In order to characterise the dynamics of proteins, a well-established method is to incorporate experimental parameters as replica-averaged structural restraints into molecular dynamics simulations. Here, we justify this approach in the case of interproton distance information provided by nuclear Overhauser effects by showing that it generates ensembles of conformations according to the maximum entropy principle. These results indicate that the use of replica-averaged structural restraints in molecular dynamics simulations, given a force field and a set of experimental data, can provide an accurate approximation of the unknown Boltzmann distribution of a system.
Molecular dynamics simulations with replica-averaged structural restraints generate structural ensembles according to the maximum entropy principle / A. Cavalli, C. Camilloni, M. Vendruscolo. - In: THE JOURNAL OF CHEMICAL PHYSICS. - ISSN 0021-9606. - 138:9(2013), pp. 094112.1-094112.5. [10.1063/1.4793625]
Molecular dynamics simulations with replica-averaged structural restraints generate structural ensembles according to the maximum entropy principle
C. CamilloniSecondo
;
2013
Abstract
In order to characterise the dynamics of proteins, a well-established method is to incorporate experimental parameters as replica-averaged structural restraints into molecular dynamics simulations. Here, we justify this approach in the case of interproton distance information provided by nuclear Overhauser effects by showing that it generates ensembles of conformations according to the maximum entropy principle. These results indicate that the use of replica-averaged structural restraints in molecular dynamics simulations, given a force field and a set of experimental data, can provide an accurate approximation of the unknown Boltzmann distribution of a system.
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