New therapies for chronic hepatitis C virus infection

Form confers function: Case of the 3’X region of the hepatitis C virus genome

At the 3’ end of genomic hepatitis C virus (HCV) RNA there is a highly conserved untranslated region, the 3’X-tail, which forms part of the 3’UTR. This region plays key functions in regulation of critical processes of the viral life cycle. The 3’X region is essential for viral replication and infectivity. It is also responsible for regulation of switching between translation and transcription of the viral RNA. There is some evidence indicating the contribution of the 3’X region to the translation efficiency of the viral polyprotein and to the encapsidation process. Several different secondary structure models of the 3’X region, based on computer predictions and experimental structure probing, have been proposed. It is likely that the 3’X region adopts more than one structural form in infected cells and that a specific equilibrium between the various forms regulates several aspects of the viral life cycle. The most intriguing explanations of the structural heterogeneity problem of the 3’X region came with the discovery of its involvement in long-range RNA-RNA interactions and the potential for homodimer formation. This article summarizes current knowledge on the structure and function of the 3’X region of hepatitis C genomic RNA, reviews previous opinions, presents new hypotheses and summarizes the questions that still remain unanswered.

Statistical linkage analysis of substitutions in patient-derived sequences of genotype 1a hepatitis C virus nonstructural protein 3 exposes targets for immunogen design

Chronic hepatitis C virus (HCV) infection is one of the leading causes of liver failure and liver cancer, affecting around 3% of the world's population. The extreme sequence variability of the virus resulting from error-prone replication has thwarted the discovery of a universal prophylactic vaccine. It is known that vigorous and multispecific cellular immune responses, involving both helper CD4(+) and cytotoxic CD8(+) T cells, are associated with the spontaneous clearance of acute HCV infection. Escape mutations in viral epitopes can, however, abrogate protective T-cell responses, leading to viral persistence and associated pathologies. Despite the propensity of the virus to mutate, there might still exist substitutions that incur a fitness cost. In this paper, we identify groups of coevolving residues within HCV nonstructural protein 3 (NS3) by analyzing diverse sequences of this protein using ideas from random matrix theory and associated methods. Our analyses indicate that one of these groups comprises a large percentage of residues for which HCV appears to resist multiple simultaneous substitutions. Targeting multiple residues in this group through vaccine-induced immune responses should either lead to viral recognition or elicit escape substitutions that compromise viral fitness. Our predictions are supported by published clinical data, which suggested that immune genotypes associated with spontaneous clearance of HCV preferentially recognized and targeted this vulnerable group of residues. Moreover, mapping the sites of this group onto the available protein structure provided insight into its functional significance. An epitope-based immunogen is proposed as an alternative to the NS3 epitopes in the peptide-based vaccine IC41.

IMPORTANCE

Despite much experimental work on HCV, a thorough statistical study of the HCV sequences for the purpose of immunogen design was missing in the literature. Such a study is vital to identify epistatic couplings among residues that can provide useful insights for designing a potent vaccine. In this work, ideas from random matrix theory were applied to characterize the statistics of substitutions within the diverse publicly available sequences of the genotype 1a HCV NS3 protein, leading to a group of sites for which HCV appears to resist simultaneous substitutions possibly due to deleterious effect on viral fitness. Our analysis leads to completely novel immunogen designs for HCV. In addition, the NS3 epitopes used in the recently proposed peptide-based vaccine IC41 were analyzed in the context of our framework. Our analysis predicts that alternative NS3 epitopes may be worth exploring as they might be more efficacious.

Inhibition of hepatitis C virus replication by chloroquine targeting virus-associated autophagy

BACKGROUND

Autophagy has been reported to play a pivotal role on the replication of various RNA viruses. In this study, we investigated the role of autophagy on hepatitis C virus (HCV) RNA replication and demonstrated anti-HCV effects of an autophagic proteolysis inhibitor, chloroquine.

METHODS

Induction of autophagy was evaluated following the transfection of HCV replicon to Huh-7 cells. Next, we investigated the replication of HCV subgenomic replicon in response to treatment with lysosomal protease inhibitors or pharmacological autophagy inhibitor. The effect on HCV replication was analyzed after transfection with siRNA of ATG5, ATG7 and light-chain (LC)-3 to replicon cells. The antiviral effect of chloroquine and/or interferon-alpha (IFNalpha) was evaluated.

RESULTS

The transfection of HCV replicon increased the number of autophagosomes to about twofold over untransfected cells. Pharmacological inhibition of autophagic proteolysis significantly suppressed expression level of HCV replicon. Silencing of autophagy-related genes by siRNA transfection significantly blunted the replication of HCV replicon. Treatment of replicon cells with chloroquine suppressed the replication of the HCV replicon in a dose-dependent manner. Furthermore, combination treatment of chloroquine to IFNalpha enhanced the antiviral effect of IFNalpha and prevented re-propagation of HCV replicon. Protein kinase R was activated in cells treated with IFNalpha but not with chloroquine. Incubation with chloroquine decreased degradation of long-lived protein leucine.

CONCLUSION

The results of this study suggest that the replication of HCV replicon utilizes machinery involving cellular autophagic proteolysis. The therapy targeted to autophagic proteolysis by using chloroquine may provide a new therapeutic option against chronic hepatitis C.

Screening for genetic heterogeneity in the interferon sensitivity determining region of the hepatitis C virus genome by polymerase chain reaction with melting curve analysis

BACKGROUND

Although mutations in the interferon (IFN) sensitivity determining region (ISDR) of hepatitis C virus (HCV) have been reported to be useful as a predictive viral factor for IFN therapy in patients infected with HCV-1b, such laboratory research has not been favorably translated into the clinic. To promote such translation, we attempted the establishment of a rapid and simple polymerase chain reaction (PCR) combined with melting curve analysis (MCA) to screen for mutations in the ISDR and for the monitoring of HCV quasispecies.

METHODS

A PCR-MCA protocol was established using in-house primers and hybridization probes designed according to the results of direct sequencing of 34 HCV-1b samples. Then, the performance of PCR-MCA was verified by comparing with mutation profiles obtained by direct sequencing and sequencing after cloning.

RESULTS

The MCA assay revealed that melting temperature (Tm) was inversely correlated with the number of nucleotide (nt) and amino acid substitutions in the ISDR deduced on the basis of the results of direct sequencing. A boundary Tm of 58.0 degrees C allowed us to discriminate HCV genomes into two groups: one with a Tm >58.0 degrees C had no or a low number of nt substitutions, while the other genomes with a Tm <58.0 degrees C had a high number of nt substitutions, corresponding to wild-type in the former and mutant-type in the latter in respect of a clinical setting for IFN therapy. Moreover, this MCA assay provided precise discrimination of Tm between clones, reflecting the degree of the genetic complexity of HCV genomes.

CONCLUSIONS

This study indicates that the MCA assay is useful to rapidly and simply screen the mutational status of the ISDR of HCV, as well as in using the ISDR as one of the targets for discriminating the genetic complexity of HCV genomes. The MCA assay could also be applicable as a convenient and useful screen of the genetic heterogeneity of clones relating to HCV quasispecies.

An accelerated vaccine schedule with a poly-antigenic hepatitis C virus MVA-based candidate vaccine induces potent, long lasting and in vivo cross-reactive T cell responses

We designed and evaluated in HLA-class I transgenic mouse models a hepatitis C virus (HCV) T cell-based MVA vectored vaccine expressing three viral antigens known to be targets of potent CD8+- and CD4+-mediated responses. An accelerated (3 week-based) vaccination induced specific CD8+ T cells harboring two effector functions (cytolytic activity - both in vitro and in vivo- and production of IFNgamma) as well as specific CD4+ T cells recognizing all three vaccine antigens. Responses were long lasting (6 months), boostable by a fourth MVA vaccination and in vivo cross-reactive as demonstrated in a surrogate Listeria-based challenge assay. This candidate vaccine has now moved into clinical trials.

Reasons why patients infected with chronic hepatitis C virus choose to defer treatment: do they alter their decision with time?

This study was designed to determine the percentage of treatment-naïve patients infected with chronic hepatitis C virus who make an informed choice to forego (defer) treatment with pegylated interferon regimens in the absence of any medical, psychosocial, or other contraindications, and to reassess their decision by using a questionnaire at least 1 year later. Patient charts dating from 2001 were retrieved and retrospectively analyzed for the following data: patient age, gender, race, hepatitis C viral load, genotype, liver biopsy results, hepatic imaging results, peak alanine aminotransferase (ALT) levels, comorbid conditions, source of infection, estimated duration of infection, and reasons given by the patient for declining pegylated interferon-based treatment at the time of their consultation. A questionnaire survey sought to determine their satisfaction with their initial decision. Of 446 patient charts reviewed, 280 patients were treatment-naïve and were judged to have no contraindications to receiving interferon-based therapy. Of these, 115 (41%) opted to defer treatment and are the subject of this analysis. Women declining therapy outnumbered men by approximately 3 to 2. Middle-aged patients (45-55 years) were most likely to choose expectant therapy compared with older or younger individuals. The proportion of African American patients who deferred therapy (48%) was higher than non-African American patients (36.6%). More than 90% of the patients choosing to be followed were genotype 1. Peak ALT values were normal in 37% and <2X upper limits of normal (ULN) in another 40%. The estimated duration of chronic hepatitis C infection was >16 years in approximately three-quarters of individuals. The most common source of their infection was intravenous drug use followed by transfusion-related. The most common reason for opting not to receive treatment, given by nearly two-thirds of patients, was the asymptomatic nature of their infection coupled with their concern about side effects of the medications. Approximately 10% had unfavorable social situations, including a lack of support or health insurance, that precluded receiving therapy (despite the availability of indigent care programs offered by the pharmaceutical manufacturers). Only five patients (4.3%) cited doubts about efficacy as the main reason that they did not want to be treated. The questionnaire survey at 1 year found that 79% of the patients confirmed their ongoing satisfaction with their initial decision to decline treatment, and another 10.6% indicated that they were still "moderately satisfied" with their decision and unlikely to change it in the near-future. Only six patients (7%) voiced their current dissatisfaction with expectant management and expressed the desire to have a follow-up discussion about treatment options. Of the remaining three patients (3.5%), two had already started treatment and one was deceased (of non-liver-related causes). A significant proportion of patients infected with hepatitis C virus who are otherwise eligible for therapy opt to defer treatment (41% overall in our series, with African American patients deferring in a higher proportion than non-African American patients). Nearly all of our patients were genotype 1 with clinically and histologically mild hepatitis of reasonably long duration. Our questionnaire survey found that most remained satisfied with their decision to defer treatment at the present time. Few patients cited a perceived low rate of efficacy of pegylated interferon and ribavirin therapy as the principal reason that they chose not to initiate treatment.

Interfering with hepatitis C virus IRES activity using RNA molecules identified by a novel in vitro selection method

Hepatitis C virus (HCV) infection is one of the world's major health problems, and the identification of efficient HCV inhibitors is a major goal. Here we report the isolation of efficient anti-HCV internal ribosome entry site (IRES) RNA molecules identified by a new in vitro selection method. The newly developed procedure consists of two sequential steps that use distinct criteria for selection: selection for binding and selection for cleaving. The selection protocol was applied to a population of more than 10(15) variants of an anti-hepatitis C virus ribozyme covalently linked to an aptamer motif. The ribozyme was directed against positions 357 to 369 of the HCV IRES, and the cleavage substrate was a 691-nucleotide-long RNA fragment that comprises the entire HCV IRES domain. After six selection cycles, seven groups of RNA variants were identified. A representative of each group was tested for its capacity to inhibit IRES activity using in vitro translation assays. All selected RNAs promoted significant inhibition, some by as much as 95%.

Simple fluorimetric method for determination of certain antiviral drugs via their oxidation with cerium (IV)

A simple and sensitive fluorimetric method for determination of antiviral drugs: ribavirin, acyclovir, and amantadine hydrochloride has been developed. The method was based on the oxidation of these drugs by cerium(IV) in presence of perchloric acid and subsequent monitoring the fluorescence of the induced cerium(III) at lambdaexcitation 255 and lambdaemission 355 nm. Different variables affecting the reaction conditions such as the concentrations of cerium(IV), type and concentration of acid medium, reaction time, temperature, and the diluting solvents were carefully studied and optimized. Under the optimum conditions, linear relationships with good correlation coefficients (0.9978-0.9996) were found between the relative fluorescence intensity and the concentrations of the investigated drugs in the range of 50-1400 ng ml-1. The assay limits of detection and quantitation were 20-49, and 62-160 ng ml-1, respectively. The precision of the method was satisfactory; the values of relative standard deviations did not exceed 1.58%. No interference could be observed from the excipients commonly present in dosage forms. The proposed method was successfully applied to the analysis of the investigated drugs in pure and pharmaceutical dosage forms with good accuracy and precision; the recovery percentages ranged from 99.2 to 101.2+/-0.48-1.30%. The results obtained by the proposed fluorimetric method were comparable with those obtained by the official method stated in the United States Pharmacopoeia.

Anti-HCV activities of selective polyunsaturated fatty acids

HCV infection can lead to chronic infectious hepatitis disease with serious sequelae. Interferon-alpha, or its PEGylated form, plus ribavirin is the only treatment option to combat HCV. Alternative and more effective therapy is needed due to the severe side effects and unsatisfactory curing rate of the current therapy. In this study, we found that several polyunsaturated fatty acids (PUFAs) including arachidonic acid (AA), docosahexaenoic acid (DHA), and eicosapentaenoic acid (EPA) are able to exert anti-HCV activities using an HCV subgenomic RNA replicon system. The EC(50) (50% effective concentration to inhibit HCV replication) of AA was 4microM that falls in the range of physiologically relevant concentration. At 100microM, alpha-linolenic acid, gamma-linolenic, and linoleic acid only reduced HCV RNA levels slightly and saturated fatty acids including oleic acid, myristic acid, palmitic acid, and steric acid had no inhibitory activities toward HCV replication. When AA was combined with IFN-alpha, strong synergistic anti-HCV effect was observed as revealed by an isobologram analysis. It will be important to determine whether PUFAs can provide synergistic antiviral effects when given as food supplements during IFN-based anti-HCV therapy. Further elucidation of the exact anti-HCV mechanism caused by AA, DHA, and EPA may lead to the development of agents with potent activity against HCV or related viruses.