Varicella zoster virus (VZV) causes chickenpox, after which the virus becomes latent in cranial nerve, dorsal root and autonomic nervous system ganglia along the entire neuraxis. Decades later, virus reactivation produces zoster (pain and rash restricted to 1-3 dermatomes) in about 1 million Americans annually. Zoster is often followed by postherpetic neuralgia (PHN, chronic pain), as well as retinitis, myelitis and vasculopathy, which are significant causes of blindness, paralysis and death. Although zoster vaccine reduces the incidence of zoster by 50% over a 3-year period, even if everyone over age 60 received it, there would still be 500,000 cases of zoster and 200,000 of PHN annually. Thus, as the elderly population increases in number, the incidence of zoster and its attendant neurological complications is still likely to increase. In 1983, we first proved that VZV is latent in human ganglia. Our subsequent analyses of >6,000 human ganglia from >700 randomly autopsied subjects showed that the entire virus genome is present, maintained as a histone-coated circular episome with a variable abundance of VZV DNA, and that VZV gene expression is restricted and regulated epigenetically without transcription of VZV micro-RNA. Nonetheless, mechanism(s) underlying VZV gene expression during latency have been hampered by the lack of a model that faithfully recapitulates the molecular events in latently infected human neurons. We have now developed an in vitro model in which human neural stem cells were induced to differentiate to >90% neurons, as evidenced by immunohistochemical staining. After infection with cell-free VZV, the neurons can be maintained for weeks in the absence of a cytopathic effect. We hypothesize that these VZV-infected neurons can be used to study VZV latency, thus obviating the need for thousands of human ganglia, and enable analyses not currently possible in human ganglia. Our goal is to prove that the in vitro differentiated neurons are latently infected with VZV after which we will use them to further study VZV latency. Specifically, we will isolate VZV-infected differentiated neuronal cells by optimized laser capture microdissection (LCM) and determine the purity of LCM-captured infected neurons by RT-PCR with neuron- and glial-specific primers (Aim 1). We will verify that these neurons are latently infected by showing that the physical state of VZV DNA and VZV gene transcription in LCM-captured neurons is the same as in latently infected human ganglia (Aim 2);we will then analyze epigenetics of the VZV DNA;and use GenomeLab Genetic Analysis System to analyze the entire VZV transcriptome (Aim 3). An in-depth understanding of the mechanism(s) of VZV gene expression in latently infected human neurons will lead to experiments designed to prevent the cascade of events leading to VZV reactivation, a cause of serious neurologic disease and blindness, particularly in the rapidly increasing elderly and immunocompromised populations.
An in-depth understanding of how varicella zoster virus lives in latently infected human nerve cells is prerequisite to developing strategies that prevent the cascade of events leading to virus reactivation, a cause of serious neurologic disease and blindness, particularly in the rapidly increasing elderly and immunocompromised populations. An in-depth understanding of how varicella zoster virus lives in latently infected human nerve cells is prerequisite to developing strategies that prevent the cascade of events leading to virus reactivation, a cause of serious neurologic disease and blindness, particularly in the rapidly increasing elderly and immunocompromised populations.
|Baird, Nicholas L; Bowlin, Jacqueline L; Hotz, Taylor J et al. (2015) Interferon Gamma Prolongs Survival of Varicella-Zoster Virus-Infected Human Neurons In Vitro. J Virol 89:7425-7|
|Cheng-Ching, Esteban; Jones, Stephen; Hui, Ferdinand K et al. (2015) High-resolution MRI vessel wall imaging in varicella zoster virus vasculopathy. J Neurol Sci 351:168-73|
|Nagel, Maria A; Lenggenhager, Daniela; White, Teresa et al. (2015) Disseminated VZV infection and asymptomatic VZV vasculopathy after steroid abuse. J Clin Virol 66:72-5|
|Traina-Dorge, Vicki; Doyle-Meyers, Lara A; Sanford, Robert et al. (2015) Simian Varicella Virus Is Present in Macrophages, Dendritic Cells, and T Cells in Lymph Nodes of Rhesus Macaques after Experimental Reactivation. J Virol 89:9817-24|
|Nagel, Maria A; Gilden, Don (2015) The relationship between herpes zoster and stroke. Curr Neurol Neurosci Rep 15:16|
|Birlea, Marius; Nagel, Maria A; Khmeleva, Nelly et al. (2014) Varicella-zoster virus trigeminal ganglioneuritis without rash. Neurology 82:90-2|
|Nagel, Maria A; Gilden, Don (2014) Neurological complications of varicella zoster virus reactivation. Curr Opin Neurol 27:356-60|
|Nagel, Maria A; Khmeleva, Nelly; Choe, Alexander et al. (2014) Varicella zoster virus (VZV) in cerebral arteries of subjects at high risk for VZV reactivation. J Neurol Sci 339:32-4|
|Teodoro, Tiago; Nagel, Maria A; Geraldes, Ruth et al. (2014) Biopsy-negative, varicella zoster virus (VZV)-positive giant cell arteritis, zoster, VZV encephalitis and ischemic optic neuropathy, all in one. J Neurol Sci 343:195-7|
|Birlea, Marius; Cohrs, Randall J; Bos, Nathan et al. (2014) Search for varicella zoster virus DNA in saliva of healthy individuals aged 20-59 years. J Med Virol 86:360-2|
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