Subcellular trafficking in rhabdovirus infection and immune evasion: a novel target for therapeutics.

Vesicular stomatitis virus (VSV) and Rabies Virus (RABV) are the prototypic members of the rhabdovirus family. These viruses have a particularly broad host range, and despite the availability of vaccines, RABV still causes more than 50,000 human deaths a year. Trafficking of the virion or viral particles is important at several stages of the replicative life cycle, including cellular entry, localization into the cytoplasmic inclusion bodies which primarily house the transcription and replication of the viral genome, and migration to the plasma membrane from whence the virus is released by budding. Intriguingly, specific viral proteins, VSV M and RABV P have also been shown to undergo intracellular trafficking independent of the other viral apparatus. These proteins are multifunctional, and play roles in antagonism of host processes, namely the IFN system, and as such enable viral evasion of the innate cellular antiviral response. A body of recent research has been aimed at characterizing the mechanisms by which these proteins are able to shuttle between and localize to various subcellular sites, including the nucleus, which is not required during the cytoplasmic replicative life cycle of the virus. This work has indicated that trafficking of these proteins plays a significant role in determining the ability of the viruses to replicate and cause infection, and as such, represents a viable target for development of a new generation of vaccines and prophylactic therapeutics which are required to battle these pathogens of human and agricultural significance

Conservation of a unique mechanism of immune evasion across the Lyssavirus genus.

International audienceThe evasion of host innate immunity by Rabies virus, the prototype of the genus Lyssavirus, depends on a unique mechanism of selective targeting of interferon-activated STAT proteins by the viral phosphoprotein (P-protein). However, the immune evasion strategies of other lyssaviruses, including several lethal human pathogens, are unresolved. Here, we show that this mechanism is conserved between the most distantly related members of the genus, providing important insights into the pathogenesis and potential therapeutic targeting of lyssaviruses

Structure and Function of Negri Bodies

Replication and assembly of many viruses occur in viral factories which are specialized intracellular compartments formed during viral infection. For rabies virus, those viral factories are called Negri bodies (NBs). NBs are cytoplasmic inclusion bodies in which viral RNAs (mRNAs as well as genomic and antigenomic RNAs) are synthesized. NBs are spherical, they can fuse together, and can reversibly deform when encountering a physical barrier. All these characteristics are similar to those of eukaryotic membrane-less liquid organelles which contribute to the compartmentalization of the cell interior. Indeed, the liquid nature of NBs has been confirmed by FRAP experiments. The co-expression of rabies virus nucleoprotein N and phosphoprotein P is sufficient to induce the formation of cytoplasmic inclusions recapitulating NBs properties. Remarkably, P and N have features similar to those of cellular proteins involved in liquid organelles formation: N is an RNA-binding protein and P contains intrinsically disordered domains. An overview of the literature indicates that formation of liquid viral factories by phase separation is probably common among Mononegavirales. This allows specific recruitment and concentration of viral proteins. Finally, as virus-associated molecular patterns recognized by cellular sensors of RNA virus replication are probably essentially present in the viral factory, there should be a subtle interplay (which remains to be characterized) between those liquid structures and the cellular proteins which trigger the innate immune response