Volumetric single-molecule tracking inside subcellular structures

The molecular interactions that underpin all cellular functions depend on molecular motion within three-dimensional environments. Large depth-of-field single-molecule localization microscopy (3D-SMLM) methods facilitate these measurements, but their increased optical complexity and bespoke post-processing pipelines can sacrifice important cellular context. Here we combine single-molecule light-field microscopy (SMLFM) with widefield Fourier light-field microscopy for correlative volumetric organelle imaging. The instantaneous acquisition of subcellular volumes improves the sensitivity of molecular organization and diffusion measurements through the rejection of non-specific localizations. We first demonstrate our approach by measuring the molecular organization of a nuclear-localized HaloTag protein relative to cell nuclei. Next, we characterize the molecular diffusion of the soluble protein, calreticulin, in the context of α ₁ -antitrypsin deficiency, which revealed an increase in heterogeneous motion within endoplasmic reticulum inclusions.