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Conduction and Gating Properties of the TRAAK Channel from Molecular Dynamics Simulations with Different Force Fields

Riccardo Ocello, Simone Furini, Francesca Lugli, Maurizio Recanatini, Cármen Domene, Matteo Masetti

2020Journal of Chemical Information and Modeling19 citationsDOIOpen Access PDF

Abstract

In recent years, the K2P family of potassium channels has been the subject of intense research activity. Owing to the complex function and regulation of this family of ion channels, it is common practice to complement experimental findings with the atomistic description provided by computational approaches such as molecular dynamics (MD) simulations, especially, in light of the unprecedented timescales accessible at present. However, despite recent substantial improvements, the accuracy of MD simulations is still undermined by the intrinsic limitations of force fields. Here, we systematically assessed the performance of the most popular force fields employed to study ion channels at timescales that are orders of magnitude greater than the ones accessible when these energy functions were first developed. Using 32 μs of trajectories, we investigated the dynamics of a member of the K2P ion channel family, the TRAAK channel, using two established force fields in simulations of biological systems: AMBER and CHARMM. We found that while results are comparable on the nanosecond timescales, significant inconsistencies arise at microsecond timescales.

Topics & Concepts

Molecular dynamicsMicrosecondNanosecondForce field (fiction)Statistical physicsIon channelGatingPhysicsThermal conductionIonChemical physicsChemistryBiophysicsThermodynamicsBiologyQuantum mechanicsBiochemistryLaserReceptorIon channel regulation and functionMass Spectrometry Techniques and ApplicationsCardiac electrophysiology and arrhythmias
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