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Biophys J, November 2001, p. 2473-2483, Vol. 81, No. 5
¶
**
*Beckman Institute for Advanced Science and Technology,
Department of Molecular and Integrative Physiology,
Center for Biophysics and Computational Biology,
§Department of Chemistry, ¶National Center
for Supercomputing Applications, Department of
Biochemistry, **Bioengineering Program, University of Illinois,
Urbana-Champaign, Urbana, Illinois 61801 USA
A hierarchical computational strategy combining
molecular modeling, electrostatics calculations, molecular dynamics,
and Brownian dynamics simulations is developed and implemented to
compute electrophysiologically measurable properties of the KcsA
potassium channel. Models for a series of channels with different pore
sizes are developed from the known x-ray structure, using insights into
the gating conformational changes as suggested by a variety of
published experiments. Information on the pH dependence of the channel
gating is incorporated into the calculation of potential profiles for
K+ ions inside the channel, which are then combined with
K+ ion mobilities inside the channel, as computed by
molecular dynamics simulations, to provide inputs into Brownian
dynamics simulations for computing ion fluxes. The open model structure
has a conductance of ~110 pS under symmetric 250 mM K+
conditions, in reasonable agreement with experiments for the largest
conducting substate. The dimensions of this channel are consistent with
electrophysiologically determined size dependence of quaternary
ammonium ion blocking from the intracellular end of this channel as
well as with direct structural evidence that tetrabutylammonium ions
can enter into the interior cavity of the channel. Realistic values of
Ussing flux ratio exponents, distribution of ions within the channel,
and shapes of the current-voltage and current-concentration curves are
obtained. The Brownian dynamics calculations suggest passage of ions
through the selectivity filter proceeds by a "knock-off" mechanism
involving three ions, as has been previously inferred from functional
and structural studies of barium ion blocking. These results suggest
that the present calculations capture the essential nature of
K+ ion permeation in the KcsA channel and provide a
proof-of-concept for the integrated microscopic/mesoscopic multitiered
approach for predicting ion channel function from structure, which can be applied to other channel structures.
Biophys J, November 2001, p. 2473-2483, Vol. 81, No. 5
© 2001 by the Biophysical Society 0006-3495/01/11/2473/11 $2.00
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