T-SNARE Protein Conformations Patterned by the Lipid Microenvironment

Colin Rickman,Claire N Medine,Alison R Dun,David J Moulton,Ondřej Mandula,Nagaraj D Halemani,Silvio O Rizzoli,Luke H Chamberlain,Rory R Duncan

doi:10.1074/jbc.m109.091058

Colin Rickman, Claire N Medine + Show 7 more

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https://doi.org/10.1074/jbc.m109.091058

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The spatial distribution of the target (t-)SNARE proteins (syntaxin and SNAP-25) on the plasma membrane has been extensively characterized. However, the protein conformations and interactions of the two t-SNAREs in situ remain poorly defined. By using super-resolution optical techniques and fluorescence lifetime imaging microscopy, we observed that within the t-SNARE clusters syntaxin and SNAP-25 molecules interact, forming two distinct conformations of the t-SNARE binary intermediate. These are spatially segregated on the plasma membrane with each cluster exhibiting predominantly one of the two conformations, representing the two- and three-helical forms previously observed in vitro. We sought to explain why these two t-SNARE intermediate conformations exist in spatially distinct clusters on the plasma membrane. By disrupting plasma membrane lipid order, we found that all of the t-SNARE clusters now adopted a single conformational state corresponding to the three helical t-SNARE intermediates. Together, our results define spatially distinct t-SNARE intermediate states on the plasma membrane and how the conformation adopted can be patterned by the underlying lipid environment.

Highlights

The soluble NSF attachment protein receptor (SNARE)4 proteins form a highly conserved family with a central role in the fusion of lipid membranes in both intracellular trafficking and exocytosis
Syntaxin self-association has been proposed as a major factor in membrane protein cluster organization [10, 14], implying that SNARE proteins can selforganize into clusters by virtue of their inherent properties
As there was no topological change in the t-SNARE distribution in the disordered plasma membrane, we examined the effect of lipid order on the two heterodimer conformational states

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Introduction

The soluble NSF attachment protein receptor (SNARE)4 proteins form a highly conserved family with a central role in the fusion of lipid membranes in both intracellular trafficking and exocytosis. The spatial distribution of the target (t-)SNARE proteins (syntaxin and SNAP-25) on the plasma membrane has been extensively characterized. By using super-resolution optical techniques and fluorescence lifetime imaging microscopy, we observed that within the t-SNARE clusters syntaxin and SNAP-25 molecules interact, forming two distinct conformations of the t-SNARE binary intermediate.

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