Tension-induced fusion of bilayer membranes and vesicles (original) (raw)

Nature Materials volume 4, pages 225–228 (2005)Cite this article

Abstract

Maintaining the integrity of their protective plasma membrane is a primary requirement of cells. Accordingly, cellular events that breach the membrane are tightly regulated1. Artificial vesicles used in drug delivery must also stay intact until they have reached the desired target2. In both cases, the intrinsic resistance of the membrane to rupture must be overcome to allow the efflux of the vesicle's contents. Here, we use mesoscopic simulations3 to study the fusion of 28-nm-diameter vesicles to 50 × 50 nm2 planar membrane patches over 2 μs. We monitor the time evolution of 93 different fusion attempts. This allows us to construct a global morphology diagram, using the initial tensions of the vesicle and the planar membrane patch as control parameters, and to determine the corresponding fusion statistics. All successful fusion events are observed to occur within 350 ns, which reflects the presence of alternative pathways for the tension relaxation.

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Acknowledgements

We thank Erwin Neher for helpful correspondence and acknowledge support by the Human Frontier Science Project through research grant RGP0072/2003. We also thank one of the reviewers for their rather detailed comments on the first version of this manuscript.

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  1. Max Planck Institute of Colloids and Interfaces, Potsdam, 14424, Germany
    Julian C. Shillcock & Reinhard Lipowsky

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  1. Julian C. Shillcock
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  2. Reinhard Lipowsky
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Correspondence toReinhard Lipowsky.

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Shillcock, J., Lipowsky, R. Tension-induced fusion of bilayer membranes and vesicles.Nature Mater 4, 225–228 (2005). https://doi.org/10.1038/nmat1333

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