posted on 2015-04-14, 00:00authored byCarmen Domene, Paolo Barbini, Simone Furini
Conduction through ion channels possesses
two interesting features:
(i) different ionic species are selected with high-selectivity and
(ii) ions travel across the channel with rates approaching free-diffusion.
Molecular dynamics simulations have the potential to reveal how these
processes take place at the atomic level. However, analysis of conduction
and selectivity at atomistic detail is still hampered by the short
time scales accessible by computer simulations. Several algorithms
have been developed to “accelerate” sampling along the
slow degrees of freedom of the process under study and thus to probe
longer time scales. In these algorithms, the slow degrees of freedom
need to be defined in advance, which is a well-known shortcoming.
In the particular case of ion conduction, preliminary assumptions
about the number and type of ions participating in the permeation
process need to be made. In this study, a novel approach for the analysis
of conduction and selectivity based on bias-exchange metadynamics
simulations was tested. This approach was compared with umbrella sampling
simulations, using a model of a Na+-selective channel.
Analogous conclusions resulted from both techniques, but the computational
cost of bias-exchange simulations was lower. In addition, with bias-exchange
metadynamics it was possible to calculate free energy profiles in
the presence of a variable number and type of permeating ions. This
approach might facilitate the definition of the set of collective
variables required to analyze conduction and selectivity in ion channels.