Expression and characterisation of the hepatitis C virus non-structural protein 3

Wardell, Andrew D.

January 1999

No description available.

572

NS3; Protein kinase; Virus replication

Design and synthesis of Hepatitis C Virus NS3 protease inhibitors /

Johansson, Anja,

January 2003

Diss. (sammanfattning) Uppsala : Univ., 2003. / Härtill 4 uppsatser.

Improved CoMFA Modeling by Optimization of Settings : toward the Design of Inhibitors of the HCV NS3 Protease /

Peterson, Shane,

January 2007

Diss. (sammanfattning) Uppsala : Uppsala universitet, 2007. / Härtill 4 uppsatser.

Unravelling The Regulators Of Translation And Replication Of Hepatitis C Virus

Ray, Upasana

January 2011

Unravelling the regulators of translation and replication of Hepatitis C virus Hepatitis C virus (HCV) is a positive sense, single stranded RNA virus belonging to the genus Hepacivirus and the family Flaviviridae. It infects human liver cells predominantly. Although, the treatment with α interferon and ribavirin can control HCV in some cases, they fail to achieve sustained virological response in others, thus emphasizing the need of novel therapeutic targets. The viral genome is 9.6 kb long consisting of a 5’ untranslated region (5’UTR), a long open reading frame (ORF) that encodes the viral proteins and the 3’ untranslated region (3’UTR). The 5’UTR contains a cis acting element, the internal ribosome entry site (IRES) that mediates the internal initiation of translation. The HCV 5’UTR is highly structured and consists of four major stem-loops (SL) and a pseudoknot structure. HCV proteins are synthesized by the IRES mediated translation of the viral RNA, which is the initial obligatory step after infection. The viral proteins are synthesized in the form of a long continuous chain of proteins, the polyprotein, which is then processed by the host cell and the viral proteases. Once viral proteins are synthesized sufficiently, the viral RNA is replicated. However the mechanism of switch from translation to viral RNA replication is not well understood. Several host proteins as well as the viral proteins help in the completion of various steps in the HCV life cycle. In this thesis, the role of two such factors in HCV RNA translation and replication has been characterized and exploited to develop anti-HCV peptides. The HCV proteins are categorized into two major classes based on the functions broadly: the non structural and the structural proteins. HCV NS3 protein (one of the viral non structural proteins) plays a central role in viral polyprotein processing and RNA replication. In the first part of the thesis, it has been demonstrated that the NS3 protease (NS3pro) domain alone can specifically bind to HCV-IRES RNA, predominantly in the SLIV region. The cleavage activity of the NS3 protease domain is reduced upon HCV-RNA binding owing to the participation of the catalytic triad residue (Ser 139) in this RNA protein interaction. More importantly, NS3pro binding to the SLIV region hinders the interaction of La protein, a cellular IRES-trans acting factor required for HCV IRES-mediated translation, thus resulting in the inhibition of HCV-IRES activity. Moreover excess La protein could rescue the inhibition caused by the NS3 protease. Additionally it was observed that the NS3 protease and human La protein could out-compete each other for binding to the HCV SL IV region indicating that these two proteins share the binding region near the initiator AUG which was further confirmed using RNase T1 foot printing assay. Although an over expression of NS3pro as well as the full length NS3 protein decreased the level of HCV IRES mediated translation in the cells, replication of HCV RNA was enhanced significantly. These observations suggested that the NS3pro binding to HCV IRES reduces translation in favour of RNA replication. The competition between the host factor (La) and the viral protein (NS3) for binding to HCV IRES might contribute in the regulation of the molecular switch from translation to replication of HCV. In the second part the interaction of NS3 protease and HCV IRES has been elucidated in detail and the insights obtained were used to target HCV RNA function. Computational approach was used to predict the putative amino acid residues within the protease that might be involved in the interaction with the HCV IRES. Based on the predictions a 30-mer peptide (NS3proC-30) was designed from the RNA binding region. This peptide retained the RNA binding ability and also inhibited IRES mediated translation. The NS3proC-30 peptide was further shortened to 15-mer length (NS3proC-C15) and demonstrated ex vivo its ability to inhibit translation as well as replication. Additionally, its activity was tested in vivo in a mice model by encapsulating the peptide in Sendai virus based virosome followed by preferential delivery in mice liver. This virosome derived from Sendai virus F protein has terminal galactose moiety that interacts with the asialoglycoprotein receptor on the hepatocytes leading to membrane fusion and release of contents inside the cell. Results suggested that this peptide can be used as a potent anti-HCV agent. It has been shown earlier from our laboratory, that La protein interacts with HCVIRES near initiator AUG at GCAC motif by its central RNA recognition motif, the RRM2 (residues 112-184). A 24 mer peptide derived from this RRM2 of La (LaR2C) retained RNA binding ability and inhibited HCV RNA translation. NMR spectroscopy of the HCV-IRES bound peptide complex revealed putative contact points, mutations at which showed reduced RNA binding and translation inhibitory activity. The residues responsible for RNA recognition were found to form a turn in the RRM2 structure. A 7-mer peptide (LaR2C-N7) comprising this turn showed significant translation inhibitory activity. The bound structure of the peptide inferred from transferred NOE (Nuclear Overhauser Effect) experiments suggested it to be a βturn. Interestingly, addition of hexa-arginine tag enabled the peptide to enter Huh7 cells and showed inhibition HCV-IRES function. More importantly, the peptide significantly inhibited replication of HCVRNA. Smaller forms of this peptide however failed to show significant inhibition of HCV RNA functions suggesting that the 7-mer peptide as the smallest but efficient anti-HCV peptide from the second RNA recognition motif of the human La protein. Further, combinations of the LaR2C-N7 and NS3proC-C15 peptide showed better inhibitory activity. Both the peptides were found to be interacting at similar regions of SLIV around the initiator AUG. The two approaches have the potential to block the HCV RNA-directed translation by targeting the host factor and a viral protein, and thus can be tried in combination as a multi drug approach to combat HCV infection. Taken together, the study reveals important insights about the complex regulation of the HCV RNA translation and replication by the host protein La and viral NS3 protein. The interaction of the NS3 protein with the SLIV of HCV IRES leads to dislodging of the human La protein to inhibit the translation in favour of the RNA replication. These two proteins thus act as the regulators of the translation and the replication of viral RNA. The peptides derived from these regulators in turn regulate the functions of these proteins and inhibit the HCV RNA functions.

Hepatitis C Virus (HCV)

Hepatitis C Virus - Replication

HCV-NS3 Protein

Non-structural Protein 3

Human La Protein

HCV IRES

NS3 Protease

Hep C Viral Switch

Hepatitis C Viral RNA

NS3 Protein

Virology

Cartographie des interactions virus-hôtes pour le virus de la fièvre catarrhale ovine et mise en évidence d'une nouvelle fonction portée par la protéine NS3 / Mapping virus-host interactions for bluetongue virus and highlighting a new function carried by NS3 protein

Kundlacz, Cindy

18 December 2018

Le virus de la fièvre catarrhale ovine (Bluetongue virus, BTV) est l’agent étiologique de la maladie du même nom, une arbovirose non contagieuse transmise aux ruminants domestiques et sauvages par l’intermédiaire de morsures de moucherons hématophages du genre Culicoides. Il existe actuellement 27 sérotypes décrits de BTV à travers le monde qui se distinguent par les pathologies qu’ils induisent et leur capacité à infecter et se propager chez leur(s) hôte(s) mammifère(s). Le premier objectif de mon projet de thèse visait à identifier les interactions cellulaires spécifiques des sérotypes 8 et 27 pour identifier des facteurs de pathogénicité/virulence et/ou de franchissement de barrière d’espèces. Pour atteindre cet objectif, l’ensemble des protéines virales du BTV a été criblé par la méthode du double-hybride en levure contre deux banques d’ADN complémentaires, l’une d’origine bovine et l’autre d’origine culicoïde. A l’issue de 70 cribles, une centaine de nouvelles interactions virus-hôtes a été mise en évidence et révèle un enrichissement pour quatre processus cellulaires : l’épissage des ARNm, les ribosomes, la SUMOylation et l’apoptose. Cette étude nous a ainsi permis de réaliser le premier interactome pour le BTV qui se poursuit au travers de multiples validations biochimiques et fonctionnelles des interactions identifiées. En parallèle de ce travail de protéomique, le second objectif de mon projet de thèse a été de déterminer l’impact du BTV sur la voie MAPK/ERK, une voie cellulaire essentielle à la prolifération et différenciation cellulaire et classiquement modulée lors d’infections virales. En plus de son rôle antagoniste sur la voie des interférons de type I, nous avons démontré la capacité de la protéine NS3 de BTV à activer la voie MAPK/ERK. En effet, nous avons démontré que NS3 a la capacité d’augmenter le niveau de phosphorylation des protéines kinases ERK1/2 mais également du facteur de traduction eIF4E. Cette fonction, qui semble être spécifique au BTV par rapport aux autres orbivirus, implique l’interaction de NS3 avec la protéine cellulaire BRAF, une protéine MAP3 kinase jouant un rôle majeur dans l’activation de la voie MAPK/ERK. L’activation cette voie par NS3 pourrait être un mécanisme de détournement de la traduction cellulaire au profit de celle du virus mais aussi constituer un élément de réponse pour expliquer l’hyper-inflammation observée dans le cas d’une infection par ce virus / Bluetongue virus (BTV) is the etiological agent of the bluetongue (BT) disease, a non-contagious arbovirus that affects a wide range of wild and domestic ruminants. It is transmitted by blood-feeding midges of the genus Culicoides. There are currently 27 serotypes described of BTV in the world that are distinguished by their differences in term of pathology/virulence and their capacity to infect and disseminate in their mammalian host(s). The first objective of my thesis project was to identify specific cellular interactions of serotype 8 and 27 to reveal new factors of pathogenicity/virulence and/or cross species barrier. To reach this goal, all the proteins encoded by BTV were used as baits to screen, by a high-throughput yeast two-hybrid (Y2H) approach, two complementary DNA libraries originating from hosts naturally infected by BTV : Culicoides and cattle. Therefore, 70 screens were performed to identify a hundred of new virus-host interactions and reveal an enrichment for four cellular processes : mRNA splicing, ribosomes, SUMOylation and apoptosis. This study allowed us to build the first interactome of BTV which continues through multiple biochemical and functional validations of the identified interactions. In parallel to this proteomics work, my second objective was to determine the impact of BTV on the MAPK/ERK pathway, a cellular pathway essential for cell proliferation and differentiation usually modulated during viral infections. In addition to its antagonist role on the type I interferon pathway, we have demonstrated the ability of BTV-NS3 to activate the MAPK/ERK pathway. Indeed, we have demonstrated that NS3 has the ability to increase the level of phosphorylation of ERK1/2 protein and the eIF4E translation factor. This function, which seems to be specific to BTV compared to other orbiviruses, involves the interaction of NS3 with BRAF cellular protein, a MAP3 kinase protein that plays a major role in the regulation of the MAPK/ERK pathway. These results could provide a better understanding of the molecular basis underlying the hijacking of the translation machinery to support virus replication but also constitute a hypothesis to explain the hyperinflammation observed in the BTV infection context

Virus de la fièvre catarrhale ovine

Interactions virus-Hôtes

Protéine NS3

Voie MAPK/ERK

Bluetongue virus

Virus-Host interactions

NS3 protein

MAPK/ERK signaling pathway