Abstract
Varicella zoster virus (VZV), a human alphaherpesvirus, causes varicella during primary infection. VZV reactivation from neuronal latency may cause herpes zoster, post herpetic neuralgia (PHN) and other neurologic syndromes. To investigate VZV neuropathogenesis, we developed a model using human dorsal root ganglia (DRG) xenografts in immunodeficient (SCID) mice. The SCID DRG model provides an opportunity to examine characteristics of VZV infection that occur in the context of the specialized architecture of DRG, in which nerve cell bodies are ensheathed by satellite glial cells (SGC) which support neuronal homeostasis. We hypothesized that VZV exhibits neuron-subtype specific tropism and that VZV tropism for SGC contributes to VZV-related ganglionopathy. Based on quantitative analyses of viral and cell protein expression in DRG tissue sections, we demonstrated that, whereas DRG neurons had an immature neuronal phenotype prior to implantation, subtype heterogeneity was observed within 20 weeks and SGC retained the capacity to maintain neuronal homeostasis longterm. Profiling VZV protein expression in DRG neurons showed that VZV enters peripherin+ nociceptive and RT97+ mechanoreceptive neurons by both axonal transport and contiguous spread from SGC, but replication in RT97+ neurons is blocked. Restriction occurs even when the SGC surrounding the neuronal cell body were infected and after entry and ORF61 expression, but before IE62 or IE63 protein expression. Notably, although contiguous VZV spread with loss of SGC support would be predicted to affect survival of both nociceptive and mechanoreceptive neurons, RT97+ neurons showed selective loss relative to peripherin+ neurons at later times in DRG infection. Profiling cell factors that were upregulated in VZV-infected DRG indicated that VZV infection induced marked pro-inflammatory responses, as well as proteins of the interferon pathway and neuroprotective responses. These neuropathologic changes observed in sensory ganglia infected with VZV may help to explain the neurologic sequelae often associated with zoster and PHN.
Highlights
Varicella-zoster virus (VZV), a human alphaherpesvirus, causes varicella, characterized by a T cell-mediated viremia and a generalized vesicular rash [1]
Varicella zoster virus (VZV) causes varicella; herpes zoster results from VZV reactivation and is associated with post herpetic neuralgia (PHN)
We hypothesized that VZV exhibits neuron-subtype specific tropism and that VZV tropism for satellite glial cells (SGC) results in loss of SGC functions that support neurons and contributes to VZV-related ganglionopathy
Summary
Varicella-zoster virus (VZV), a human alphaherpesvirus, causes varicella, characterized by a T cell-mediated viremia and a generalized vesicular rash [1]. VZV reactivation from neuronal latency may cause herpes zoster, with pain and rash corresponding to the affected dermatome, and may be complicated by post herpetic neuraliga [2]. VZV reactivation can produce chronic radicular pain without skin lesions (zoster sine herpete), cranial nerve palsies and other neurologic syndromes [2]. While VZV readily infects and replicates in neurons derived from embryonic stem cells and neuronal cell lines, these systems do not model the in vivo heterogeneity of DRG neuronal subpopulations and their associated satellite glial cells (SGC). Large light neurons comprise 30–40% of adult differentiated DRG neurons and have myelinated A betafibers with specialized mechanoreceptive termini in skin [3]. Small dark neurons with unmyelinated C-fibers or thinly myelinated A delta-fibers have “pain sensing” nociceptive free nerve endings in skin and comprise 40–60% of DRG neurons [4,5]. SGC participate in neuronal signaling, as well as pathological degeneration and regeneration of axons [8]
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