The riboflavin/FAD cycle in rat liver mitochondria.

Here we provide evidence that mitochondria isolated from rat liver can synthesize FAD from riboflavin that has been taken up and from endogenous ATP. Riboflavin uptake takes place via a carrier-mediated process, as shown by the inverse relationship between fold accumulation and riboflavin concentration, the saturation kinetics [riboflavin Km and Vmax values were 4.4+/-1.3 microM and 35+/-5 pmol x min(-1) (mg protein)(-1), respectively] and the inhibition shown by the thiol reagent mersalyl, which cannot enter the mitochondria. FAD synthesis is due to the existence of FAD synthetase (EC 2.7.7.2), localized in the matrix, which has as a substrate pair mitochondrial ATP and FMN synthesized from taken up riboflavin via the putative mitochondrial riboflavin kinase. In the light of certain features, including the protein thermal stability and molecular mass, mitochondrial FAD synthetase differs from the cytosolic isoenzyme. Apparent Km and apparent Vmax values for FMN were 5.4+/-0.9 microM and 22.9+/-1.4 pmol x min(-1) x (mg matrix protein)(-1), respectively. Newly synthesized FAD inside the mitochondria can be exported from the mitochondria in a manner sensitive to atractyloside but insensitive to mersalyl. The occurrence of the riboflavin/FAD cycle is proposed to account for riboflavin uptake in mitochondria biogenesis and riboflavin recovery in mitochondrial flavoprotein degradation; both are prerequisites for the synthesis of mitochondrial flavin cofactors.     

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.     

Flavokinase and FAD synthetase from Bacillus subtilis specific for reduced flavins.

A flavokinase preparation from Bacillus subtilis is described which catalyzes the phosphorylation of reduced, but not oxidized, riboflavin. The enzyme is distinguished from other known flavokinases also in having an unusually low Km for the flavin substrate, 50 to 100 nM. ATP is the obligatory phosphate donor; one ATP is utilized for each FMNH2 formed. Mg2+ or Zn2+ is required for the reaction; Co2+ and Mn2+ will substitute, but less effectively. The same enzyme preparation catalyzes the synthesis of FADH2 from FMNH2 and ATP, but not the synthesis of FAD from FMN and ATP. FADH2 is also formed from reduced riboflavin, presumably by sequential flavokinase and FAD synthetase action. Zn2+ cannot replace Mg2+ in FADH2 formation. The reverse reaction, formation of FMN from FAD, occurs only with reduced FAD, giving rise to FMNH2, and is dependent on the presence of inorganic pyrophosphate. The enzyme thus appears to be an FADH2 pyrophosphorylase. The two enzymatic activities, flavokinase and FADH2 pyrophosphorylase, although not separated during the purification procedure, are distinguished by differences in metal ion specificity, in concentration dependence for ATP (apparent Km for ATP = 300 microM for FADH2 synthesis and 6.5 microM for flavokinase), and in the inhibitory effects of riboflavin analogues.     

5'-Nucleotidase of human placental trophoblastic microvilli possesses cobalt-stimulated FAD pyrophosphatase activity

An enzyme with FAD pyrophosphatase activity was extracted from human placental syncytiotrophoblast microvilli and purified to near-homogeneity. The enzyme has been identified as 5'-nucleotidase by several criteria. Throughout purification, parallel increases in the specific activities of FAD pyrophosphatase and AMP phosphatase were observed. The enzyme was a glycoprotein with a subunit molecular weight of 74,000. EDTA treatment resulted in a marked decline in both activities, and restoration of FAD pyrophosphatase activity but not 5'-nucleotidase activity was accomplished by the addition of Co2+ or, to a lesser extent, Mn2+. The substrate specificity of the 5'-nucleotidase activity that we observed agreed closely with the results of others. The pyrophosphatase activity was relatively specific for FAD. ADP, ATP, NAD(H), and FMN were not hydrolyzed, and ADP strongly inhibited both activities. For FAD pyrophosphatase activity, a Km of 1.2 x 10(-5) M and a Vmax of 1.1 mumol/min/mg protein were determined in assays performed in the presence of Co2+. In the absence of added Co2+, the Vmax declined but the Km was unchanged. For 5'-nucleotidase (AMP as substrate) the Km was 4.1 x 10(-5) M and the Vmax 109 mumol/min/mg protein. Hydrolysis of FMN to riboflavin was observed in partially purified detergent extracts of microvilli that contained alkaline phosphatase activity and lacked FAD pyrophosphatase and 5'-nucleotidase activity. The presence of both FAD pyrophosphatase and FMN phosphatase activities in syncytiotrophoblast microvilli supports the view that the placental uptake of vitamin B2 involves the hydrolysis of FAD and FMN to riboflavin which is then absorbed, a sequence postulated for intestinal absorption and liver uptake.     

A continuous spectrophotometric determination of hepatic microsomal azo reductase activity and its dependence on cytochrome P-450.

1. A continuous spectrophotometric determination of rat hepatic microsomal anaerobic azo reductase activity has been developed. 2. The addition of soluble flavins (riboflavin, FMN or FAD) greatly increased this NADPH-dependent activity towards a number of azo substrates. 3. Investigations with amaranth as substrate gave an apparent Km of 34 microM and Vmax. of 4 nmol/min per mg of microsomal protein. The inclusion of a fixed concentration of FMN increased Vmax. and greatly decreased Km, the magnitude of these changes reflecting the concentration of flavin present. 4. Investigations using a fixed amaranth concentration over a range of flavin concentrations gave biphasic double-reciprocal plots with two apparent Km and Vmax. values. 5. Pretreatment of animals with cobaltous chloride, 2-allyl-2-isopropylacetamide, carbon tetrachloride, phenobarbitone and 3-methylcholanthrene altered azo reductase activity in parallel with changes in cytochrome P-450 content. 6. The significance of these results is discussed in terms of the electron-transfer components present in the hepatic microsomal fraction.     

FAD is a preferred substrate and an inhibitor of Escherichia coli general NAD(P)H:flavin oxidoreductase

Escherichia coli general NAD(P)H:flavin oxidoreductase (Fre) does not have a bound flavin cofactor; its flavin substrates (riboflavin, FMN, and FAD) are believed to bind to it mainly through the isoalloxazine ring. This interaction was real for riboflavin and FMN, but not for FAD, which bound to Fre much tighter than FMN or riboflavin. Computer simulations of Fre.FAD and Fre.FMN complexes showed that FAD adopted an unusual bent conformation, allowing its ribityl side chain and ADP moiety to form an additional 3.28 H-bonds on average with amino acid residues located in the loop connecting Fbeta5 and Falpha1 of the flavin-binding domain and at the proposed NAD(P)H-binding site. Experimental data supported the overlapping binding sites of FAD and NAD(P)H. AMP, a known competitive inhibitor with respect to NAD(P)H, decreased the affinity of Fre for FAD. FAD behaved as a mixed-type inhibitor with respect to NADPH. The overlapped binding offers a plausible explanation for the large K(m) values of Fre for NADH and NADPH when FAD is the electron acceptor. Although Fre reduces FMN faster than it reduces FAD, it preferentially reduces FAD when both FMN and FAD are present. Our data suggest that FAD is a preferred substrate and an inhibitor, suppressing the activities of Fre at low NADH concentrations.     

Evolutionary divergence of chloroplast FAD synthetase proteins

Background  

Flavin adenine dinucleotide synthetases (FADSs) - a group of bifunctional enzymes that carry out the dual functions of riboflavin phosphorylation to produce flavin mononucleotide (FMN) and its subsequent adenylation to generate FAD in most prokaryotes - were studied in plants in terms of sequence, structure and evolutionary history.     

The FAD binding sites of human liver monoamine oxidases A and B: investigation of the role of flavin ribityl side chain hydroxyl groups in the covalent flavinylation reaction and catalytic activities

The role of ribityl side chain hydroxyl groups of the flavin moiety in the covalent flavinylation reaction and catalytic activities of recombinant human liver monoamine oxidases (MAO) A and B have been investigated using the riboflavin analogue: N(10)-omega-hydroxypentyl-isoalloxazine. Using a rib5 disrupted strain of Saccharomyces cerevisiae which is auxotrophic for riboflavin, MAO A and MAO B were expressed separately under control of a galactose inducible GAL10/CYC1 promoter in the presence of N(10)-omega-hydroxypentyl-isoalloxazine as the only available riboflavin analogue. Analysis of mitochondrial membrane proteins shows both enzymes to be expressed at levels comparable to those cultures grown on riboflavin and to contain covalently bound flavin. Catalytic activities, as monitored by kynuramine oxidation, are equivalent to (MAO A) or 2-fold greater (MAO B) than control preparations expressed in the presence of riboflavin. Although N(10)-omega-hydroxypentyl-isoalloxazine is unable to support growth of riboflavin auxotrophic S. cerevisiae, it is converted to the FMN level by yeast cell free extracts. The FMN form of the analogue is converted to the FAD level by the yeast FAD synthetase, as shown by expression of the recombinant enzyme in Escherichia coli. These data show that the ribityl hydroxyl groups of the FAD moiety are not required for covalent flavinylation or catalytic activities of monoamine oxidases A and B. This is in contrast to the suggestion based on mutagenesis studies that an interaction between the 3'-hydroxyl group of the flavin and the beta-carbonyl of Asp(227) is required for the covalent flavinylation reaction of MAO B (Zhou et al., J. Biol. Chem. 273 (1998) 14862-14868).     

Cloning and characterization of FAD1, the structural gene for flavin adenine dinucleotide synthetase of Saccharomyces cerevisiae.

The FAD1 gene of Saccharomyces cerevisiae has been selected from a genomic library on the basis of its ability to partially correct the respiratory defect of pet mutants previously assigned to complementation group G178. Mutants in this group display a reduced level of flavin adenine dinucleotide (FAD) and an increased level of flavin mononucleotide (FMN) in mitochondria. The restoration of respiratory capability by FAD1 is shown to be due to extragenic suppression. FAD1 codes for an essential yeast protein, since disruption of the gene induces a lethal phenotype. The FAD1 product has been inferred to be yeast FAD synthetase, an enzyme that adenylates FMN to FAD. This conclusion is based on the following evidence. S. cerevisiae transformed with FAD1 on a multicopy plasmid displays an increase in FAD synthetase activity. This is also true when the gene is expressed in Escherichia coli. Lastly, the FAD1 product exhibits low but significant primary sequence similarity to sulfate adenyltransferase, which catalyzes a transfer reaction analogous to that of FAD synthetase. The lower mitochondrial concentration of FAD in G178 mutants is proposed to be caused by an inefficient exchange of external FAD for internal FMN. This is supported by the absence of FAD synthetase activity in yeast mitochondria and the presence of both extramitochondrial and mitochondrial riboflavin kinase, the preceding enzyme in the biosynthetic pathway. A lesion in mitochondrial import of FAD would account for the higher concentration of mitochondrial FMN in the mutant if the transport is catalyzed by an exchange carrier. The ability of FAD1 to suppress impaired transport of FAD is explained by mislocalization of the synthetase in cells harboring multiple copies of the gene. This mechanism of suppression is supported by the presence of mitochondrial FAD synthetase activity in S. cerevisiae transformed with FAD1 on a high-copy-number plasmid but not in mitochondrial of a wild-type strain.     

Metabolic and bioprocess engineering of the yeast Candida famata for FAD production

Flavins in the form of flavin mononucleotide (FMN) and flavin adenine dinucleotide (FAD) play an important role in metabolism as cofactors for oxidoreductases and other enzymes. Flavin nucleotides have applications in the food industry and medicine; FAD supplements have been efficiently used for treatment of some inheritable diseases. FAD is produced biotechnologically; however, this compound is much more expensive than riboflavin. Flavinogenic yeast Candida famata synthesizes FAD from FMN and ATP in the reaction catalyzed by FAD synthetase, a product of the FAD1 gene. Expression of FAD1 from the strong constitutive promoter TEF1 resulted in 7- to 15-fold increase in FAD synthetase activity, FAD overproduction, and secretion to the culture medium. The effectiveness of FAD production under different growth conditions by one of these recombinant strains, C. famata T-FD-FM 27, was evaluated. First, the two-level Plackett–Burman design was performed to screen medium components that significantly influence FAD production. Second, central composite design was adopted to investigate the optimum value of the selected factors for achieving maximum FAD yield. FAD production varied most significantly in response to concentrations of adenine, KH₂PO₄, glycine, and (NH₄)₂SO₄. Implementation of these optimization strategies resulted in 65-fold increase in FAD production when compared to the non-optimized control conditions. Recombinant strain that has been cultivated for 40 h under optimized conditions achieved a FAD accumulation of 451 mg/l. So, for the first time yeast strains overproducing FAD were obtained, and the growth media composition for maximum production of this nucleotide was designed.     

High-affinity binding of riboflavin and FAD by immunoglobulins from normal human serum

The binding of [3H]FAD and [3H]riboflavin to a pooled, human plasma immunoglobulin fraction was studied. For each flavin, the data fit best a model with two binding sites of high affinity and a class of sites of lower affinity. The dissociation constants estimated for the two high affinity sites were 1.73 nM and 0.078 nM for [3H]FAD and 2.43 nM and 0.068 nM for [3H]riboflavin. The results of studies with a series of possible competitors suggested that the flavin ring system was an important determinant of the binding. Other studies showed that the binding reaction was largely enthalpy-driven. Our findings show that normal human immunoglobulins contain one or more species that bind riboflavin and FAD with very high affinity.     

The recognition of glycolate oxidase apoprotein with flavin analogs in higher plants

The net photosynthetic efficiency in C3 plants (such asrice, wheat and other major crops) can be decreased by30% due to the metabolism of photorespiration [1], inwhich glycolate oxidase (GO) serves as a key enzyme. Itis known that GO, with flavin mononucleotide (FMN) asa cofactor, belongs to flavin oxidase [2]. But it differs fromother flavoproteins in that FMN is loosely bound to itsapoprotein and there exists a dissociation balance betweenthem, which indicates that FMN probably regulate…     

Oligomeric State in the Crystal Structure of Modular FAD Synthetase Provides Insights into Its Sequential Catalysis in Prokaryotes

The crystal structure of the modular flavin adenine dinucleotide (FAD) synthetase from Corynebacterium ammoniagenes has been solved at 1.95 Å resolution. The structure of C. ammoniagenes FAD synthetase presents two catalytic modules—a C-terminus with ATP-riboflavin kinase activity and an N-terminus with ATP-flavin mononucleotide (FMN) adenylyltransferase activity—that are responsible for the synthesis of FAD from riboflavin in two sequential steps. In the monomeric structure, the active sites from both modules are placed 40 Å away, preventing the direct transfer of the product from the first reaction (FMN) to the second catalytic site, where it acts as substrate. Crystallographic and biophysical studies revealed a hexameric assembly formed by the interaction of two trimers. Each trimer presents a head-tail configuration, with FMN adenylyltransferase and riboflavin kinase modules from different protomers approaching the active sites and allowing the direct transfer of FMN. Experimental results provide molecular-level evidences of the mechanism of the synthesis of FMN and FAD in prokaryotes in which the oligomeric state could be involved in the regulation of the catalytic efficiency of the modular enzyme.     

Entamoeba histolytica: flavins in axenic organisms.

The individual flavin species of axenic Entamoeba histolytica were assayed: separated riboflavin was assayed by the lumiflavin method; flavin-adenine dinucleotide (FAD), by an enzymatic method; flavin mononucleotide (FMN) was calculated from the difference, total flavin minus FAD and riboflavin. The amount of flavin in micrograms per grams fresh cells follows: total flavin, 7.6 ± 0.9 calculated as riboflavin; riboflavin, 1.6 ± 0.7; FMN, 6.6 ± 0.5; and FAD, 1.2 ± 0.1. Recalculated to nanomoles per milligrams total amebal protein these values were: total flavin, 0.21; riboflavin, 0.04; FMN, 0.15; and FAD, 0.02. The identity of each flavin was confirmed by a paper chromatographic method. Analyses on Panmede, the main source of flavins in the TP-S-1 medium, indicate that it contains all three forms of flavin. Its contribution to growth medium in micrograms per milliliters: riboflavin, 2.1 ± 0.3; FMN, 0.6 ± 0.1; and FAD, 0.4 ± 0.1. The in vivo biosynthesis of FMN and FAD from riboflavin by E. histolytica is demonstrated. A new and convenient method was found to separate riboflavin from flavin nucleotides in tissue extracts.     

A conserved domain in prokaryotic bifunctional FAD synthetases can potentially catalyze nucleotide transfer

Biosynthesis of flavin adenine dinucleotides in most prokaryotes is catalyzed by a family of bifunctional flavin adenine dinucleotide (FAD) synthetases. These enzymes carry out the dual functions of phosphorylation of flavin mononucleotide (FMN) and its subsequent adenylylation to generate FAD. Using various sequence analysis methods, a new domain has been identified in the N-terminal region that is well conserved in all the bacterial FAD synthetases. We also identify remote similarity of this domain to the nucleotidyl transferases and, hence, this domain is suggested to be invloved in the adenylylation reaction of FAD synthetases.     

Flavin specificity and subunit interaction of Vibrio fischeri general NAD(P)H-flavin oxidoreductase FRG/FRase I

Apoenzyme of the major NAD(P)H-utilizing flavin reductase FRG/FRase I from Vibrio fischeri was prepared. The apoenzyme bound one FMN cofactor per enzyme monomer to yield fully active holoenzyme. The FMN cofactor binding resulted in substantial quenching of both the flavin and the protein fluorescence intensities without any significant shifts in the emission peaks. In addition to FMN binding (K(d) 0.5 microM at 23 degrees C), the apoenzyme also bound 2-thioFMN, FAD and riboflavin as a cofactor with K(d) values of 1, 12, and 37 microM, respectively, at 23 degrees C. The 2-thioFMN containing holoenzyme was about 40% active in specific activity as compared to the FMN-containing holoenzyme. The FAD- and riboflavin-reconstituted holoenzymes were also catalytically active but their specific activities were not determined. FRG/FRase I followed a ping-pong kinetic mechanism. It is proposed that the enzyme-bound FMN cofactor shuttles between the oxidized and the reduced form during catalysis. For both the FMN- and 2-thioFMN-containing holoenzymes, 2-thioFMN was about 30% active as compared to FMN as a substrate. FAD and riboflavin were also active substrates. FRG/FRase I was shown by ultracentrifugation at 4 degrees C to undergo a monomer-dimer equilibrium, with K(d) values of 18.0 and 13.4 microM for the apo- and holoenzymes, respectively. All the spectral, ligand equilibrium binding, and kinetic properties described above are most likely associated with the monomeric species of FRG/FRase I. Many aspects of these properties are compared with a structurally and functionally related Vibrio harveyi NADPH-specific flavin reductase FRP.     

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.     

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.     

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.