Ubiquitin Targets and Molecular Mechanisms of Herpes Simplex Virus 1 Infection in Adult Sensory Neurons
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Abstract
Herpes simplex virus 1 (HSV-1) is a double-stranded DNA virus, often acquired during childhood, that currently infects more than 50% of the human population. The symptoms of infection are herpetic lesions that frequently appear throughout a host's life in response to stress in the orofacial or genital region. As a pathogen, HSV-1 replicates rapidly in epithelial cells, but it is also capable of infecting neurons where it can pursue a lytic or latent infection. Latency is a state of viral quiescence where the virus can persist indefinitely yet remain poised to reactivate. Latency is unique to herpesviruses and key to HSV's success, but the molecular mechanisms that govern this state are unclear. A virus-encoded E3-ubiquitin ligase, Infected Cell protein 0 (ICP0), is often correlated with latency establishment but is detected in opposition to the state of latency. During lytic infection, ICP0 has many biological roles but primarily catalyzes the addition of ubiquitin to target substrate, marking proteins for degradation or altering their function. This ubiquitination ability allows ICP0 to alter the intracellular environment making neurons conducive to lytic or latent HSV-1 infection. ICP0's neuron-specific targets, however, are unknown, representing a significant gap in knowledge. Through the studies presented in this dissertation, we identified some of the neuron-specific ubiquitination targets of ICP0 in neurons. We utilized primary adult sensory neurons of the dorsal root ganglia and HSV-1 viral strains KOS, wild-type virus encoding a fully functional ICP0, and HSV-1 n212, encoding a truncated ICP0 protein, to illuminate the mechanisms involved in establishing and maintaining HSV latency. By using adult primary neurons and functional HSV-1 strains with and without ICP0, we were able to show that ICP0 regulates host and viral proteins during the initial onset of neuronal infection. We also show that based on neuronal conditions set forth before HSV-1 initial infection, host proteins will influence HSV-1 viral proteins to repress viral gene expression, thereby promoting the establishment of latency.