Visualization of an alphaherpesvirus membrane protein that is essential for anterograde axonal spread of infection in neurons.

UNLABELLED: Pseudorabies virus (PRV), an alphaherpesvirus with a broad host range, replicates and spreads in chains of synaptically connected neurons. The PRV protein Us9 is a small membrane protein that is highly conserved among alphaherpesviruses and is essential for anterograde axonal spread in neurons. Specifically, the Us9 protein is required for the sorting of newly assembled PRV particles into axons. However, the molecular details underlying the function of Us9 are poorly understood. Here we constructed PRV strains that express functional green fluorescent protein (GFP)-Us9 fusion proteins in order to visualize axonal transport of viral particles in infected rat superior cervical ganglion neurons. We show that GFP-Us9-labeled structures are transported exclusively in the anterograde direction within axons. Additionally, the vast majority of anterograde-directed capsids (labeled with VP26-monomeric red fluorescent protein) and a viral membrane protein (labeled with glycoprotein M fused to mCherry) are cotransported with GFP-Us9 in the anterograde direction. In contrast, during infection with PRV strains that express nonfunctional mutant GFP-Us9 proteins, cotransport of mutant GFP-Us9 with capsids in axons is abolished. These findings show that axonal sorting of progeny viral particles is dependent upon the association of viral structures with membranes that contain functional Us9 proteins. This association is required for anterograde spread of infection in neurons. IMPORTANCE: Alphaherpesviruses, such as pseudorabies virus (PRV), are parasites of the mammalian nervous system. These viruses spread over long distances in chains of synaptically connected neurons. PRV encodes several proteins that mediate directed virion transport and spread of infection. Us9 is a highly conserved viral membrane protein that is essential for anterograde neuronal spread of infection. In the absence of Us9, newly replicated viral particles are assembled in the cell body but are not sorted into or transported within axons. Here, we constructed and characterized novel PRV strains that express functional green fluorescent protein (GFP)-Us9 fusion proteins in order to visualize its localization in living neurons during infection. This enabled us to better understand the function of Us9 in facilitating the spread of infection. We show that all viral particles moving in the anterograde direction are labeled with GFP-Us9, suggesting that the presence of Us9 determines the capacity for directed transport within axons.

Comparison of the pseudorabies virus Us9 protein with homologs from other veterinary and human alphaherpesviruses.

Pseudorabies virus (PRV) Us9 is a small, tail-anchored (TA) membrane protein that is essential for axonal sorting of viral structural proteins and is highly conserved among other members of the alphaherpesvirus subfamily. We cloned the Us9 homologs from two human pathogens, varicella-zoster virus (VZV) and herpes simplex virus type 1 (HSV-1), as well as two veterinary pathogens, equine herpesvirus type 1 (EHV-1) and bovine herpesvirus type 1 (BHV-1), and fused them to enhanced green fluorescent protein to examine their subcellular localization and membrane topology. Akin to PRV Us9, all of the Us9 homologs localized to the trans-Golgi network and had a type II membrane topology (typical of TA proteins). Furthermore, we examined whether any of the Us9 homologs could compensate for the loss of PRV Us9 in anterograde, neuron-to-cell spread of infection in a compartmented chamber system. EHV-1 and BHV-1 Us9 were able to fully compensate for the loss of PRV Us9, whereas VZV and HSV-1 Us9 proteins were unable to functionally replace PRV Us9 when they were expressed in a PRV background.

Repair of the UL21 locus in pseudorabies virus Bartha enhances the kinetics of retrograde, transneuronal infection in vitro and in vivo.

The attenuated pseudorabies virus (PRV) strain Bartha contains several characterized mutations that affect its virulence and ability to spread through neural circuits. This strain contains a small genomic deletion that abrogates anterograde spread and is widely used as a retrograde-restricted neural circuit tracer. Previous studies showed that the retrograde-directed spread of PRV Bartha is slower than that of wild-type PRV. We used compartmented neuronal cultures to characterize the retrograde defect and identify the genetic basis of the phenotype. PRV Bartha is not impaired in retrograde axonal transport, but transneuronal spread among neurons is diminished. Repair of the U(L)21 locus with wild-type sequence restored efficient transneuronal spread both in vitro and in vivo. It is likely that mutations in the Bartha U(L)21 gene confer defects that affect infectious particle production, causing a delay in spread to presynaptic neurons and amplification of infection. These events manifest as slower kinetics of retrograde viral spread in a neural circuit.

Fusion of enhanced green fluorescent protein to the pseudorabies virus axonal sorting protein Us9 blocks anterograde spread of infection in mammalian neurons.

Pseudorabies virus encodes a membrane protein (Us9) that is essential for the axonal sorting of virus particles within neurons and anterograde spread in the mammalian nervous system. Enhanced green fluorescent protein (GFP)-tagged Us9 mimicked the trafficking properties of the wild-type protein in nonneuronal cells. We constructed a pseudorabies virus strain that expressed Us9-GFP and tested its spread capabilities in the rat visual system and in primary neuronal cultures. We report that Us9-EGFP does not promote anterograde spread of infection and may disrupt packing of viral membrane proteins in lipid rafts, an essential step for Us9-mediated axonal sorting.

Pseudorabies virus Us9 directs axonal sorting of viral capsids.

Pseudorabies virus (PRV) mutants lacking the Us9 gene cannot spread from presynaptic to postsynaptic neurons in the rat visual system, although retrograde spread remains unaffected. We sought to recapitulate these findings in vitro using the isolator chamber system developed in our lab for analysis of the transneuronal spread of infection. The wild-type PRV Becker strain spreads efficiently to postsynaptic neurons in vitro, whereas the Us9-null strain does not. As determined by indirect immunofluorescence, the axons of Us9-null infected neurons do not contain the glycoproteins gB and gE, suggesting that their axonal sorting is dependent on Us9. Importantly, we failed to detect viral capsids in the axons of Us9-null infected neurons. We confirmed this observation by using three different techniques: by direct fluorescence of green fluorescent protein-tagged capsids; by transmission electron microscopy; and by live-cell imaging in cultured, sympathetic neurons. This finding has broad impact on two competing models for how virus particles are trafficked inside axons during anterograde transport and redefines a role for Us9 in viral sorting and transport.