Your search keyword '"Sorre, Benoit"' showing total 2 results

1. Membrane curvature controls dynamin polymerization

Author

Roux, Aurelien, Koster, Gerbrand, Lenz, Martin, Sorre, Benoit, Manneville, Jean-Baptiste, Nassoy, Pierre, and Bassereau, Patricia

Subjects

Protein binding -- Observations, Polymerization -- Observations, Cell membranes -- Properties, Endocytosis -- Research, Science and technology

Abstract

The generation of membrane curvature in intracellular traffic involves many proteins that can curve lipid bilayers. Among these, dynamin-like proteins were shown to deform membranes into tubules, and thus far are the only proteins known to mechanically drive membrane fission. Because dynamin forms a helical coat circling a membrane tubule, its polymerization is thought to be responsible for this membrane deformation. Here we show that the force generated by dynamin polymerization, 18 pN, is sufficient to deform membranes yet can still be counteracted by high membrane tension. Importantly, we observe that at low dynamin concentration, polymer nucleation strongly depends on membrane curvature. This suggests that dynamin may be precisely recruited to membrane buds' necks because of their high curvature. To understand this curvature dependence, we developed a theory based on the competition between dynamin polymerization and membrane mechanical deformation. This curvature control of dynamin polymerization is predicted for a specific range of concentrations (~0.1-10 [micro]M), which corresponds to our measurements. More generally, we expect that any protein that binds or self-assembles onto membranes in a curvature-coupled way should behave in a qualitatively similar manner, but with its own specific range of concentration. force | nucleation | fission | endocytosis | dynamin-like proteins doi/10.1073/pnas.0913734107

Published

2010

2. Curvature-driven lipid sorting needs proximity to a demixing point and is aided by proteins

Author

Sorre, Benoit, Callan-Jones, Andrew, Manneville, Jean-Baptiste, Nassoy, Pierre, Joanny, Jean-Francois, Prost, Jacques, Goud, Bruno, and Bassereau, Patricia

Subjects

Lipids -- Properties, Lipids -- Health aspects, Nanotubes -- Properties, Cholera toxin -- Properties, Protein binding -- Research, Homeostasis -- Research, Science and technology

Abstract

Sorting of lipids and proteins is a key process allowing eukaryotic cells to execute efficient and accurate intracellular transport and to maintain membrane homeostasis. It occurs during the formation of highly curved transport intermediates that shuttle between cell compartments. Protein sorting is reasonably well described, but lipid sorting is much less understood. Lipid sorting has been proposed to be mediated by a physical mechanism based on the coupling between membrane composition and high curvature of the transport intermediates. To test this hypothesis, we have performed a combination of fluorescence and force measurements on membrane tubes of controlled diameters pulled from giant unilamellar vesicles. A model based on membrane elasticity and nonideal solution theory has also been developed to explain our results. We quantitatively show, using 2 independent approaches, that a difference in lipid composition can build up between a curved and a noncurved membrane. Importantly, and consistent with our theory, lipid sorting occurs only if the system is close to a demixing point. Remarkably, this process is amplified when even a low fraction of lipids is clustered upon cholera toxin binding. This can be explained by the reduction of the entropic penalty of lipid sorting when some lipids are bound together by the toxin. Our results show that curvature-induced lipid sorting results from the collective behavior of lipids and is even amplified in the presence of lipid-clustering proteins. In addition, they suggest a generic mechanism by which proteins can facilitate lipid segregation in vivo. cholera toxin | giant unilamellar vesicte | membrane curvature | membrane nanotube | optical tweezers

Published

2009