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Biology of a small RNA virus that infects Drosophila melanogasterSadanandan, Sajna Anand January 2016 (has links)
Drosophila melanogaster has been extensively used as a model organism to study diverse facets of biology, including host-pathogen interactions and the basic biology of its pathogens. I have used the fruit fly as a model to study elementary aspects of Nora virus biology, such as the role of the different proteins encoded by the virus genome. Nora virus, an enteric virus transmitted via the feca-oral route, does not cause any obvious pathology in the fly, although the infection is persistent. Nora virus genome consists of a positive strand RNA that is translated in four open reading frames (ORF). Since sequence homology studies did not yield much information about the different Nora virus proteins, I have used the cDNA clone of the virus to construct mutants to identify the specific function of each protein. My results have shown that, 1) The protein(s) encoded by ORF 1 are crucial for the replication of the virus genome. 2) The C-terminus of the ORF 1-encoded protein (VP1), is an inhibitor to the RNAi pathway. 3) The transmembrane domain in the N-terminus of the ORF2-encoded protein (VP2) is important for the formation of Nora virus virions. 4) The ORF 3-encoded protein (VP3) forms α-helical trimers and this protein is essential for the stability of Nora virus capsid. I have also performed RNA sequencing to investigate the transcriptional response of D. melanogaster in response to Nora virus infection and my results indicate that, 5) The upregulation of genes related to cellular stress and protein synthesis and the downregulation of basal digestive machinery, together with the induction of upd3, implies major gut epithelium damage and subsequent regeneration.
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Nora virus as a model to study persistent infection in Drosophila melanogasterHabayeb, Mazen January 2009 (has links)
Drosophila melanogaster has been widely used as a model organism to study the immune responses against bacteria, fungi, parasites and viruses. Here, I present a D. melanogaster virus as a model to study persistent virus infections. I have discovered and characterized the Nora virus, a small picorna-like RNA virus able to persistently infect D. melanogaster. The Nora virus genome encodes four open reading frames; a feature not present in other picorna-like viruses. The Nora virus is not closely related to any other virus family, but rather is the first virus in a new family of picorna-like viruses. The major replicative proteins of this virus are encoded in the second open reading frame and the capsid proteins are encoded in the fourth open reading frame. The sequence of the capsid proteins are not obviously related to any other previously described protein. By looking at expressed sequence tags (EST) projects, we identified an EST sequence from the parasitic wasp Nasonia which appears to encode proteins that have sequence similarity to the Nora virus capsid proteins. I have shown that the Nora virus persists in the fly intestine however I did not observe serious pathological effects in the infected flies. The virus is shed through feces and the transmission occurs horizontally via the ingestion of virus-contaminated food. Moreover, I observed variability in the viral titers among single flies of the same infected stock. Some flies are able to clear the Nora virus but not others and this phenomenon seems to be titer-dependent. Surprisingly, none of the known Drosophila antiviral responses play a role against the Nora virus. In conclusion, my work shows that studying the Nora virus interaction with the Drosophila immune system can lead to new findings on viral persistence mechanisms of RNA viruses and of Drosophila viral innate immunity.
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Pastrel, a restriction factor for picornalike-viruses in Drosophila melanogaster / Le gène pastrel contrôle l'infection par les virus de type picorna chez la drosophileBarbier, Vincent 10 December 2013 (has links)
La drosophile est un excellent modèle pour l’étude des mécanismes moléculaires de l’immunité innée, y compris les virus. Elle a permis la caractérisation de mécanismes de défense immunitaire conservés au cours de l’évolution, tel que les voies Toll et IMD qui régulent l’expression des peptides antimicrobiens induits en réponse aux infections fongiques et bactériennes. Deux types de réponse sont impliqués dans le contrôle des infections virales chez la drosophile : une réponse inductible et l’ARN interférence. Nous avons montré que l’ARN interférence est un mécanisme global de défense antivirale puisqu’il contrôle l’infection par un virus à ADN, en plus des virus à ARN tel que le virus C de la drosophile (DCV). Le virus DCV, apparenté aux Picornaviridae, est un pathogène naturel de la drosophile. Nous avons également observé que la résistance de mouches contrôles à l’infection par le virus DCV est dépendante du fond génétique. Elle est d’ailleurs corrélée à des polymorphismes présents dans un gène porté par le chromosome III : le gène pastrel. Nos expériences de perte et gain de fonction indiquent que ce gène code pour un facteur de restriction viral, bloquant l’infection par le virus DCV mais aussi par le virus de la paralysie du cricket (CrPV). Cette restriction apparait dans les premières heures après infection. La région C-terminale de la protéine Pastrel est nécessaire à son activité antivirale ainsi qu’à sa localisation dans les cellules. La protéine Pastrel co-localise avec le Rouge de Nil, un marqueur des gouttelettes lipidiques. Ainsi, nos résultats suggèrent un lien entre le métabolisme lipidique et le blocage d’une infection virale chez la drosophile. / Since the discovery of the evolutionarily conserved TOLL and IMD pathways, involved in antifungal and antibacterial immune responses, the fruit fly Drosophila melanogaster is used as a model to study the molecular mechanisms of innate immunity. To defend against viral pathogens, Drosophila relies on two main facets: the RNA interference (RNAi) pathway and virus specific inducible responses. We show that the RNAi pathway plays a role in the control of a DNA virus, in addition to RNA viruses. We also observe that the fly genetic background can modulate the resistance to infection by Drosophila C virus (DCV), a natural pathogen of Drosophila. This resistance to DCV infection is correlated with polymorphisms in a gene named pastrel,localized on the left arm of the third chromosome. Our loss- and gain-of-function experiments indicate that pastrel encodes a molecule opposing infection by picorna-like viruses DCV and also Cricket Paralysis virus (CrPV), raising the question of the mechanism involved. This restriction appears early after infection. The Cterminal region of Pastrel protein is important for its antiviral activity and its localization in vesicular structures co-localizing with Nile Red staining, a marker for lipid droplets. Altogether, our data suggest a connection between lipid droplets and restriction of viral infection in Drosophila, as already described in mammals between the restriction factor Viperin, present on lipid droplets, and the replication of the human pathogen Hepatitis C Virus.
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