Structural Basis of Membrane Bending by the N-BAR Protein Endophilin

Mim, Carsten; Cui, Haosheng; Gawronski-Salerno, Joseph; Frost, Adam; Lyman, Edward; Voth, Gregory A.; Unger, Vinzenz M.

doi:10.1016/j.cell.2012.01.048

Cited by 226 publications

(338 citation statements)

References 49 publications

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“…Contrary to the prevailing picture of BARs on membranes, in our simulations the proteins initially aggregate in the areas of negative Gaussian curvature, i.e., in troughs. The crescent shape (28) of BARs and the way they coat tubules (14) are what has motivated the perception of them populating positively curved membrane regions. Although single N-BAR proteins were observed in the present simulations to readily explore convex areas of the membrane, it appears that the quasi-linear aggregates have very different curvature proclivities at early stages of membrane remodeling.…”

Section: Resultsmentioning

confidence: 99%

“…1073/pnas.1309819110/-/DCSupplemental. a single protein or dense N-BAR lattices were studied theoretically and experimentally (14,(23)(24)(25)(26), simulating the N-BAR protein behavior at low and intermediate surface densities provides microscopic insights into the transient structures during the membrane restructuring at physiologically relevant concentrations. This is especially important in light of recent experimental work revealing the difference in mechanics of membrane bending under low-and high-density regimes of N-BAR proteins (27) and showed that N-BAR's mode of action needs to be studied with precise control of the bound protein density.…”

Section: Significancementioning

confidence: 99%

“…It is becoming increasingly apparent that these proteins do more than simply imprint their shape on the membrane surface; rather, membrane remodeling is a result of a collective effort among many proteins. Recent cryo-electron microscopic reconstruction revealed a high structural organization among BARs on membrane tubules under very high protein surface densities (14), and showed a required lateral alignment of amphipathic helices for the stabilization of membrane tubes. At the same time, fluorescence experiments suggest protein crowding also may be responsible for membrane remodeling resulting in the same membrane structures as with the binding of N-BAR domains (15).…”

mentioning

confidence: 99%

“…Protein-induced membrane remodeling is an intriguing problem from both structural and biophysical standpoints, so a computational approach connecting the underlying physics to the observed behavior may help reveal a more complete scope of the mechanism. Our recently developed coarse-grained (CG) models of N-BAR domain proteins (14,18,19) and of lipid bilayers (20) form the basis for the present work. The forces between CG lipids are derived from their underlying atomic interactions, using the multiscale coarse-graining method (21,22), which minimizes the number of adjustable ad hoc parameters.…”

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confidence: 99%

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Linear aggregation of proteins on the membrane as a prelude to membrane remodeling

Šimunović

Srivastava

Voth

2013

Proc. Natl. Acad. Sci. U.S.A.

143

185

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Adhesion and insertion of curvature-mediating proteins can induce dramatic structural changes in cell membranes, allowing them to participate in several key cellular tasks. The way proteins interact to generate curvature remains largely unclear, especially at early stages of membrane remodeling. Using a coarse-grained model of Bin/ amphiphysin/Rvs domain with an N-terminal helix (N-BAR) interacting with flat membranes and vesicles, we demonstrate that at low protein surface densities, binding of N-BAR domain proteins to the membrane is followed by a linear aggregation and the formation of meshes on the surface. In this process, the proteins assemble at the base of emerging membrane buds. Our work shows that beyond a more straightforward scaffolding mechanism at high bound densities, the interplay of anisotropic interactions and the local stress imposed by the N-BAR proteins results in deep invaginations and endocytic vesicular bud-like deformations, an order of magnitude larger than the size of the individual protein. Our results imply that by virtue of this mechanism, cell membranes may achieve rapid local increases in protein concentration.coarse-grained simulation | membrane stress | self-assembly | membrane curvature | Gaussian curvature L ipid membranes protect cells and their organelles and serve as mechanical support for proteins involved in signal transduction and cellular trafficking (1). Owing to the way lipids are assembled into bilayers of mesoscopic length and molecular width, membranes behave as elastic and highly dynamic molecular sheets. Their innate multiscale nature is further evident in the local interplay between proteins and lipids, which results in large-scale membrane remodeling characterized by an impressive array of morphologies (2). These properties allow biological membranes to take part in several important cellular processes, as their restructuring is key to enabling communication between cells, formation of organelles, trafficking, division, and cell migration (1).The interactions between individual proteins and lipid molecules alone are insufficient to remodel flat membrane sheets to an appreciable extent, implying that the experimentally observed membrane remodeling is a result of the concerted action of multiple proteins (3) in ways mechanistically differing from the mode of action of a single protein. Considering the multiple timescales required to capture protein dynamics as the membrane deformations are induced, as well as the difficulty in separating individual events of the remodeling process, this mechanism remains largely unclear. It previously was demonstrated that the binding of curvature-inducing nanoparticles may form tubular and vesicular structures, in which particles interact with one another solely via curvature (3-6). Furthermore, analytical theory predicts that anisotropic inclusions may induce budding on the membrane surface (7). However, the way proteins assemble on the membrane and how their oligomerization couples to both local and long-wavelength transformat...

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Section: Resultsmentioning

confidence: 99%

Section: Significancementioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Linear aggregation of proteins on the membrane as a prelude to membrane remodeling

Šimunović

Srivastava

Voth

2013

Proc. Natl. Acad. Sci. U.S.A.

143

185

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“…Generating curvature in a phospholipid bilayer implies that some form of packing asymmetry exists between the two leaflets of the membrane (Kirchhausen 2012). In principle, there are at least four ways in which cytosolic EAPs may contribute to lipid asymmetry and membrane curvature during CCP invagination: (1) by locally clustering lipids with larger-than-average head groups through interaction with membrane-associated proteins (Zimmerberg and Kozlov 2006), by converting one lipid type to another (Kooijman et al 2003) or by actively transporting a lipid type(s) from one leaflet to the other (Rauch and Farge 2000;Roelants et al 2010); (2) by "floating" an amphipathic helix in the inner leaflet of the membrane (Ford et al 2002) or by inserting a hydrophobic loop into the inner leaflet of the membrane (Plomann et al 2010); (3) by association of a precurved membrane-binding protein domain (such as BAR, F-BAR, or i-BAR) with the membrane surface (Mim et al 2012); or, most simply, (4) by membrane-associated protein crowding (Stachowiak et al 2012). The different mechanisms for generating membrane curvature are summarized in Figure 2.…”

Section: Coat Maturation and The Propagation Of Membrane Curvaturementioning

confidence: 99%

Endocytic Accessory Factors and Regulation of Clathrin-Mediated Endocytosis

Merrifield

Kaksonen

2014

Cold Spring Harbor Perspectives in Biology

114

111

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Molecular mechanisms of force production in clathrin‐mediated endocytosis

et al. 2018

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During clathrin-mediated endocytosis (CME), a flat patch of membrane is invaginated and pinched off to release a vesicle into the cytoplasm. In yeast CME, over 60 proteins—including a dynamic actin meshwork—self-assemble to deform the plasma membrane. Several models have been proposed for how actin and other molecules produce the forces necessary to overcome the mechanical barriers of membrane tension and turgor pressure, but the precise mechanisms and a full picture of their interplay are still not clear. In this review, we discuss the evidence for these force production models from a quantitative perspective and propose future directions for experimental and theoretical work that could clarify their various contributions.

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Structural Basis of Membrane Bending by the N-BAR Protein Endophilin

Cited by 226 publications

References 49 publications

Linear aggregation of proteins on the membrane as a prelude to membrane remodeling

Linear aggregation of proteins on the membrane as a prelude to membrane remodeling

Endocytic Accessory Factors and Regulation of Clathrin-Mediated Endocytosis

Molecular mechanisms of force production in clathrin‐mediated endocytosis

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