Six major hepatitis C virus (HCV) genotypes and numerous subtypes have been described, and recently a seventh major genotype was discovered. Genotypes show significant molecular and clinical differences, such as differential response to combination therapy with interferon-␣ and ribavirin. Recently, HCV research has been accelerated by cell culture systems based on the unique growth capacity of strain JFH1 (genotype 2a). By development of JFH1-based intergenotypic recombinants containing Core, envelope protein 1 and 2 (E1, E2), p7, and nonstructural protein 2 (NS2) of genotype 6a and 7a strains, as well as subtype 1b and 2b strains, we have completed a panel of culture systems for all major HCV genotypes. Efficient growth in Huh7.5 cells depended on adaptive mutations for HK6a/JFH1 (6a/2a, in E1 and E2) and J4/JFH1 (1b/2a, in NS2 and NS3); viability of J8/JFH1 (2b/2a) and QC69/JFH1 (7a/2a) did not require adaptation. To facilitate comparative studies, we generated virus stocks of genotype 1-7 recombinants with infectivity titers of 10 3.7 to 10 5.2 50% tissue culture infectious dose/mL and HCV RNA titers of 10 7.0 to 10 7.9 IU/mL. Huh7.5 cultures infected with genotype 1-6 viruses had similar spread kinetics, intracellular Core, NS5A, and lipid amounts, and colocalization of Core and NS5A with lipids. Treatment with interferon-␣2b but not ribavirin or amantadine showed a significant antiviral effect. Infection with all genotypes could be blocked by specific antibodies against the putative coreceptors CD81 and scavenger receptor class B type I in a dose-dependent manner. Finally, neutralizing antibodies in selected chronic phase HCV sera had differential effects against genotype 1-7 viruses. Conclusion: We completed and characterized a panel of JFH1-based cell culture systems of all seven major HCV genotypes and important subtypes and used these viruses in comparative studies of antivirals, HCV receptor interaction, and neutralizing antibodies. (HEPATOLOGY 2009;49:364-377.) A bout 180 million people are infected with hepatitis C virus (HCV) worldwide, and HCV is a main contributor to chronic liver disease. The positive-stranded RNA genome of HCV has significant heterogeneity with six major genotypes and numerous subtypes. In the Americas, Europe and Japan genotypes 1a, 1b, and 3a are the most common, but 2a and 2b also show a significant presence. Genotypes 4 and 5 are found primarily in the Middle East and Africa, while genotype 6 predominates in Southeast Asia, a region with a high prevalence of HCV. 1 Recently, genotype 7a was discovered in Canadian and Belgian patients, who were presumably infected in Central Africa. 2
Development of JFH1-based cell culture systems for hepatitis C virus genotype 4a and evidence for cross-genotype neutralization
Efficient in vitro systems to study the life cycle of hepatitis C virus (HCV) were recently developed for JFH1 (genotype 2a), which has unique replication capacity in Huh7 cells. We developed 4a/JFH1 intergenotypic recombinants containing the structural genes (Core, E1, and E2), p7, and all or part of NS2 of the 4a prototype strain ED43 that, after transfection of Huh7.5 cells with RNA transcripts, produced infectious viruses. Compared with the J6/JFH control virus, production of viruses was delayed. However, efficient spread of infection and high HCV RNA and infectivity titers were obtained in serial passages. Sequence analysis of recovered viruses and subsequent reverse genetic studies revealed a vital dependence on one or two NS2 mutations, depending on the 4a/2a junction. Infectivity of ED43/JFH1 viruses was CD81 dependent. The genotype 4 cell culture systems permit functional analyses as well as drug and vaccine research on an increasingly important genotype in the Middle East, Africa, and Europe. We also developed genotype 1a intergenotypic recombinants from H77C with vital mutations in NS3. Using H77C/JFH1 and ED43/JFH1 viruses, we demonstrated high homologous neutralizing antibody titers in 1a and 4a patient sera, respectively. Furthermore, availability of JFH1 viruses with envelope proteins of the six major HCV genotypes permitted cross-neutralization studies; 1a and 4a serum crossneutralized 1a, 4a, 5a, and 6a but not 2a and 3a viruses. Thus, the JFH1 intergenotypic recombinants will be of importance for future studies of HCV neutralization and accelerate the development of passive and active immunoprophylaxis.Egypt ͉ hepatitis C virus strain ED43 ͉ in vitro infection ͉ intergenotypic recombinant ͉ vaccine A pproximately 180 million people are infected with hepatitis C virus (HCV) and are at increased risk of developing severe liver disease. HCV isolates from around the world cluster into six major genotypes, which differ by Ϸ30% at the nucleotide (nt) and deduced amino acid level (1). Genotype 4 is primarily found in the Middle East and Africa (2, 3). In Egypt, Ϸ15% of the population is HCV-infected, with genotype 4a comprising Ϸ90% of cases (2, 3). This particularly high prevalence, presumably caused by an unintended transmission through parenteral treatment for schistosomiasis (3, 4), is at least partly responsible for a still rather high incidence (5), making Egypt a potential region for vaccine trials. Additionally, genotype 4 has been spreading in Europe, resulting in a prevalence of 10% in certain regions (2). Although the only approved treatment for chronic HCV infection, combination therapy with IFN-␣ and ribavirin, leads to a sustained virologic response in most of genotype 2 or 3 patients, viral clearance is obtained for only approximately half of patients with genotype 1 or 4. There is no vaccine against HCV.Research on specific antiviral drugs and vaccines has been hampered by the absence of a full viral life cycle cell culture system. However, development of such a system came with cDNA c...
Hypervariable region 1 (HVR1) of hepatitis C virus (HCV) E2 envelope glycoprotein has been implicated in virus neutralization and persistence. We deleted HVR1 from JFH1-based HCV recombinants expressing Core/E1/E2/p7/NS2 of genotypes 1 to 6, previously found to grow efficiently in human hepatoma Huh7.5 cells. The 2a ⌬HVR1 , 5a ⌬HVR1 , and 6a ⌬HVR1 Core-NS2 recombinants retained viability in Huh7.5 cells, whereas 1a ⌬HVR1 , 1b ⌬HVR1 , 2b ⌬HVR1 , 3a ⌬HVR1 , and 4a ⌬HVR1 recombinants were severely attenuated. However, except for recombinant 4a ⌬HVR1 , viruses eventually spread, and reverse genetics studies revealed adaptive envelope mutations that rescued the infectivity of 1a ⌬HVR1 , 1b ⌬HVR1 , 2b ⌬HVR1 , and 3a ⌬HVR1 recombinants. Thus, HVR1 might have distinct functional roles for different HCV isolates. Ultracentrifugation studies showed that deletion of HVR1 did not alter HCV RNA density distribution, whereas infectious particle density changed from a range of 1.0 to 1.1 g/ml to a single peak at ϳ1.1 g/ml, suggesting that HVR1 was critical for low-density HCV particle infectivity. Using chronic-phase HCV patient sera, we found three distinct neutralization profiles for the original viruses with these genotypes. In contrast, all HVR1-deleted viruses were highly sensitive with similar neutralization profiles. In vivo relevance for the role of HVR1 in protecting HCV from neutralization was demonstrated by ex vivo neutralization of 2a and 2a ⌬HVR1 produced in human liver chimeric mice. Due to the high density and neutralization susceptibility of HVR1-deleted viruses, we investigated whether a correlation existed between density and neutralization susceptibility for the original viruses with genotypes 1 to 6. Only the 2a virus displayed such a correlation. Our findings indicate that HVR1 of HCV shields important conserved neutralization epitopes with implications for viral persistence, immunotherapy, and vaccine development.
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