Insertion and Pore Formation Driven by Adsorption of Proteins Onto Lipid Bilayer Membrane-Water Interfaces

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Insertion and Pore Formation Driven by Adsorption of Proteins Onto Lipid Bilayer Membrane-Water Interfaces

Martin J. Zuckermann^* and Thomas Heimburg^*

^*MEMPHYS Group, Department of Chemistry, Technical University of Denmark, DK-2800 Lyngby, Denmark, School of Physics, University of New South Wales, Sydney 2052, Australia, and Membrane Thermodynamics Group, Max-Planck-Institute for Biophysical Chemistry, 37077 Göttingen, Germany

We describe the binding of proteins to lipid bilayers in the case for which binding can occur either by adsorption to thelipid bilayer membrane-water interface or by direct insertioninto the bilayer itself. We examine in particular the case whenthe insertion and pore formation are driven by the adsorptionprocess using scaled particle theory. The adsorbed proteins forma two-dimensional "surface gas" at the lipid bilayer membrane-waterinterface that exerts a lateral pressure on the lipid bilayermembrane. Under conditions of strong intrinsic binding and a highdegree of interfacial converge, this pressure can become highenough to overcome the energy barrier for protein insertion. Underthese conditions, a subtle equilibrium exists between the adsorbedand inserted proteins. We propose that this provides a controlmechanism for reversible insertion and pore formation of proteinssuch as melittin and magainin. Next, we discuss experimental datafor the binding isotherms of cytochrome c to charged lipid membranesin the light of our theory and predict that cytochrome c insertsinto charged lipid bilayers at low ionic strength. This predictionis supported by titration calorimetry results that are reportedhere. We were furthermore able to describe the observed bindingisotherms of the pore-forming peptides endotoxin ( $alpha$ 5-helix) andof pardaxin to zwitterionic vesicles from our theory by assumingadsorption/insertionequilibrium.

Biophys J, November 2001, p. 2458-2472, Vol. 81, No. 5
© 2001 by the Biophysical Society 0006-3495/01/11/2458/15 $2.00

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