Avaliação da utilização do teste immunoblot recombinanre (RIBA) no diagnóstico da infecção pelo vírus da hepatite C (VHC) em doadores de sangue com anti-VHC reagente / Avaliação da utilização do teste immunoblot recombinanre (RIBA) no diagnóstico da infecção pelo vírus da hepatite C (VHC) em doadores de sangue com anti-VHC reagente

Pereira, Felicidade Mota

January 2011

Submitted by Ana Maria Fiscina Sampaio (fiscina@bahia.fiocruz.br) on 2012-07-18T19:50:32Z No. of bitstreams: 1 Felicidade Mota Pereira Avaliação da utilização do teste....pdf: 1069374 bytes, checksum: 6d5e3ef5ace61dfaf117c001157d5cec (MD5) / Made available in DSpace on 2012-07-18T19:50:32Z (GMT). No. of bitstreams: 1 Felicidade Mota Pereira Avaliação da utilização do teste....pdf: 1069374 bytes, checksum: 6d5e3ef5ace61dfaf117c001157d5cec (MD5) Previous issue date: 2011 / Fundação Oswaldo Cruz. Centro de Pesquisas Gonçalo Moniz. Salvador, Bahia, Brasil / A infecção pelo vírus da hepatite C (VHC) é comumente assintomática e apresenta uma elevada taxa de cronicidade, podendo evoluir para cirrose e carcinoma hepatocelular. O diagnóstico da hepatite C é realizado através da pesquisa de anticorpos pelo teste de ELISA (Enzyme Linked Immunosorbent Assay) e confirmado por testes suplementares, tais como o RIBA (Recombinant Immunoblot Assay) e westernblot e teste confirmatório, como a pesquisa do VHC-RNA. O objetivo deste trabalho foi avaliar a eficácia do RIBA no diagnóstico da infecção pelo VHC em doadores de sangue com anti-VHC reagente. Foram analisadas 102 amostras com resultado de anti-VHC reagente na HEMOBA, utilizando-se o teste anti-VHC Architect Abbott por quimioluminescência para detecção dos anticorpos anti-VHC, o RIBA III (CHIRON) como teste suplementar para as amostras anti-VHC reagentes e indeterminadas e a Reação em Cadeia da Polimerase (RT-PCR) convencional ou em tempo real (Amplicor Roche) para detecção do VHC-RNA. As amostras com VHC-RNA detectável foram genotipadas por hibridização reversa (LIPA; SIEMENS). Das 102 amostras analisadas no LACEN, 38,2% (39/102) foram reagentes, 57,8% (59/102) foram não reagentes e 3,9% (4/102) foram indeterminadas para o anti-VHC. Os resultados do RIBA foram 58,1% (25/43) positivos, 9,3% (4/43) negativos e 32,6% (14/43) indeterminados. Todas as amostras com resultado de RIBA indeterminado tiveram carga viral indetectável. As bandas predominantes nas amostras indeterminadas foram c33 e c22. Das amostras indeterminadas no RIBA, repetidas após seis meses com nova coleta, 20% (2/10) negativaram e 71,4% (10/14) permaneceram RIBA indeterminado. Destas, (8/10) continuaram indeterminadas com o mesmo padrão de bandas. O VHC-RNA foi realizado em todas as amostras do estudo (102) e foi detectável em apenas 22,5% (23/102). Todas as amostras com VHC-RNA detectável foram RIBA positivo e tinham índex maior que cinco na relação S/CO. Em apenas duas amostras que tiveram resultado de RIBA positivo, o VHC-RNA não foi detectado. As 23 amostras com VHC-RNA detectável foram genotipadas, sendo 78,3% (18/23) do genótipo 1, 17,4% (4/23) do genótipo 3 e 4,3% (1/23) do genótipo 2. A positividade do anti-VHC associou-se com o uso de droga intranasal (< 0,001), com drogas injetáveis (< 0,001)) e ocorrência de DST (< 0,05). Diante dos resultados encontrados, observa-se que o RIBA apresenta um elevado número de resultados indeterminados, sendo necessária a realização do VHC-RNA para a confirmação da infecção pelo VHC. Indivíduos com resultado de anti-VHC índex menor que cinco e resultado de RIBA indeterminado têm grande probabilidade de não apresentarem o VHC-RNA detectável e portanto, de não estarem infectados pelo VHC, mas devem ser acompanhados sorologicamente, de acordo com o critério médico. / The hepatitis C virus (HCV) infection is usually asymptomatic and has a high rate of chronicity, which may progress to cirrhosis and hepatocellular carcinoma. The hepatitis C diagnosis is realized by antibodies research using ELISA test (Enzyme Linked Immunosorbent Assay) and confirmed by additional serological tests, such as RIBA (Recombinant Immunoblot Assay) and westernblot, and confirmatory test, like HCV-RNA research. The objective of this study was to evaluate the RIBA efficacy in the diagnosis of HCV infection in blood donors with anti-HCV reagent. Were analyzed 102 samples with anti-HCV reagent in HEMOBA using the anti-HCV test Abbott Architect chemiluminescence for detection of anti-HCV antibodies, the RIBA III (Chiron) as a supplemental test for anti-HCV reactive and indeterminate samples and the Polymerase Chain Reaction test (RT-PCR) conventional or realtime (Roche Amplicor) for HCV-RNA detection. Samples with HCV-RNA detectable were genotyped by reverse hybridization (LIPA SIEMENS). Of the 102 samples analyzed in LACEN 38.2% (39/102) were positive, 57.8% (59/102) were negative and 3.9% (4 / 102) were indeterminate for anti-HCV. The RIBA results were 58.1% (25/43) positive, 9.3% (4 / 43) negative and 32.6% (14/43) indeterminate. All samples with indeterminate RIBA results had undetectable viral load. The predominant bands in the indeterminate RIBA samples were c33 and c22. Of the RIBA indeterminate samples, repeated after six months with a new collection, 20% (2 / 10) became negative and 71.4% (10/14) remained indeterminate. Of these, (8 / 10) remained undetermined with the same banding pattern. HCV-RNA was performed in all study samples (102) and was detectable in only 22.5% (23/102). All samples with detectable HCV-RNA were RIBA positive and had more than five in the ratio index S / CO. Only two samples had RIBA positive results with HCV-RNA not detected. The 23 samples with detectable HCV-RNA were genotyped, and 78.3% (18/23) were genotype 1, 17.4% (4 / 23) genotype 3 and 4.3% (1 / 23) genotype 2 . The anti-HCV positivity was associated with intranasal drug use (p<0.001), injectable drugs (p<0.001)) and STDs (p<0.05). Given the results, it is noted that the RIBA has a high number of indeterminate results, requiring the HCVRNA detection for HCV infection confirmation. Individuals with anti-HCV index below five, and indeterminate RIBA results are likely undetectable HCV-RNA and therefore are not infected with HCV, but must be serologically accompanied, according to medical criteria.

VHC

Anti-VHC

RIBA

VHC-RNA

HCV

Anti-HCV

RIBA

HCV-RNA

Characterization of Host Protein Interactions with HCV RNA : Implications in Viral Translation, Replication and Design of Antivirals

Bhat, Prasanna

January 2014

HCV genome is a positive sense single-stranded RNA containing a single open reading frame (ORF) flanked by untranslated regions (UTRs), 5’UTR and 3’UTR.Initiation of HCV RNA translation is mediated by internal ribosome entry site (IRES) present in 5’ UTR and this process is independent of cap-structure and requires only a small subset of canonical initiation factors. Hence, HCV IRES-mediated translation initiation mechanism is quite different from canonical cellular mRNA translation initiation. The IRES is organized into highly structured domains, namely domain II, III and IV. High affinity interactions between structured RNA elements present in the IRES and 40S ribosomal proteins mediate 40S recruitment to HCV IRES. However, details of the RNA elements and region of ribosomal proteins involved in these interactions are poorly understood. In recent days, RNA-based molecules like siRNAs, antisense RNAs and RNA decoys have become promising candidates for antiviral molecules. So designing short RNA molecules that target unique HCV translation initiation mechanism might help in developing novel anti-HCV molecules. HCV 3’UTR and antisense-5’ UTRs serve as sites for replication initiation to synthesize negative and positive strand and this process is catalyzed by NS5B protein (RNA-dependent RNA polymerase). Hence, host proteins binding to both 3’UTR and antisense-5’UTR might play important role in HCV replication. This puts the study of HCV RNA–host protein interactions and its role in viral translation and replication in perspective. Studying the HCV IRES-ribosomal protein S5 interactions and its role in HCV IRES function Previous studies from our laboratory have demonstrated that binding of La protein to GCAC close to initiator AUG enhances ribosomal protein S5 (RPS5) binding with HCV IRES and stimulates HCV translation. However in-detail study on HCV IRES–RPS5 interactions and its implication on HCV translation initiation were lacking. In present study computational modelling suggested that domain II and IV interact majorly with the beta hairpin structure and C-terminal helix of RPS5. Filter-binding and UV cross-linking studies with peptides derived from predicated RNA-binding region of RPS5 and mutational studies with RPS5 demonstrated that beta hairpin structure present in RPS5 is critical for IRES–RPS5 interaction. In parallel, we have studied RNA elements involved in the IRES–RPS5 interactions using deletions and substitution mutations, which we had generated on the basis of the computational model. Direct and competition UV cross-linking experiments performed with these IRES mutants and 40S subunits as a source of RPS5 suggested that structure and sequence of both domain II and IV play crucial role in IRES–RPS5 interactions. We further investigated the effect of these mutations on IRES activity by in vitro translation assay and found that all the mutants that were compromised in binding to RPS5 showed reduced IRES activity. Moreover, ribosome assembly experiments on HCV IRES demonstrated that mutations affecting IRES–RPS5 interactions result in reduction of 80S peak and slight increase of 48S peak. Since the 40S subunit had been previously reported to bind with HCV 3’UTR, we explored the possible interaction of RPS5 with HCV 3’UTR. From direct and competition UV cross-linking assays, we found that RPS5 does not bind to 3’UTR and the interaction is unique to IRES (5’UTR). Interestingly, partial silencing of RPS5 preferentially inhibited HCV translation with marginal effect on cap-dependent translation. Recently, reduction in 40S subunit abundance was reported to preferentially inhibit HCV translation. So, we investigated the abundance of free 40S subunit upon silencing RPS5 and results showed reduction in free 40S subunit level. So, we hypothesize that silencing of RPS5 reduces free 40S abundance to inhibit HCV translation. Taken together, results identified specific RNA elements present in HCV IRES that are critical for IRES–RPS5 interactions and demonstrated the role of these interactions in HCV translation initiation. Targeting ribosome assembly on HCV IRES using short RNAs Stem-loops (SL) IIIe and IIIf of HCV IRES are known to play an important role in stable IRES–40S complex formation. However interaction of these stem-loops with 40S subunit in isolation, independent of other regions of HCV IRES, was not studied. In this study, using electrophoretic mobility shift assay (EMSA) and sucrose gradient centrifugation experiments, we demonstrate that short RNA containing both SLIIIe and SLIIIf together (SLRef RNA) binds to 40S subunit, while short RNAs containing either of the stem-loops (SLRe RNA and SLRf RNA) lose their ability to interact with 40S subunit. Further, SLRef RNA inhibited ribosome assembly on the IRES, whereas SLRe and SLRf RNA failed to inhibit the same. Since SLRef RNA is derived from IRES, we investigated the interaction SLRef RNA with IRES–trans-acting factors (ITAFs). UV cross-linking of radio-labelled HCV IRES with cytoplasmic extract (S10) in presence of unlabelled short RNAs suggested possible interactions of La and RPS5 proteins with SLRef RNA. Studies with recombinant La protein and RPS5 further confirmed their interaction with SLRef RNA. Ex vivo experiments with HCV bicistronic RNA suggested that SLRef RNA specifically inhibits HCV translation. In addition to that SLRef RNA inhibited the HCV RNA synthesis in JFH1 HCV cell culture system. Moreover, specific delivery of pSUPER construct expressing SLRef RNA (pSUPERSLRef) to mice liver along with HCV bicistronic construct using Sendai virosomes demonstrated specific inhibition of HCV IRES activity by SLRef RNA in mice hepotocytes. In summary, short RNA derived from HCV IRES was shown to bind with La protein and RPS5 to inhibit ribosome assembly on HCV IRES. Further, targeted delivery of SLRef RNA into mice liver using Sendai virosome resulted in inhibition of HCV RNA translation in mice hepatocytes. Characterizing the interaction of host proteins with antisense-5’UTR and 3’UTR and its significance in HCV replication Antisense-5’UTR and 3’UTR of HCV RNA are the sites of replication initiation. Hence, host proteins binding to both of these RNA sequences are potential candidates for regulation of HCV replication. In this study, we have investigated host proteins binding with antisense-5’UTR and 3’UTRof HCV RNA by performing UV cross-linking experiments with cytoplasmic extract of Huh7 cells, and found that a protein of ~42kDa protein interacts with both antisense-5’UTR and 3’UTR. Based on earlier report, we predicted that the ~42kDa protein could be hnRNPC1/C2. Results of UV cross-linking followed by immuno pull-down (UV-IP assay) and UV cross-linking experiments with recombinant hnRNPC1 protein confirmed that hnRNPC1 indeed binds to antisense-5’UTR and 3’UTR. Further, filter-binding experiments demonstrated that hnRNPC1 protein binds to 3’UTR with higher affinity compared to antisense-5’UTR. Subsequently, we investigated the regions within 3’UTR and antisense-5’UTR that interact with hnRNPC1protein. Results demonstrated that poly-(U/UC) region of 3’UTR and region containing stem-loops SL-IIIa’, SL-IIIb’, SL-IIIcdef’ and SL-IV’ in antisense-5’UTR were mostly involved in the interaction. Interestingly, studies with confocal microscopy suggested that hnRNPC1/C2 re-localizes from nucleus to cytoplasm upon JFH1 infection, which might in turn influence HCV replication. To investigate the role of hnRNPC1/C2 in HCV replication, partial silencing of hnRNPC1/C2 was performed in HCV cell culture system (JFH1) and results demonstrated that hnRNPC1/C2 is critical for HCV RNA synthesis. However experiments with HCV bicistronic RNA suggested that hnRNPC1/C2 does not play significant role in HCV translation. Taken together, results suggested that hnRNPC1/C2 re-localizes from nucleus to cytoplasm upon JFH1 infection and binds to HCV 3’UTR and antisense- 5’UTR to regulate HCV replication. In summary, this thesis provides novel insights into the interaction of host proteins with HCV RNA and its significance in HCV translation and replication. Inhibition of the ribosome assembly and consequent reduction in HCV translation with mutations interfering with IRES–RPS5 interaction, reported in the present study, unfolds the novel role of this interaction in HCV translation. Further, results obtained in the present study with a small RNA SLRef, derived from HCV IRES, provide proof of concept for using short RNAs to specifically inhibit HCV translation. In addition, studies of interaction of hnRNPC1/C2 with HCV RNA and its re-localization upon HCV infection sheds light on the significance of host–virus interaction in viral RNA replication.

Hepatitis C Virus (HCV) RNA

HCV RNA Host Protein Interactions

HVC Infection

HCV RNA Translation

HCV Genomes

HCV Replication

HCV IRES RNA

HCV IRES

HCV Replication

HCV-IRES

HCV-IRES

HCV RNA

Virus-Host Protein Interactions

Viral RNA Replication

Microbiology and Cell Biology

From Screening to Therapy: Anti-HCV Screening and Linkage to Care in a Network of General Practitioners and a Private Gastroenterology Practice

Petroff, David, Bätz, Olaf, Jedrysiak, Katrin, Lüllau, Anja, Kramer, Jan, Möller, Hjördis, Heyne, Renate, Jäger, Burkhard, Berg, Thomas, Wiegand, Johannes

08 May 2023

(1) Background: Low rates of hepatitis C virus (HCV) diagnosis and sub-optimal linkage to care constitute barriers toward eliminating the infection. In 2012/2013, we showed that HCV screening in primary care detects unknown cases. However, hepatitis C patients may not receive further diagnostics and therapy because they drop out during the referral pathway to secondary care. Thus, we used an existing network of primary care physicians and a practice of gastroenterology to investigate the pathway from screening to therapy. (2) Methods: HCV screening was prospectively included in a routine check-up of primary care physicians who cooperated regularly with a private gastroenterology practice. Anti-HCV-positive patients were referred for further specialized diagnostics and treatment if indicated. (3) Results: Seventeen primary care practices screened 1875 patients. Twelve individuals were anti-HCV-positive (0.6%), six of them reported previous antiviral HCV therapy, and one untreated patient was HCV-RNA-positive (0.05% of the population). None of the 12 anti-HCV-positive cases showed up at the private gastroenterology practice. Further clinical details of the pathway from screening to therapy could not be analyzed. (4) Conclusions: The linkage between primary and secondary care appears to be problematic in the HCV setting even among cooperating partners, but robust conclusions require larger datasets.

info:eu-repo/classification/ddc/570

ddc:570

The Impact of Imprecision in HCV Viral Load Test Results on Clinicians’ Therapeutic Management Decisions and on the Economic Value of the Test

Madej, Roberta M.

01 January 2013

Clinical laboratory test results are integral to patient management. Important aspects of laboratory tests’ contributions are the use of the test information and the role they have in facilitating efficient and effective use of healthcare resources. Methods of measuring those contributions were examined using quantitative HCV RNA test results (HCV VL) in therapeutic management decisions as a model. Test precision is important in those decisions; therefore, the clinical use was evaluated by studying the impact that knowledge of inherent assay imprecision had on clinicians’ decisions. A survey describing a simulated patient at a decision point for HCV triple-combination therapy management was sent to 1491 hepatology clinicians. Participants saw HCV RNA results at five different levels and were asked to choose to: continue therapy, discontinue therapy, or repeat the test. Test results were presented both with and without the 95% confidence intervals (CIs). Three of the VLs had CIs that overlapped the therapeutic decision level. Participants saw both sets of results in random order. Demographics and practice preferences were also surveyed. One-hundred-thirty-eight responses were received. Adherence to clinical guidelines was demonstrated in self-reported behaviors and in most decisions. However, participants chose to repeat the test up to 37% of the time. The impact of the knowledge of assay imprecision did not have a statistically significant effect on clinicians’ decisions. To determine economic value, an analytic decision-tree model was developed. Transition probabilities, costs, and Quality of Life values were derived from published literature. Survey respondents’ decisions were used as model inputs. Across all HCV VL levels, the calculated test value was approximately $2600, with up to $17,000 in treatment-related cost savings per patient at higher HCV VLs. The test value prevailed regardless of the presence or absence of CIs, and despite repeat testing. The calculated value in cost savings/patient was up to 100 times the investment for HCV VL testing. Laboratory tests are investments in efficient uses of healthcare resources. Proper interpretation and use of their information is integral to that value. This type of analysis can inform institutional decisions and higher level policy discussions.

HCV viral load

HCV RNA

Test imprecision

HCV therapeutic management decisions

Health economics

Value of information

Economic value

Laboratory tests

Medicine and Health Sciences

Host-Pathogen Interactions in Hepatitis C Virus Infection : Deciphering the Role of Host Proteins and MicroRNAs

Shwetha, S

January 2015

Host-pathogen interactions in Hepatitis C Virus infection: Deciphering the role of host proteins and microRNAs Hepatitis C virus (HCV) is a positive sense single stranded RNA virus belonging to the Hepacivirus genus of the Flaviviridae family. HCV genome consists of a single open reading frame flanked by highly structured 5‟ and 3‟ untranslated regions (UTRs) at both ends. Unlike cellular mRNAs, HCV RNA translation is independent of the cap structure and is mediated by an internal ribosomal entry site (IRES) present in the 5‟UTR. HCV replication begins with the synthesis of a complementary negative-strand RNA using the positive strand RNA genome as a template catalyzed by the NS5B RNA dependent RNA polymerase (RdRp). The de novo priming of HCV RNA synthesis by NS5B occurs at the very end of the 3‟UTR. The 3‟UTR is organized into highly structured regions namely the variable region, poly U/UC region and the 3‟X region. These regions contain cis-acting elements that determine the efficiency of viral replication. In addition, the interaction of trans-acting factors with the 3‟ UTR is also important for regulation of HCV replication. HCV 3‟UTR interacts with several cellular proteins such as the human La protein, polypyrimdine tract binding protein (PTB), poly (rC)-binding protein 2 (PCBP2) and Human antigen R (HuR). However, the molecular basis of regulation of viral replication by these proteins is not well understood. Many proteins that are hijacked by HCV as well as other cytoplasmic RNA viruses, such as La, PCBP2, HuR and PTB are RNA binding proteins (RBPs). They are involved in post transcriptional regulation of cellular gene expression. Thus the subversion of these proteins by the virus can affect their normal physiological functions. In addition to proteins, recent reports also describe the involvement of non-coding RNAs including microRNAs (miRNA) and long non coding RNAs (lncRNA) in HCV infection. miRNAs can either directly bind to the HCV genome and regulate its life cycle or indirectly modulate the expression of host proteins required by the virus. miRNAs that are differentially regulated in virus infected tissues or body fluids of infected patients can also serve as biomarkers for diagnosis of various stages of the disease. Hence, it was planned to study the role of host proteins and miRNAs in the HCV life cycle and pathogenesis to have novel insights into the biology of HCV infection. Riboproteomic studies have identified several host proteins that directly interact with the 5‟ and/or 3‟UTRs of the HCV RNA. One of the RNA binding proteins that predominantly interact with the 3‟UTR of HCV RNA was found to be HuR. In the present study, we have extensively characterized the interaction between HuR and HCV 3‟UTR and studied its functional implications in HCV life cycle along with other host factors. Characterizing the HCV 3’UTR–HuR interaction and its role in HCV replication HuR is a ubiquitously expressed member of the Hu family which shuttles between the nucleus and cytoplasm in response to stress. Whole genome siRNA knockdown and other studies have suggested that HuR is essential for HCV replication. However, the molecular mechanism of its involvement in this process was not clear. We observed that siRNA mediated knockdown of HuR reduces the HCV RNA and protein levels. Immunofluorescence studies indicated that HuR relocalizes from the nucleus to the cytoplasm in HCV infected cells. Through confocal microscopy and GST pulldown assays, we have demonstrated that HuR co localizes with the viral polymerase, NS5B and directly interacts with the NS5B protein. Membrane flotation assays showed that HuR is present in the detergent resistant membrane fractions which are the active sites of HCV replication. In addition to the interaction of HuR with the viral protein NS5B, we also characterized its interaction with the viral RNA. Direct UV cross linking assays and UV cross linking immunoprecipitation assays were performed to demonstrate the interaction of HuR with the HCV 3‟UTR. The RRM3, hinge region and RRM1 of HuR were found to be important for binding. Further, we observed that HuR competes with PTB for binding to the 3‟UTR when cytoplasmic S10 extracts or recombinant proteins were used in UV cross linking assays. In contrast, the addition of HuR facilitated the binding of La protein to the HCV 3‟UTR in the above assays. Competition UV cross linking assays indicated that both HuR and PTB bind to the poly U/UC region of the 3‟UTR while La binds to the variable region. HuR and La showed higher affinities for binding to the 3‟UTR as compared to PTB in filter binding assays. Since HuR and PTB interact with the same region on the 3‟UTR and HuR showed ~4 fold higher affinity for binding, it could displace PTB from the 3‟UTR. Next, we investigated the roles of HuR, PTB and La in HCV translation and replication in cell culture using three different assay systems, HCV sub genomic replicon, HCV bicistronic SGR-JFH1/Luc replicon as well as the infectious HCV full length RNA (JFH1). Results clearly indicated that HuR and La are positive modulators of HCV replication. Interestingly, PTB facilitated HCV IRES mediated translation but appeared to have a negative effect on HCV replication. The positive effectors, HuR and La showed significant co localization with one another in the cytoplasm in immunofluorescence studies. GST pulldown and coimmunoprecipitation experiments indicated protein-protein interactions between HuR and La but not between HuR and PTB. Through quantitative IP-RT assays, we demonstrated that the overexpression of HuR in HCV RNA transfected cells increases the association of La with the HCV RNA while HuR knockdown reduces the association of La with the HCV RNA. Previous studies in our laboratory have shown that La helps in HCV genome circularization. The addition of HuR significantly increased La mediated interactions between the 5‟UTR and the 3‟UTR of HCV RNA as monitored by 5‟-3‟ co precipitation assays, suggesting a possible mechanism by which cooperative binding of HuR and La could positively regulate HCV replication. Taken together, our results suggest a possible interplay between HuR, PTB and La in the regulation of HCV replication. Studying the role of HuR- associated cellular RNAs in HCV infection HuR belongs to the category of mRNA turnover and translation regulatory proteins (TTR-RBPs), which are capable of triggering rapid and robust changes in cellular gene expression. HuR plays a role in several post transcriptional events such as mRNA splicing, export, stability and translation. In the present study, we have investigated the possible consequences of relocalization of HuR on cellular processes in the context of HCV infection. We observed that 72h post transfection of infectious HCV-JFH1 RNA, there is an increase in the mRNA levels of some of the validated targets of HuR including the vascular endothelial growth factor A (VEGFA), dual specificity phosphatise 1 (MKP1) and metastasis - associated lung adenocarcinoma transcript (MALAT1). IP-RT assays demonstrated that the association of HuR with VEGFA and MKP1 was higher in HCV-JFH1 RNA transfected cells as compared to the mock transfected cells indicating that increase in HuR association could probably help in stabilization of these mRNAs. Interestingly, we observed that the association of HuR with the lncRNA MALAT1 decreases in the presence of HCV RNA, while its RNA levels increased. Earlier it has been reported that MALAT1 interacts with HuR and was predicted to interact with La. We confirmed the interaction of both HuR and La proteins with MALAT1 RNA in vitro and in the cell culture system. Results from our time course experiments suggest that relocalization of HuR and La upon HCV infection might decrease their association with the nuclear retained MALAT1 RNA leading to significant reduction in MALAT1 RNA levels at the initial time points. However at later time points, MALAT1 was found to be unregulated through activation of the Wnt/beta-catenin pathway as demonstrated using a chemical inhibitor against β-catenin. Since MALAT1 is a known regulator of epithelial mesenchymal transition (EMT) and metastasis, we further studied the physiological consequence of the observed increase in MALAT1 levels upon HCV infection. Cell migration and cell invasion studies suggested that the knockdown of MALAT1 led to the inhibition of HCV- triggered wound healing and matrigel invasion and also rescued the down regulation of E-Cadherin protein levels, an EMT marker. Our study highlights the importance of the lncRNA, MALAT1 in HCV infection and suggests its possible involvement in HCV induced HCC. Investigating the role of miRNAs in HCV pathogenesis and replication miRNAs can also regulate HCV infection and pathogenesis in multiple ways. It is known that under disease conditions, there is aberrant expression of intracellular as well as circulating miRNAs. We have investigated the expression profile of 940 human miRNAs in HCV infected patient serum samples to identify the differentially regulated miRNAs. miR-320c, miR-483-5p and the previously reported miR-125b were found to be upregulated in the serum of cirrhotic and non-cirrhotic HCV infected patient serum samples. All three miRNAs were also unregulated in the cell culture supernatant of HCV infected cells as well as within the HCV infected cells. miR-483-5p was specifically enriched in the exosomes isolated from patient serum samples. Knockdown of miR-320c and miR-483-5p did not have significant effect on HCV replication while knockdown of miR-125b affected HCV replication through regulation of one of its target genes, HuR. We observed that with time, miR-125b levels in HCV-JFH1 RNA transfected cells increase while the HuR protein levels decrease. Using luciferase reporter constructs, we demonstrated that the decrease in HuR protein levels is indeed mediated by miR-125b. Mutations in the target site of miR-125b in the HuR 3‟UTR prevented the down regulation of luciferase activity. Next we tested the effect of silencing miR-125b on HCV replication. Knockdown of miR-125b prevented the reduction in HuR protein levels but with no significant effect on HCV replication. It appeared that the HuR protein already present in the cytoplasm could be sufficient to support HCV replication. Hence similar experiments were carried out in cells depleted of HuR using either siRNA against HuR or a chemical inhibitor of nucleocytoplasmic transport of HuR, Leptomycin B. We observed that when the intracellular levels of HuR are reduced using either of the two approaches, there is a decrease in HCV replication. This is in accordance with the results obtained in the first part of the thesis. However when miR-125b was silenced in HuR depleted cells, we noticed an upregulation in the HuR protein levels by western blot analysis and a consequent increase in HCV RNA levels as quantified by qRT-PCR. From our findings, we can conclude that miR-125b mediated regulation of HuR plays an important role in HCV replication. We hypothesize that this could be a cellular response to HCV infection to which the virus responds by inducing protein relocalization. Altogether, these studies outline the importance of host factors including cellular proteins and non-coding RNAs in the regulation of HCV life cycle and pathogenesis. Results reveal the mechanistic insights into how HCV infection triggers host defense pathways, which are evaded by the virus by counter strategies.

Hepatitis C Virus Infection

Micro RNAs - HCV Infection

RNA Viruses

Hepatitis C Virus Replication

Hepatitis C Virus (HCV) RNA Binding

Viral Proteins

Host Proteins-HCV Infection

Hepatitis C Virus Pathogenesis

Hepatitis C Virus Diagnosis and Therapy

HCV-RNA Translation

HCV - miRNA

HCV Replication

HCV IRES

HCV Pathogenesis

Microbiology and Cell Biology