Your search keyword '"*FLAVINS"' showing total 16 results

1. A Flavin-Dependent Decarboxylase-Dehydrogenase- Monooxygenase Assembles the Warhead of α,β-Epoxyketone Proteasome Inhibitors.

Author

Zabala, Daniel, Cartwright, Joshua W., Roberts, Douglas M., Law, Brian J. C., Lijiang Song, Samborskyy, Markiyan, Leadlay, Peter F., Micklefield, Jason, and Challis, Gregory L.

Subjects

*FLAVINS, *DEHYDROGENASES, *MONOOXYGENASES, *STREPTOMYCES, *PROTEASOME inhibitors

Abstract

The α,β-epoxyketone proteasome inhibitor TMC-86A was discovered as a previously unreported metabolite of Streptomyces chromofuscus ATCC49982, and the gene cluster responsible for its biosynthesis was identified via genome sequencing. Incorporation experiments with [13C-methyl]L-methionine implicated an α-dimethyl-β-keto acid intermediate in the biosynthesis of TMC-86A. Incubation of the chemically synthesized α-dimethyl-β-keto acid with a purified recombinant flavin-dependent enzyme that is conserved in all known pathways for epoxyketone biosynthesis resulted in formation of the corresponding α-methyl-α,β-epoxyketone. This transformation appears to proceed via an unprecedented decarboxylation-dehydrogenation-monooxygenation cascade. The biosynthesis of the TMC-86A warhead is completed by cytochrome P450-mediated hydroxylation of the α-methyl-α,β-epoxyketone. [ABSTRACT FROM AUTHOR]

Published

2016

2. Mechanism of Oxygen Activation in a Flavin-Dependent Monooxygenase: A Nearly Barrierless Formation of C4a-Hydroperoxyflavin via Proton-Coupled Electron Transfer.

Author

Visitsatthawong, Surawit, Chenprakhon, Pirom, Chaiyen, Pimchai, and Surawatanawong, Panida

Subjects

*ACTIVATION (Chemistry), *FLAVINS, *MONOOXYGENASES, *HYDROPEROXIDES, *CHARGE exchange, *PROTON-proton interactions

Abstract

Understanding how flavin-dependent enzymes activate oxygen for their oxidation and oxygenation reactions is one of the most challenging issues in flavoenzymology. Density functional calculations and transient kinetics were performed to investigate the mechanism of oxygen activation in the oxygenase component (C2) of p-hydroxyphenylacetate 3-hydroxylase (HPAH). We found that the protonation of dioxygen by His396 via a proton-coupled electron transfer mechanism is the key step in the formation of the triplet diradical complex of flavin semiquinone and ·OOH. This complex undergoes intersystem crossing to form the open-shell singlet diradical complex before it forms the closed-shell singlet C4a-hydroperoxyflavin intermediate (C4aOOH). Notably, density functional calculations indicated that the formation of C4aOOH is nearly barrierless, possibly facilitated by the active site arrangement in which His396 positions the proximal oxygen of the ·OOH in an optimum position to directly attack the C4a atom of the isoalloxazine ring. The nearly barrierless formation of C4aOOH agrees well with the experimental results; based on transient kinetics and Eyring plot analyses, the enthalpy of activation for the formation of C4aOOH is only 1.4 kcal/mol and the formation of C4aOOH by C2 is fast (~106 M-1 s-1 at 4 °C). The calculations identified Ser171 as the key residue that stabilizes C4aOOH by accepting a hydrogen bond from the H(N5) of the isoalloxazine ring. Both Ser171 and Trp112 facilitate H2O2 elimination by donating hydrogen bonds to the proximal oxygen of the OOH moiety during the proton transfer. According to our combined theoretical and experimental studies, the existence of a positively charged general acid at the position optimized for facilitating the proton-coupled electron transfer has emerged as an important catalytic feature for the oxygen activation process in flavin-dependent enzymes. [ABSTRACT FROM AUTHOR]

Published

2015

3. Biochemical Establishment and Characterization of EncM's Flavin-N5-oxide Cofactor.

Author

Teufel, Robin, Stull, Frederick, Meehan, Michael J., Michaudel, Quentin, Dorrestein, Pieter C., Palfey, Bruce, and Moore, Bradley S.

Subjects

*FLAVINS, *COFACTORS (Biochemistry), *MONOOXYGENASES, *OXYGENATION (Chemistry), *ENTEROCINS, *HYDROGEN transfer reactions

Abstract

The ubiquitous flavin-dependent monooxygenases commonly catalyze oxygenation reactions by means of a transient C4a--peroxyflavin. A recent study, however, suggested an unprecedented flavin-oxygenating species, proposed as the flavin-N5-oxide (FlN5[0]), as key to an oxidative Favorskii-type rearrangement in the biosynthesis of the bacterial polyketide antibiotic enterocin. This stable superoxidized flavin is covalently tethered to the enzyme EncM and converted into FADH2 (Flred) during substrate turnover. Subsequent reaction of Flred with molecular oxygen restores the postulated F1N5[O] via an unknown pathway. Here, we provide direct evidence for the FlN5[O] species via isotope labeling, proteolytic digestion, and high-resolution tandem mass spectrometry of EncM. We propose that formation of this species occurs by hydrogen-transfer from Flred to molecular oxygen, allowing radical coupling of the formed protonated superoxide and anionic flavin semiquinone at N5, before elimination of water affords the FlN5[0] cofactor. Further biochemical and spectroscopic investigations reveal important features of the FlN5[0] species and the EncM catalytic mechanism. We speculate that flavin-N5-oxides may be intermediates or catalytically active species in other flavoproteins that form the anionic semiquinone and promote access of oxygen to N5. [ABSTRACT FROM AUTHOR]

Published

2015

4. Mechanism of N-Hydroxylation Catalyzed by Flavin-Dependent Monooxygenases.

Author

Badieyan, Somayesadat, Bach, Robert D., and Sobrado, Pablo

Subjects

*HYDROXYLATION, *MONOOXYGENASES, *FLAVINS, *HYDROXYL group, *HYDROGEN atom

Abstract

Aspergillus fumigatus siderophore (SidA), a member of class B flavin-dependent monooxygenases, was selected as a model system to investigate the hydroxylation mechanism of heteroatom-containing molecules by this group of enzymes. SidA selectively hydroxylates ornithine to produce N5-hydroxyornithine. However, SidA is also able to hydroxylate lysine with lower efficiency. In this study, the hydroxylation mechanism and substrate selectivity of SidA were systematically studied using DFT calculations. The data show that the hydroxylation reaction is initiated by homolytic cleavage of the O-O bond in the C4a-hydroperoxyflavin intermediate, resulting in the formation of an internal hydrogen-bonded hydroxyl radical (HO·). As the HO· moves to the ornithine N5 atom, it rotates and donates a hydrogen atom to form the C4a-hydroxyflavin. Oxygen atom transfer yields an aminoxide, which is subsequently converted to hydroxylamine via water-mediated proton shuttling, with the water molecule originating from dehydration of the C4a-hydroxyflavin. The selectivity of SidA for ornithine is predicted to be the result of the lower energy barrier for oxidation of ornithine relative to that of lysine (16 vs 24 kcal/mol, respectively), which is due to the weaker stabilizing hydrogen bond between the incipient HO· and O3' of the ribose ring of NADP+ in the transition state for lysine. [ABSTRACT FROM AUTHOR]

Published

2015

5. Finding the Switch: Turning a Baeyer-Villiger Monooxygenase into a NADPH Oxidase.

Author

Brondani, Patrícia B., Dudek, Hanna M., Martinoli, Christian, Mattevi, Andrea, and Fraaije, Marco W.

Subjects

*ENZYMES, *CHEMICAL synthesis, *NADPH oxidase, *BAEYER-Villiger rearrangement, *MONOOXYGENASES, *FLAVINS, *INTERMEDIATES (Chemistry)

Abstract

By a targeted enzyme engineering approach, we were able to create an efficient NADPH oxidase from a monooxygenase. Intriguingly, replacement of only one specific single amino acid was sufficient for such a monooxygenase-to-oxidase switch--a complete transition in enzyme activity. Pre-steady-state kinetic analysis and elucidation of the crystal structure of the C65D PAMO mutant revealed that the mutation introduces small changes near the flavin cofactor, resulting in a rapid decay of the peroxyflavin intermediate. The engineered biocatalyst was shown to be a thermostable, solvent tolerant, and effective cofactor-regenerating biocatalyst. Therefore, it represents a valuable new biocatalytic tool. [ABSTRACT FROM AUTHOR]

Published

2014

6. Structure and Mechanism of Styrene Monooxygenase Reductase: New Insight into the FAD-Transfer Reaction.

Author

Morrison, Eliot, Kantz, Auric, Gassner, George T., and Sazinsky, Matthew H.

Subjects

*STYRENE, *MONOOXYGENASES, *REDUCTASES, *FLAVOPROTEINS, *STYRENE oxide, *FLAVINS, *PYRIDINE nucleotides

Abstract

The two-component flavoprotein styrene monooxygenase (SMO) from Pseudomonas putidaS12 catalyzes the NADH- and FAD-dependent epoxidation of styrene to styrene oxide. In this study, we investigate the mechanism of flavin reduction and transfer from the reductase (SMOB) to the epoxidase (NSMOA) component and report our findings in light of the 2.2 Å crystal structure of SMOB. Upon rapidly mixing with NADH, SMOB forms an NADH → FADox charge-transfer intermediate and catalyzes a hydride-transfer reaction from NADH to FAD, with a rate constant of 49.1 ± 1.4 s-1, in a step that is coupled to the rapid dissociation of NAD+. Electrochemical and equilibrium-binding studies indicate that NSMOA binds FADhq 13-times more tightly than SMOB, which supports a vectoral transfer of FADhq from the reductase to the epoxidase. After binding to NSMOA, FADhq rapidly reacts with molecular oxygen to form a stable C(4a)-hydroperoxide intermediate. The half-life of apoSMOB generated in the FAD-transfer reaction is increased ∼21-fold, supporting a protein-protein interaction between apoSMOB and the peroxide intermediate of NSMOA. The mechanisms of FAD dissociation and transport from SMOB to NSMOA were probed by monitoring the competitive reduction of cytochrome c in the presence and absence of pyridine nucleotides. On the basis of these studies, we propose a model in which reduced FAD binds to SMOB in equilibrium between an unreactive, sequestered state (S state) and more reactive, transfer state (T state). The dissociation of NAD+ after the hydride-transfer reaction transiently populates the T state, promoting the transfer of FADhq to NSMOA. The binding of pyridine nucleotides to SMOB-FADhq shifts the FADhq-binding equilibrium from the T state to the S state. Additionally, the 2.2 Å crystal structure of SMOB-FADox reported in this work is discussed in light of the pyridine nucleotide-gated flavin-transfer and electron-transfer reactions. [ABSTRACT FROM AUTHOR]

Published

2013

7. Spiro-Ring Formation is Catalyzed by a Multifunctional Dioxygenase in Austinol Biosynthesis.

Author

Matsuda, Yudai, Awakawa, Takayoshi, Wakimoto, Toshiyuki, and Abe, Ikuro

Subjects

*SPIRO compounds, *RING formation (Chemistry), *DIOXYGENASES, *BIOSYNTHESIS, *CHEMICAL structure, *LACTONES, *MONOOXYGENASES, *FLAVINS

Abstract

Austinol, a fungal meroterpenoid derived from 3,5-dimethylorsellinic acid, has a unique chemical structure with a remarkable spiro-lactone ring system. Despite the recent identification of its biosynthetic gene cluster and targeted gene-deletion experiments, the process for the conversion of protoaustinoid A (2), the first tetracyclic biosynthetic intermediate, to the spiro-lactone preaustinoid A3 (7) has remained enigmatic. Here we report the mechanistic details of the enzyme-catalyzed, stereospecific spiro-lactone ring-forming reaction, which is catalyzed by a non-heme iron-dependent dioxygenase, AusE, along with two flavin monooxygenases, the 5′-hydroxylase AusB and the Baeyer–Villiger monooxygenase AusC. Remarkably, AusE is a multifunctional dioxygenase that is responsible for the iterative oxidation steps, including the oxidative spiro-ring-forming reaction, to produce the austinol scaffold. [ABSTRACT FROM AUTHOR]

Published

2013

8. Substrate Binding Modulates the Activity of Mycobacterium smegmatis G, a Flavin-Dependent Monooxygenase Involved in the Biosynthesis of Hydroxamate-Containing Siderophores.

Author

Robinson, Reeder and Sobrado, Pablo

Subjects

*MYCOBACTERIUM, *FLAVINS, *MONOOXYGENASES, *BIOSYNTHESIS, *SIDEROPHORES, *HYDROXYLATION

Abstract

Mycobacterium smegmatis G (MbsG) is a flavin-dependent monooxygenase that catalyzes the NAD(P)H- and oxygen-dependent hydroxylation of the terminal amino group on the side chain of l-lysine in the biosynthetic pathway of the siderophore mycobactin. Mycobactins are essential for mycobacterium growth under iron-limiting conditions encountered during infection in mammals. Thus, enzymes involved in the biosynthesis of mycobactin represent potential drug targets. MbsG was expressed in Escherichia coli and purified using metal affinity and ionic exchange chromatographies. Recombinant MbsG represents the first member of this class of enzymes isolated in the active form, with a tightly bound FAD cofactor. The kcat value for formation of hydroxylated l-lysine under steady-state conditions was 5.0 min-1, and Km values of 0.21 mM for l-lysine, 1.1 mM for NADH, and 2.4 mM for NADPH were calculated. The enzyme functioned as an oxidase when the activity of MbsG was measured by monitoring oxygen consumption in the absence of l-lysine, oxidizing NADH and NADPH with kcat values of 59 and 49 min-1, respectively. Under these conditions, MbsG produced both hydrogen peroxide and superoxide. In contrast, when l-lysine was present, the reaction became more coupled, producing hydroxylated l-lysine and decreasing the oxidase activity. These results suggest that substrate binding modulates the function of MbsG from an oxidase to a monooxygenase [ABSTRACT FROM AUTHOR]

Published

2011

9. Functional Role of a Conserved Arginine Residue Located on a Mobile Loop of Alkanesulfonate Monooxygenase.

Author

Carpenter, Russell A., Xiong, Jingyuan, Robbins, John M., and Ellis, Holly R.

Subjects

*ARGININE, *MONOOXYGENASES, *FLAVINS, *CHEMICAL reduction, *PROTEOLYSIS, *CONFORMATIONAL analysis

Abstract

The structure of the flavin-dependent alkanesulfonate monooxygenase (SsuD) exists as a TIM-barrel structure with an insertion region located over the active site that contains a conserved arginine (Arg297) residue present in all SsuD homologues. Substitution of Arg297 with alanine (R297A SsuD) or lysine (R297K SsuD) was performed to determine the functional role of this conserved residue in SsuD catalysis. While the more conservative R297K SsuD possessed a lower kcat/Km value (0.04 ± 0.01 μM-1 min-1) relative to wild-type (1.17 ± 0.22 μM-1 min-1), there was no activity observed with the R297A SsuD variant. Each of the arginine variants had similar Kd values for flavin binding as wild-type SsuD (0.32 ± 0.15 μM), but there was no measurable binding of octanesulfonate. The low levels of activity for the R297A and R297K SsuD variants correlated with the absence of any detectable C4a-(peroxy)flavin formation in stopped-flow kinetic studies. Single-turnover experiments were performed in the presence of SsuE to evaluate both the reductive and oxidative half-reaction. With wild-type SsuD a lag phase is observed following the reductive half-reaction by SsuE that represents flavin transfer or conformational changes associated with the binding of substrates. Evaluation of the Arg297 SsuD variants in the presence of SsuE showed no lag phase following reduction by SsuE, and the flavin was oxidized immediately following the reductive half-reaction. These results corresponded with a lack of detectable changes in the proteolytic susceptibility of R297A and R297K SsuD in the presence of reduced flavin and/or octanesulfonate, signifying the absence of a conformational change in these variants with the substitution of Arg297. [ABSTRACT FROM AUTHOR]

Published

2011

10. Structure and Ligand Binding Properties of the Epoxidase Component of Styrene Monooxygenase.

Author

Ukaegbu, Uchechi E., Kantz, Auric, Beaton, Michelle, Gassner, George T., and Rosenweig, Amy C.

Subjects

*LIGAND binding (Biochemistry), *CHEMICAL structure, *STYRENE, *MONOOXYGENASES, *STYRENE oxide, *FLAVOPROTEINS, *FLAVINS

Abstract

Styrene monooxygenase (SMO) is a two-component flavoprotein monooxygenase that transforms styrene to styrene oxide in the first step of the styrene catabolic and detoxification pathway of Pseudontonas putida S12. The crystal structure of the N-terminally histidine-tagged epoxidase component of this system, NSMOA, determined to 2.3 Å resolution, indicates the enzyme exists as a homodimer in which each monomer forms two distinct domains. The overall architecture is most similar to that of p-hydroxybenzoate hydroxylase (PHBH), although there are some significant differences in secondary structure. Structural comparisons suggest that a large cavity open to the surface forms the FAD binding site. At the base of this pocket is another cavity that likely represents the styrene binding site. Flavin binding and redox equilibria are tightly coupled such that reduced FAD binds apo NSMOA ∼8000 limes more tightly than the oxidized coenzyme. Equilibrium fluorescence and isothermal titration calorimetry data using benzene as a substrate analogue indicate that the oxidized flavin and substrate analogue binding equilibria of NSMOA are linked such that the binding affinity of each is increased by 60-fold when the enzyme is saturated with Ihe other. A much weaker ∼2-fold positive cooperative interaction is observed for the linked binding equilibria of benzene and reduced FAD. The low affinity of the substrate analogue for the reduced FAD complex of NSMOA is consistent with it preferred restction order in which flavin reduction and reaction with oxygen precede the binding of styrene, identifying the apoenzyme structure as the key catalytic resting state of NSMOA poised to bind reduced FAD and initiate the oxygen reaction. [ABSTRACT FROM AUTHOR]

Published

2010

11. Detection of a C4a-Hydroperoxyflavin Intermediate in the Reaction of a Flavoprotein Oxidase.

Author

Sucharitakul, Jeerus, Prongjit, Methinee, Haltrich, Dietmar, and Chaiyen, Pimchai

Subjects

*FLAVINS, *FLAVOPROTEINS, *OXIDASES, *OXIDATION, *ABSORPTION spectra, *MONOOXYGENASES

Abstract

This work describes for the first time the identification of a reaction intermediate, C4a- hydroperoxyflavin, during the oxidative half-reaction of a flavoprotein oxidase, pyranose 2-oxidase (P2O) from Trametes multicolor, by using rapid kinetics. The reduced P2O reacted with oxygen with a forward rate constant of 5.8 × 104 M-1 s-1 and a reverse rate constant of 2 s-1, resulting in the formation of a C4a-hydroperoxyflavin intermediate which decayed with a rate constant of 18 s-1. The absorption spectrum of the intermediate resembled the spectra of flavin-dependent monooxygenases. A hydrophobic cavity formed at the re side of the flavin ring in the closed state structure of P2O may help in stabilizing the intermediate. [ABSTRACT FROM AUTHOR]

Published

2008

12. Kinetic Mechanism of Phenylacetone Monooxygenase from Thermobifida fusca.

Author

Tones Pazmiño, Daniel E., Baas, Bert-Jan, Janssen, Dick B., and Fraaije, Marco W.

Subjects

*MONOOXYGENASES, *ACETONE, *CATALYSIS, *MOLECULAR structure, *X-ray crystallography, *FLAVINS

Abstract

Phenylacetone monooxygenase (PAMO) from Thermobifida fusca is a FAD-containing Baeyer-Villiger monooxygenase (BVMO). To elucidate the mechanism of conversion of phenylacetone by PAMO, we have performed a detailed steady-state and pre-steady-state kinetic analysis. In the catalytic cycle (kcat = 3.1 s-1), rapid binding of NADPH (Kd = 0.7 µM) is followed by a transfer of the 4(R)-hydride from NADPH to the FAD cofactor (kred = 12 s-1). The reduced PAMO is rapidly oxygenated by molecular oxygen (kox = 870 mM-1 s-1), yielding a C4a-peroxyflavin. The peroxyflavin enzyme intermediate reacts with phenylacetone to form benzylacetate (k1 = 73 s-1). This latter kinetic event leads to an enzyme intermediate which we could not unequivocally assign and may represent a Criegee intermediate or a C4a-hydroxyflavin form. The relatively slow decay (4.1 s-1) of this intermediate yields fully reoxidized PAMO and limits the turnover rate. NADP+ release is relatively fast and represents the final step of the catalytic cycle. This study shows that kinetic behavior of PAMO is significantly different when compared with that of sequence-related monooxygenases, e.g., cyclohexanone monooxygenase and liver microsomal flavin-containing monooxygenase. Inspection of the crystal structure of PAMO has revealed that residue R337, which is conserved in other BVMOs, is positioned close to the flavin cofactor. The analyzed R337A and R337K mutant enzymes were still able to form and stabilize the C4a-peroxyflavin intermediate. The mutants were unable to convert either phenylacetone or benzyl methyl sulfide. This demonstrates that R337 is crucially involved in assisting PAMO-mediated Baeyer-Villiger and sulfoxidation reactions. [ABSTRACT FROM AUTHOR]

Published

2008

13. Thermodynamic Analysis of the Binding of Oxidized and Reduced FMN Cofactor to Vibrio harveyi NADPH-FMN Oxidoreductase FRP Apoenzyme.

Author

Xi Li, Dar-Chone Chow, and Shiao-Chun Tu

Subjects

*FLAVINS, *COENZYMES, *MONOOXYGENASES, *BIOLUMINESCENCE, *ENZYMES, *OXIDOREDUCTASES, *BIOCHEMICAL research

Abstract

The Vibrio harveyi NADPH-specific flavin reductase FRP follows a ping-pong mechanism but switches to a sequential mechanism in the luciferase-coupled reaction. The bound FMN co-isolated with FRP, while acting as a genuine cofactor in the single-enzyme reaction, functions in the luciferase-coupled reaction as a prebound substrate and is directly transferred to luciferase once it is reduced [Lei, B., and Tu, S.-C. (1998) Biochemistry 37, 14623–14629]. With the aim of better understanding the functions of FMN in the FRP holoenzyme, this study was undertaken to quantify and compare the thermodynamic properties of the binding of oxidized and reduced FMN by the FRP apoenzyme. By isothermal titration calorimetry (ITC) measurements in various buffers at pH 7.0 and 15–30 °C, the binding of FMN by apo-FRP was found to be noncooperative, exothermic, and primarily enthalpy driven. The binding free energy change (hence, the association constant) was nearly invariant over this temperature range. Significant conformational changes in FRP upon binding of FMN were indicated. Equilibrium bindings of reduced flavins by flavin-dependent proteins have rarely been studied. In this work, the thermodynamic properties of binding of reduced FMN by apo-FRP were found to closely resemble those of FMN binding under three sets of experimental conditions via ITC measurements and, in one case, fluorescence quenching. The kinetically deduced ping-pong mechanism of FRP is now supported by direct measurements of binding affinities of the oxidized and reduced FMN cofactors. These findings are also discussed in relation to the function of FRP as a reduced flavin donor in the FRP-luciferase couple. [ABSTRACT FROM AUTHOR]

Published

2006

14. Tigecycline Is Modified by the Flavin-Dependent Monooxygenase TetX.

Author

Moore, Ian F., Hughes, Donald W., and Wright, Gerard D.

Subjects

*MONOOXYGENASES, *ANTIBIOTICS, *ANTI-infective agents, *FLAVINS, *ANTIBACTERIAL agents, *CHEMICAL reactions

Abstract

The clinical use of tetracycline antibiotics has decreased due to the emergence of efflux and ribosomal protection-based resistance mechanisms. Currently in phase III clinical trials, the glycylcycline derivative tigecycline (GAR-936) containing a 9-tert-butylglycylamido group is part of a new generation of tetracycline antibiotics developed during the 1990s. Tigecycline displays a broad spectrum of antibacterial activity and circumvents the efflux and ribosomal protection resistance mechanisms. The TetX protein is a flavin-dependent monooxygenase that modifies first and second generation tetracyclines and requires NADPH, Mg2+, and O2 for activity. We report that tigecycline is a substrate for TetX and that bacterial strains containing the tet(X) gene are resistant to tigecycline. The resistance is due to the modification of tigecycline by TetX to form 11a-hydroxytigecycline, which we have shown has a weakened ability to inhibit protein translation compared with tigecycline. We have explored the basis of this decreased ability to block translation and found that hydroxylation occurs in the region of the molecule important for coordinating magnesium. 11a-Hydroxytigecycline forms a weaker complex with magnesium than tigecycline; the crystal structure of tetracycline in complex with the ribosome has shown that magnesium coordination is critical for binding tetracycline. Although tet(X) has not been isolated from any clinically resistant strains, our report demonstrates the first enzymatic resistance mechanism to tigecycline and provides an alert for the surveillance of resistant strains that may contain tet(X). [ABSTRACT FROM AUTHOR]

Published

2005

15. Structural Insight into the Mechanism of Oxygen Activation and Substrate Selectivity of Flavin-Dependent N-Hydroxylating Monooxygenases.

Author

Franceschini, Stefano, Fedkenheuer, Michael, Vogelaar, Nancy J., Robinson, Howard H., Sobrado, Pablo, and Mattevi, Andrea

Subjects

*FLAVINS, *MONOOXYGENASES, *ASPERGILLUS fumigatus, *SIDEROPHORES, *MICROBIAL virulence, *BIOSYNTHESIS, *HYDROXYLATION, *ELECTROSTATICS

Abstract

SidA from the human pathogen Aspergillus fumigatus catalyzes the generation of N5-hydroxyornithine in the biosynthesis of siderophores, a reaction essential for virulence. The crystal structures of SidA m complex with omithine and lysine reveal the geometry of the interactions among flavin, NADP+, and the substrate amine group that underlie the hydroxylation reaction. The structural elucidation of the enzyme in complex with arginine provides insight into the role of electrostatics and hydrogen bonding in the mechanism of oxygen activation in this family of enzymes. [ABSTRACT FROM AUTHOR]

Published

2012

16. Direct Electrochemistry of Drug Metabolizing Human Flavin-Containing Monooxygenase: Electrochemical Turnover of Benzydamine and Tamoxifen.

Author

Sadeghi, Sheila J., Meirinhos, Rita, Catucci, Gianluca, Dodhia, Vikash R., Di Nardo, Giovanna, and Gilardi, Gianfranco

Subjects

*ELECTROCHEMISTRY, *MONOOXYGENASES, *FLAVINS, *CARBON, *GOLD, *ELECTRODES, *TAMOXIFEN

Abstract

The article presents a study that describes the direct electrochemistry of human flavin-containing monooxygenase 3 (hFMO3) immobilized on glassy carbon (GC) and gold electrodes. The study analyzed the capability of the immobilized hFMO3 to oxygenate benzydamine and tamoxifen as well as differentiated it with solution studies. It states that benzydamine was metabolized by hFMO3 to its N-oxide while in tamoxifen there are three other metabolites generated by cytochromes P450.

Published

2010