AI Article Synopsis
- Curved cellular membranes are crucial for biological functions, but studying their dynamics is complicated due to curvature effects on diffusion.
- Molecular simulations are needed for better analysis, and the new tool CurD facilitates this by providing faster computations of lipid diffusion on curved membranes.
- Research using CurD shows that mean curvature significantly influences lipid movement, while Gaussian curvature has a minor effect, highlighting the importance of lipid headgroup packing.
Article Abstract
Curved cellular membranes are both abundant and functionally relevant. While novel tomography approaches reveal the structural details of curved membranes, their dynamics pose an experimental challenge. Curvature especially affects the diffusion of lipids and macromolecules, yet neither experiments nor continuum models distinguish geometric effects from those caused by curvature-induced changes in membrane properties. Molecular simulations could excel here, yet despite community interest toward curved membranes, tools for their analysis are still lacking. Here, we satisfy this demand by introducing CurD, our novel and openly available implementation of the Vertex-oriented Triangle Propagation algorithm to the study of lipid diffusion along membranes with mean and/or Gaussian curvature. This approach, aided by our highly optimized implementation, computes geodetic distances significantly faster than conventional implementations of path-finding algorithms. Our tool, applied to coarse-grained simulations, allows for the first time the analysis of curvature effects on diffusion at size scales relevant to physiological processes such as endocytosis. Our analyses with different membrane geometries reveal that Gaussian curvature plays a surprisingly small role on lipid motion, whereas mean curvature; i.e., the packing of lipid headgroups largely dictates their mobility.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11444424 | PMC |
| http://dx.doi.org/10.1021/acs.jpclett.4c00338 | DOI Listing |
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