Bovine Viral Diarrhea Virus: Biotypes and their Contribution to Pathogenesis of the Disease in Susceptible Cells

Ammari, Mais Ghazi

15 December 2012

Bovine Viral Diarrhea Virus (BVDV) is a significant disease causing agent with major economic impact on the cattle industry, causing both productive and reproductive losses. One reason for its widespread distribution is that the majority of all BVDV infections occur without clinical signs, leaving most cases of BVDV undetected in cow herds. BVDV occur as cytopathic (CP) or non-cytopathic (NCP) biotypes, classified according to whether or not they produce visible changes in cell culture. CP BVDV biotype but not NCP biotype is implicated in the induction of apoptosis in vivo. The interaction of BVDV with its host has several unique features, most notably the capacity to infect its host either transiently or persistently. The pathogenesis of the disease caused by BVDV is complicated and interaction between BVDV and the host are poorly understood. The overall goal of this research is to identify mechanistic pathways that govern the outcome of BVDV infection in susceptible host cells. Specific aspects of this goal is to understand BVDV biotypes-induced changes on cellular proteome, cell death and survival mechanisms used by BVDV biotypes in apoptosis pathway, interactions of BVDV NS3 viral protein with host cellular proteins and how BVDV cell entry and infection interfere with an early step of professional antigen presentation, antigen uptake. The results of this work showed, for the first time, the successful use of proteomics in studying BVDV-host interactions in a comprehensive approach. Using the Gene Ontology and systems biology analysis we identified biotype-related differences in significant biological pathways and functions. Also, using a proteomics approach, we identified multiple critical cellular proteins that interact with CP NS3 viral protein at multiple stages of CP BVDV replication cycle. This project provides insight into the cellular pathways and functions involved in the viral cytopathogenicity of CP BVDV biotype. In addition, our data not only confirmed the previous observations on the critical involvement of the intrinsic pathway of apoptosis in CP BVDV infection, it also identified multiple mitochondrial and antioxidant proteins contributing to this pathway. Finally, we show that BVDV exploit selective antigen uptake mechanisms in professional antigen presenting cells monocytes during viral entry.

virus-host interaction

mass spectrometry

apoptosis

virology

Bovine viral diarrhea virus

proteomics

Host Gene Expression Profiling of Japanese Encephalitis Virus Infected cells : Identification of Novel Pro- and Anti-viral Genes

Bhandari, Prakash

January 2013

Japanese encephalitis virus (JEV), a mosquito-borne flavivirus is the causative agent of Japanese encephalitis (JE). The disease affects mostly children and around 30000– 50000 cases of JE and up to 15000 deaths are reported annually. No anti-viral drugs have been discovered against JE so far, but advances in our knowledge of the molecular biology of flaviviruses is propelling flaviviral drug research at an expeditious pace. Since JEV has a small genome which encodes for only ten proteins, there is dearth of potential drug targets. Researchers are now focusing on cellular interactomes, a complex and dynamic molecular biosystem which identifies host proteins which interact with either viral proteins or viral genomes, leading to the generation of an astronomical number of potential drug targets involving common cellular pathways that are required for the life cycle of different viruses. Such studies can pave way for the development of ‘broad-spectrum’, ‘silver-bullet’ anti-viral drugs for the treatment of multiple viral diseases. The cellular interactomes can be studied by Genomics tools such as microarray. Systematic profiling of genes involved in virus infection by RNAi, transcriptome sequencing, microRNA profiling and yeast two-hybrid system has allowed us to assess global gene expression changes providing an unprecedented view on the host-side of the virus–host interactions. Advent of these tools has led to identification of plethora anti-viral genes. For example, over expression of IFN-stimulated gene15 (ISG15) results in inhibition of JEV leading to significant reduction of viral titers. Chemokine profiling of JEV-infected cells by microarray can provide possible therapeutic modalities that can mitigate the morbidity associated with JEV infection. Functional classification of interferon-stimulated genes (ISG) identified using innovative methods have been the stepping stone for identification of many anti-viral genes, among them are few Broadly acting effectors like IRF1, C6orf150, HPSE, RIG-I, MDA5 and IFITM3 and some more targeted antiviral specific like DDX60, IFI44L, IFI6, IFITM2, MAP3K14, MOV10, NAMPT, OASL, RTP4, TREX1 and UNC84B. In this study, we have identified a B16F10 murine melanoma cell line that is resistant to JEV infection. DNA microarray analysis of JEV-susceptible and resistant B16F10 cell lines gave us interesting insights into JEV-induced host gene expression changes. Real time PCR validation of microarray data indicates that a number of virus and interferon inducible genes are expressed constitutively at high levels in this JEV-resistant cell line. Further, several of the mouse genes induced by JEV in B16F10 cell line were also upregulated in JEV-infected mouse brain. To understand the significance of these host gene expression changes, we attempted to generate stable murine cell lines constitutively expressing select JEV-inducible genes and study the JEV infection pattern in these cell lines. One of the JEV-inducible genes encoding thymidylate kinase (Tyki), a mitochondrial protein involved in the sysnthesis of nucleoside diphosphates, when overexpressed in NIH3T3 cells confers resistance to JEV infection as evident from reduced JEV-induced cytopathic effects and significant reduction in viral titer. Since TYKI has two distinct domains: the N-terminal domain with unknown function and the C-terminal domain with the nucleoside monophosphate kinase function, suggest that TYKI may be a bifunctional protein with other biological functions in addition to its UMP-CMP kinase activity. In order to examine whether N-terminal domain is responsible for antiviral activity of the protein, a stable cell line constitutively expressing N-terminal domain of gene was made, but the overexpression of N-terminal domain didn't confer any antiviral immunity. Thus signifying importance of kinase activity in confering antiviral immunity. Our studies indicate for the first time that Tyki may have a role in host resistance to JEV and understanding the mechanism of action Tyki may pave way for novel anti-JEV therapy. Stable cell lines constitutively expressing other JEV-inducible genes (Atf3, Gimap3, Rtp4, Glipr2, Tmem140 and Garg49) couldn't be generated. Therefore, to study the effect of overexpression of these genes on JEV infection, expression vectors encoding these genes were transfected individually to human 293T cells by nucleofection, then infected with JEV and viral titres were examined by plaque assay. Nucleofection was opted as a method of choice since it is the only non-viral method, which transfects DNA directly enter the nucleus. In contrast, other commonly used non-viral transfection methods rely on cell division for the transfer of DNA into the nucleus. Nucleofection of vectors encoding different JEV-inducible genes followed by JEV infection and assay of viral titer led to identification of one more anti-viral gene and three pro-viral genes. Garg49, an interferon and JEV inducible mitochondrial gene was identified as antiviral gene. Further studies led to the identification of GARG49 as a mitochondrial protein. Three genes, Atf3, encoding a cAMP responsive element binding protein family transcription factor, Glipr2, encoding a Glioma related pathogenesis protein and Gimap3, encoding an outer mitochondrial membrane GTPase were identified as pro viral genes. Overexpression of Tmem140, encoding a transmembrane protein and Rtp4, encoding a golgi chaperone did not significantly affect JEV titer. Conclusions: . A JEV-resistant B16F10 murine melanoma cell line was identified and several JEV-inducible genes were found to be expressed constitutively at high levels in this cell line. .We demonstrate for the first time that Tyki/Ump-Cmpk2 encoding a mitochondrial nucleoside monophosphate kinase has an anti-JEV function and the C-terminal domain is essential for anti-viral activity. .Garg49/Ifit3 encodes an interferon and JEV-inducible mitochondrial protein and it has an anti-JEV function. . Activating transcription factor 3 (ATF3), GTPase, IMAP family member 3 (GIMAP3) and GLI pathogenesis-related 2 (GLIPR2) are pro-viral proteins which facilitate virus multiplication resulting in enhanced JEV titer.

Japanese Encephalitis Virus (JEV)

Virus-Host Interaction

Japanese Encephalitis Virus

Tyki

Garg49

JEV Resistant Murine Melanoma Cells

Flaviviruses

JEV-induced Host-Gene Expression

Pro-Viral Genes

Anti-Viral Genes

JEV Inducible Mouse Genes

Biochemistry

Study of cell host factors involved in Hepatitis C virus tropism / Etude des facteurs cellulaires de l'hôte impliqués dans le tropisme du virus de l'hépatite C

Da Costa, Daniel

18 September 2012

Le virus de l’hépatite C (HCV) est un problème majeur de santé publique. Le développement de nouveaux traitements pour lutter contre le HCV a été ralenti par l’absence de modèles d’études in vitro et in vivo convenables. Le but de mon travail de thèse a été, dans un premier temps, de caractériser les facteurs déterminant le tropisme hépatique du HCV. En exprimant des facteurs clés dans une lignée cellulaire humaine non-hépatocytaire, nous avons reconstitué in fine l’ensemble du cycle viral dans ces cellules. L’entrée du virus dans la cellule hôte fait intervenir différents récepteurs d’entrée dont CD81, occludin (OCLN), claudin-1 (CLDN1) et scavenger receptor class B type I (SR-BI). L’expression de ces quatre récepteurs sur cette lignée la rend hautement permissive à l’entrée du virus, mais ne permet pas de rétablir la réplication du virus. L’expression du micro-ARN 122, un micro-RNA important pour l’infection du HCV, dans les cellules exprimant les quatre récepteurs, restaure une forte réplication de l’ARN viral mais ne permet pas de détecter une production de particules infectieuses. L’expression de l’apolipoprotein E (apoE), jouant un rôle primordial dans l’assemblage et la sécrétion, rétablis cette dernière étape du cycle viral du HCV dans la lignée cellulaire humaine non-hépatocytaire. Dans un second temps, j’ai utilisé la stratégie, précédemment établie, pour étudier la spécificité d’espèce de l’infection du HCV dans plusieurs lignées hépatocytaires murines. Nous avons pu rendre ces cellules permissives à l’entrée du HCV et pu détecter une très faible réplication. L’ensemble de mes travaux apportent de nouvelles informations sur la compréhension des facteurs clés nécessaire au cycle viral du HCV dans des cellules murines et humaines. / Hepatitis C virus (HCV) is a global health burden. The development of new therapeutics to treat HCV infection has been hampered by the lack of convenient in vitro and in vivo model systems. The goal of my PhD work was, in a first time, to characterize the factors determining the hepatotropism of HCV. By expressing key factors within a non-hepatic cell line, we reconstituted in fine the full HCV life cycle in those cells. Virus entry into the host cell requires different entry factors which are CD81, occludin (OCLN), claudin-1 (CLDN1) and the scavenger receptor class B type I (SR-BI). The expression of these four factors in this cell line renders it highly permissive to viral entry, but does not allow restoring replication of the virus. The expression of miR-122, a micro-RNA important for HCV infection, into the cell lines expressing the four HCV entry factors restore a strong replication of the HCV RNA but does not allow detecting infectious viral particle production. Further expression of the apolipoprotein E (apoE), which plays a critical role in the assembly and release process, restore the last step of the HCV life cycle in a non-hepatic cell line. In a second part of my PhD, I have used the previously developed strategy to study the species specificity of HCV infection using different mouse hepatoma cell lines. We have been able to render these cell lines permissive to HCV entry and have been able to detect a slight replication. Altogether, my results bring new information on the understanding of key factors important for HCV life cycle in mouse and human cells.

Intéraction virus-hôte

Tropisme du HCV

Spécificité d’espèce du HCV

Entrée du HCV

Replication du HCV

Hepatitis C virus infection

Virus-host interaction

HCV tropism

HCV species specificity

HCV entry

HCV replication

HCV assembly and HCV mouse model

579.2

616.91

572.8