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Your search keyword '"Elias-Wolff, Federico"' showing total 7 results
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7 results on '"Elias-Wolff, Federico"'

1. Structural symmetry and membrane curvature sensing

Author

Elías-Wolff, Federico, Lyubartsev, Alexander, Brandt, Erik G., and Lindén, Martin

Subjects
Physics - Biological Physics, Quantitative Biology - Biomolecules
Abstract

Symmetry is closely intertwined with the function, genetics, and chemical properties of multiprotein complexes. Here, we explore the relation between structural symmetry and the ability of membrane proteins to sense and induce membrane curvature, which is a key factor for modulating the shape and organization of cell membranes. Using coarse-grained simulations and elasticity theory, we show that the potential for direction-dependent membrane curvature sensing is limited to asymmetric proteins, dimers, and tetramers, and argue that one should expect this anisotropy to be strongest for dimers. Odd and higher-order symmetries strongly suppress directional curvature sensing. This classification gives a new perspective on the structure-function relation for membrane proteins, and simplifies the task of translating between molecular sensing mechanisms and their large-scale cellular consequences., Comment: 6 pages, 4 figures

Published
2018

2. Anisotropic membrane curvature sensing by amphipathic peptides

Author

Gómez-Llobregat, Jordi, Elías-Wolff, Federico, and Lindén, Martin

Subjects
Physics - Biological Physics, Condensed Matter - Soft Condensed Matter, Quantitative Biology - Biomolecules
Abstract

Many proteins and peptides have an intrinsic capacity to sense and induce membrane curvature, and play crucial roles for organizing and remodelling cell membranes. However, the molecular driving forces behind these processes are not well understood. Here, we describe a new approach to study curvature sensing, by simulating the direction-dependent interactions of single molecules with a buckled lipid bilayer. We analyse three amphipathic antimicrobial peptides, a class of membrane-associated molecules that specifically target and destabilize bacterial membranes, and find qualitatively different sensing characteristics that would be difficult to resolve with other methods. These findings provide new insights into the curvature sensing mechanisms of amphipathic peptides and challenge existing theories of hydrophobic insertion. Our approach is generally applicable to a wide range of curvature sensing molecules, and our results provide strong motivation to develop new experimental methods to track position and orientation of membrane proteins., Comment: 14 pages. Supplementary movies available on request. Accepted version, with corrected description lipid bilayer composition

Published
2014
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5. Curvature sensing by cardiolipin in simulated buckled membranes

Author

Elias-Wolff, Federico, Lindén, Martin, Lyubartsev, Alexander P., Brandt, Erik G., Elias-Wolff, Federico, Lindén, Martin, Lyubartsev, Alexander P., and Brandt, Erik G.

Abstract

Cardiolipin is a non-bilayer phospholipid with a unique dimeric structure. It localizes to negative curvature regions in bacteria and is believed to stabilize respiratory chain complexes in the highly curved mitochondrial membrane. Cardiolipin's localization mechanism remains unresolved, because important aspects such as the structural basis and strength for lipid curvature preferences are difficult to determine, partly due to the lack of efficient simulation methods. Here, we report a computational approach to study curvature preferences of cardiolipin by simulated membrane buckling and quantitative modeling. We combine coarse-grained molecular dynamics with simulated buckling to determine the curvature preferences in three-component bilayer membranes with varying concentrations of cardiolipin, and extract curvature-dependent concentrations and lipid acyl chain order parameter profiles. Cardiolipin shows a strong preference for negative curvatures, with a highly asymmetric chain order parameter profile. The concentration profiles are consistent with an elastic model for lipid curvature sensing that relates lipid segregation to local curvature via the material constants of the bilayers. These computations constitute new steps to unravel the molecular mechanism by which cardiolipin senses curvature in lipid membranes, and the method can be generalized to other lipids and membrane components as well.

Published
2019
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6. Computing Curvature Sensitivity of Biomolecules in Membranes by Simulated Buckling

Author

Elias-Wolff, Federico, Lindén, Martin, Lyubartsev, Alexander P., Brandt, Erik G., Elias-Wolff, Federico, Lindén, Martin, Lyubartsev, Alexander P., and Brandt, Erik G.

Abstract

Membrane curvature sensing, where the binding free energies of membrane-associated molecules depend on the local membrane curvature, is a key factor to modulate and maintain the shape and organization of cell membranes. However, the microscopic mechanisms are not well understood, partly due to absence of efficient simulation methods. Here, we describe a method to compute the curvature dependence of the binding free energy of a membrane associated probe molecule that interacts with a buckled membrane, which has been created by lateral compression of a flat bilayer patch. This buckling approach samples a wide range of curvatures in a single simulation, and anisotropic effects can be extracted from the orientation statistics. We develop an efficient and robust algorithm to extract the motion of the probe along the buckled membrane surface, and evaluate its numerical properties by extensive sampling of three coarse-grained model systems: local lipid density in a curved environment for single-component bilayers, curvature preferences of individual lipids in two-component membranes, and curvature sensing by a homotrimeric transmembrane protein. The method can be used to complement experimental data from curvature partition assays and provides additional insight into mesoscopic theories and molecular mechanisms for curvature sensing.

Published
2018
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