Morphology and interaction between lipid domains

Creators: Ursell, Tristan S.; Klug, William S.; Phillips, Rob

Abstract

Cellular membranes are a heterogeneous mix of lipids, proteins and small molecules. Special groupings enriched in saturated lipids and cholesterol form liquid-ordered domains, known as "lipid rafts," thought to serve as platforms for signaling, trafficking and material transport throughout the secretory pathway. Questions remain as to how the cell maintains small fluid lipid domains, through time, on a length scale consistent with the fact that no large-scale phase separation is observed. Motivated by these examples, we have utilized a combination of mechanical modeling and in vitro experiments to show that membrane morphology plays a key role in maintaining small domain sizes and organizing domains in a model membrane. We demonstrate that lipid domains can adopt a flat or dimpled morphology, where the latter facilitates a repulsive interaction that slows coalescence and helps regulate domain size and tends to laterally organize domains in the membrane.

Additional Information

©2009 by the National Academy of Sciences. Edited by L. B. Freund, Brown University, Providence, RI, and approved June 10, 2009. Published online before print July 20, 2009, doi: 10.1073/pnas.0903825106 We thank Patricia Bassereau, Evan Evans, Ben Freund, Kerwyn Huang, Greg Huber, Sarah Keller, and Udo Seifert for stimulating discussion and comments on the manuscript and Jenny Hsaio for help with experiments. T.U. and R.P. acknowledge the support of National Science Foundation (NSF) Award CMS-0301657, NSF Award ACI-0204932, Nanoscale Interdisciplinary Research Teams Award CMS-0404031, and the National Institutes of Health Director's Pioneer Award, and National Institutes of Health Award RO1 GM084211. W.S.K. acknowledges support from NSF CAREER Award CMMI-0748034. Author contributions: T.S.U. and W.S.K. performed research; T.S.U. analyzed data; and T.S.U., W.S.K., and R.P. wrote the paper. The authors declare no conflict of interest. This article is a PNAS Direct Submission. This article contains supporting information online at www.pnas.org/cgi/content/full/0903825106/DCSupplemental.

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Published - Ursell2009p5759P_Natl_Acad_Sci_Usa.pdf

Supplemental Material - UrsellAppendix_PDF.pdf

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