Mechanisms for Flavin-Mediated Oxidation: Hydride or Hydrogen-Atom Transfer?

Curtolo, Felipe; Arantes, Guilherme Menegon

doi:10.1021/acs.jcim.0c00945

Cited by 11 publications

(19 citation statements)

References 57 publications

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“…They found that the oxidation of 1-methylnicotinamide by lumiflavin proceeded by hydride transfer. 30 As depicted by the spin density surface of Fig. 2b (and the Mulliken spin density values of Fig.…”

Section: Resultsmentioning

confidence: 94%

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Flavin-mediated photoactivation of Pt(iv) anticancer complexes: computational insights on the catalytic mechanism

Scoditti

Dabbish

Pieslinger

et al. 2022

Phys. Chem. Chem. Phys.

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Section: Resultsmentioning

confidence: 94%

“…Similar initial guess structures were also obtained by others in studies concerning flavins and nicotinamide derivatives. 29,30 Conversely, Vianello et al 31 found that hydride transfer from amino donors to the flavin cofactor of the Monoamine oxidase (MAO) flavoenzyme did not involve p-p stacked adducts, rather more angular structures.…”

Section: Resultsmentioning

confidence: 99%

Flavin-mediated photoactivation of Pt(iv) anticancer complexes: computational insights on the catalytic mechanism

Scoditti

Dabbish

Pieslinger

et al. 2022

Phys. Chem. Chem. Phys.

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“…Note that the pitfalls of using population analysis to examine reaction mechanisms recently discussed in the context of PCET 20,76 are partially mitigated when summing populations over whole chemical groups, 77 such as in Q or imidazole groups used here. Table 2 shows population analysis for reactant and product geometries of proton transfer.…”

Section: ■ Methodsmentioning

confidence: 99%

“…Several enzymes employ PCET as a strategy to decrease the overpotential that would have to be surmounted for electron or proton transfer alone. , Their catalytic mechanisms have been studied with molecular simulation, particularly for analysis of the tunneling behavior and participation of electronic excited states. − Although various aspects of cytochrome bc 1 have already been investigated by simulations, − proton tunneling and nonadiabatic effects of reactions in the Q o site have received less attention. , …”

Section: Introductionmentioning

confidence: 99%

Tunneling and Nonadiabatic Effects on a Proton-Coupled Electron Transfer Model for the Q_o Site in Cytochrome bc₁

Camilo

Curtolo

Galassi

et al. 2021

J. Chem. Inf. Model.

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Cytochrome bc 1 is a fundamental enzyme for cellular respiration and photosynthesis. This dimeric protein complex catalyzes a proton-coupled electron transfer (PCET) from the reduced coenzyme-Q substrate (Q) to a bimetallic iron− sulfur cluster in the Q o active site. Herein, we combine molecular dynamics simulations of the complete cytochrome bc 1 protein with electronic-structure calculations of truncated models and a semiclassical tunneling theory to investigate the electron−proton adiabaticity of the initial reaction catalyzed in the Q o site. After sampling possible orientations between the Q substrate and a histidine side chain that functions as hydrogen acceptor, we find that a truncated model composed by ubiquinol-methyl and imidazole-iron(III)-sulfide captures the expected changes in oxidation and spin states of the electron donor and acceptor. Diabatic electronic surfaces obtained for this model with multiconfigurational wave function calculations demonstrate that this reaction is electronic nonadiabatic, and proton tunneling is faster than mixing of electronic configurations. These results indicate the formalism that should be used to calculate vibronic couplings and kinetic parameters for the initial reaction in the Q o site of cytochrome bc 1 . This framework for molecular simulation may also be applied to investigate other PCET reactions in the Q-cycle or in various metalloproteins that catalyze proton translocation coupled to redox processes.

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“…[2,3] F I G U R E 1 Structure and heavy-atom numbering for the isoalloxazine ring, the core group of flavins responsible for their redox and photophysical properties Redox flavoproteins participate in single-electron transfer reactions, [4] in oxygen-dependent oxidation, [5] and in proton-coupled electron transfers (PCET) with varying number of electrons. [2,6,7] Flavin chromophores are found in blue-light protein receptors [3] and in photodependent enzymes. [8] Recently, the biological role of flavins as general acid-base catalysts has also been demonstrated.…”

Section: Introductionmentioning

confidence: 99%

Molecular properties and tautomeric equilibria of isolated flavins

Curtolo

Arantes

2022

J Comput Chem

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Flavins are employed as redox cofactors and chromophores in a plethora of flavoenzymes. Their versatility is an outcome of intrinsic molecular properties of the isoalloxazine ring modulated by the protein scaffold and surrounding solvent. Thus, an investigation of isolated flavins with high‐level electronic‐structure methods and with error assessment of the calculated properties will contribute to building better models of flavin reactivity. Here, we benchmarked ground‐state properties such as electron affinity, gas‐phase basicity, dipole moment, torsion energy, and tautomer stability for lumiflavins in all biologically relevant oxidation and charge states. Overall, multiconfigurational effects are small and chemical accuracy is achieved by coupled‐cluster treatments of energetic properties. Augmented basis sets and extrapolations to the complete basis‐set limit are necessary for consistent agreement with experimental energetics. Among DFT functionals tested, M06‐2X shows the best performance for most properties, except gas‐phase basicity, in which M06 and CAM‐B3LYP perform better. Moreover, dipole moments of radical flavins show large deviations for all functionals studied. Tautomers with noncanonical protonation states are significantly populated at normal temperatures, adding to the complexity of modeling flavins. These results will guide future computational studies of flavoproteins and flavin chemistry by indicating the limitations of electronic‐structure methodologies and the contributions of multiple tautomeric states.

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Mechanisms for Flavin-Mediated Oxidation: Hydride or Hydrogen-Atom Transfer?

Cited by 11 publications

References 57 publications

Flavin-mediated photoactivation of Pt(iv) anticancer complexes: computational insights on the catalytic mechanism

Flavin-mediated photoactivation of Pt(iv) anticancer complexes: computational insights on the catalytic mechanism

Tunneling and Nonadiabatic Effects on a Proton-Coupled Electron Transfer Model for the Q_o Site in Cytochrome bc₁

Molecular properties and tautomeric equilibria of isolated flavins

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Mechanisms for Flavin-Mediated Oxidation: Hydride or Hydrogen-Atom Transfer?

Cited by 11 publications

References 57 publications

Flavin-mediated photoactivation of Pt(iv) anticancer complexes: computational insights on the catalytic mechanism

Flavin-mediated photoactivation of Pt(iv) anticancer complexes: computational insights on the catalytic mechanism

Tunneling and Nonadiabatic Effects on a Proton-Coupled Electron Transfer Model for the Qo Site in Cytochrome bc1

Molecular properties and tautomeric equilibria of isolated flavins

Contact Info

Product

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Tunneling and Nonadiabatic Effects on a Proton-Coupled Electron Transfer Model for the Q_o Site in Cytochrome bc₁