Abstract
Preferential binding of proteins on curved membranes (membrane curvature sensing) is increasingly emerging as a general mechanism whereby cells may effect protein localization and trafficking. Here we use a novel single liposome fluorescence microscopy assay to examine a common sensing motif, the amphipathic helix (AH), and provide quantitative measures describing and distinguishing membrane binding and sensing behavior. By studying two AH-containing proteins, α-synuclein and annexin B12, as well as a range of AH peptide mutants, we reveal that both the hydrophobic and hydrophilic faces of the helix greatly influence binding and sensing. Although increased hydrophobic and electrostatic interactions with the membrane both lead to greater densities of bound protein, the former yields membrane curvature-sensitive binding, whereas the latter is not curvature-dependent. However, the relative contributions of both components determine the sensing of AHs. In contrast, charge density in the lipid membrane seems important primarily in attracting AHs to the membrane but does not significantly influence sensing. These observations were made possible by the ability of our assay to distinguish within our samples liposomes with and without bound protein as well as the density of bound protein. Our findings suggest that the description of membrane curvature-sensing requires consideration of several factors such as short and long range electrostatic interactions, hydrogen bonding, and the volume and structure of inserted hydrophobic residues.
Highlights
Amphipathic helices preferentially bind highly curved lipid membranes, providing a method of protein sorting
It is clear from structural studies that the amphipathic helical repeat is important for membrane curvature sensing, these results suggest that the cooperative effect of several repeats is necessary for efficient binding, in agreement with the notion that ␣-synuclein takes up a very long, almost 100-amino acid-containing amphipathic helix (14, 36, 48 –50)
The single liposome curvatures (SLiC) assay used in this study is a uniquely suited method for accurately describing various aspects of curvature sensitive binding
Summary
Amphipathic helices preferentially bind highly curved lipid membranes, providing a method of protein sorting. Bfrac (i.e. the ability of the protein to bind the membrane at all) is affected by both aspects and generally correlates negatively with strong sensing This is corroborated by our examination of annexin B12, amplifying electrostatic interactions between the AHs and the membrane increased Bfrac as well as the B on flat membranes, revealing a powerful modulating element in membrane binding of AH-containing proteins. It is the relative contributions from two sources of binding energy, hydrophobic insertion and electrostatic interactions, that determine the ability of an amphipathic helix to sense membrane curvature
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