Aleksij Aksimentiev and Klaus Schulten.
Imaging alpha-hemolysin with molecular dynamics: Ionic conductance,
osmotic permeability and the electrostatic potential map.
Biophysical Journal, 88:3745-3761, 2005.
(PMC: 1305609)
AKSI2005
-Hemolysin of Staphylococcus aureus is a self-assembling toxin that forms a
water-filled transmembrane channel upon oligomerization in a lipid membrane. Apart
from being one of the best-studied toxins of bacterial origin, -hemolysin is the
principal component in several biotechnological applications, including systems for
controlled delivery of small solutes across lipid membranes, stochastic sensors for small
solutes, and an alternative to conventional technology for DNA sequencing. Through
large-scale molecular dynamics simulations, we studied the permeability of the -
hemolysin/lipid bilayer complex for water and ions. The studied system, composed of
about 300,000 atoms, included one copy of the protein, a patch of a DPPC lipid bilayer,
and a 1 M water solution of KCl. Monitoring the fluctuations of the pore structure revealed
an asymmetric, on average, cross section of the -hemolysin stem. Applying
external electrostatic fields produced a transmembrane ionic current; repeating
simulations at several voltage biases yielded a current/voltage curve of -
hemolysin and a set of electrostatic potential maps. The selectivity of -hemolysin
to Cl was found to depend on the direction and the magnitude of the applied
voltage bias. The results of our simulations are in excellent quantitative agreement with
available experimental data. Analyzing trajectories of all water molecule, we computed the
-hemolysin's osmotic permeability for water as well as its electroosmotic effect,
and characterized the permeability of its seven side channels. The side channels were
found to connect seven His-144 residues surrounding the stem of the protein to the bulk
solution; the protonation of these residues was observed to affect the ion conductance,
suggesting the seven His-144 to comprise the pH sensor that gates conductance of the
-hemolysin channel.
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