Structure and Energy of Fusion Stalks: The Role of Membrane Edges

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Structure and Energy of Fusion Stalks: The Role of Membrane Edges

Sylvio May

Institut für Molekularbiologie, Friedrich-Schiller-Universität Jena, 07745 Jena, Germany

Fusion of lipid bilayers proceeds via a sequence of distinct structural transformations. Its early stage involves a localized,hemifused intermediate in which the proximal but not yet the distalmonolayers are connected. Whereas the so-called stalk model mostsuccessfully accounts for the properties of the hemifused intermediate,there is still uncertainty about its microscopic structure andenergy. We reanalyze fusion stalks using the theory of membraneelasticity. In our calculations, a short (cylindrical micelle-like)tether connects the two proximal monolayers of the hemifused membranes.The shape of the stalk and the length of the tether are calculatedsuch as to minimize the overall free energy and to avoid the formationof voids within the hydrocarbon core. Our free energy expressionis based on three internal degrees of freedom of a perturbed lipidlayer: thickness, splay, and tilt deformations. Based on exactlythe same model, we compare fusion stalks with and without theability included to form sharp edges at the interfacial regionbetween the hydrocarbon core and the polar environment. Requiringthe interface to be smooth everywhere, our detailed calculationsrecover previous results: the stalk energies are far too highto account for the experimental observation of fusion intermediates.However, if we allow the interface to be nonsmooth, we find aremarkable reduction of the stalk free energy down to more realisticvalues. The corresponding structure of a nonsmooth stalk exhibitssharp edges at the transition regions between the bilayer andtether parts. In addition to that, a corner is formed at eachof the two distal monolayers. We discuss the mechanism how membraneedges reduce the energy of fusionstalks.

Biophys J, December 2002, p. 2969-2980, Vol. 83, No. 6
© 2002 by the Biophysical Society 0006-3495/02/12/2969/12 $2.00

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