Crystal Structures of Intermediates in the Nitroalkane Oxidase Reaction

Héroux, A.; Bozinovski, D.M.; Valley, Michael P.; Fitzpatrick, Paul F.; Orville, Allen M.

doi:10.1021/bi8023042

Cited by 27 publications

(30 citation statements)

References 24 publications

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“…In these examples, hydrogen bonding provided by the 2Ј-hydroxyl group polarizes the acyl carbonyl and stabilizes its developing charge. Nitroalkane oxidase is a member of the same acyl-CoA dehydrogenase superfamily and demonstrates an equivalent interaction between the 2Ј-hydroxyl of FAD and an oxygen of the nitro group (42). This same activation strategy may also be proposed for BluB, an enzyme closely related to IYD in structure but not function (7,15).…”

Section: Discussionmentioning

confidence: 84%

A Switch between One- and Two-electron Chemistry of the Human Flavoprotein Iodotyrosine Deiodinase Is Controlled by Substrate

Chuenchor

Rokita

2015

Journal of Biological Chemistry

240

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Background: Iodotyrosine deiodinase utilizes FMN to maintain iodide homeostasis by reductive deiodination of iodotyrosine. Results: Crystallographic, pH, and redox studies demonstrate the role of substrate in organizing the active site for effective catalysis. Conclusion:Stepwise single electron transfer is promoted only after coordination of a halotyrosine within iodotyrosine deiodinase. Significance: A synergy between substrate selectivity and catalytic activity is created by the enzyme.

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Section: Discussionmentioning

confidence: 84%

A Switch between One- and Two-electron Chemistry of the Human Flavoprotein Iodotyrosine Deiodinase Is Controlled by Substrate

Chuenchor

Rokita

2015

Journal of Biological Chemistry

240

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“…The variability likely results from a combination of real enzyme-substrate binding effects and the modest resolution of the crystal structure. For comparison, the crystal structures with the substrates 1-nitrohexane or 1-nitrooctane demonstrate similar complexes, but with less binding orientation variability (33). Thus, nitroethane exhibits the most active site variability in the D402N complex, which correlates well with the lower k cat /K m value relative to the longer chain nitroalkane substrates (7,8).…”

Section: Crystal Structure and Computational Model Of The Michaelis Cmentioning

confidence: 89%

“…We have determined crystal structures of NAO complexes with a series of nitroalkanes (33) including nitroethane, which is reported here (Fig. 1A).…”

Section: Crystal Structure and Computational Model Of The Michaelis Cmentioning

confidence: 99%

Differential quantum tunneling contributions in nitroalkane oxidase catalyzed and the uncatalyzed proton transfer reaction

Major

Héroux

Orville

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

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The proton transfer reaction between the substrate nitroethane and Asp-402 catalyzed by nitroalkane oxidase and the uncatalyzed process in water have been investigated using a path-integral free-energy perturbation method. Although the dominating effect in rate acceleration by the enzyme is the lowering of the quasiclassical free energy barrier, nuclear quantum effects also contribute to catalysis in nitroalkane oxidase. In particular, the overall nuclear quantum effects have greater contributions to lowering the classical barrier in the enzyme, and there is a larger difference in quantum effects between proton and deuteron transfer for the enzymatic reaction than that in water. Both experiment and computation show that primary KIEs are enhanced in the enzyme, and the computed Swain-Schaad exponent for the enzymatic reaction is exacerbated relative to that in the absence of the enzyme. In addition, the computed tunneling transmission coefficient is approximately three times greater for the enzyme reaction than the uncatalyzed reaction, and the origin of the difference may be attributed to a narrowing effect in the effective potentials for tunneling in the enzyme than that in aqueous solution.PI-FEP/UM simulations ͉ enzyme catalysis ͉ kinetic isotope effects ͉ X-ray structure A lthough the dominant factor in enzyme catalysis is the lowering of the quasiclassical free energy barrier of the enzymatic reaction in comparison with the uncatalyzed process (1-3), quantum mechanical tunneling has been recognized to also play a role in enzymatic hydrogen transfer reactions (2, 3). An intriguing, yet unanswered, question is whether enzymes have evolved to enhance tunneling to accelerate the reaction rate because quantum effects on rate acceleration are much smaller than hydrogen bonding and electrostatic stabilization of the transition state (1, 4, 5). Nevertheless, a small factor of two in rate enhancement can have important physiological impacts. Although it appears straightforward to address this question by comparing the enzymatic and the uncatalyzed reaction in solution, the difficulty is to design a model system that mimics exactly the same enzymatic reaction and mechanism. The present study examines the structure of nitroalkane oxidase (NAO) complex with nitroethane and kinetic isotope effects at the primary and secondary sites for the enzymatic and the uncatalyzed reaction. The computational findings are consistent with experimental data, suggesting that there is a differential tunneling effect for the proton transfer reaction in NAO and in water. Analysis of tunneling paths reveals that the enzyme reduces both the free energy of activation and the width of the effective potential, resulting in enhanced proton tunneling in the active site.The flavoenzyme NAO catalyzes the conversion of nitroalkanes to nitrite and aldehydes or ketones (Fig. S1) (6). The ␣-proton abstraction of the small substrate nitroethane by Asp-402 is rate-limiting, which is accelerated by a factor of 10 9 over the uncatalyzed reaction between n...

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“…This flavin intermediate has not been previously observed for flavoprotein oxidases but has been limited to reactions of flavoprotein monooxygenases (5)(6)(7). Besides P2O, an intermediate in flavoprotein oxidases has been detected only in the crystalline forms of choline oxidase (1.86 Å) (8) and nitroalkane oxidase (in the presence of cyanide) (9), and in the mutant form, C42S, of an NADH oxidase (10). In the case of glucose oxidase from Aspergillus niger, the generation of a flavin semiquinone-superoxide radical pair using pulse radiolysis resulted in formation of a putative C4a-hydroperoxyflavin intermediate (11).…”

mentioning

confidence: 99%

A Conserved Active-site Threonine Is Important for Both Sugar and Flavin Oxidations of Pyranose 2-Oxidase

Pitsawong

Sucharitakul

Prongjit

et al. 2010

Journal of Biological Chemistry

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(D-Glc) and several aldopyranoses at the C2 position to yield the corresponding 2-ketoaldoses and hydrogen peroxide (2). The overall catalytic reaction can be divided into two half-reactions (Scheme 1) obeying a Ping-Pong type mechanism at pH 7 (3): a reductive half-reaction in which the protein-bound flavin receives a hydride equivalent from a sugar substrate to produce the reduced FAD (FADH Ϫ ) and the 2-keto-sugar, and an oxidative half-reaction in which two electrons are transferred from the reduced flavin to O 2 to form H 2 O 2 (2, 3).We reported the first detection of a C4a-hydroperoxyflavin intermediate for a flavoprotein oxidase (4). This flavin intermediate has not been previously observed for flavoprotein oxidases but has been limited to reactions of flavoprotein monooxygenases (5-7). Besides P2O, an intermediate in flavoprotein oxidases has been detected only in the crystalline forms of choline oxidase (1.86 Å) (8) and nitroalkane oxidase (in the presence of cyanide) (9), and in the mutant form, C42S, of an NADH oxidase (10). In the case of glucose oxidase from Aspergillus niger, the generation of a flavin semiquinone-superoxide radical pair using pulse radiolysis resulted in formation of a putative C4a-hydroperoxyflavin intermediate (11). Studies on the P2O reductive half-reaction indicate that P2O binds D-Glc according to a two-step binding mechanism: first an initial complex is formed, followed by an isomerization step to form an active Michaelis ES complex (P2O⅐glucose). Interestingly, this complex shows higher absorbance at 395 nm than does the oxidized enzyme, which is unique among flavoprotein oxidases (3).P2O belongs to the large family of glucose-methanol-choline oxidoreductases (12, 13) with the catalytic side chains His 548 - * This work was supported in part by the Thailand Research Fund throughGrants BRG5180002 (to P. C.), MRG4980117 (to J. S.), and PHD/0151/2547 of the Royal Golden Jubilee Ph.D. program (to M. P.) and by the Faculty of Science, Mahidol University (to P. C.) and from the Faculty of Dentistry Chulalongkorn University (to J. S.). The atomic coordinates and structure factors (codes 3K4B and 3K4C) The abbreviations used are: P2O, pyranose 2-oxidase; ABTS, 2,2Ј-azinobis(3-ethylbenzthiazoline-6-sulfonic acid) diammonium salt; , wavelength; WT, wild type; Mes, 4-morpholineethanesulfonic acid.

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Crystal Structures of Intermediates in the Nitroalkane Oxidase Reaction

Cited by 27 publications

References 24 publications

A Switch between One- and Two-electron Chemistry of the Human Flavoprotein Iodotyrosine Deiodinase Is Controlled by Substrate

A Switch between One- and Two-electron Chemistry of the Human Flavoprotein Iodotyrosine Deiodinase Is Controlled by Substrate

Differential quantum tunneling contributions in nitroalkane oxidase catalyzed and the uncatalyzed proton transfer reaction

A Conserved Active-site Threonine Is Important for Both Sugar and Flavin Oxidations of Pyranose 2-Oxidase

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