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Biophys J, March 2000, p. 1359-1375, Vol. 78, No. 3
School of Chemistry, Tel Aviv University, Ramat Aviv, Tel Aviv 69978, Israel
A molecular dynamics simulation of melittin in a hydrated
dipalmitoylphosphatidylcholine (DPPC) bilayer was performed. The 19,000-atom system included a 72-DPPC phospholipid bilayer, a 26-amino
acid peptide, and more than 3000 water molecules. The N-terminus of the
peptide was protonated and embedded in the membrane in a transbilayer
orientation perpendicular to the surface. The simulation results show
that the peptide affects the lower (intracellular) layer of the bilayer
more strongly than the upper (extracellular) layer. The simulation
results can be interpreted as indicating an increased level of disorder
and structural deformation for lower-layer phospholipids in the
immediate vicinity of the peptide. This conclusion is supported by the
calculated deuterium order parameters, the observed deformation at the
intracellular interface, and an increase in fractional free volume. The
upper layer was less affected by the embedded peptide, except for an
acquired tilt relative to the bilayer normal. The effect of melittin on the surrounding membrane is localized to its immediate vicinity, and
its asymmetry with respect to the two layers may result from the fact
that it is not fully transmembranal. Melittin's hydrophilic C-terminus
anchors it at the extracellular interface, leaving the N-terminus
"loose" in the lower layer of the membrane. In general, the
simulation supports a role for local deformation and water penetration
in melittin-induced lysis. As for the peptide, like other
membrane-embedded polypeptides, melittin adopts a significant 25o tilt relative to the membrane normal. This tilt is
correlated with a comparable tilt of the lipids in the upper membrane
layer. The peptide itself retains an overall helical structure
throughout the simulation (with the exception of the three N-terminal
residues), adopting a 30o intrahelical bend angle.
Biophys J, March 2000, p. 1359-1375, Vol. 78, No. 3
© 2000 by the Biophysical Society 0006-3495/00/03/1359/17 $2.00
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