Parasitology meets cryo-electron tomography - exciting prospects await.

Cryo-electron tomography (cryo-ET) is a cryo-electron microscopy (EM) approach that allows 3D imaging of cellular structures in near-native, frozen-hydrated conditions with molecular resolution. Continued development of technologies, including direct electron detectors, phase plates, and energy filters, has improved the information yield from cellular samples, which is further extended by newly developed workflows for data collection and analyses. Moreover, advanced sample-thinning techniques, such as cryogenic focused ion-beam (cryo-FIB) milling, provide access to parasitic events and structures that were previously inaccessible for cryo-ET. Cryo-ET has therefore become more versatile and capable of transforming our understanding of parasite biology, particularly that of apicomplexans. This review discusses cryo-ET's implementation, its recent contributions, and how it can reveal pathogenesis mechanisms in the near future using apicomplexans as a case study.

In situ ultrastructures of two evolutionarily distant apicomplexan rhoptry secretion systems.

Parasites of the phylum Apicomplexa cause important diseases including malaria, cryptosporidiosis and toxoplasmosis. These intracellular pathogens inject the contents of an essential organelle, the rhoptry, into host cells to facilitate invasion and infection. However, the structure and mechanism of this eukaryotic secretion system remain elusive. Here, using cryo-electron tomography and subtomogram averaging, we report the conserved architecture of the rhoptry secretion system in the invasive stages of two evolutionarily distant apicomplexans, Cryptosporidium parvum and Toxoplasma gondii. In both species, we identify helical filaments, which appear to shape and compartmentalize the rhoptries, and an apical vesicle (AV), which facilitates docking of the rhoptry tip at the parasite's apical region with the help of an elaborate ultrastructure named the rhoptry secretory apparatus (RSA); the RSA anchors the AV at the parasite plasma membrane. Depletion of T. gondii Nd9, a protein required for rhoptry secretion, disrupts the RSA ultrastructure and AV-anchoring. Moreover, T. gondii contains a line of AV-like vesicles, which interact with a pair of microtubules and accumulate towards the AV, leading to a working model for AV-reloading and discharging of multiple rhoptries. Together, our analyses provide an ultrastructural framework to understand how these important parasites deliver effectors into host cells.