Hepatitis C Virus Experimental Model Systems and Antiviral drug Research

An estimated 130 million people worldwide are chronically infected with hepatitis C virus (HCV) making it a leading cause of liver disease worldwide. Because the currently available therapy of pegylated interferon-alpha and ribavirin is only effective in a subset of patients, the development of new HCV antivirals is a healthcare imperative. This review discusses the experimental models available for HCV antiviral drug research, recent advances in HCV antiviral drug development, as well as active research be...     

In-vitro model systems to study Hepatitis C Virus

Hepatitis C virus (HCV) is a major cause of chronic liver diseases including steatosis, cirrhosis and hepatocellular carcinoma. Currently, there is no vaccine available for prevention of HCV infection due to high degree of strain variation. The current treatment of care, Pegylated interferon α in combination with ribavirin is costly, has significant side effects and fails to cure about half of all infections. The development of in-vitro models such as HCV infection system, HCV sub-genomic replicon, HCV producing pseudoparticles (HCVpp) and infectious HCV virion provide an important tool to develop new antiviral drugs of different targets against HCV. These models also play an important role to study virus lifecycle such as virus entry, endocytosis, replication, release and HCV induced pathogenesis. This review summarizes the most important in-vitro models currently used to study future HCV research as well as drug design.     

Hepatitis C virus: current understanding and prospects for future therapies.

Hepatitis C virus (HCV) is the leading cause of chronic liver disease worldwide and the leading indication for liver transplantation. The hallmark of the disease is its propensity to evolve into chronicity, probably because viral heterogeneity allows the virus to escape immune-mediated neutralization. Treatment with interferon alpha (IFN-alpha) has been disappointing, but higher and more frequent doses, and combination therapies, including nucleoside analogs, might lead to improved suppression of HCV RNA levels. Molecular analysis of HCV before and during treatment has indicated that high viral RNA levels and the presence of HCV genotype 1 are independent predictors of poor treatment outcome. New antiviral agents in development include inhibitors of HCV replicative enzymes, such as protease, helicase and polymerase, as well as several genetic approaches, such as ribozymes and antisense oligonucleotides. The main hindrance to drug development for hepatitis C is the lack of a small animal model or a productive tissue culture system for assessing drug action.     

Computer aided screening of Accacia nilotica phytochemicals against HCV NS3/4a

Background: HCV has become a leading cause of liver cirrhosis and hepatocellular carcinoma and is a major health concern worldwide. To date, there is no vaccine available in the market to tackle this disease, therefore there is a strong need to develop antiviral compounds that can target all genotypes of HCV with the same efficiency. Medicinal plants have low cost and are less toxic therefore, extracts of medicinal plants can serve as important antiviral agents against HCV. This study was designed to screen phytochemicals of Accacia nilotica to find a potent drug candidate that can inhibit HCV infection effectively.Results: Docking of NS3/4A protease and Flavonoids of Accacia nilotica revealed that most of the flavonoids bound deeply with the active site of NS3/4A protease. Compound 01 showed a high ranking on docking score. All other compounds also showed reliable docking scores and had interactions with the binding cavity of NS3/4A protease, suggesting them as a potent drug candidate to block HCV replication.Conclusion: To recognize binding interactions of Accacia nilotica phytochemicals with NS3/4A protease, molecular docking was performed to find potential inhibitor against NS3/4A protease of HCV. After post docking analysis, important interactions were found between active compounds and active site of NS3/4A protease. It can be concluded from the study that phytochemicals of Accacia nilotica may serve as a potential drug candidate with relatively simple structural changes against HCV NS3/4A protease.     

Discovery and development of telaprevir: an NS3-4A protease inhibitor for treating genotype 1 chronic hepatitis C virus

Infection with hepatitis C virus (HCV) is a major medical problem with over 170 million people infected worldwide. Substantial morbidity and mortality are associated with hepatic manifestations (cirrhosis and hepatocellular carcinoma), which develop with increasing frequency in people infected with HCV for more than 20 years. Less well known is the burden of HCV disease associated with extrahepatic manifestations (diabetes, B-cell proliferative disorders, depression, cognitive disorders, arthritis and Sj?gren's syndrome). For patients infected with genotype 1 HCV, treatment with polyethylene glycol decorated interferon (peginterferon) α and ribavirin (PR) is associated with a low (40-50%) success rate, substantial treatment-limiting side effects and a long (48-week) duration of treatment. In the past 15 years, major scientific advances have enabled the development of new classes of HCV therapy, the direct-acting antiviral agents, also known as specifically targeted antiviral therapy for hepatitis C (STAT-C). In combination with PR, the HCV NS3-4A protease inhibitor telaprevir has recently been approved for treatment of genotype 1 chronic HCV in the United States, Canada, European Union and Japan. Compared with PR, telaprevir combination therapy offers significantly improved viral cure rates and the possibility of shortened treatment duration for diverse patient populations. Developers of innovative drugs have to blaze a new path with few validated sign posts to guide the way. Indeed, telaprevir's development was once put on hold because of its performance in a standard IC(50) assay. Data from new hypotheses and novel experiments were required to justify further investment and reduce risk that the drug might fail in the clinic. In addition, the poor drug-like properties of telaprevir were a formidable hurdle, which the manufacturing and formulation teams had to overcome to make the drug. Finally, novel clinical trial designs were developed to improve efficacy and shorten treatment in parallel instead of sequentially. Lessons learned from the development of telaprevir suggest that makers of innovative medicines cannot rely solely on traditional drug discovery metrics, but must develop innovative, scientifically guided pathways for success.     

Molecular models of NS3 protease variants of the Hepatitis C virus

Background  

Hepatitis C virus (HCV) currently infects approximately three percent of the world population. In view of the lack of vaccines against HCV, there is an urgent need for an efficient treatment of the disease by an effective antiviral drug. Rational drug design has not been the primary way for discovering major therapeutics. Nevertheless, there are reports of success in the development of inhibitor using a structure-based approach. One of the possible targets for drug development against HCV is the NS3 protease variants. Based on the three-dimensional structure of these variants we expect to identify new NS3 protease inhibitors. In order to speed up the modeling process all NS3 protease variant models were generated in a Beowulf cluster. The potential of the structural bioinformatics for development of new antiviral drugs is discussed.     

Review on chemogenomic approaches towards hepatitis C viral targets

Hepatitis C virus (HCV) is the most prevalent viral pathogen that infects more than 185 million people worldwide. HCV infection leads to chronic liver diseases such as liver cirrhosis and hepatocellular carcinoma. Direct-acting antivirals (DAAs) are the recent combination therapy for HCV infection with reduced side effects than prior therapies. Sustained virological response (SVR) acts as a gold standard marker to monitor the success of antiviral treatment. Older treatment therapies attain 50-55% of SVR compared with DAAs which attain around 90-95%. The current review emphasizes the recent chemogenomic updates that have been unfolded through structure-based drug design of HCV drug target proteins (NS3/4A, NS5A, and NS5B) and ligand-based drug design of DAAs in achieving a stable HCV viral treatment strategies.     

Discovery of a synthetic dual inhibitor of HIV and HCV infection based on a tetrabutoxy-calix[4]arene scaffold

A potential anti-HIV and HCV drug candidate is highly desirable as coinfection has become a worldwide public health challenge. A potent compound based on a tetrabutoxy-calix[4]arene scaffold that possesses dual inhibition for both HIV and HCV is described. Structural activity relationship studies demonstrate the effects of lower-rim alkylation in maintaining cone conformation and upper-rim interacting head groups on the calix[4]arene play key roles for its potent dual antiviral activities.     

Identification of the Niemann-Pick C1-like 1 cholesterol absorption receptor as a new hepatitis C virus entry factor

Hepatitis C virus (HCV) is a leading cause of liver disease worldwide. With ～170 million individuals infected and current interferon-based treatment having toxic side effects and marginal efficacy, more effective antivirals are crucially needed. Although HCV protease inhibitors were just approved by the US Food and Drug Administration (FDA), optimal HCV therapy, analogous to HIV therapy, will probably require a combination of antivirals targeting multiple aspects of the viral lifecycle. Viral entry represents a potential multifaceted target for antiviral intervention; however, to date, FDA-approved inhibitors of HCV cell entry are unavailable. Here we show that the cellular Niemann-Pick C1-like 1 (NPC1L1) cholesterol uptake receptor is an HCV entry factor amendable to therapeutic intervention. Specifically, NPC1L1 expression is necessary for HCV infection, as silencing or antibody-mediated blocking of NPC1L1 impairs cell culture-derived HCV (HCVcc) infection initiation. In addition, the clinically available FDA-approved NPC1L1 antagonist ezetimibe potently blocks HCV uptake in vitro via a virion cholesterol-dependent step before virion-cell membrane fusion. Moreover, ezetimibe inhibits infection by all major HCV genotypes in vitro and in vivo delays the establishment of HCV genotype 1b infection in mice with human liver grafts. Thus, we have not only identified NPC1L1 as an HCV cell entry factor but also discovered a new antiviral target and potential therapeutic agent.     

RNA干扰技术在抗丙型病毒性肝炎中的应用

RNA干扰技术可以特异性敲低或关闭特定基因的表达,已经在生命科学的各基础研究领域中得到广泛应用,并且在抗病毒和肿瘤治疗等药物开发研究中具有良好的应用前景。近年来,RNA干扰技术被逐渐用于抗丙型病毒性肝炎的研究,不仅可以特异性地阻断丙型肝炎病毒的复制和表达,而且还可以特异性地阻断与丙型肝炎病毒结合的蛋白的复制和表达。我们简要综述了近年来RNA干扰技术在此方面的应用。     

HCV entry receptors as potential targets for siRNA-based inhibition of HCV

Hepatitis C virus (HCV) infection is a major worldwide problem causes acute and chronic HCV infection. Current treatment of HCV includes pegylated interferon-α (PEG IFN- α) plus ribavirin (RBV) which has significant side effects depending upon the type of genotype. Currently, there is a need to develop antiviral agents, both from synthetic chemistry and Herbal sources. In the last decade, various novel HCV replication, helicase and entry inhibitors have been synthesized and some of which have been entered in different phases of clinical trials. Successful results have been acquired by executing combinational therapy of compounds with standard regime in different HCV replicons. Even though, diverse groups of compounds have been described as antiviral targets against HCV via Specifically Targeted Antiviral Therapy for hepatitis C (STAT-C) approach (in which compounds are designed to directly block HCV or host proteins concerned in HCV replication), still there is a need to improve the properties of existing antiviral compounds. In this review, we sum up potent antiviral compounds against entry, unwinding and replication of HCV and discussed their activity in combination with standard therapy. Conclusively, further innovative research on chemical compounds will lead to consistent standard therapy with fewer side effects.     

Immune-based novel therapies for chronic hepatitis C virus infection

Hepatitis C virus (HCV) infection is a great public health problem, with an estimated 200 million chronically infected patients worldwide. No vaccines are currently available for HCV, and only a subset of HCV patients responds to interferon-alpha (IFN-alpha) and Ribavirin treatment. Substantial evidence has emerged recently to support the role of the host immune response in the outcome and pathogenesis of HCV infection. Our aims of this article are to present the immune-based novel therapeutic options for HCV infection and the evidence supporting their use in patients with chronic hepatitis C. There is a growing consensus that acute control of HCV infection is associated with a vigorous intrahepatic antiviral CD4+ and CD8+ T cell response. IFN-gamma was detectable in the livers of the chimpanzees that cleared or controlled the virus, raising the possibility that IFN-gamma might perform antiviral effector functions during HCV infection. Based on these observations, therapeutic induction of intrahepatic IFN-gamma by adoptive immunotherapy might be able to control chronic HCV infection. Immune-based novel therapies appear to hold great promise in treating chronic HCV infection.     

An NS3 serine protease inhibitor abrogates replication of subgenomic hepatitis C virus RNA

The hepatitis C virus (HCV) NS3 protease is essential for polyprotein maturation and viral propagation, and it has been proposed as a suitable target for antiviral drug discovery. An N-terminal hexapeptide cleavage product of a dodecapeptide substrate identified as a weak competitive inhibitor of the NS3 protease activity was optimized to a potent and highly specific inhibitor of the enzyme. The effect of this potent NS3 protease inhibitor was evaluated on replication of subgenomic HCV RNA and compared with interferon-alpha (IFN-alpha), which is currently used in the treatment of HCV-infected patients. Treatment of replicon-containing cells with the NS3 protease inhibitor or IFN-alpha showed a dose-dependent decrease in subgenomic HCV RNA that reached undetectable levels following a 14-day treatment. Kinetic studies in the presence of either NS3 protease inhibitor or IFN-alpha also revealed similar profiles in HCV RNA decay with half-lives of 11 and 14 h, respectively. The finding that an antiviral specifically targeting the NS3 protease activity inhibits HCV RNA replication further validates the NS3 enzyme as a prime target for drug discovery and supports the development of NS3 protease inhibitors as a novel therapeutic approach for HCV infection.     

Mathematical modeling of multi-drugs therapy: a challenge for determining the optimal combinations of antiviral drugs

In the current era of antiviral drug therapy, combining multiple drugs is a primary approach for improving antiviral effects, reducing the doses of individual drugs, relieving the side effects of strong antiviral drugs, and preventing the emergence of drug-resistant viruses. Although a variety of new drugs have been developed for HIV, HCV and influenza virus, the optimal combinations of multiple drugs are incompletely understood. To optimize the benefits of multi-drugs combinations, we must investigate the interactions between the combined drugs and their target viruses. Mathematical models of viral infection dynamics provide an ideal tool for this purpose. Additionally, whether drug combinations computed by these models are synergistic can be assessed by two prominent drug combination theories, Loewe additivity and Bliss independence. By combining the mathematical modeling of virus dynamics with drug combination theories, we could show the principles by which drug combinations yield a synergistic effect. Here, we describe the theoretical aspects of multi-drugs therapy and discuss their application to antiviral research.     

Development of novel antiviral therapies for hepatitis C virus

Over 170 million people worldwide are infected with hepatitis C virus (HCV), a major cause of liver diseases. Current interferon-based therapy is of limited efficacy and has significant side effects and more effective and better tolerated therapies are urgently needed. HCV is a positive, single-stranded RNA virus with a 9.6 kb genome that encodes ten viral proteins. Among them, the NS3 protease and the NSSB polymerase are essential for viral replication and have been the main focus of drug discovery efforts. Aided by structure-based drug design,potent and specific inhibitors of NS3 and NSSB have been identified, some of which are in late stage clinical trials and may significantly improve current HCV treatment. Inhibitors of other viral targets such as NSSA are also being pursued. However, HCV is an RNA virus characterized by high replication and mutation rates and consequently, resistance emerges quickly in patients treated with specific antivirals as monotherapy. A complementary approach is to target host factors such as cyclophilins that are also essential for viral replication and may present a higher genetic barrier to resistance. Combinations of these inhibitors of different mechanism are likely to become the essential components of future HCV therapies in order to maximize antiviral efficacy and prevent the emergence of resistance.     

天然来源的乙型和丙型肝炎病毒抑制剂的研究进展

慢性病毒性肝炎是威胁人类健康的主要流行病之一,目前全球约有 4 亿慢性乙型和丙型肝炎患者,现有临床药物仍不能很好地治愈 病毒性肝炎。作为药物发现的重要来源,天然产物提供了许多能强效抑制乙型肝炎病毒 (hepatitis B virus, HBV) 和丙型肝炎病毒（hepatitis C virus, HCV）的抑制剂。综述近 10 年来国内外报道的抗 HBV 和 HCV 的活性中药成分和天然产物的研究进展。     

Identification of serotonin 2A receptor as a novel HCV entry factor by a chemical biology strategy

Hepatitis C virus(HCV)is a leading cause of liver disease worldwide.Although several HCV protease/polymerase inhibitors were recently approved by U.S.FDA,the combination of antivirals targeting multiple processes of HCV lifecycle would optimize anti-HCV therapy and against potential drug-resistanee.Viral entry is an essential target step for antiviral development,but FDA-approved HCV entry inhibitor remains exclusive.Here we identify serotonin 2A receptor(5-HT2aR)is a HCV entry factor amendable to therapeutic intervention by a chemical biology strategy.The silencing of 5-HT2aR and clinically available 5-HT2aR antagonist suppress cell culture-derived HCV(HCVcc)in different liver cells and primary human hepatocytes at late endocytosis process.The mechanism is related to regulate the correct plasma membrane localization of claudin 1(CLDN1).Moreover,phenoxybenzamine(PBZ),an FDAapproved 5-HT2aR antagonist,inhibits all major HCV genotypes in vitro and displays synergy in combination with clinical used anti-HCV drugs.The impact of PBZ on HCV genotype 2a is documented in immune-competent humanized transgenic mice.Our results not only expand the understanding of HCV entry,but also present a promising target for the invention of HCV entry inhibitor.     

Replicative Homeostasis III: implications for antiviral therapy and mechanisms of response and non-response

While improved drug regimens have greatly enhanced outcomes for patients with chronic viral infection, antiviral therapy is still not ideal due to drug toxicities, treatment costs, primary drug failure and emergent resistance. New antiviral agents, alternative treatment strategies and a better understanding of viral pathobiology, host responses and drug action are desperately needed. Interferon (IFN) and ribavirin, are effective drugs used to treat hepatitis C (HCV), but the mechanism(s) of their action are uncertain. Error catastrophe (EC), or precipitous loss of replicative fitness caused by genomic mutation, is postulated to mediate ribavirin action, but is a deeply flawed hypothesis lacking empirical confirmation. Paradoxically ribavirin, a proven RNA mutagen, has no impact on HCV viraemia long term, suggesting real viruses, replicating in-vitro, as opposed to mathematical models, replicating in-silico, are likely to resist EC by highly selective replication of fit (~consensus sequence) genomes mediated, in part, by replicative homeostasis (RH), an epicyclic mechanism that dynamically links RNApol fidelity and processivity and other viral protein functions. Replicative homeostasis provides a rational explanation for the various responses seen during treatment of HCV, including genotype-specific and viral load-dependent differential response rates, as well as otherwise unexplained phenomena like the transient inhibition and rebound of HCV viraemia seen during ribavirin monotherapy. Replicative homeostasis also suggests a primarily non-immunological mechanism that mediates increased immune responsiveness during treatment with ribavirin (and other nucleos(t)ide analogues), explicating the enhanced second-phase clearance of HCV ribavirin promotes and, thus, the apparent immunomodulatory action of ribavirin. More importantly, RH suggests specific new antiviral therapeutic strategies.     

Molnupiravir,favipiravir and other antiviral drugs with proposed potentials for management of COVID-19: a concern on antioxidant aspect

COVID-19 is an important global public health problem that causes millions of infections worldwide. The specific antiviral drug for this new infection is still under research. Some new antiviral drugs, including molnupiravir and favipiravir, are proposed for usefulness in management of COVID-19. Additionally, some classic antiviral drugs used for other viral infections are also reproposed for the potentials for management of COVID-19. In the management of COVID-19, there are several pharmacological actions. An important consideration in antiviral therapy is the management of oxidative stress, which plays important roles in viral infections including to COVID-19. The analysis of antioxidative properties of alternative drugs for management of COVID-19 is interesting and can give basic data for further new antiviral drug researching. Here, the authors perform a molecular analysis on molnupiravir, favipiravir and other antiviral drugs with proposed potentials for management of COVID-19 to determine their antioxidative properties. Data from electron acceptor and donor calculation for each drug is used for further estimating overall antioxidative characteristic. Based on the present study, all studied drugs have overall antioxidative properties. Hence, the advantage of molnupiravir, favipiravir and other antiviral drugs with proposed potentials for the management of COVID-19 is their direct action on viral molecule via binding-blocking process as well as antixodiative process. For management of COVID-19 antioxidative stress, other non-antiviral drugs that are proposed for clinical advantage might also be useful.     

Acetylsalicylic acid (ASA) blocks influenza virus propagation via its NF-kappaB-inhibiting activity

Influenza is still one of the major plagues worldwide. The statistical likeliness of a new pandemic outbreak highlights the urgent need for new and amply available antiviral drugs. We and others have shown that influenza virus misuses the cellular IKK/NF-kappaB signalling pathway for efficient replication suggesting that this module may be a suitable target for antiviral intervention. Here we examined acetylsalicylic acid (ASA), also known as aspirin, a widely used drug with a well-known capacity to inhibit NF-kappaB. We show that the drug efficiently blocks influenza virus replication in vitro and in vivo in a mechanism involving impaired expression of proapoptotic factors, subsequent inhibition of caspase activation as well as block of caspase-mediated nuclear export of viral ribonucleoproteins. As ASA showed no toxic side-effects or the tendency to induce resistant virus variants, existing salicylate-based aerosolic drugs may be suitable as anti-influenza agents. This is the first demonstration that specific targeting of a cellular factor is a suitable approach for anti-influenza virus intervention.