The Modified Stalk Mechanism of Lamellar/Inverted Phase Transitions and Its Implications for Membrane Fusion

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The Modified Stalk Mechanism of Lamellar/Inverted Phase Transitions and Its Implications for Membrane Fusion

David P. Siegel

Chemistry Department, The Ohio State University, Columbus, Ohio 43210 USA

A model of the energetics of lipid assemblies (Siegel. 1993. Biophys. J. 65:2124-2140) is used to predict the relative freeenergy of intermediates in the transitions between lamellar (L)inverted hexagonal (H_II), and inverted cubic (Q_II) phases. Themodel was previously used to generate the modified stalk theoryof membrane fusion. The modified stalk theory proposes that thelowest energy structures to form between apposed membranes arethe stalk and the transmonolayer contact (TMC), respectively.The first steps in the L/H_II and L/Q_II phase transitionsare also intermembrane events: bilayers of the L phase mustinteract to form new topologies during these transitions. Hencethe intermediates in these phase transitions should be similarto the intermediates in the modified stalk mechanism of fusion.The calculations here show that stalks and TMCs can mediate transitionsbetween the L, Q_II, and H_II phases. These predictions aresupported by studies of the mechanism of these transitions viatime-resolved cryoelectron microscopy (Siegel et al. 1994. Biophys.J. 66:402-414; Siegel and Epand. 1997. Biophys. J. 73:3089-3111),whereas the predictions of previously proposed transition mechanismsare not. The model also predicts that Q_II phases should be thermodynamicallystable in all thermotropic lipid systems. The profound hysteresisin L/Q_II transitions in some phospholipid systems may bedue to lipid composition-dependent effects other than differencesin lipid spontaneous curvature. The relevant composition-dependentproperties are the Gaussian curvature modulus and the membranerupture tension, which could change the stability of TMCs. TMCstability also influences the rate of membrane fusion of apposedbilayers, so these two properties may also affect the fusion ratein model membrane and biomembrane systems. One way proteins catalyzemembrane fusion may be by making local changes in these lipidproperties. Finally, although the model identifies stalks andTMCs as the lowest energy intermembrane intermediates in fusionand lamellar/inverted phase transitions, the stalk and TMC energiescalculated by the present model are still large. This suggeststhat there are deficiencies in the current model for intermediatesor intermediate energies. The possible nature of these deficienciesisdiscussed.

Biophys J, January 1999, p. 291-313, Vol. 76, No. 1
© 1999 by the Biophysical Society 0006-3495/99/01/291/23 $2.00

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