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The Range and Shielding of Dipole-Dipole Interactions in Phospholipid Bilayers

Theoretical Biological Physics, Royal Institute of Technology, AlbaNova University Center, Stockholm, Sweden

Correspondence: Address reprint requests to Olle Edholm, Royal Institute of Technology, Theoretical Biophysics, Department of Biophysics, KTH-SCFAB, Stockholm SE-106 91 Sweden. Tel.: 46-8-553-78168; E-mail: oed{at}theophys@kth.se.

In molecular dynamics simulations of lipid bilayers, the structure is sensitive to the precise treatment of electrostatics. The dipole-dipole interactions between headgroup dipoles are not long-ranged, but the area per lipid and, through it, other properties of the bilayer are very sensitive to the detailed balance between the perpendicular and in-plane components of the headgroup dipoles. This is affected by the detailed properties of the cutoff scheme or if long-range interactions are included by Ewald or particle-mesh Ewald techniques. Interaction between the in-plane components of the headgroup dipoles is attractive and decays as the inverse sixth power of distance. The interaction is screened by the square of a dielectric permittivity close to the value for water. Interaction between the components perpendicular to the membrane plane is repulsive and decays as the inverse third power of distance. These interactions are screened by a dielectric permittivity of the order 10. Thus, despite the perpendicular components being much smaller in magnitude than the in-plane components, they will dominate the interaction energies at large distances.

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