Reduction Potentials and Acidity Constants of Mn Superoxide Dismutase Calculated by QM/MM Free‐Energy Methods

Heimdal, Jimmy; Kaukonen, Maria; Srnec, Martin; Rulı́s̆ek, Lubomı́r; Ryde, Ulf

doi:10.1002/cphc.201100339

Cited by 39 publications

(85 citation statements)

References 133 publications

(141 reference statements)

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“…The QTCP calculations were performed as has been described before: [72][73][74] First, each state of interest was optimised by QM/MM, keeping system 2 fixed at the crystal structure. Then, the protein was further solvated in an octahedral box of TIP3P water molecules, 75 extending at least 9 Å from the QM/MM system.…”

Section: Qtcp Calculationsmentioning

confidence: 99%

O₂ Activation in Salicylate 1,2-Dioxygenase: A QM/MM Study Reveals the Role of His162

Dong

Ryde

2016

Inorg. Chem.

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Section: Qtcp Calculationsmentioning

confidence: 99%

O₂ Activation in Salicylate 1,2-Dioxygenase: A QM/MM Study Reveals the Role of His162

Dong

Ryde

2016

Inorg. Chem.

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“…This reflects that the oxidation state of the Mo ion has changed in SP and also partly in TS2, something that is frequently problematic to describe with the DFT functionals, giving a strong dependence on the amount of exact exchange of the functionals. 66,67 To get an indication of which DFT functional gives the more reliable results, we estimated the electronic energies for the stationary structures with the LCCSD(T0) method (correcting for basis set incompleteness and domain errors with an MP2 correction as described in the Methods section). In the LCCSD(T0) calculations, the number of pairs included in the CCSD iterations (and the groups included in the triples list) are controlled by distance criteria.…”

Section: Effect Of the Dft Functionalmentioning

confidence: 99%

Large Density-Functional and Basis-Set Effects for the DMSO Reductase Catalyzed Oxo-Transfer Reaction

Mata

Ryde

2013

J. Chem. Theory Comput.

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105

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The oxygen-atom transfer reaction catalyzed by the mononuclear molybdenum enzyme dimethyl sulfoxide reductase (DMSOR) has attracted considerable attention by both experimental and theoretical studies. We show here that this reaction is more sensitive to details of quantum mechanical calculations that what has previously been appreciated. Basis sets of at least triplezeta quality are needed to obtain qualitatively correct results. Dispersion has an appreciable effect on the reaction, in particular the binding of the substrate or the dissociation of the product (up to 34 kJ/mol). Polar and non-polar solvation effects are also significant, especially if the enzyme can avoid cavitation effects by using a pre-formed active-site cavity. Relativistic effects are considerable (up to 22 kJ/mol), but they are reasonably well treated by a relativistic effective core potential. Various density-functional methods give widely different results for the activation and reaction energy (differences of over 100 kJ/mol), mainly reflecting the amount of exact exchange in the functional, owing to the oxidation of Mo from +IV to +VI. By calibration towards local CCSD(T0) calculations, we show that none of eight tested functionals (TPSS, BP86, BLYP, B97-D, TPSSH, B3LYP, PBE0, and BHLYP) give accurate energies for all states in the reaction. Instead, B3LYP gives the best activation barrier, whereas pure functionals give more accurate energies for the other states. Our best results indicate that the enzyme follows a two-step associative reaction mechanism with an overall activation enthalpy of 63 kJ/mol, which is in excellent agreement with the experimental results.

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“…Test calculations at the semiempirical level have shown that this is does not affect the final free energies significantly. 70 The QTCP calculations were performed as previously described, 68,69,71,72 with simple extensions to the QM/MM-2QM case: First, each redox state was optimised by QM/MM-2QM, using a solvated spherical system with a radius of 38 Å. 37 Second, the total system was moved into a periodic octahedral box and was further solvated with water molecules extending at least 9 Å from the original system, giving a total of 12270 water molecules (a set of QTCP calculations in which the solvent shell was increased to 15 Å or 19803 water molecules was also performed).…”

Section: Qtcp-2qm Calculationsmentioning

confidence: 99%

“…77 Finally, T is the temperature and S QM/MM is the entropy, calculated from the frequencies, using a normal-mode harmonicoscillator and ideal-gas approximation. 75 In this investigation, we assume that the contribution from the surrounding protein cancels between the reactant and the product, as has been done before, 72,75 so only the entropy of the isolated QM systems in vacuum was considered. Several variants of QM/MM-PBSA are available.…”

Section: Mementioning

confidence: 99%

Reorganization Energy for Internal Electron Transfer in Multicopper Oxidases

Farrokhnia

Heimdal

et al. 2011

J. Phys. Chem. B

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We have calculated the reorganisation energy for the intramolecular electron transfer between the reduced type 1 copper site and the peroxy intermediate of the trinuclear cluster in the multicopper oxidase CueO. The calculations are performed at the combined quantum mechanics and molecular mechanics (QM/MM) level, based on molecular dynamics simulations with tailored potentials for the two copper sites. We obtain a reorganisation energy of 91-133 kJ/mol, depending on the theoretical treatment. The two Cu sites contribute by 12 and 22 kJ/mol to this energy, whereas the solvent contribution is 34 kJ/mol. The rest comes from the protein, involving small contributions from many residues. We have also estimated the energy difference between the two electron-transfer states and show that the reduction of the peroxy intermediate is exergonic by 43-87 kJ/mol, depending on the theoretical method. Both the solvent and the protein contribute to this energy difference, especially charged residues close to the two Cu sites. We compare these estimates with energies obtained from QM/MM optimisations and QM calculations in vacuum, and discuss differences between the results obtained at various levels of theory.

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Reduction Potentials and Acidity Constants of Mn Superoxide Dismutase Calculated by QM/MM Free‐Energy Methods

Cited by 39 publications

References 133 publications

O₂ Activation in Salicylate 1,2-Dioxygenase: A QM/MM Study Reveals the Role of His162

O₂ Activation in Salicylate 1,2-Dioxygenase: A QM/MM Study Reveals the Role of His162

Large Density-Functional and Basis-Set Effects for the DMSO Reductase Catalyzed Oxo-Transfer Reaction

Reorganization Energy for Internal Electron Transfer in Multicopper Oxidases

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Reduction Potentials and Acidity Constants of Mn Superoxide Dismutase Calculated by QM/MM Free‐Energy Methods

Cited by 39 publications

References 133 publications

O2 Activation in Salicylate 1,2-Dioxygenase: A QM/MM Study Reveals the Role of His162

O2 Activation in Salicylate 1,2-Dioxygenase: A QM/MM Study Reveals the Role of His162

Large Density-Functional and Basis-Set Effects for the DMSO Reductase Catalyzed Oxo-Transfer Reaction

Reorganization Energy for Internal Electron Transfer in Multicopper Oxidases

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O₂ Activation in Salicylate 1,2-Dioxygenase: A QM/MM Study Reveals the Role of His162

O₂ Activation in Salicylate 1,2-Dioxygenase: A QM/MM Study Reveals the Role of His162