Modulation du système interféron de type I par les virus : en particulier par le virus de l'hépatite C et le virus influenza / Modulation of the type I interferon system by viruses : in particular by hepatitis C virus and influenza virus

Pradezynski, Fabrine

17 November 2010

Afin de se répliquer et de se propager efficacement, les virus ont développé de multiples stratégies leur permettant d’échapper au système de défense innée : le système IFN de type I. Ce travail de thèse a alors consisté à étudier les interactions entre protéines virales et protéines de ce système de défense afin de mieux comprendre les mécanismes de subversion virale et d’identifier d’éventuelles cibles cellulaires thérapeutiques. La reconstruction d’un réseau d’interactions entre ces protéines nous a permis d’identifier des stratégies différentielles de subversion pour 4 familles virales et de montrer un ciblage massif et significatif des protéines du système IFN de type I par les virus. Les protéines en interaction directe avec ces protéines sont également fortement touchées par les virus et sont de potentiels modulateurs du système IFN de type I. Parmi ces modulateurs, le processus biologique sur-représenté est le transport nucléocytoplasmique et la protéine KPNA1 impliquée dans ce processus a retenu notre attention. L’étude fonctionnelle de l’interaction entre la protéine KPNA1 et la protéine NS3 du VHC a montré que la protéine NS3 associée à son cofacteur NS4A inhibe partiellement la réponse IFN de type I en empêchant l’import nucléaire de STAT1. Ce phénotype pourrait résulter de la dégradation de KPNA1 par NS3/4A. Par ailleurs, l’identification de nouveaux inter-acteurs de la protéine NS1 du virus influenza par criblage double-hybride levure a révélé la protéine induite par les IFN de type I, ADAR1, comme partenaire de la protéine NS1 de multiples souches virales et nous avons montré qu'ADAR1 est un facteur pro-viral dont la fonction editing est activée par NS1 / To replicate and propagate efficiently, viruses have developed multiple strategies allowing them to escape the innatedefense system: the type I IFN system, This work of thesis then consisted in studying the interactions between viralproteins and proteins of this defence system in order to understand better the mechanisms of viral subversion andidentifY possible therapeutic cellular tatgets. The reconstruction of a network of interacting proteins involved in the typeI IFN system allowed us to identifY differentiai subversion strategies for 4 viral families and to show a massive andsignificant targeting of proteins of the type I IFN system by viruses. Proteins directly interacting with the type Iinterferon system network are also strongly targeted by viruses and are potential modulators of the type I IFN system.Among these modulators, the most tatgeted function conesponds to the transport of NLS-bearing substrates to thenucleus and the KPNAI protein involved in this process held our attention. The functional study of the interactionbetween KPNA1 and NS3 protein of the HCV showed that NS3 protein associated with its cofactor NS4A inhibitsprutially the type I IFN response by preventing the nuclear translocation of ST A Tl. This phenotype could result fromthe degradation of KPNAI by NS3/4A. Besides, the identification of new cellular prutners ofNS 1 prote in of influenzavirus by yeast two-hybrid screens revealed ADARI, an interferon-stimulated prote in, as partner of NS 1 of ali testedvirus strains and we showed that ADARI is an essential host factor for viral replication and its editing function isactivated by NS 1 protein

Interféron (IFN) de type I

Virus de l‟hépatite C

Virus influenza

Interactome

KPNA1

ADAR1

Stratégies virales d‟échappement

Type I interferon (IFN)

Hepatitis C virus

Influenza Virus

Interactome

KPNA1 protein, mouse

DsRNA adenosine deaminase

Viral exhaust strategies

616.91

Innate Immune Signaling Drives Pathogenic Events Leading to Autoimmune Diabetes

Qaisar, Natasha

26 April 2018

Type 1 diabetes (T1D) is a chronic autoimmune disease characterized by the immune-mediated destruction of insulin-producing beta-cells of pancreatic islets, culminating in critical insulin deficiency. Both genetic and environmental factors likely orchestrate an immune-mediated functional loss of beta cell mass, leading to the clinical manifestation of disease and lifelong dependence on insulin therapy. Additional evidence suggests the role of innate and adaptive immune mechanisms leading to inflammation in beta cells mediated by proinflammatory cytokines and chemokines, activation of beta-cell-reactive T cells,and failure of immune tolerance. Viral infections have been proposed as causal determinants or initiating triggers for T1D but remain unproven. Understanding the relationship between viral infections and the development of T1D is essential for T1D prevention. Importantly, virus-induced innate immune responses, particularly type I interferon (IFN-I, IFN-a/b), have been implicated in the initiation of islet autoimmunity and development of T1D. The goal of my thesis project is to investigate how the IFN-I signaling pathway affects the development of T1D using the LEW.1WR1 rat model of autoimmune diabetes. My hypothesis is that disrupting IFN-Isignaling via functional deficiency of the IFN-I interferon receptor (IFNAR) prevents or delays the development of virus-induced diabetes.For this purpose, I generated IFNAR subunit 1(IFNAR1)-deficient LEW.1WR1 rats using CRISPR-Cas9 genome editing and confirmed the functional disruption of IFNAR1. The absence of IFNAR1 results in a significant delay in onset and frequency of diabetes following poly I:C challenge and reduces the incidence of insulitis after poly I:C treatment. The frequency of diabetes induced by Kilham rat virus (KRV) is also reduced in IFNAR1-deficient LEW.1WR1 rats. Furthermore, I observe a decrease in CD8+T cells in spleens from KRV-infected IFNAR1-deficient rats relative to that in KRV-infected wild-type rats. While splenic regulatory T cells are depleted in WT rats during KRV-infection, no such decrease is observed in KRV-infected IFNAR1-deficient rats. A comprehensive bulk RNA-seq analysis reveals a decrease of interferon-stimulated genes and inflammatory gene expression in IFNAR1-deficient rats relative to wild-type rats following KRV challenge. Collectively, the results from these studies provided mechanistic insights into the essential role of virus-induced, IFN-I-initiated innate immune responses in the early phase of autoimmune diabetes pathogenesis.

Type 1 diabetes (T1D)

type I interferon (IFN)

type I interferon receptor (IFNAR)

virus-induced diabetes

innate immunity in type 1 diabetes

autoimmune diabetes in rat

pancreatic islets

Immunology and Infectious Disease

Microbiology

Modulace funkce plazmacytoidních dendritických buněk: role immunoreceptorů TIM-3 a BDCA-2 / Modulation of plasmacytoid dendritic cell function: role of immunoreceptors TIM-3 and BDCA-2

Font Haro, Albert

January 2021

Albert Font Haro ABSTRACT Modulation of plasmacytoid dendritic cell function: role of immunoreceptors TIM-3 and BDCA-2 Plasmacytoid dendritic cells (pDCs) are key players in the antiviral response as well as in linking innate and adaptive immune response. They express endosomal toll-like receptors 7 and 9, which can detect ssRNA and unmethylated CpG DNA, respectively. Due to the constitutive expression of the transcription factor IRF7, pDCs are able to rapidly produce massive quantities of type I (α, β, ω) and type III (1, 2, 3, 4) interferons (IFN-I and IFN-III) as well as pro- inflammatory cytokines such as IL-1, IL-6 and TNF-α. After maturation, they also function as antigen-presenting cells. Despite intense research, the mechanisms of IFN and pro-inflammatory cytokines production and regulation are still poorly understood. Using the pDC cell line GEN2.2 and also primary human pDCs, we shed light on the role of kinases MEK and SYK in IFN-I production and regulation. We found that SYK is not only involved in the regulatory receptor (RR)-mediated BCR-like pathway that represents the negative regulation of IFN-I and IFN-III secretion but also in the positive TLR7/9-mediated signal transduction pathway that leads to IFN-I production, representing the immunogenic function. We also found that MEK plays a...