Litcius/Paper detail

How Membrane Geometry Regulates Protein Sorting Independently of Mean Curvature

Jannik B. Larsen, Kadla R. Rosholm, Celeste Kennard, Søren L. Pedersen, Henrik K. Munch, Vadym Tkach, John J. Sakon, Thomas Bjørnholm, Keith Weninger, Poul Martin Bendix, Knud J. Jensen, Nikos S. Hatzakis, Mark J. Uline, Dimitrios Stamou

2020ACS Central Science38 citationsDOIOpen Access PDF

Abstract

Biological membranes have distinct geometries that confer specific functions. However, the molecular mechanisms underlying the phenomenological geometry/function correlations remain elusive. We studied the effect of membrane geometry on the localization of membrane-bound proteins. Quantitative comparative experiments between the two most abundant cellular membrane geometries, spherical and cylindrical, revealed that geometry regulates the spatial segregation of proteins. The measured geometry-driven segregation reached 50-fold for membranes of the same mean curvature, demonstrating a crucial and hitherto unaccounted contribution by Gaussian curvature. Molecular-field theory calculations elucidated the underlying physical and molecular mechanisms. Our results reveal that distinct membrane geometries have specific physicochemical properties and thus establish a ubiquitous mechanistic foundation for unravelling the conserved correlations between biological function and membrane polymorphism.

Topics & Concepts

MembraneGaussian curvatureCurvatureGeometryMembrane curvatureBiophysicsMean curvatureFunction (biology)Membrane proteinSortingChemistryPhysicsBiologyCell biologyBiochemistryMathematicsLipid bilayerAlgorithmLipid Membrane Structure and BehaviorBacterial Genetics and BiotechnologyGlycosylation and Glycoproteins Research
How Membrane Geometry Regulates Protein Sorting Independently of Mean Curvature | Litcius