Cryptococcus extracellular vesicles properties and their use as vaccine platforms.

Juliana Rizzo,Flavia C G Reis,Thibault Chaze,Anastasia D Gazi,Mariette Matondo,Sarah Sze Wah Wong,Matthijn Vos,Gérard Péhau‐Arnaudet,Robin C May,Marcio L Rodrigues,Lysangela R Alves,Leonardo Nimrichter,Pierre‐Henri Commere,Frédérique Moyrand,Guilhem Janbon,Vishukumar Aimanianda,Sophie Novault

doi:10.1002/jev2.12129

Abstract

Whereas extracellular vesicle (EV) research has become commonplace in different biomedical fields, this field of research is still in its infancy in mycology. Here we provide a robust set of data regarding the structural and compositional aspects of EVs isolated from the fungal pathogenic species Cryptococcus neoformans, C. deneoformans and C. deuterogattii. Using cutting‐edge methodological approaches including cryogenic electron microscopy and cryogenic electron tomography, proteomics, and flow cytometry, we revisited cryptococcal EV features and suggest a new EV structural model, in which the vesicular lipid bilayer is covered by mannoprotein‐based fibrillar decoration, bearing the capsule polysaccharide as its outer layer. About 10% of the EV population is devoid of fibrillar decoration, adding another aspect to EV diversity. By analysing EV protein cargo from the three species, we characterized the typical Cryptococcus EV proteome. It contains several membrane‐bound protein families, including some Tsh proteins bearing a SUR7/PalI motif. The presence of known protective antigens on the surface of Cryptococcus EVs, resembling the morphology of encapsulated virus structures, suggested their potential as a vaccine. Indeed, mice immunized with EVs obtained from an acapsular C. neoformans mutant strain rendered a strong antibody response in mice and significantly prolonged their survival upon C. neoformans infection.

Highlights

All living organisms release lipid bilayer-delimited particles defined as extracellular vesicles (EVs) (Deatherage & Cookson, 2012; Witwer & Théry, 2019)
Cryo-EM imaging on rapidly-frozen samples at low temperature could potentially reduce sample damaging and artefacts caused by the addition of heavy metals, dehydration, or fixation steps (Chiang & Chen, 2019; Orlov et al, 2017)
We used cryo-electron microscopy (cryo-EM) and cryo-electron tomography (cryo-ET) to analyse EVs purified from C. neoformans, in their near-native state

Summary

Introduction

All living organisms release lipid bilayer-delimited particles defined as extracellular vesicles (EVs) (Deatherage & Cookson, 2012; Witwer & Théry, 2019). Two major classes of EVs have been defined, microvesicles and exosomes, according to their size and cellular origin (Meldolesi, 2018; van Niel et al, 2018). In these organisms, a large body of literature describes how EVs participate in intercellular signalling within and in organism-to-organism communication, including carcinogenesis and host-pathogen interactions (Shopova et al, 2020; Xu et al, 2018). The molecular mechanisms implicated in these exchanges of information, as well as the genetics regulating fungal EV biogenesis and release, remain elusive

Methods

Results

Conclusion