HCV in liver transplantation

HCV-related cirrhosis represents the leading indication for liver transplantation in the Western countries. HCV reinfection after liver transplantation occurs in virtually all patients transplanted for HCV-related liver disease Histological evidence of chronic HCV infection develops in 50 to 90 % of patients by 12 months after liver transplantation, and cirrhosis occurs in about 20 % of patients within 5 years after transplant. Several studies have evaluated host, viral, and transplant-related factors that might be associated with the severity of HCV recurrence. Among host factors, immunosuppression is one of the major factors that accounts for accelerated HCV recurrence and it has been an area of extensive research and controversy. Donor age, steatosis, and immunogenetic factors are also relevant in determining the outcome in patients transplanted for HCV-related cirrhosis. A major step to prevent complications of HCV recurrence related to the rapid fibrosis is the posttransplant antiviral treatment. Two strategies have been tried: pre-emptive or other strategies as soon as possible after liver transplantation or elective therapy once there is histological evidence of recurrent hepatitis C. Retransplantation due to graft failure from recurrent hepatitis C is rarely an option in the era of organ shortage as it is associated with poor outcome, but many case needs to be considered early in the evolution of disease. New antivirals may change the outcome dramatically of patients transplanted for HCV cirrhosis.     

Effects of corticosteroids on HCV infection.

The risk factors for clinical recurrent hepatitis C in liver transplant recipients are not clearly defined. It has been suggested that the corticosteroids included in the treatments of patients undergoing allograft rejection might induce acute hepatitis by increasing HCV replication. In this study we investigated the effects of corticosteroid boluses on HCV viremia in liver allograft recipients treated for acute rejection. Since we had previously developed a model of HCV replication in peripheral blood mononuclear cells (PBMC) in vitro, we also studied the effects of corticosteroids on HCV replication in vitro. A transient peak of HCV viremia was observed in patients treated with corticosteroid boluses for an acute allograft rejection. In the cell cultures, corticosteroids induced an increase of the total amount of viral RNA detectable. Our results demonstrate that corticosteroids induce an increase of hepatitis C virus replication in vivo and in vitro.     

Inhibition of translation initiation factors might be the potential therapeutic targets for HCV patients with hepatic iron overload

Standard therapy, interferon-alpha (IFN-α) and ribavirin, remains the only available option for treatment of patients with hepatitis C virus (HCV) infection. However, iron overload, a common finding among HCV patients, have a poor response to treatment with current therapy. These data suggest that both host and viral factors are involved in the determination of the outcome of the therapy. Currently, novel antiviral compounds focus on the development of indirect antiviral drugs. The process of the viral translation is considered as the potential therapeutic targets. Coincidentally, study has found that hepatic iron load enhances the levels of eukaryotic initiation factor 3 (eIF3), which is essential for HCV translation. Reversely, iron chelation could reduce eIF3 p170 translation. Our hypothesis is that iron overload may specifically enhance cellular eIFs. As a result, the cellular mechanisms, in patients with iron overload, are utilized for translating viral mRNA into protein. Thus, treatment strategies that target eIFs should be an exceptionally good candidate therapeutic method for HCV patients with hepatic iron overload.     

HCV core protein and virus assembly: what we know without structures

Chronic hepatitis C virus (HCV) infection results in a progressive disease that may end in cirrhosis and, eventually, in hepatocellular carcinoma. In the last several years, tremendous progress has been made in understanding the HCV life cycle and in the development of small molecule compounds for the treatment of chronic hepatitis C. Nevertheless, the complete understanding of HCV assembly and particle release as well as the detailed characterization and structure of HCV particles is still missing. One of the most important events in the HCV assembly is the nucleocapsid formation which is driven by the core protein, that can oligomerize upon interaction with viral RNA, and is orchestrated by viral and host proteins. Despite a growing number of new factors involved in HCV assembly process, we do not know the three-dimensional structure of the core protein or its topology in the nucleocapsid. Since the core protein contains a hydrophobic C-terminal domain responsible for the binding to cellular membranes, the assembly pathway of HCV virions might proceed via coassembly at endoplasmic reticulum membranes. Recently, new mechanisms involving viral proteins and host factors in HCV particle formation and egress have been described. The present review aims to summarize the advances in our understanding of HCV assembly with an emphasis on the core protein as a structural component of virus particles that possesses the ability to interact with a variety of cellular components and is potentially an attractive target for the development of a novel class of anti-HCV agents.     

Influence of the dynamics of the hypervariable region 1 of hepatitis C virus (HCV) on the histological severity of HCV recurrence after liver transplantation

Recurrence of hepatitis C virus (HCV) infection after liver transplantation is almost universal and usually leads to chronic hepatitis with different degrees of severity. The pathogenic mechanisms underlying the variable outcome of HCV infection recurrence are not well defined, but recent data suggest that the dynamics of HCV quasispecies may be involved. HCV quasispecies evolution was traced by longitudinal single strand conformation polymorphism, direct sequencing, and cloning analyses of pre- and post-transplant HCV-1b isolates from patients with histologically severe (seven cases) or mild or moderate (nine cases) HCV infection recurrence. Differences between the two groups of patients that concerned the level of viremia or the degree of HCV quasispecies complexity and diversity were not observed at any of the three time points analyzed. However, emergence of nucleotide and amino acid changes during the 12 months follow-up was significantly more frequent in patients with mild or moderate than in those with severe HCV infection recurrence. The ratio of non-synonymous to synonymous nucleotide substitutions 12 months after transplantation was also greater in the former, suggesting that the HVR1 of HCV is under stronger selective pressure in these subjects. These findings suggest that the degree of amino acid diversification in the HVR1 of HCV, which probably reflects the strength of immune pressure on HCV, is inversely related to the histological severity of HCV infection recurrence.     

Treatment of recurrent HCV infection after liver transplantation

End-stage liver disease associated with hepatitis C virus (HCV) infection is the most common indication for orthotopic liver transplantation (OLT) and accounts for 50% of these procedures in Spain and 42% of OLT performed in the United States. Recurrent infection with HCV after OLT, however, is almost universal and is associated with substantial morbidity, mortality, and graft loss. In contrast to immunocompetent individuals, HCV infection in immunosuppressed transplant recipients usually has an accelerated course. Acute hepatitis develops in approximately 75% of HCV recipients in the first six months following OLT. By the fifth postoperative year, over 80% of HCV-infected liver transplant recipients will develop histologic evidence of chronic allograft injury secondary to hepatitis C, with up to 30% developing cirrhosis. While the choice of calcineurin inhibitor has not been clearly shown to affect the histologic recurrence of hepatitis C or the frequency of rejection in HCV-infected recipients, cumulative exposure to corticosteroids is associated with increased mortality, higher levels of HCV viremia and more severe histologic recurrence. There have been no well-controlled, large, prospective, multicenter and randomized clinical trials to determine the optimal approach to the treatment of recurrent HCV infection following OLT. Most published studies were small, lacked controls, had short follow-up periods, and were devoid of histologic analysis. Furthermore, most of the published studies are largely incomparable due to differences in the definition of recurrent hepatitis C, timing of anti-HCV therapy administration relative to transplantation, the drugs and doses used and regimens employed, and the study end points assessed (i. e. biochemical, virologic and histologic end points have not all been consistently investigated). In lieu of large studies in post-transplant patients, monotherapy with conventional interferon or monotherapy with pegylated interferon should be considered in recipients with histologically confirmed recurrence of HCV infection. The role of hepatitis C immunoglobulin and new imunosuppression agents in the management of post-transplant HCV infection is still evolving.     

Hepatitis C virus (HCV) infection and hepatic steatosis

There are two discrete forms of steatosis that may be found in patients infected with hepatitis C virus (HCV). Metabolic steatosis can coexist with HCV, regardless of genotype, in patients with risk factors such as obesity, hyperlipidemia, and insulin resistance. The second form of hepatic steatosis in HCV patients is a result of the direct cytopathic effect of genotype 3 viral infections. There have been proposed mechanisms for this process but it remains elusive. Both categories of steatosis tend to hasten the progression of liver fibrosis and therefore prompt recognition and management should be initiated in patients with HCV and steatosis. The authors review the current understanding of the relationship between hepatitis C infection and hepatic steatosis and discuss future research directions.     

Viral factors associated with cytokine expression during HCV/HIV co-infection.

Co-infection with human immunodeficiency virus (HIV) is associated with reduced hepatitis C virus (HCV) treatment response and accelerated HCV disease. Cytokines, as mediators of immune responses, inflammation, and fibrogenesis, may underlie important differences in HCV pathogenesis during HIV co-infection. We previously found that serum interleukin-8 (IL-8) and tumor necrosis factor-alpha (TNF-alpha) increased after HCV therapy with interferon (IFN) in HCV/HIV co-infected patients; however, cytokine levels were not predictive of HCV therapeutic response. Here, we examined viral factors associated with expression of IL-8, TNF-alpha, and transforming growth factor-beta1 (TGF-beta1) in uninfected, HCV mono-infected, HIV mono-infected, and HCV/HIV co-infected persons. HIV co-infection was associated with decreased IL-8 detection but not TNF-alpha detection. A significant interaction effect demonstrated that HIV infection was associated with elevated TGF-beta1 in HCV-positive individuals but not in HCV-negative individuals. The induction of a sustained profibrotic signal, such as TGF-beta1, by HIV may cause accelerated liver fibrosis during HCV/HIV co-infection and may hinder the host's ability to mount an effective HCV-specific immune response. Further studies are warranted to identify noninvasive markers of liver disease for the clinical management of HCV disease, particularly when liver biopsies have not been performed or are contraindicated.     

Assessment of viral loads in patients with chronic hepatitis C with AMPLICOR HCV MONITOR version 1.0, COBAS HCV MONITOR version 2.0, and QUANTIPLEX HCV RNA version 2.0 assays

The correlation between response to antiviral therapy and pretreatment viral load in patients with chronic hepatitis C has prompted the development of quantitative assays to measure viral load. The aim of our study was to assess the clinical relevance of the newly developed semiautomated PCR system COBAS HCV MONITOR version 2.0 in comparison with (i) the AMPLICOR HCV MONITOR version 1.0 assay, which underestimates RNA concentration of hepatitis C virus (HCV) genotypes 2 to 6, and (ii) the QUANTIPLEX HCV RNA version 2.0 assay, which achieves equivalent quantification for each HCV genotype, with samples from 174 patients diagnosed with chronic hepatitis C before therapy. The level and range of quantification measured with AMPLICOR HCV MONITOR version 1.0 were 1 log lower than when measured with the COBAS HCV MONITOR version 2.0, at 0.261 x 10(6) RNA copies/ml (range, 0.001 x 10(6) to 2.50 x 10(6) RNA copies/ml) and 4.032 x 10(6) RNA copies/ml (range, 0.026 x 10(6) to 72.6 x 10(6) RNA copies/ml), respectively. The two assays showed a poor correlation (r(2) = 0.175). The level and range of quantification were similar when measured with the COBAS HCV MONITOR version 2.0 and QUANTIPLEX HCV RNA version 2.0 assays, at 3.03 x 10(6) RNA copies/ml (range, 0.023 x 10(6) to 72.6 x 10(6) RNA copies/ml) and 4.91 Meq/ml (range, 0.200 to 49.5 Meq/ml), respectively. The two assays showed a strong correlation (r(2) = 0. 686) for each HCV genotype. The duration of treatment (6 or 12 months) is modulated according to HCV genotype and viral load. Our results indicate that COBAS HCV MONITOR version 2.0 and QUANTIPLEX HCV RNA version 2.0 assays showing an equal dynamic range for each HCV genotype are suitable tools to assess patients before therapy.     

Role of La autoantigen and polypyrimidine tract-binding protein in HCV replication

To determine if the cellular factors La autoantigen (La) and polypyrimidine tract-binding protein (PTB) are required for hepatitis C virus (HCV) replication, we used siRNAs to silence these factors and then monitored their effect on HCV replication using quantitative RT-PCR. In addition, we determined the influence of PTB on the activity of the 3' noncoding region (NCR) of HCV and investigated its interaction with the components of the HCV replicase complex. We found that La is essential for efficient HCV replication while PTB appears to partially repress replication. PTB does, however, block the binding of HCV RNA-dependent RNA polymerase (RdRp, NS5B) to the 3'NCR. Indirect immunofluorescence microscopy showed co-localization of cytoplasmic PTB with the HCV RdRp in hepatoma cells (Huh-7) expressing HCV proteins, while in vitro translation of viral proteins from the HCV replicon revealed the interaction of PTB isoforms with NS5B polymerase and NS3.     

HCV准种多样性及其与临床关系的研究

目的     

Host factors involved in the replication of hepatitis C virus

Hepatitis C virus (HCV) is the major causative agent of blood-borne hepatitis. The majority of HCV-infected individuals develop chronic hepatitis, which eventually progresses to liver cirrhosis, and hepatocellular carcinoma. Although the precise mechanisms of entry, replication, assembly, egress and pathogenesis of HCV are largely unknown, information about viral receptor candidates has accumulated by the development of pseudotype viruses and an in vitro replication system of the HCV JFH1 strain. Furthermore, the autonomous RNA replication system based on the artificial viral genome revealed that HCV replicates in the intracellular replication complex composed of viral and host proteins. Recently, an immunosuppress ant, cyclosporin A and inhibitors for sphingolipid synthesis and chaperon were reported to inhibit the replication of HCV by counteracting the interplay between host and viral proteins. This review considers the current knowledge of the host proteins that participate in HCV replication and the possibility of developing novel therapeutics intervention for chronic hepatitis C.     

The natural history of hepatitis C virus (HCV) infection

Hepatitis C virus (HCV) is a leading cause of chronic liver disease, cirrhosis, and hepatocellular carcinoma, as well as the most common indication for liver transplantation in many countries. Although the incidence of hepatitis C infection has dramatically decreased during the past decade, the worldwide reservoir of chronically infected persons is estimated at 170 million, or 3% of the global population. There is much controversy surrounding the natural history of hepatitis C infection. The rate of chronic HCV infection is affected by a person's age, gender, race, and viral immune response. Approximately 75%-85% of HCV-infected persons will progress to chronic HCV infection, and are at risk for the development of extrahepatic manifestations, compensated and decompensated cirrhosis, and hepatocellular carcinoma (HCC). The rate of progression to cirrhosis is highly variable, and is influenced by several factors, including the amount of alcohol consumption, age of initial HCV infection, degree of inflammation and fibrosis on liver biopsy, HIV and HBV coinfection, and comordid conditions. An estimated 10%-15% of HCV-infected persons will advance to cirrhosis within the first 20 years. Persons with cirrhosis are at increased risk of developing HCC. An understanding of the natural history of hepatitis C is essential to effectively manage, treat, and counsel individuals with HCV infection.     

HCV quasispecies evolution during treatment with interferon alfa-2b and ribavirin in two children coinfected with HCV and HIV-1

Two children who acquired hepatitis C virus (HCV) and human immunodeficiency virus type 1 (HIV-1) infection by mother-to-child transmission were monitored during interferon alfa-2b and ribavirin treatment. In Patient C1, CD4(+) T cell counts were within normal range and HIV-1 viral load was undetectable. HCV viral load declined slightly following treatment initiation while novel variants rapidly emerged, indicative of quasispecies diversification. In Patient C2, CD4(+) T cell counts were low and HIV-1 replication was not fully controlled by antiretroviral therapy. HCV viral load rose during treatment and a striking conservation of the variant spectrum was observed. In both cases, there was no decline in quasispecies complexity following treatment initiation and sustained virological response was not achieved. These results suggest that reduction in quasispecies complexity, which is observed in adult responders following interferon treatment, may be mechanistically unrelated with evolution of the variant profile and/or selective pressure exerted on HCV.     

Total HCV core antigen assay. A new marker of HCV viremia and its application during treatment of chronic hepatitis C

The present study assesses the clinical usefulness of the hepatitis C core antigen assay for monitoring of patients being treated for chronic hepatitis C virus (HCV) infection. Eighty-six serum samples were selected at random from 16 patients and levels of HCV RNA and HCV core antigen were determined simultaneously and in parallel to compare both techniques. The data obtained were compared by Pearson’s correlation and the coefficients calculated by Fisher transformation and by calculating the difference and standard error. A good linear correlation was observed between both techniques. Maximum correlation, with significant difference, was found between patients infected with the 1a genotype and other genotypes. In conclusion, the HCV core antigen assay is useful for the diagnosis of early infection; however, its use for determining the exact timing of viral elimination during treatment is clearly unsuitable.     

New HCV therapies on the horizon

Improved understanding of the hepatitis C virus (HCV) life cycle has led to the discovery of numerous potential targets for antiviral therapy. HCV polyprotein processing and replication have been identified as the most promising viral targets. However, viral entry and fusion, RNA translation, virus assembly and release and several host cell factors may provide alternative attractive targets for future anti-HCV therapies. Inhibitors of the HCV NS3/4A protease are currently the most advanced in clinical development. Monotherapy with protease inhibitors has shown high antiviral activity, but is associated with frequent selection of resistant HCV variants, often resulting in viral breakthrough. However, there is encouraging evidence from phase 2/3 trials indicating that the addition of a protease inhibitor (e.g. telaprevir and boceprevir) to pegylated interferon-α/ribavirin substantially improves sustained virological response rates in both treatment-naïve and treatment-experienced patients with HCV genotype 1. Nucleos(t)ide inhibitors of the HCV NS5B polymerase have shown variable antiviral activity against different HCV genotypes, but seem to have a higher genetic barrier to resistance than protease inhibitors. In addition, several allosteric binding sites have been identified for non-nucleoside inhibitors of the NS5B polymerase. However, the development of a substance with high antiviral activity and a high genetic barrier to resistance seems to be difficult. Among the different host cell-targeting compounds in early clinical development, cyclophilin inhibitors have shown the most promising results. Although advances have also been made in improving interferons, combinations of antiviral agents with different mechanisms of action may lead to the eventual possibility of interferon-free regimens.     

Clinical evaluation of the automated COBAS AMPLICOR HCV MONITOR test version 2.0 for quantifying serum hepatitis C virus RNA and comparison to the quantiplex HCV version 2.0 test

A second-generation hepatitis C virus (HCV) quantitative assay (COBAS AMPLICOR HCV MONITOR Test, version 2.0; COBAS HCM-2) has been developed, with the intention of achieving equivalent quantification of all HCV genotypes and improving assay performance. To evaluate the clinical performance of COBAS HCM-2 and its utility in predicting the response to alpha interferon treatment, sera from 215 chronic hepatitis C patients were analyzed and the results were compared with those obtained by the Quantiplex bDNA HCV RNA, version 2.0, assay (bDNA-2). The COBAS HCM-2 had significantly greater sensitivity than bDNA-2 (94.9 versus 88.4%; P < 0.001) when performed with sera from chronic hepatitis C patients who were viremic by a qualitative PCR test. The standard deviations for the within-run and between-run reproducibilities of COBAS HCM-2 were <0. 1 and <0.2, respectively, and it showed an improved linear range between genotypes with the threefold serial dilutions tested (r(2) = 0.986 to 0.995). The COBAS HCM-2 results were positively correlated with the bDNA-2 results, but the values for COBAS HCM-2 were on average 0.96 log lower than the values for bDNA-2. The mean difference in quantification values between these two assays did not differ among samples with different genotypes (0.70 to 1.00 log). No genotype-dependent difference in viral load was observed. The pretreatment viral load was significantly lower in complete responders. By using multivariate analysis, the viral load 2 weeks after the initiation of alpha interferon treatment was the strongest predictor of a complete response. In conclusion, COBAS HCM-2 demonstrated good sensitivity, linearity, and reproducibility and efficiency equal to that of bDNA-2 for the quantification of HCV genotypes 1 and 2. Hence, this assay provides a rapid and reliable method for the quantification of HCV RNA in serum and is useful for the planning of interferon treatment.     

Comparison of different HCV viral load and genotyping assays.

BACKGROUND: We report an interlaboratory comparison of methods for the determination of hepatitis C virus (HCV) serum load and genotype between a recently, established molecular laboratory at the Alaska Native Medical Center (ANMC) and two independent laboratories using different assays. At ANMC, a Real-time quantitative RT-PCR amplification methodology (QPCR) has been developed in which HCV viral loads are determined by interpolation of QPCR results to those of standards calibrated to the World Health Organization (WHO) First International Standard for HCV. HCV genotype is subsequently determined by direct sequencing of the DNA fragment generated from the QPCR assay. OBJECTIVES AND STUDY DESIGN: The above methods were statistically compared to results obtained for the same patient sera by two independent laboratories using different commercially available viral load assays; Quantiplex HCV RNA (Bayer Diagnostics) and Amplicor HCV Monitor (v 2.0) (Roche Molecular Systems), as well as two different genotyping assays; restriction fragment length polymorphism (RFLP) and INNO-LiPA HCV II (Innogenetics). RESULTS: ANMC's Real-time QPCR HCV viral load results compared moderately well with those obtained by the Quantiplex HCV RNA method (R2=0.3813), and compared quite well with recent lot numbers of Amplicor HCV Monitor in which viral loads are derived in IU/ml (R2=0.6408), but compared poorly with earlier lot numbers of Amplicor HCV Monitor in which viral loads were derived in copies/ml (R2=0.0913). The ANMC direct sequencing method for genotype determination compared moderately to very well with both the RFLP (84-86%) and INNO-LiPA (85-97.5%) methods. CONCLUSIONS: These viral load comparisons highlight the discrepancies that may occur when patient HCV viral loads are monitored using different types of assays. Comparison of HCV genotype by different methods is more reliable statistically and important clinically for predicting probability of response to antiviral therapy. However, viral loads are important for monitoring response once therapy has begun.     

Virus-specific T-cell responses associated with hepatitis C virus (HCV) persistence in the liver after apparent recovery from HCV infection

Hepatitis C virus (HCV) RNA persistence in the liver has been described even after apparent resolution of HCV infection. Because T-cell reactivity plays a role in recovery from HCV infection, virus-specific T-cell responses were investigated in apparently recovered individuals in whom hepatic HCV RNA persistence was documented: 15 sustained virological responders to interferon (IFN)-treatment and 9 asymptomatic aviremic anti-HCV carriers. HCV-specific CD4(+) T-cell proliferative responses were detected significantly more often in apparently recovered individuals (sustained virological responders: 60%; asymptomatic anti-HCV carriers: 66%) compared with 50 chronic hepatitis C patients (28%; P < 0.05). However, T-cell frequencies and numbers tended to decline over time and the number of HCV proteins targeted by CD4(+) T-cell proliferative responses was limited. Interestingly, liver viral load correlated inversely with virus-specific immune responses. Thus, CD4(+) T-cell responders showed significantly lower hepatic HCV RNA levels (P < 0.05). HCV-specific IFN-gamma-secreting CD4(+) T-cells were not detected in all the apparently recovered patients although they were found significantly more often compared with chronic hepatitis C patients (P < 0.05). Also, HCV NS3-specific CD8(+) T-cells were detected in 11 HLA-A2-positive apparently recovered individuals (8 sustained virological responders and 3 asymptomatic anti-HCV carriers); T-cell frequencies tended to be greater in those patients who had lower hepatic viral levels. In conclusion, HCV-specific T-cells are detectable in apparently recovered individuals in whom HCV RNA can persist in the liver indicating that HCV replication may be prolonged in the face of an insufficient or inadequate virus-specific CD4(+) and CD8(+) T-cell response.     

Management of HCV infection and liver transplantation

A major challenge facing liver transplant recipients and their physicians is recurrence of hepatitis C virus infection following otherwise technically successful liver transplantation. Recurrent infection leads to diminished graft and patient survival. Although a number or predictors of severe recurrence have been identified, no definitive strategy has been developed to prevent recurrence. Generally the tempo of hepatitis C recurrence is gauged by serial liver biopsies with the decision to intervene with antiviral therapy based on local philosophy and expertise. Treating hepatitis C in this population has a number of major challenges including diminished patient tolerance for side-effects as well as managing the patient's immunesuppression. However sustained viral responses are possible with the potential to reduce the impact of recurrent hepatitis on the graft. However recurrent hepatitis C virus infection will remain the most frequent form of recurrent disease in liver transplant programs for the foreseeable future.