On-lamella super-resolution cryo-CLEM for cryo-ET enabled by vacuum-free ultra-stable cryogenic fluorescence microscopy

Cryogenic correlative light and electron microscopy (cryo-CLEM) combines specific fluorescence labelling of proteins inside cells with structural information at the angstrom-level. The introduction of super-resolution fluorescence methods in the field of cryogenic fluorescence microscopy is a necessary step to bridge the large resolution gap between the different imaging modalities. However, there are many challenges hindering the full potential of cryogenic super-resolution correlative light and electron microscopy and seamless integration with structural cell biology. One of the main limiting factors is a lack of dedicated cryogenic fluorescence microscopy systems with sufficient mechanical stability to enable the collection of high-quality super-resolution data and full compatibility with vitrified specimens for cryo-electron tomography. Here, we address this by developing a vacuum-free ultra-stable cryogenic optical microscope (VULCROM). VULCROM is a dedicated super-resolution cryo-CLEM (cryo-SR-CLEM) setup that combines the stability of a vacuum-insulated cryostat with the flexibility and modularity of an open microscopy system. We demonstrate that VULCROM enables detailed investigations of single-molecule cryo-photo-physics across timescales spanning milliseconds to hours. We furthermore demonstrate its suitability for routine cryo-SR-CLEM with a resolution in the 10 nm range in distinct vitrified biological specimen types. We resolve the nanoscale architecture of YFP-labelled PML bodies within the nucleus of mammalian cells and the distribution of ATG9-eGFP in its cellular structural context in a cryo-lift-out lamella of N. benthamiana plant tissue. Owing to its vacuum-free design, VULCROM can be readily adapted for diverse correlative workflows and other cryo-light microscopy applications.