Project description:The UbiX-UbiD enzymes are widespread in microbes, acting in concert to decarboxylate alpha-beta unsaturated carboxylic acids using a highly modified flavin cofactor, prenylated FMN (prFMN). UbiX serves as the flavin prenyltransferase, extending the isoalloxazine ring system with a fourth non-aromatic ring, derived from sequential linkage between a dimethylallyl moiety and the FMN N5 and C6. Using structure determination and solution studies of both dimethylallyl monophosphate (DMAP) and dimethyallyl pyrophosphate (DMAPP) dependent UbiX enzymes, we reveal the first step, N5-C1' bond formation, is contingent on the presence of a dimethylallyl substrate moiety. Hence, an SN1 mechanism similar to other prenyltransferases is proposed. Selected variants of the (pyro)phosphate binding site are unable to catalyse subsequent Friedel-Crafts alkylation of the flavin C6, but can be rescued by addition of (pyro)phosphate. Thus, retention of the (pyro)phosphate leaving group is required for C6-C3' bond formation, resembling pyrophosphate initiated class I terpene cyclase reaction chemistry.

Project description:Soil bacteria can detoxify Cr(VI) ions by reduction. Within the last 2 decades, numerous reports of chromate reductase enzymes have been published. These reports describe catalytic reduction of chromate ions by specific enzymes. These enzymes each have sequence similarity to known redox-active flavoproteins. We investigated the enzyme NfoR from Staphylococcus aureus, which was reported to be upregulated in chromate-rich soils and to have chromate reductase activity (H. Han, Z. Ling, T. Zhou, R. Xu, et al., Sci Rep 7:15481, 2017, https://doi.org/10.1038/s41598-017-15588-y). We show that NfoR has structural similarity to known flavin mononucleotide (FMN) reductases and reduces FMN as a substrate. NfoR binds FMN with a dissociation constant of 0.4 μM. The enzyme then binds NADPH with a dissociation constant of 140 μM and reduces the flavin at a rate of 1,350 s-1 Turnover of the enzyme is apparently limited by the rate of product release that occurs, with a net rate constant of 0.45 s-1 The rate of product release limits the rate of observed chromate reduction, so the net rate of chromate reduction by NfoR is orders of magnitude lower than when this process occurs in solution. We propose that NfoR is an FMN reductase and that the criterion required to define chromate reduction as enzymatic has not been met. That NfoR expression is increased in the presence of chromate suggests that the survival adaption was to increase the net rate of chromate reduction by facile, adventitious redox processes.IMPORTANCE Chromate is a toxic by-product of multiple industrial processes. Chromate reduction is an important biological activity that ameliorates Cr(VI) toxicity. Numerous researchers have identified chromate reductase activity by observing chromate reduction. However, all identified chromate reductase enzymes have flavin as a cofactor or use a flavin as a substrate. We show here that NfoR, an enzyme claimed to be a chromate reductase, is in fact an FMN reductase. In addition, we show that reduction of a flavin is a viable way to transfer electrons to chromate but that it is unlikely to be the native function of enzymes. We propose that upregulation of a redox-active flavoprotein is a viable means to detoxify chromate that relies on adventitious reduction that is not catalyzed.

Project description:Siderophore A (SidA) from Aspergillus fumigatus is a flavin-containing monooxygenase that hydroxylates ornithine (Orn) at the amino group of the side chain. Lysine (Lys) also binds to the active site of SidA; however, hydroxylation is not efficient and H2 O2 is the main product. The effect of pH on steady-state kinetic parameters was measured and the results were consistent with Orn binding with the side chain amino group in the neutral form. From the pH dependence on flavin oxidation in the absence of Orn, a pKa value >9 was determined and assigned to the FAD-N5 atom. In the presence of Orn, the pH dependence displayed a pKa value of 6.7 ±0.1 and of 7.70 ±0.10 in the presence of Lys. Q102 interacts with NADPH and, upon mutation to alanine, leads to destabilization of the C4a-hydroperoxyflavin (FADOOH ). Flavin oxidation with Q102A showed a pKa value of ~8.0. The data are consistent with the pKa of the FAD N5-atom being modulated to a value >9 in the absence of Orn, which aids in the stabilization of FADOOH . Changes in the FAD-N5 environment lead to a decrease in the pKa value, which facilitates elimination of H2 O2 or H2 O. These findings are supported by solvent kinetic isotope effect experiments, which show that proton transfer from the FAD N5-atom is rate limiting in the absence of a substrate, however, is significantly less rate limiting in the presence of Orn and or Lys.

Project description:Quinone reductases are flavin-containing enzymes that have been implicated in protecting organisms from redox stress and, more recently, as redox switches controlling the action of the proteasome. The reactions of the catalytic cycle of the dimeric quinone reductase Lot6p from Saccharomyces cerevisiae were studied in anaerobic stopped-flow experiments at 4 degrees C. Both NADH and NADPH reacted similarly, reducing the FMN prosthetic group rapidly at saturation but binding with very low affinity. The enzyme stereospecifically transferred the proS-hydride of NADPH with an isotope effect of 3.6, indicating that hydride transfer, and not an enzyme conformational change, is rate-determining in the reductive half-reaction. No intermediates such as charge-transfer complexes were detected. In the oxidative half-reaction, reduced enzyme reacted in a single phase with the six quinone substrates tested. The observed rate constants increased linearly with quinone concentration up to the limits allowed by solubility, indicating either a bimolecular reaction or very weak binding. The logarithm of the bimolecular rate constant increases linearly with the reduction potential of the quinone, consistent with the notion that quinone reductases strongly disfavor radical intermediates. Interestingly, both half-reactions of the catalytic cycle strongly resemble bioorganic model reactions; the reduction of Lot6p by NAD(P)H is moderately faster than nonenzymatic models, while the oxidation of Lot6p by quinones is actually slower than nonenzymatic reactions. This curious situation is consistent with the structure of Lot6p, which has a crease we propose to be the binding site for pyridine nucleotides and a space, but no obvious catalytic residues, near the flavin allowing the quinone to react. The decidedly suboptimized catalytic cycle suggests that selective pressures other than maximizing quinone consumption shaped the evolution of Lot6p. This may reflect the importance of suppressing other potentially deleterious side reactions, such as oxygen reduction, or it may indicate that the role Lot6p plays as a redox sensor in controlling the proteasome is more important than its role as a detoxifying enzyme.

Project description:The initial-rate kinetics of the flavin reductase reaction catalysed by biliverdin-IXbeta reductase at pH 7.5 are consistent with a rapid-equilibrium ordered mechanism, with the pyridine nucleotide binding first. NADPH binding to the free enzyme was characterized using stopped-flow fluorescence quenching, and a K(d) of 15.8 microM was calculated. Equilibrium fluorescence quenching experiments indicated a K(d) of 0.55 microM, suggesting that an enzyme-NADPH encounter complex (K(d) 15.8 microM) isomerizes to a more stable 'nucleotide-induced' conformation. The enzyme was shown to catalyse the reduction of FMN, FAD and riboflavin, with K(m) values of 52 microM, 125 microM and 53 microM, respectively. Lumichrome was shown to be a competitive inhibitor against FMN, with a K(i) of 76 microM, indicating that interactions with the isoalloxazine ring are probably sufficient for binding. During initial experiments it was observed that both the flavin reductase and biliverdin reductase activities of the enzyme exhibit a sharp optimum at pH 5 in citrate buffer. An initial-rate study indicated that the enzyme obeys a steady-state ordered mechanism in this buffer. The initial-rate kinetics in sodium acetate at pH 5 are consistent with a rapid-equilibrium ordered mechanism, indicating that citrate may directly affect the enzyme's behaviour at pH 5. Mesobiliverdin XIIIalpha, a synthetic biliverdin which binds to flavin reductase but does not act as a substrate for the enzyme, exhibits competitive kinetics with FMN (K(i) 0.59 microM) and mixed-inhibition kinetics with NADPH. This is consistent with a single pyridine nucleotide site and competition by FMN and biliverdin for a second site. Interestingly, flavin reductase/biliverdin-IXbeta reductase has also been shown to exhibit ferric reductase activity, with an apparent K(m) of 2.5 microM for the ferric iron. The ferric reductase reaction requires NAD(P)H and FMN. This activity is intriguing, as haem cleavage in the foetus produces non-alpha isomers of biliverdin and ferric iron, both of which are substrates for flavin reductase/biliverdin-IXbeta reductase.

Project description:Elucidating atmospheric oxidation mechanisms is necessary for estimating the lifetimes of atmospheric species and understanding secondary organic aerosol formation and atmospheric oxidation capacity. We report an unexpectedly fast mechanistic pathway for the unimolecular reactions of large stabilized Criegee intermediates, which involves the formation of bicyclic structures from large Criegee intermediates containing an aldehyde group. The barrier heights of the mechanistic pathways are unexpectedly low - about 2-3 kcal/mol - and are at least 10 kcal/mol lower than those of hydrogen shift processes in large syn Criegee intermediates; and the calculated rate constants show that the mechanistic pathways are 105-109 times faster than those of the corresponding hydrogen shift processes. The present findings indicate that analogous low-energy pathways can now also be expected in other large Criegee intermediates and that oxidative capacity of some Criegee intermediates is smaller than would be predicted by existing models.

Project description:Free reduced flavins are involved in a variety of biological functions. They are generated from NAD(P)H by flavin reductase via co-factor flavin bound to the enzyme. Although recent findings on the structure and function of flavin reductase provide new information about co-factor FAD and substrate NAD, there have been no reports on the substrate flavin binding site. Here we report the structure of TTHA0420 from Thermus thermophilus HB8, which belongs to flavin reductase, and describe the dual binding mode of the substrate and co-factor flavins. We also report that TTHA0420 has not only the flavin reductase motif GDH but also a specific motif YGG in C terminus as well as Phe-41 and Arg-11, which are conserved in its subclass. From the structure, these motifs are important for the substrate flavin binding. On the contrary, the C terminus is stacked on the NADH binding site, apparently to block NADH binding to the active site. To identify the function of the C-terminal region, we designed and expressed a mutant TTHA0420 enzyme in which the C-terminal five residues were deleted (TTHA0420-ΔC5). Notably, the activity of TTHA0420-ΔC5 was about 10 times higher than that of the wild-type enzyme at 20-40 °C. Our findings suggest that the C-terminal region of TTHA0420 may regulate the alternative binding of NADH and substrate flavin to the enzyme.

Project description:There are two known types of microbial two-component flavin-dependent monooxygenases that catalyze oxygenation of p-hydroxyphenylacetate (HPA), and they are distinguished by having structurally distinct reductases and oxygenases. This paper presents a detailed analysis of the properties of the enzyme from Pseudomonas aeruginosa, an example of one group, and compares its properties to those published for the Acinetobacter baumannii enzyme, an example of the alternative group. The reductase and oxygenase from P. aeruginosa were expressed in Escherichia coli. The reductase was purified as a stable C-terminally His-tagged yellow protein containing weakly bound FAD, and the oxygenase was purified as a stable colorless N-terminally His-tagged protein. The reductase catalyzes the reduction of FAD by NADH and releases the FADH(-) product into solution, but unlike the reductase from A. baumannii, this catalysis is not influenced by HPA. The oxygenase binds the released FADH(-) and catalyzes the oxygenation of HPA to form 3,4-dihydroxyphenylacetate, after which the FAD dissociates to be re-reduced by the reductase, a common overall pattern for two-component flavin-dependent oxygenases. With this system, it appears that interactions between the reductase and the oxygenase can facillitate the transfer of FADH(-) to the oxygenase, although they are not required. We show that the P. aeruginosa oxygenase system in complex with FADH(-) reacts with O(2) to form a quasi-stable, unusually high-extinction flavin hydroperoxide species that binds HPA and reacts to form the product. The resultant flavin hydroxide decomposes to FAD and water while still bound to the oxygenase and then releases product and FAD from the protein. Unlike the enzyme from A. baumannii, during normal catalysis involving both the reductase and oxygenase, the rate-determining step in catalysis is the dissociation of FAD from the oxygenase in a process that is independent of the concentration of HPA. Structures for the reductases and oxygenases from A. baumannii and from Thermus thermophilus (similar to the P. aeruginosa system) form a basis for interpreting the molecular origins of the differences between the two groups of flavin-dependent two-component oxygenases.

Project description: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 degrees C pH 8.0, Km for NADH, Km for FMN, and kcat were calculated to be 15.1 microM, 2.7 microM, 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.

Project description:Sustainable practices in process chemistry are highlighted by a novel, 9 week team project of 8-12 students, in collaboration with AstraZeneca chemists, in an organic chemistry laboratory. Students synthesize the antiulcer medicine esomeprazole, which involves the asymmetric oxidation of pyrmetazole. To provide insight into the modern process chemistry industry, they propose environmentally friendly modifications to the asymmetric oxidation. Students first synthesize pyrmetazole and then follow a standard oxidation procedure and carry out modified, greener reactions of their choice. They investigate how a change in reaction conditions affects both the yield and enantioselectivity of esomeprazole. Positive student feedback was received and student postlab reports were analyzed over a 4 year period (2015-2018). Results consistently showed that the project provided students with the key tools to develop greener syntheses. This contextual approach not only offers the opportunity to develop valuable communication and team-working skills, but it also gives students creative input into their experimental work. It teaches the important research skills involved in sustainable process chemistry, from reproducing and modifying a literature procedure to identifying green metrics.