In vitro reconstitution reveals membrane clustering and RNA recruitment by the enteroviral AAA+ ATPase 2C.

Enteroviruses are a vast genus of positive-sense RNA viruses that cause diseases ranging from common cold to poliomyelitis and viral myocarditis. They encode a membrane-bound AAA+ ATPase, 2C, that has been suggested to serve several roles in virus replication, e.g. as an RNA helicase and capsid assembly factor. Here, we report the reconstitution of full-length, poliovirus 2C's association with membranes. We show that the N-terminal membrane-binding domain of 2C contains a conserved glycine, which is suggested by structure predictions to divides the domain into two amphipathic helix regions, which we name AH1 and AH2. AH2 is the main mediator of 2C oligomerization, and is necessary and sufficient for its membrane binding. AH1 is the main mediator of a novel function of 2C: clustering of membranes. Cryo-electron tomography reveal that several 2C copies mediate this function by localizing to vesicle-vesicle interfaces. 2C-mediated clustering is partially outcompeted by RNA, suggesting a way by which 2C can switch from an early role in coalescing replication organelles and lipid droplets, to a later role where 2C assists RNA replication and particle assembly. 2C is sufficient to recruit RNA to membranes, with a preference for double-stranded RNA (the replicating form of the viral genome). Finally, the in vitro reconstitution revealed that full-length, membrane-bound 2C has ATPase activity and ATP-independent, single-strand ribonuclease activity, but no detectable helicase activity. Together, this study suggests novel roles for 2C in membrane clustering, RNA membrane recruitment and cleavage, and calls into question a role of 2C as an RNA helicase. The reconstitution of functional, 2C-decorated vesicles provides a platform for further biochemical studies into this protein and its roles in enterovirus replication. Author summary: Enteroviruses are frequent causes of diseases that range from mild common colds to severe conditions such as poliomyelitis, acute flaccid myelitis and viral myocarditis. Enterovirus particles are tiny, even by virus standards, and they can only package a small amount of viral genetic material. With such a small genetic 'toolbox', how can these viruses so vigorously hijack the interior of a cell and turn it into a viral factory? One reason is that the viral genes often encode multifunctional proteins. Here, we studied one such multifunctional viral protein, called 2C. This protein is found in all enteroviruses and in related viruses, and the virus cannot replicate without it. We developed a new way of studying 2C that allowed us to work with the complete 2C protein 'in its element', namely bound to a membrane. We found that 2C not only binds one membrane, but can gather several membranes together–a function that may be important to building the viral factory. We also found that 2C can bind RNA (the chemical form of the virus' genetic material) to membranes and can cleave RNA. Our findings reinforce the view of 2C as an organizer of the viral factory. [ABSTRACT FROM AUTHOR]