1 research outputs found
Molecular Dynamics Simulations of Membrane–Sugar Interactions
It is well documented that disaccharides
in general and trehalose
(TRH) in particular strongly affect physical properties and functionality
of lipid bilayers. We investigate interactions between lipid membranes
formed by 1,2-dimyristoyl-<i>sn</i>-glycero-3-phosphocholine
(DMPC) and TRH by means of molecular dynamics (MD) computer simulations.
Ten different TRH concentrations were studied in the range <i>w</i><sub>TRH</sub> = 0–0.20 (w/w). The potential of
mean force (PMF) for DMPC bilayer–TRH interactions was determined
using two different force fields, and was subsequently used in a simple
analytical model for description of sugar binding at the membrane
interface. The MD results were in good agreement with the predictions
of the model. The net affinities of TRH for the DMPC bilayer derived
from the model and MD simulations were compared with experimental
results. The area per lipid increases and the membrane becomes thinner
with increased TRH concentration, which is interpreted as an intercalation
effect of the TRH molecules into the polar part of the lipids, resulting
in conformational changes in the chains. These results are consistent
with recent experimental observations. The compressibility modulus
related to the fluctuations of the membrane increases dramatically
with increased TRH concentration, which indicates higher order and
rigidity of the bilayer. This is also reflected in a decrease (by
a factor of 15) of the lateral diffusion of the lipids. We interpret
these observations as a formation of a glassy state at the interface
of the membrane, which has been suggested in the literature as a hypothesis
for the membrane–sugar interactions