Host and viral factors that determine the clinical outcome of hepatitis C virus genotype 3a infection

Humphreys, Isla Sheree

January 2011

HCV infects 170 million persons worldwide and is a serious global health problem. Genotype-3a is the dominant genotype in newly diagnosed infections within the UK and has a high response rate to interferon therapy, with up to 70% patients achieving a sustained virological response (SVR). The reason(s) for this are unknown; therefore the aim was to assess host and viral factors that determine treatment outcome of subtype-3a infection. Full-length subtype-3a viral sequence analysis identified 2 novel regions of hypervariability within E2 - HVR495 and HVR575, that are subject to positive selection pressure. A 5 amino-acid insertion found only in subtype-3a and a putative glycosylation site were contained within HVR575. These data suggest that HVR495 and HVR575 may serve as major antigenic sites in subtype-3a HCV infection. Successful treatment of chronic subtype-3a infection was not associated with pre-treatment quasispecies diversity and complexity, PePHD, HVR495 or HVR575 sequence. Different patterns of quasispecies variation were observed in patients that failed treatment. Subtype-3a specific CD8+ T-cell responses in chronic infection target non-structural proteins, in contrast to pre-dominant genotype-1 core-specific CD4+ T-cell responses. SVR was associated with a decline in subtype-3a specific and non-specific T-cell responses, and also total lymphocyte counts, which all recovered after treatment. These data do not support the theory that clearance of subtype-3a is associated with an enhancement of antiviral T-cell responses. Overlapping peptides detected a greater number of subtype-3a T-cell responses compared with peptides representing putative predicted CD8 epitopes. Therefore subtype-3a HCV is distinct from genotype-1 in terms of genome sequence, effect of treatment on quasispecies and subtype-3a specific T-cell responses, further emphasising the importance in understanding this distinct subtype.

616.9

Analyse biochimique et structurale des interactions multiples des oncoprotéines E6 produites par les papillomavirus / Biochemical and structural analysis of multiple interactions of the oncoprotein E6 produced by papillomavirus

Ould Babah, Khaled

21 September 2012

L’ oncoprotéine E6 - qui joue un rôle crucial dans le processus d’oncogenèse induit par les papillomavirus a longtemps résisté à toute analyse. Depuis 1995 l’équipe Oncoprotéines a concentré ses efforts sur cette problématique. Ce qui a permis la résolution par RMN de la structure du domaine C-terminal de E6 en 2006. C’est dans ce cadre que j’ai commencé ce Doctorat en 2008, avec objectif de continuer la quête de données structurales sur E6 tout en acquérant des informations sur ses modes d’interaction avec ses cibles cellulaires. Les travaux de cette thèse ont permis l’obtention de la structure cristallographique de E6 (HPV16) en complexe avec un peptide de E6AP, en utilisant une approche originale capable de produire des protéines E6 stables et solubles. Cette structure constitue la première information structurale publiée sur des protéines E6 entières, attendue depuis plus de 20 ans par la communauté scientifique. J’ai effectué également durant cette thèse une analyse du système d’interaction de la protéine E6 basée sur une large étude d’interaction entre les protéines E6 (7 types) et 93 peptides porteurs de motif LxxLL. / The oncoprotein E6 which plays a crucial role in the process of carcinogenesis induced by HPV, has withstood all tests for a long time. Since 1995 the team « oncoproteins » has focused on this issue. This allowed the resolution of structure of C-terminal domain of E6 by NMR analysis, in 2006. In this context, i started my PhD in 2008 with aim to continue the pursuit of structural data on E6 while also acquiring information about its modes of interaction with its cellular targets. The work of this thesis has enabled us to obtain the crystal structure of E6 (HPV16) in complex with a peptide of E6AP, using an original approach capable of producing stable and soluble proteins E6. This structure represents the first structural information on full-length E6, awaited for over 20 years by the scientific community. I also performed during this thesis an analysis of the interaction system of the E6 protein based on a large study of interaction between proteins E6 (7 types) and 93 peptides bearing LxxLL motif.

Papillomavirus

Oncoprotéines E6

Cancer du col de l’utérus

Cristallographie

Optimisation de production de protéines

Interaction protéique

Protéine E2

Protéine Brd4

Papillomavirus

E6 oncoprotéines

Cervial cancer

Crystallography

Optimization of protein production

Protein interactions

E2 protein

Brd4 protein

571.4

Characterisation of Monoclonal Antibodies and Small Molecule Inhibitors as Hepatitis C Virus Entry Inhibitors

Bose, Mihika

January 2016

Hepatitis C virus (HCV) represents a global health threat. HCV is a blood-borne positive-strand RNA virus belonging to the Flaviviridae family that infects ~160 million people worldwide. About 70% of infected individuals fail to clear the virus and subsequently develop chronic hepatitis, frequently leading to liver cirrhosis and in some cases hepatocellular carcinoma. Therapeutic options for HCV infection are still limited and a protective vaccine is not yet available. Currently available therapies include administration of pegylated alpha interferon in combination with ribavirin. The recently approved protease inhibitors Boceprevir and Telaprevir are also included in the treatment regimen. However, limitations to the treatment with direct-acting antivirals (DAAs) are associated with severe side effects and low sustained virological response (SVR) rates that vary depending on the virus and host genotype. The replication step of the viral life cycle is mostly targeted by majority of DAAs. Recent findings have suggested that a combination of entry inhibitors together with DAAs exhibit a synergistic effect in the treatment of HCV. Therefore, identification of efficient HCV entry inhibitors is of high priority In vitro studies have shown that HCV attachment and subsequent entry into the host cells is mediated by E1 and E2 viral envelope proteins. HCV entry requires interaction with a number of receptors which include CD81, scavenger receptor B1 (SR-B1) and the tight junction proteins, claudin 1 (CLDN1) and occludin (OCLN). Since the E2 glycoprotein is reported to interact directly with cellular receptors, it is an attractive target for neutralisation. The present study focuses on the establishment and characterisation of entry inhibitors as antivirals for HCV. The thesis is presented in three chapters: Chapter 1- ‘Introduction’, provides a brief overview on HCV genotypes, genome organisation, life cycle including details on the entry process and therapies used for the treatment of HCV. Chapter 2 describes the generation of monoclonal antibodies (mAbs) against HCV envelope proteins as potent anti-viral agents for the prevention of HCV infection. Data on the identification and characterization of the neutralizing epitopes of HCV envelope proteins have been presented. Chapter 3 includes isolation of entry inhibitors of HCV from natural sources and identification and characterization of the active components exhibiting antiviral property. A number of studies have reported the role of neutralizing antibodies in the course of HCV infection and emerging data suggest protective effect of antibodies against HCV infection. Most of the ongoing studies are based on HCV genotype 1a which is prevalent globally. However in India, the prevalent genotype is 3a. Therefore, we established a panel of mAbs against HCV-LPs comprising of core-E1-E2 derived from genotype 3a as described in chapter 2. HCV-LP based system has been used in this study since it mimics the biophysical conformation, morphology and antigenic properties of the native virion and represents a model system for studies on viral binding and entry. MAbs were characterised and analyzed for their ability to prevent viral binding and entry into host cells. Three mAbs namely E3D8, H6D3 and A10F2 were identified to recognize the E2 viral glycoprotein which significantly inhibited HCV-LP binding to Huh7 cells in vitro. The neutralizing epitopes corresponding to the mAbs were identified using overlapping truncated fragments and synthetic peptides of the E2 protein. Our experiments suggest that the epitopes recognised by the inhibitory mAbs are unique and different from those reported till now. The synergistic effect of a combination of mAbs on virus neutralization has shown promising results for treatment of viral infections. Since in the present study the epitopes recognised by the mAbs are non-overlapping, we went ahead to determine whether a combination of these mAbs would enhance the ability to block HCV-LP binding. Indeed, flow cytometry and fluorescence microscopy studies revealed that a combination of the antibodies efficiently blocked the binding of HCV-LP to human hepatoma cells. More importantly and of relevance is the observation that the mAbs in combination inhibited viral infection (JFH1 strain) and replication in permissive human hepatocytes as determined by real time RT-PCR. Phytochemicals present in plants have been considered as conducive for prevention of several viral infections and are found to be promising antiviral agents. Natural products which are biologically active disclose drug-like properties since they are small molecules and can be easily metabolised and absorbed by the body. In our study as described in chapter 3, we evaluated extracts from Indian medicinal plants and fruits which are known to have hepato-protective effect, for natural potent attachment and entry inhibitors for HCV. Flow cytometric analysis suggested that the root extract of the herb Boerhavia diffusa and fruit extract of Prunus domestica exhibited high antiviral activity by inhibiting the binding of Hepatitis C virus like particles (HCV-LPs) to the human hepatoma cells. We went on to isolate, identify and confirm the active principles to be Boeravinone H, a dehydrorotenoid, (from Boerhavia diffusa) and Rutin, a flavonoid, (from Prunus domestica) by LC-ESI-MS, NMR, UV and IR spectral analysis. Our study revealed that the compounds block the attachment as well as entry step probably by targeting the viral particle. We also assessed the efficiency of these small molecules (Boeravinone H and Rutin) to inhibit HCV negative strand synthesis post entry by real time RT-PCR. Results suggest significant inhibition of viral entry and infection in the HCV cell culture (ex vivo). To our knowledge it is the first report on Boeravinone H and Rutin as entry inhibitor for HCV. In conclusion, our findings support the potential of employing a cocktail of neutralizing mAbs and antiviral agents from natural source in the management of HCV infection.

Hepatitis C Virus

Monoclonal Antibodies

Hepatitis C Virus Infection

Hepatitis C Virus Entry

HCV Small Molecule Inhibitors

Hepatitis C Virus Treatment

HCV Treatment

Rutin

Hepatitis C Virus E2 Protein

Biochemistry