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Biophys J, August 2001, p. 659-666, Vol. 81, No. 2
and
*Department of Materials and Interfaces, Weizmann Institute of
Science, Rehovot 76100, Israel; Department of Chemical
Engineering and Materials Science, University of California, Davis,
California 95616-5294 USA; and Department of Chemical
Engineering, University of California, Santa Barbara, California 93106 USA
Experiments have shown that the depletion of polymer in
the region between two apposed (contacting or nearly contacting)
bilayer membranes leads to fusion. In this paper we show theoretically that the addition of nonadsorbing polymer in solution can promote lateral contraction and phase separation of the lipids in the outer
monolayers of the membranes exposed to the polymer solution, i.e.,
outside the contact zone. This initial phase coexistence of higher- and
lower-density lipid domains in the outer monolayer results in surface
tension gradients in the outer monolayer. Initially, the inner layer
lipids are not exposed to the polymer solution and remain in their
original "unstressed" state. The differential stresses on the
bilayers give rise to a Marangoni flow of lipid from the outer
monolayers in the "contact zone" (where there is little polymer and
hence a uniform phase) to the outer monolayers in the "reservoir"
(where initially the surface tension gradients are large due to the
polymer-induced phase separation). As a result, the low-density domains
of the outer monolayers in the contact zone expose their hydrophobic
chains, and those of the inner monolayers, to the solvent and to each
other across the narrow water gap, allowing fusion to occur via a
hydrophobic interaction. More generally, this type of mechanism
suggests that fusion and other intermembrane interactions may be
triggered by Marangoni flows induced by surface tension gradients that
provide "action at a distance" far from the fusion or interaction zone.
Biophys J, August 2001, p. 659-666, Vol. 81, No. 2
© 2001 by the Biophysical Society 0006-3495/01/08/659/08 $2.00
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