The Neuroinvasion and Neuropathology of West Nile virus

Rebecca Biron

Unknown Date

West Nile Virus (WNV) has emerged as a major cause of viral encephalitis. Since its outbreak in the United States 27,000 people have presented with clinical WNV disease resulting in 1074 fatalities. WNV causes a range of disease from mild febrile illnesses to severe and fatal encephalitis. To date, there are currently no therapeutic agents or vaccines available to treat WNV infection in humans. In order to address this, a better understanding of the mechanisms responsible for viral neuroinvasion and neuropathology are required. Using a range of in vitro and in vivo studies, we have investigated the routes by which WNV enters the CNS. Virus replication was observed in the brain microvascular endothelial cells in mice that succumbed to WNV encephalitis. Moreover, we demonstrated that infection of a polarized HBMEC with WNV induced apoptosis. Microarray analysis of WNV-infected HBMEC’s revealed that WNV elicited the expression of cytokines that have been shown to contribute to permeablization of the BBB. These findings suggest that WNV can enter the CNS through the BBB via multiple mechanisms. Real-time RT-PCR performed on WNVinfected HBMECs identified two host genes involved in the host cellular anti-oxidant response that were differentially regulated during viral infection. Furthermore, the addition of the antioxidant, N-acetylcysteine, restored cell viability and decreased viral replication, indicating that oxidative stress contributes to WNV-induced pathogenesis. The current state of knowledge regarding the pathogenesis of WNV encephalitis is based on studies that have defined the role of systemic immune responses to WNV. Limited investigations have been undertaken to determine the contribution of brain cells in the defence, or damage to the brain once WNV has gained access to the CNS. Real-time RT-PCR results in conjunction with in vivo CBA assay data, suggested several candidate host genes that could contribute to the pathogenesis of WNV. Thus, it is necessary to further define the mechanisms of WNV induced pathogenesis as this will aid in the development of targeted strategies to prevent neurological infection and mitigate neurological diseases in affected individuals.

West Nile virus

neuroinvasion

neuropathology

blood-brain-barrier

Regulation and Function of IL-36γ in Genital HSV-2 Infection and Disease Pathogenesis

January 2019

abstract: An estimated 267 million women worldwide are HSV-2 seropositive, including roughly 20% of reproductive-aged American women. HSV-2 is a neurotropic virus that establishes a persistent, life-long infection that increases risk for STI acquisition in individuals. The vaginal epithelium represents a critical first line of defense against infection, and during acute infection, underlying immune mechanisms in the epithelium may be critical to protect against disease pathogenesis. The recently identified pro-inflammatory cytokine IL-36gamma has been shown to be expressed at mucosal epithelia, including the female reproductive tract (FRT) and may be an important factor in host defense. Although IL-36gamma has been shown to be induced in the FRT after exposure to microbial products, the contributions of IL-36gamma to host defense mechanisms in response to this clinically relevant STI pathogen are not well understood. This dissertation describes the regulation of IL-36gamma in the FRT and explores its contribution to the host response against genital HSV-2 infection. To test the hypothesis that IL-36gamma is a key regulator of mucosal inflammation and immunity in the FRT, hormonal regulation of IL-36gamma in the FRT was investigated using estrogen- and progesterone-conditioned mice. From this preliminary study, it was shown that progesterone dampens IL36G expression relative to estrogen and may potentially increase susceptibility to infection. Next, the impact of IL-36gamma treatment on HSV-2 infection and replication in human 3-D vaginal epithelial cells was explored. In parallel, the impact of intravaginal IL-36gamma delivery on HSV-2 disease pathogenesis was evaluated using a lethal murine challenge model. IL-36gamma pre-treatment significantly limited HSV-2 replication in vitro and in vivo and was associated with transient neutrophil infiltration that corresponded with decreased disease severity and increased survival in mice. Last, the requirement for IL-36gamma in host defense was investigated utilizing IL-36gamma-/- mice in a lethal HSV-2 murine challenge model. Following infection, IL-36gamma-/- mice exhibited significantly impaired neutrophil recruitment, decreased overall survival time, and significantly increased viral neuroinvasion relative to wild type mice. Collectively, these data indicate that IL-36gamma is a crucial regulator of HSV-2-induced neutrophil infiltration and appears to function in a previously uncharacterized manner to limit viral neuroinvasion in genital HSV-2 disease pathogenesis. / Dissertation/Thesis / Doctoral Dissertation Molecular and Cellular Biology 2019

Immunology

Virology

Cytokine

Genital herpes

IL-36

Neuroinvasion

Neutrophil

Vaginal epithelial cell

Unraveling viral encephalitis in vivo : dynamic imaging of neuro-invasion and neuro inflammation processes in the zebrafish / Etudes analytiques des encéphalites virales in vivo : imagerie dynamique du processus de neuro-invasion et neuro-inflammation dans le modèle poisson zèbre

Passoni, Gabriella

10 December 2015

Le danio zébré est un modèle bien établi pour étudier la biologie du développement des vertébrés. Ses larves transparentes sont favorables à des approches de microscopie non invasive, qui permettent de réaliser des observations à l’échelle d’un individu entier à des niveaux de résolution cellulaire et subcellulaire. Ces atouts font du danio zébré un excellent modèle pour étudier les infections virales in vivo. Au cours de mon projet, j’ai etudié l’entrée et la colonisation du système nerveux central (SNC) par le virus Sindbis (SINV) dans le modèle danio zébré. Mon projet présentait plusieurs axes: 1) développer un modèle d’infection du virus Sindbis chez le danio zébré, 2) caractériser l’invasion du SNC par le virus par des techniques d’imagerie à haute résolution, 3) définir la voie d’entrée du virus dans le SNC, 4) évaluer la dynamique de la réponse immunitaire innée par l’étude de la réponse interféron. Le suivi de la propagation du virus a été rendu possible par l’utilisation d’un ARN viral recombinant exprimant la protéine fluorescente verte ‘GFP’. L’utilisation de cette construction m’a permis de caractériser la progression de SINV chez le danio zébré et d’identifier les organes/tissus cibles que sont le vitellus, le foie, le cœur et enfin, le cerveau. Les données rassemblées jusqu'à présent m’ont aussi permis d’identifier le mécanisme par lequel SINV se propage vers le cerveau: le virus se propage par un transport axonal du system nerveux périphérique vers le SNC. Dans le cadre de la réponse immunitaire au niveau cellulaire, j’ai pu observer le rôle joué par les leucocytes, en particulier les neutrophiles, comme cellules productrices d'interféron. / The zebrafish (Danio rerio) is an important model organism, particularly for studies of development and more recently host pathogen interactions. As opposed to other vertebrate model organisms, its optical clarity and ease of genetic manipulations allow to visualize highly dynamic cellular processes in vivo at the whole organism scale. These assets make the zebrafish a perfect model for the study of viral infections in vivo, such as those caused by neurotropic viruses. The aim of this project has been to gain insights in some of the interactions that determine encephalitis, by characterizing the neurotropic Sindbis virus (SINV). This Thesis project has consisted therefore in: 1) the development of a SINV infection model in zebrafish larvae, 2) the characterization of SINV neuroinvasion upon its inoculation in the bloodstream, thanks to the use of high resolution microscopy, 3) the study of SINV mechanism of entry in the CNS, 4) the characterization of the innate immune response, both at the whole organism and organ specific level. Thanks to the use of a SINV recombinant strain, engineered to express the green fluorescent protein “GFP” in infected cells upon viral replication, we have been able to follow the onset and the progression of the infection. We have suggested infection of peripheral neurons and subsequent axonal transport to the CNS as SINV entry mechanism. At the cellular level, we have identified neutrophils as the main IFN producing cells.

Encephalite virale

Virus sindbis

Poisson zèbre

Imagerie intravitale

Transport axonale

Neuroinvasion

Viral encephalitis

In vivo imaging

Zebrafish

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