Dengue and Zika virus capsid proteins bind to membranes and self-assemble into liquid droplets with nucleic acids

Liquid-liquid phase separation is prone to occur when positively charged proteins interact with nucleic acids. Here, we studied biophysical properties of Dengue (DENV) and Zika (ZIKV) virus capsid proteins to understand the process of RNA genome encapsidation. In this route, the capsid proteins efficiently recruit the viral RNA at the ER membrane to yield nascent viral particles. However, little is known either about the molecular mechanisms by which multiple copies of capsid proteins assemble into nucleocapsids or how the nucleocapsid is recruited and wrapped by the ER membrane during particle morphogenesis. Here, we measured relevant interactions concerning the viral process using purified DENV and ZIKV capsids proteins, membranes mimicking the ER lipid composition and nucleic acids at in vitro conditions. We found that both ZIKV and DENV capsid proteins bound to liposomes at liquid-disordered phase regions and docked exogenous membranes and RNA molecules. When the proteins bound nucleic acids, droplet liquid-liquid phase separation was observed. We characterized these liquid condensates by measuring nucleic acid partition constant and the extent of water dipolar relaxation observing a cooperative process for the formation of the new phase that involves a distinct water organization. Our data supports a new model in which capsid-RNA complexes directly bind the ER membrane, seeding the process of RNA recruitment for viral particle assembly. These results contribute to understand the viral nucleocapsid formation as a stable liquid-liquid phase transition, which could be relevant for Dengue and Zika gemmation, opening new avenues for antiviral intervention.