Metadynamics as a Tool for Exploring Free Energy Landscapes of Chemical Reactions

Ensing, Bernd; Vivo, Marco De; Liu, Zhiwei; Moore, Preston B.; Klein, Michael L.

doi:10.1021/ar040198i

Cited by 351 publications

(311 citation statements)

References 47 publications

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“…[26][27][28] Metadynamics has been successfully used to study a wide range of problems in the physical, chemical, biological, and material sciences. 26,[29][30][31][32][33][34] As metadynamics efficiency decreases with the number of biased CVs, the minimal CV set providing meaningful results should be chosen. To map the conformers of Asp, the three backbone torsional angles α, β, and γ are an obvious, but not adequate choice, as we observed with preliminary calculations.…”

Section: Methodsmentioning

confidence: 99%

Mapping the conformational free energy of aspartic acid in the gas phase and in aqueous solution

Comitani

Rossi

Ceriotti

et al. 2017

The Journal of Chemical Physics

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Mapping the conformational free energy of aspartic acid in the gas phase and in aqueous solution The conformational free energy landscape of aspartic acid, a proteogenic amino acid involved in a wide variety of biological functions, was investigated as an example of the complexity that multiple rotatable bonds produce even in relatively simple molecules. To efficiently explore such a landscape, this molecule was studied in the neutral and zwitterionic forms, in the gas phase and in water solution, by means of molecular dynamics and the enhanced sampling method metadynamics with classical force-fields. Multi-dimensional free energy landscapes were reduced to bi-dimensional maps through the non-linear dimensionality reduction algorithm sketch-map to identify the energetically stable conformers and their interconnection paths. Quantum chemical calculations were then performed on the minimum free energy structures. Our procedure returned the low energy conformations observed experimentally in the gas phase with rotational spectroscopy [M. E. Sanz et al., Phys. Chem. Chem. Phys. 12, 3573 (2010)]. Moreover, it provided information on higher energy conformers not accessible to experiments and on the conformers in water. The comparison between different force-fields and quantum chemical data highlighted the importance of the underlying potential energy surface to accurately capture energy rankings. The combination of force-field based metadynamics, sketchmap analysis, and quantum chemical calculations was able to produce an exhaustive conformational exploration in a range of significant free energies that complements the experimental data. Similar protocols can be applied to larger peptides with complex conformational landscapes and would greatly benefit from the next generation of accurate force-fields.

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Section: Methodsmentioning

confidence: 99%

Mapping the conformational free energy of aspartic acid in the gas phase and in aqueous solution

Comitani

Rossi

Ceriotti

et al. 2017

The Journal of Chemical Physics

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show abstract

“…Several methods are available to study chemical reactions, including static quantum approaches or even advanced sampling techniques, e.g., umbrella sampling [21], metadynamics [22][23][24], and parallel tempering [25]. In this work, the reaction mechanism was explored using the static quantum approach [26].…”

Section: Theoretical Calculationsmentioning

confidence: 99%

The mechanism of formate oxidation by metal-dependent formate dehydrogenases

et al. 2011

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Metal-dependent formate dehydrogenases (Fdh) from prokaryotic organisms are members of the dimethyl sulfoxide reductase family of mononuclear molybdenum-containing and tungsten-containing enzymes. Fdhs catalyze the oxidation of the formate anion to carbon dioxide in a redox reaction that involves the transfer of two electrons from the substrate to the active site. The active site in the oxidized state comprises a hexacoordinated molybdenum or tungsten ion in a distorted trigonal prismatic geometry. Using this structural model, we calculated the catalytic mechanism of Fdh through density functional theory tools. The simulated mechanism was correlated with the experimental kinetic properties of three different Fdhs isolated from three different Desulfovibrio species. Our studies indicate that the C-H bond break is an event involved in the rate-limiting step of the catalytic cycle. The role in catalysis of conserved amino acid residues involved in metal coordination and near the metal active site is discussed on the basis of experimental and theoretical results.

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“…It locally modifies the energy profile of those regions in the configurational space that have already been visited and thereby prevents the trajectory from hanging about in the same basin of attraction for very long time. [36] This approach enforces the exploration of the free energy surface and is able to disclose the most probable pathways of a reaction, even if no prior knowledge of the transition and of the products is available. The scope of the applications was significantly broadened by its implementation together with ab initio methods [24] , such as DFT-based Car-Parrinello MD [37] .…”

Section: Ab Initio Metadynamicsmentioning

confidence: 99%

Towards a Rational Design of Ruthenium CO₂ Hydrogenation Catalysts by Ab Initio Metadynamics

Urakawa

Iannuzzi

Hutter

et al. 2007

Chemistry A European J

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Complete reaction pathways relevant to CO2 hydrogenation by using a homogeneous ruthenium dihydride catalyst ([Ru(dmpe)2H2], dmpe=Me2PCH2CH2PMe2) have been investigated by ab initio metadynamics. This approach has allowed reaction intermediates to be identified and free‐energy profiles to be calculated, which provide new insights into the experimentally observed reaction pathway. Our simulations indicate that CO2 insertion, which leads to the formation of formate complexes, proceeds by a concerted insertion mechanism. It is a rapid and direct process with a relatively low activation barrier, which is in agreement with experimental observations. Subsequent H2 insertion into the formateRu complex, which leads to the formation of formic acid, instead occurs via an intermediate [Ru(η2‐H2)] complex in which the molecular hydrogen coordinates to the ruthenium center and interacts weakly with the formate group. This step has been identified as the rate‐limiting step. The reaction completes by hydrogen transfer from the [Ru(η2‐H2)] complex to the formate oxygen atom, which forms a dihydrogen‐bonded RuH⋅⋅⋅HO(CHO) complex. The activation energy for the H2 insertion step is lower for the trans isomer than for the cis isomer. A simple measure of the catalytic activity was proposed based on the structure of the transition state of the identified rate‐limiting step. From this measure, the relationship between catalysts with different ligands and their experimental catalytic activities can be explained.

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Metadynamics as a Tool for Exploring Free Energy Landscapes of Chemical Reactions

Cited by 351 publications

References 47 publications

Mapping the conformational free energy of aspartic acid in the gas phase and in aqueous solution

Mapping the conformational free energy of aspartic acid in the gas phase and in aqueous solution

The mechanism of formate oxidation by metal-dependent formate dehydrogenases

Towards a Rational Design of Ruthenium CO₂ Hydrogenation Catalysts by Ab Initio Metadynamics

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Metadynamics as a Tool for Exploring Free Energy Landscapes of Chemical Reactions

Cited by 351 publications

References 47 publications

Mapping the conformational free energy of aspartic acid in the gas phase and in aqueous solution

Mapping the conformational free energy of aspartic acid in the gas phase and in aqueous solution

The mechanism of formate oxidation by metal-dependent formate dehydrogenases

Towards a Rational Design of Ruthenium CO2 Hydrogenation Catalysts by Ab Initio Metadynamics

Contact Info

Product

Resources

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Towards a Rational Design of Ruthenium CO₂ Hydrogenation Catalysts by Ab Initio Metadynamics