The targeted spatial organization (sorting) of Gprotein-coupled receptors (GPCRs) is essential for their biological function and often takes place in highly curved membrane compartments such as filopodia, endocytic pits, trafficking vesicles or endosome tubules. However, the influence of geometrical membrane curvature on GPCR sorting remains unknown. Here we used fluorescence imaging to establish a quantitative correlation between membrane curvature and sorting of three prototypic class A GPCRs (the neuropeptide Y receptor Y2, the β adrenergic receptor and the β adrenergic receptor) in living cells. Fitting of a thermodynamic model to the data enabled us to quantify how sorting is mediated by an energetic drive to match receptor shape and membrane curvature. Curvature-dependent sorting was regulated by ligands in a specific manner. We anticipate that this curvature-dependent biomechanical coupling mechanism contributes to the sorting, trafficking and function of transmembrane proteins in general.
The droplet on hydrogel bilayer (DHB) is a novel platform for investigating the function of ion channels. Advantages of this setup include tight control of all bilayer components, which is compelling for the investigation of mechanosensitive (MS) ion channels, since they are highly sensitive to their lipid environment. However, the activation of MS ion channels in planar supported lipid bilayers, such as the DHB, has not yet been established. Here we present the activation of the large conductance MS channel of E. coli, (MscL), in DHBs. By selectively stretching the droplet monolayer with nanolitre injections of buffer, we induced quantifiable DHB tension, which could be related to channel activity. The MscL activity response revealed that the droplet monolayer tension equilibrated over time, likely by insertion of lipid from solution. Our study thus establishes a method to controllably activate MS channels in DHBs and thereby advances studies of MS channels in this novel platform.
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.
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