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Article
Effect of cholesterol on structural and mechanical properties of membranes depends on lipid chain saturation
Phys. Rev. E
  • Jianjun Pan, Carnegie Mellon University
  • Stephanie Tristram-Nagle, Carnegie Mellon University
  • John F. Nagle, Carnegie Mellon University
Date of Original Version
5-1-2009
Type
Article
Rights Management
Copyright 2009 by the American Physical Society
Abstract or Description

The effects of cholesterol on membrane bending modulus KC, membrane thickness DHH, the partial and apparent areas of cholesterol and lipid, and the order parameter Sxray are shown to depend upon the number of saturated hydrocarbon chains in the lipid molecules. Particularly striking is the result that up to 40% cholesterol does not increase the bending modulus KC of membranes composed of phosphatidylcholine lipids with two cis monounsaturated chains, although it does have the expected stiffening effect on membranes composed of lipids with two saturated chains. The B fluctuational modulus in the smectic liquid crystal theory is obtained and used to discuss the interactions between bilayers. Our KC results motivate a theory of elastic moduli in the high cholesterol limit and they challenge the relevance of universality concepts. Although most of our results were obtained at 30 °C, additional data at other temperatures to allow consideration of a reduced temperature variable do not support universality for the effect of cholesterol on all lipid bilayers. If the concept of universality is to be valid, different numbers of saturated chains must be considered to create different universality classes. The above experimental results were obtained from analysis of x-ray scattering in the low angle and wide angle regions.

DOI
10.1103/PhysRevE.80.021931
Citation Information
Jianjun Pan, Stephanie Tristram-Nagle and John F. Nagle. "Effect of cholesterol on structural and mechanical properties of membranes depends on lipid chain saturation" Phys. Rev. E Vol. 80 (2009) p. 021931
Available at: http://works.bepress.com/john_nagle1/10/