Retrograde axonal transport of rabies virus is unaffected by interferon treatment but blocked by emetine locally in axons.

Margaret A Macgibeny,Orkide O Koyuncu,Christoph Wirblich,Matthias J Schnell,Lynn W Enquist,Anthony Lawrence Cunningham

doi:10.1371/journal.ppat.1007188

Margaret A Macgibeny, Orkide O Koyuncu + Show 4 more

Open Access

https://doi.org/10.1371/journal.ppat.1007188

Copy DOI

Journal: PLoS Pathogens	Publication Date: Jul 20, 2018
Citations: 39	License type: CC BY 4.0

Affiliation: Princeton University, Thomas Jefferson University

Abstract

Neuroinvasive viruses, such as alpha herpesviruses (αHV) and rabies virus (RABV), initially infect peripheral tissues, followed by invasion of the innervating axon termini. Virus particles must undergo long distance retrograde axonal transport to reach the neuron cell bodies in the peripheral or central nervous system (PNS/CNS). How virus particles hijack the axonal transport machinery and how PNS axons respond to and regulate infection are questions of significant interest. To track individual virus particles, we constructed a recombinant RABV expressing a P-mCherry fusion protein, derived from the virulent CVS-N2c strain. We studied retrograde RABV transport in the presence or absence of interferons (IFN) or protein synthesis inhibitors, both of which were reported previously to restrict axonal transport of αHV particles. Using neurons from rodent superior cervical ganglia grown in tri-chambers, we showed that axonal exposure to type I or type II IFN did not alter retrograde axonal transport of RABV. However, exposure of axons to emetine, a translation elongation inhibitor, blocked axonal RABV transport by a mechanism that was not dependent on protein synthesis inhibition. The minority of RABV particles that still moved retrograde in axons in the presence of emetine, moved with slower velocities and traveled shorter distances. Emetine’s effect was specific to RABV, as transport of cellular vesicles was unchanged. These findings extend our understanding of how neuroinvasion is regulated in axons and point toward a role for emetine as an inhibitory modulator of RABV axonal transport.

Highlights

Unlike most nervous system pathogens, which are either accidental or opportunistic, some neuroinvasive viruses have evolved strategies to enter and exit the nervous system
Axonal transport of rabies virus is unaffected by interferon treatment but blocked by emetine knowledge, only a single study has investigated RABV infection in superior cervical ganglia (SCG) in vitro [28]
Axonal transport of rabies virus is unaffected by interferon treatment but blocked by emetine enters SCG axons and moves retrograde to infect approximately half of the connected cell bodies within 24 h

Summary

Introduction

Unlike most nervous system pathogens, which are either accidental or opportunistic, some neuroinvasive viruses have evolved strategies to enter and exit the nervous system. A distinct but effective strategy is used by alpha herpesviruses (αHV) of the Herpesviridae family (e.g. human herpes simplex virus type 1 and 2 (HSV-1 and 2) and swine pseudorabies virus (PRV)) in their natural and non-natural hosts. These viruses replicate in peripheral epithelia prior to invading the innervating PNS neurons where they establish life-long latent infections. Latent αHV infections undergo stress-induced reactivation, which can lead to peripheral herpetic lesions (e.g. cold sores) that facilitate inter-host spread Despite their distinct clinical pathologies, both RABV and αHV must invade axons, something most viruses do not do. How these distinct neuroinvasive viruses infect the nervous system efficiently remains a question of significant interest

Methods

Results

Discussion

Conclusion