James C. Gumbart, Ivan Teo, Benoit Roux, and Klaus Schulten.
Reconciling the roles of kinetic and thermodynamic factors in
membrane-protein insertion.
Journal of the American Chemical Society, 135:2291-2297, 2013.
(PMC: 3573731)
GUMB2013
For the vast majority of membrane proteins, insertion into a membrane is not direct, but
rather is catalyzed by a protein-conducting channel, the translocon. This channel provides
a lateral exit into the bilayer while simultaneously offering a pathway into the lumen. The
determinants of a nascent protein's choice between these two pathways are not
comprehensively understood, although both energetic and kinetic factors have been
observed. To elucidate the specific roles of some of these factors we have carried out
extensive all-atom molecular dynamics simulations of different nascent transmembrane
segments embedded in a ribosome-bound bacterial translocon, SecY. Simulations on the
s time scale reveal a spontaneous motion of the substrate segment into the
membrane or back into the channel, depending on its hydrophobicity, while potential of
mean force (PMF) calculations confirm that the observed motion is the result of local free-
energy differences between channel and membrane. Based on these and other PMFs, the
time-dependent probability of membrane insertion is determined and is shown to mimic a
two-state partitioning with an apparent free energy that is compressed relative to the
molecular-level PMFs. It is concluded that insertion kinetics underlie the apparent
thermodynamic partitioning process that is observed experimentally.
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