Nanoscale imaging of native symbiotic animal tissue using a multimodal large volume imaging pipeline for cryo-electron tomography

The field of cryo-EM offers the possibility to gain high-resolution structural information of biomolecules in their native state. Advances in sample thinning of cryo-EM samples allows the study of proteins inside intact cells using tomography, opening the door for ‘visual proteomics’. However, thicker samples such as tissues or entire organisms are still largely unsuitable for cryo-electron tomography (cryo-ET). Therefore, significant efforts are directed toward developing and improving preparation methods to enable cryo-ET of such complex samples. We focused on the binary association between the Hawaiian bobtail squid Euprymna scolopes and the luminous bacteria Vibrio fischeri . The Squid–Vibrio system has long been studied to understand host-symbiont interactions. Our goal is to study the bacterial-host interface using cryo-ET, at a resolution previously unattainable by conventional EM methods. Here, we present a multi-modal preparation and correlative imaging workflow—including cryo- fluorescence microscopy, microCT, freeze-substitution electron tomography (FS-ET), and serial blockface SEM—to localize and prepare specific regions of the dissected symbiotic light organs for cryo-ET. This approach enabled us to directly visualize symbiotic V. fischeri within the internal host crypts at macromolecular resolution, revealing spatial organization, physical contact, and putative exchange interfaces between host and microbe. Our findings provide structural insights into a foundational model of host–microbe symbiosis and demonstrate the feasibility of cryo-ET for investigating intact tissues at the nanoscale.