Neuronal expression of herpes simplex virus type-1 VP16 protein induces pseudorabies virus escape from silencing and reactivation by activating Jun

Abstract

AbstractAlpha herpesvirus (α-HV) particles enter their hosts from mucosal surfaces and efficiently maintain fast transport in peripheral nervous system (PNS) axons to establish infections in the peripheral ganglia. The path from axons to distant neuronal nuclei is challenging to dissect due to the difficulty of monitoring early events in a dispersed neuron culture model. We have established well-controlled, reproducible, and reactivateable latent infections in compartmented rodent neurons by infecting physically isolated axons with a small number of viral particles. This system not only recapitulates the physiological infection route, but also facilitates independent treatment of isolated cell bodies or axons. Consequently, this system enables study not only of the stimuli that promote reactivation, but also the factors that regulate the initial switch from productive to latent infection. Adeno associated virus (AAV) mediated expression of herpes simplex type 1 (HSV-1) VP16 alone in neuronal cell bodies enabled the escape from silencing of incoming pseudorabies virus (PRV) genomes. Furthermore, expression of HSV VP16 alone reactivated a latent PRV infection in this system. Surprisingly, expression of PRV VP16 protein supported neither PRV escape from silencing nor reactivation. We compared transcription transactivation activity of both VP16 proteins in primary neurons by RNA sequencing and found that these homolog viral proteins produce different gene expression profiles. AAV transduced HSV VP16 specifically induced expression of proto-oncogenes including Jun and Pim2. In addition, HSV VP16 induces phosphorylation of Jun in neurons, and when this activity is inhibited, escape of PRV silencing is dramatically reduced.