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Biophys J, May 2001, p. 2284-2297, Vol. 80, No. 5
Department of Chemistry, Dartmouth College, Hanover, New Hampshire 03755 USA
Exceptions to the Meyer-Overton rule are commonly cited
as evidence against indirect, membrane-mediated mechanisms of general anesthesia. However, another interpretation is possible within the
context of an indirect mechanism in which solubilization of an
anesthetic in the membrane causes a redistribution of lateral pressures
in the membrane, which in turn shifts the conformational equilibrium of
membrane proteins such as ligand-gated ion channels. It is suggested
that compounds of different stiffness and interfacial activity have
different intrinsic potencies, i.e., they cause widely different
redistributions of the pressure profile (and thus different effects on
protein conformational equilibria) per unit concentration of the
compound in the membrane. Calculations incorporating the greater
stiffness of perfluoromethylenic chains and the large interfacial
attraction of hydroxyl groups predict the higher intrinsic potency of
short alkanols than alkanes, the cutoffs in potency of alkanes and
alkanols and the much shorter cutoffs for their perfluorinated
analogues. Both effects, increased stiffness and interfacial activity,
are present in unsaturated hydrocarbon solutes, and the intrinsic
potencies are predicted to depend on the magnitude of both effects and
on the number and locations of multiple bonds within the molecule. Most
importantly, the intrinsic potencies of polymeric alkanols with
regularly spaced hydroxyl groups are predicted to rise
with increasing chain length, without cutoff; such molecules should
serve to distinguish unambiguously between indirect mechanisms and
direct binding mechanisms of anesthesia.
Biophys J, May 2001, p. 2284-2297, Vol. 80, No. 5
© 2001 by the Biophysical Society 0006-3495/01/05/2284/14 $2.00
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