Resolving protein organization in cells with nanometer resolution

Due to its high sensitivity and ability to specifically label molecules in cells fluorescence microscopy is one of the most widely used tools in biological research. The invention of super-resolution microscopy and its latest refinements allowed imaging with so far unprecedented spatial resolution in the one nanometer range under certain conditions. However, the improvement of localization precision advanced much faster than the labeling methods impeding the translation of such high resolutions to cells. Hence, imaging of the molecular nano-architecture of multiprotein complexes in cells remains challenging. Here we introduce an expansion microscopy (ExM) method that enables direct stochastic optical reconstruction microscopy ( d STORM) of 7-8-fold expanded immunolabeled samples. We experimentally verify the performance of the method by resolving the 8-nm periodicity of α,ß-heterodimers in microtubules and the polyhedral lattice in clathrin-coated pits with nanometer resolution in cells. Moreover, two-color Ex- d STORM reveals the molecular organization of RIM scaffolding protein and Munc13-1, an essential synaptic vesicle priming protein, in ring-like structures with diameters of 40-45 nm at the presynapse in hippocampal neurons. Our results demonstrate that Ex- d STORM resolves the molecular organization of endogenous multiprotein complexes with nanometer spatial resolution in cells using standard labeling methods. Thus, it provides a versatile method for the investigation of molecular protein distributions in their physiologically relevant context.