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Biophys J, September 2002, p. 1501-1510, Vol. 83, No. 3
*Department of Biological Sciences, University of Calgary, Calgary,
Alberta T2N 1N4, Canada; and Department of Bioscience and
Biotechnology, Drexel University, Philadelphia, Pennsylvania 19104 USA
The spontaneous formation of the phospholipid bilayer
underlies the permeability barrier function of the biological membrane. Tears or defects that expose water to the acyl chains are spontaneously healed by lipid lateral diffusion. However, mechanical barriers, e.g.,
protein aggregates held in place, could sustain hydrophobic defects.
Such defects have been postulated to occur in processes such as
membrane fusion. This gives rise to a new question in bilayer
structure: What do the lipids do in the absence of lipid lateral
diffusion to minimize the free energy of a hydrophobic defect? As a
first step to understand this rather fundamental question about bilayer
structure, we performed molecular dynamic simulations of up to 10 ns of
a planar bilayer from which lipids have been deleted randomly from one
monolayer. In one set of simulations, approximately one-half of the
lipids in the defect monolayer were restrained to form a mechanical
barrier. In the second set, lipids were free to diffuse around. The
question was simply whether the defects caused by removing a lipid
would aggregate together, forming a large hydrophobic cavity, or
whether the membrane would adjust in another way. When there are no
mechanical barriers, the lipids in the defect monolayer simply spread
out and thin with little effect on the other intact monolayer. In the
presence of a mechanical barrier, the behavior of the lipids depends on
the size of the defect. When 3 of 64 lipids are removed, the remaining
lipids adjust the lower one-half of their chains, but the headgroup
structure changes little and the intact monolayer is unaffected. When 6 to 12 lipids are removed, the defect monolayer thins, lipid disorder increases, and lipids from the intact monolayer move toward the defect
monolayer. Whereas this is a highly simplified model of a fusion site,
this engagement of the intact monolayer into the fusion defect is
strikingly consistent with recent results for influenza hemagglutinin
mediated fusion.
Biophys J, September 2002, p. 1501-1510, Vol. 83, No. 3
© 2002 by the Biophysical Society 0006-3495/02/09/1501/10 $2.00
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