Cloning of FAD synthetase gene from Corynebacterium ammoniagenes and its application to FAD and FMN production

The cloning of a bifunctional FAD synthetase gene, which shows flavokinase and FMN adenylyltransferase activities, from Corynebacterium ammoniagenes was tried by hybridization with synthetic DNAs corresponding to the N-terminal amino acid sequence. The cloned PstI-digested 4.4 × 10³-base (4.4-kb) fragment could not express the FAD synthetase activity in E. coli, but could increase the two activities by the same factor of about 20 in C. amminoagenes. The FAD-synthetase-gene-amplified C. amminoagenes cells were applied to the production of FAD from FMN or riboflavin. The productivity of FAD from FMN was increased four to five times compared with the parent strain, and reached a 90% molar yield. The productivity of FAD from riboflavin was increased about eight times, with a 50% molar yield. The addition of Zn²⁺ to the reaction mixtures for the conversion from riboflavin to FAD brought about the specific inhibition of adenylyltransferase activity and resulted in the accumulation of FMN.     

Insights into the role of F26 residue in the FMN: ATP adenylyltransferase activity of Staphylococcus aureus FAD synthetase

The bifunctional flavin adenine dinucleotide synthetase (FADS) synthesizes the flavin mononucleotide (FMN) and flavin adenine dinucleotide (FAD) co-factors essential for the function of flavoproteins. The Staphylococcus aureus FADS (SaFADS) produces FMN from riboflavin (RF) by ATP:riboflavin kinase (RFK) activity at its C-terminal domain. The N-terminal domain converts FMN to FAD under a reducing environment by FMN:ATP adenylyltransferase (FMNAT) activity which is reversible (FAD pyrophosphorylase activity). Herein, we investigated the role of F26 residue of the 24-GFFD-28 motif of SaFADS FMNAT domain, mostly conserved in the reducing agent-dependent FADSs. The steady-state kinetics studies showed changes in the K_m^ATP values for mutants, indicating that the F26 residue is crucial for the FMNAT activity. Further, the FMNAT activity of the F26S mutant was observed to be higher than that of the wild-type SaFADS and its other variants at lower reducing agent concentration. In addition, the FADpp activity was inhibited by an excess of FAD substrate, which was more potent in the mutants. The altered orientation of the F26 side-chain observed in the molecular dynamics analysis suggested its plausible involvement in stabilizing FMN and ATP substrates in their respective binding pockets. Also, the SaFADS ternary complex formed with reduced FMN exhibited significant structural changes in the β4n-β5n and L3n regions compared to the oxidised FMN bound and apo forms of SaFADS. Overall, our data suggests the functional role of F26 residue in the FMNAT domain of SaFADS.     

Production of flavin mononucleotide by metabolically engineered yeast Candida famata

Recombinant strains of the flavinogenic yeast Candida famata able to overproduce flavin mononucleotide (FMN) that contain FMN1 gene encoding riboflavin (RF) kinase driven by the strong constitutive promoter TEF1 (translation elongation factor 1α) were constructed. Transformation of these strains with the additional plasmid containing the FMN1 gene under the TEF1 promoter resulted in the 200-fold increase in the riboflavin kinase activity and 100-fold increase in FMN production as compared to the wild-type strain (last feature was found only in iron-deficient medium).Overexpression of the FMN1 gene in the mutant that has deregulated riboflavin biosynthesis pathway and high level of riboflavin production in iron-sufficient medium led to the 30-fold increase in the riboflavin kinase activity and 400-fold increase in FMN production of the resulted transformants. The obtained C. famata recombinant strains can be used for the further construction of improved FMN overproducers.     

Fluorescence titration with apoflavodoxin: a sensitive assay for riboflavin 5'-phosphate and flavin adenine dinucleotide in mixtures.

A method is described for determining riboflavin 5′-phosphate (FMN) and flavin adenine dinucleotide (FAD) in mixtures by fluorimetric titration with the FMN-specific apoprotein of flavodoxin from Peptostreptococcus elsdenii. Accurate determinations can be carried out in the presence of a variety of compounds that decrease the fluorescence yield of FMN; the method may therefore be especially useful in the analysis of crude protein-free extracts of biological materials.     

Relationship of prolactin receptors to concanavalin A binding

Concanavalin A, which binds to specific carbohydrate determinants on the cell surface, was used to investigate the binding of prolactin to its receptors in liver membranes from female rats. The binding of ¹²⁵I-labeled ovine prolactin to receptors was sharply inhibited by concanavalin A. This effect was reversed by the competitive sugar α-methyl-D-mannopyranoside and thus required the presence of specifically bound lectin. Concentrations of concanavalin A of up to 50 μg/ml caused a progressive decrease in the apparent affinity of the prolactin receptor for hormone. When higher concentrations were used, the number of available binding sites decreased. Concanavalin A-resistant receptors, about 30% of the total, had the same dissociation constant (K_d) as the controls. The binding of ¹²⁵I-labeled concanavalin A in the same membrane preparations showed the presence of two distinct types of concanavalin A binding. At low concentrations, the lectin bound with high affinity (K_d ≈ 6.6 · 10^?8 M). At high lectin concentrations, low affinity (K_d ≈ 6.7 · 10^?5 M) binding predominated. Since high affinity concanavalin A binding was saturated at 50 μg/ml, this class of binding most likely alters the affinity of the prolactin receptor for hormone; low affinity concanavalin A binding may mask prolactin receptors, making them inaccessible to the hormone.Binding sites for concanavalin A and prolactin appear to be independent but closely related since (i) concanavalin A did not displace bound prolactin from its receptor, and (ii) detergent-solubilized ¹²⁵I-labeled prolactin-receptor complexes bound to concanavalin A-Sepharose and were eluted by α-methyl-D-mannopyranoside.     

Characterisation of the electron transfer and complex formation between Flavodoxin from D. vulgaris and the haem domain of Cytochrome P450 BM3 from B. megaterium

Investigation of the complex formation and electron transfer kinetics between P450 BMP and flavodoxin was carried out following the suggested involvement of flavodoxin in modulating the electron transfer to BMP in artificial redox chains bound to an electrode surface. While electron transfer measurements show the formation of a tightly bound complex, the NMR data indicate the formation of shortly lived complexes. The measured k_obs ranged from 24.2 s^− 1 to 44.1 s^− 1 with k_on ranging from 0.07 × 10⁶ to 1.1 × 10⁶ s^− 1M^− 1 and K_d ranging from 300 μM to 24 μM in buffers of different ionic strength. This apparent contradiction is due to the existence of two events in the complex formation prior to electron transfer. A stable complex is initially formed. Within such tightly bound complex, flavodoxin rocks rapidly between different positions. The rocking of the bound flavodoxin between several different orientations gives rise to the transient complexes in fast exchange as observed in the NMR experiments. Docking simulations with two different approaches support the theory that there is no highly specific orientation in the complex, but instead one side of the flavodoxin binds the P450 with high overall affinity but with a number of different orientations. The level of functionality of each orientation is dependent on the distance between cofactors, which can vary between 8 and 25 Å, with some of the transient complexes showing distances compatible with the measured electron transfer rate constants.     

Purification and characterization of flavokinase from Neurospora crassa

The ATP-dependent phosphorylation of riboflavin to FMN by flavokinase is the key step in flavin biosynthesis. Flavokinase has been purified from a fungal source for the first time. The enzyme purified from a cell wall lacking mutant of Neurospora crassa, slime, is a monomer of M(r) 35.5 kDa with maximal activity at alkaline pH and high temperature (55 degrees C). The K(m) for both substrates is the lowest reported for flavokinase from any source so far (120 nM for riboflavin and 210 nM for MgATP2-). The enzyme exhibits preference for Mg2+ over Zn2+ as the essential activator and is also significantly activated by several cations. Activation by orthophosphate may be physiologically relevant for the intracellular regulation of flavokinase.     

In vitro binding of riboflavin to subcellular particles from maize coleoptiles and Cucurbita hypocotyls

Saturable and reversible in vitro binding of [¹⁴C]riboflavin was found to occur on subcellular, sedimentable particles from maize coleoptiles and Cucurbita hypocotyls. The K_D was ca. 6 M, the pH optimum was near 6.0, and the number of binding sites amounted to 0.1–0.5 M on a fresh-weight basis. When the reducing agent dithionite was present, riboflavin binding increased-the K_D was 2.5 M, and the pH optimum above 8.0. The binding was specific: flavin mononucleotide (FMN) and flavin adenosine-dinucleotide (FAD) bound less tightly to these sites than riboflavin and another major soluble flavin, the previously described riboflavin-analog FX, occurring in grass coleoptiles. These flavin-binding sites were localized on vesicles derived from plasmalemma and endoplasmic reticulum by analyzing sucrose and metrizamide density gradients and marker enzymes.Abbreviations CCO cytochrome-c oxidase - CCR NADH-cytochrome-c oxidoreductase - ER endoplasmic reticulum - FAD flavin-adenosinedinucleotide - FMN flavin mononucleotide - MOPS N-morpholino-3-propansulfonic acid - NADH reduced -nicotinamide dinucleotide - nKP n thousand times g pellet - NPA l-naphthylphthalamic acid - PM plasma membrane, plasmalemma - RBF riboflavin - IAA indoleacetic acid - BA benzoic acid     

Polyamine oxidase from Zea mays shoots

Polyamine oxidase of maize shoots purified 10-fold had a pH optimum of 6·3 with spermidine as substrate, and K_m of 6 × 10^?4 M. The enzyme was inhibited by the acridine compounds quinacrine, 6,9-diamino-2-ethoxyacridine and acriflavin, but carbonyl reagents, typical thiol inhibitors and copper-binding agents were without effect. Inhibition by quinacrine was reversed by FMN and FAD. Furthermore, about 50 % of the activity of the apoenzyme was restored by the addition of FAD, but not by FMN or riboflavin, indicating that the maize polyamine oxidase is an FAD-dependent flavoprotein.     

Characterization of a spontaneous mutant of Azotobacter vinelandii in which vanadium-dependent nitrogen fixation is not inhibited by molybdenum

A spontaneous mutant derivative of Azotobacter vinelandii CA12 (ΔnifHDK), in which vanadium-dependent nitrogen fixation is not inhibited by molybdenum (A. vinelandii CARR), grows profusely on BNF-agar containing 1 μM Na₂MoO₄, alone or supplemented with 1 μM V₂O₅. The expression of A. vinelandii vnfH::lacZ and vnfA::lacZ fusions in A. vinelandii CARR was not inhibited by 1 mM Na₂MoO₄, whereas molybdenum at much lower concentration inhibited the expression of vnfH::lacZ and vnfA::lacZ fusions in A. vinelandii CA12. The mutant also exhibited normal acetylene reduction activity in the presence of 1 μM Na₂MoO₄. The expression of A. vinelandii nifH::lacZ fusion in A. vinelandii CARR was low even though the cells were cultured under non-repressing conditions with urea as nitrogen source in the presence of Na₂MoO₄. The molybdenum content of A. vinelandii CARR cells was found to be about one-fourth that of A. vinelandii CA12. No nitrate reductase activity could be detected in A. vinelandii CARR when the cells were cultured in the presence of 10 μM Na₂MoO₄, whereas A. vinelandii CA12 exhibited some activity even with 100 pM Na₂MoO₄.     

Molecular characterization of FMN1, the structural gene for the monofunctional flavokinase of Saccharomyces cerevisiae

Flavokinase catalyzes the transfer of the gamma-phosphoryl group of ATP to riboflavin to form the flavocoenzyme FMN. Consistent patterns of sequence similarities have identified the open reading frame of unknown function YDR236c as a candidate to encode flavokinase in Saccharomyces cerevisiae. In order to determine whether the product of this gene corresponds to yeast flavokinase, its coding region was amplified from S. cerevisiae genomic DNA by polymerase chain reaction and expressed in Escherichia coli. The purified form of the expressed recombinant protein efficiently catalyzed the formation of FMN from riboflavin and ATP. In contrast to bifunctional prokaryotic flavokinase/FAD synthetase enzymes, the yeast enzyme did not show accompanying FAD synthetase activity. Deletion of YDR236c produced yeast mutants unable to grow on rich medium; however, the growth of the ydr236cDelta mutants could be rescued by the addition of FMN to the medium. Overexpression of YDR236c caused a 50-fold increase in flavokinase specific activity in yeast cells. These findings demonstrate that YDR236c corresponds to the gene encoding a monofunctional flavokinase in yeast, which we propose to be designated as FMN1. The FMN1 gene codes for a 25-kDa protein with characteristics of signals for import into mitochondria. By immunoblotting analysis of Saccharomyces subcellular fractions, we provide evidence that the Fmn1 protein is localized in microsomes and in mitochondria. Analysis of submitochondrial fractions revealed that the mitochondrial form of Fmn1p is an integral protein of the inner membrane exposing its COOH-terminal domain to the matrix space. A similarity search in the data base banks revealed the presence of sequences homologous to yeast flavokinase in the genome of several eukaryotic organisms such as Schizosaccharomyces pombe, Arabidopsis thaliana, Drosophila melanogaster, Caenorhabditis elegans, and humans.     

Orthophosphate is a non-essential activator of Vigna radiata flavokinase.

The ATP-dependent phosphorylation of riboflavin to FMN by flavokinase from Vigna radiata was activated by orthophosphate (Pi) in a concentration dependent manner. Pi affected both the K(m) and Vmax, indicating that it is a non-essential, mixed type activator. The extent of activation by Pi was dependent on the cation (Mg2+ or Zn2+). Activation by other anions could be correlated to similarity to Pi in molecular size and structure. These observations suggest the presence of a binding site(s) for a phosphate-like anion on flavokinase.