6533b85dfe1ef96bd12be740
RESEARCH PRODUCT
Force probe simulations using a hybrid scheme with virtual sites.
Ken SchäferGregor DiezemannJürgen GaussMarco Oestereichsubject
CouplingQuantitative Biology::Biomolecules010304 chemical physicsChemistryResolution (electron density)General Physics and AstronomyInverse transform samplingDegrees of freedom (mechanics)010402 general chemistry01 natural sciencesBoltzmann equation0104 chemical sciencesComputational physicssymbols.namesakeMolecular dynamics0103 physical sciencesBoltzmann constantsymbolsPhysical and Theoretical ChemistryRemainderdescription
Hybrid simulations, in which a part of the system is treated with atomistic resolution and the remainder is represented on a coarse-grained level, allow for fast sampling while using the accuracy of atomistic force fields. We apply a hybrid scheme to study the mechanical unfolding and refolding of a molecular complex using force probe molecular dynamics (FPMD) simulations. The degrees of freedom of the solvent molecules are treated in a coarse-grained manner while atomistic resolution is retained for the solute. The coupling between the solvent and the solute is provided using virtual sites. We test two different common coarse-graining procedures, the iterative Boltzmann inversion method and the force matching procedure, and find that both methodologies give similar results. The results of the FPMD simulations are compared to all-atom simulations of the same system and we find that differences between these simulations and the ones using the hybrid scheme are in a similar range as the differences obtained when using different atomistic force fields. Thus, a hybrid scheme yields qualitatively correct results in the strong non-equilibrium situation the system is experiencing in FPMD simulations.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2017-10-07 | The Journal of chemical physics |