Hypervariable regions in the putative glycoprotein of hepatitis C virus.

A comparison of the sequences of the putative glycoprotein region in three independent cDNA clones of hepatitis C virus and of sequences of four other clones revealed extensive genetic variation clustered and interspersed with highly conserved amino acid sequences. We obtained evidence for two hypervariable regions in the putative envelope glycoprotein, one region was assumed to be a potential antigenic site, as deduced from the hydrophilicity and analyses of secondary structures. These observations suggest the existence of a large pool of antigenic variants of hepatitis C virus, in Japan.     

Characterization of functional hepatitis C virus envelope glycoproteins

Hepatitis C virus (HCV) encodes two envelope glycoproteins, E1 and E2, that assemble as a noncovalent heterodimer which is mainly retained in the endoplasmic reticulum. Because assembly into particles and secretion from the cell lead to structural changes in viral envelope proteins, characterization of the proteins associated with the virion is necessary in order to better understand how they mature to be functional in virus entry. There is currently no efficient and reliable cell culture system to amplify HCV, and the envelope glycoproteins associated with the virion have therefore not been characterized yet. Recently, infectious pseudotype particles that are assembled by displaying unmodified HCV envelope glycoproteins on retroviral core particles have been successfully generated. Because HCV pseudotype particles contain fully functional envelope glycoproteins, these envelope proteins, or at least a fraction of them, should be in a mature conformation similar to that on the native HCV particles. In this study, we used conformation-dependent monoclonal antibodies to characterize the envelope glycoproteins associated with HCV pseudotype particles. We showed that the functional unit is a noncovalent E1E2 heterodimer containing complex or hybrid type glycans. We did not observe any evidence of maturation by a cellular endoprotease during the transport of these envelope glycoproteins through the secretory pathway. These envelope glycoproteins were recognized by a panel of conformation-dependent monoclonal antibodies as well as by CD81, a molecule involved in HCV entry. The functional envelope glycoproteins associated with HCV pseudotype particles were also shown to be sensitive to low-pH treatment. Such conformational changes are likely necessary to initiate fusion.     

Basic residues in hypervariable region 1 of hepatitis C virus envelope glycoprotein e2 contribute to virus entry

The N terminus of hepatitis C virus (HCV) envelope glycoprotein E2 contains a hypervariable region (HVR1) which has been proposed to play a role in viral entry. Despite strong amino acid variability, HVR1 is globally basic, with basic residues located at specific sequence positions. Here we show by analyzing a large number of HVR1 sequences that the frequency of basic residues at each position is genotype dependent. We also used retroviral pseudotyped particles (HCVpp) harboring genotype 1a envelope glycoproteins to study the role of HVR1 basic residues in entry. Interestingly, HCVpp infectivity globally increased with the number of basic residues in HVR1. However, a shift in position of some charged residues also modulated HCVpp infectivity. In the absence of basic residues, infectivity was reduced to the same level as that of a mutant deleted of HVR1. We also analyzed the effect of these mutations on interactions with some potential HCV receptors. Recognition of CD81 was not affected by changes in the number of charged residues, and we did not find a role for heparan sulfates in HCVpp entry. The involvement of the scavenger receptor class B type I (SR-BI) was indirectly analyzed by measuring the enhancement of infectivity of the mutants in the presence of the natural ligand of SR-BI, high-density lipoproteins (HDL). However, no correlation between the number of basic residues within HVR1 and HDL enhancement effect was observed. Despite the lack of evidence of the involvement of known potential receptors, our results demonstrate that the presence of basic residues in HVR1 facilitates virus entry.     

Sequence evolution of the hypervariable region in the putative envelope region E2/NS1 of hepatitis C virus is correlated with specific humoral immune responses.

Sequence evolution of the hypervariable region 1 (HVR1) in the N terminus of E2/NS1 of hepatitis C virus (HCV) was studied retrospectively in six chimpanzees inoculated with the same genotype 1b strain, containing a unique predominant HVR1 sequence. Immediately after inoculation, all animals contained the same HVR predominant sequence. Two animals developed an acute self-limiting infection. Anti-HVR1 immunoglobulin G (IgG) was produced 40 to 60 days after inoculation and rapidly disappeared after normalization of transaminases. Another chimpanzee, previously infected with human immunodeficiency virus type 1, showed a delayed response to HVR1 epitopes after superinfection with HCV. No sequence variation of HVR1 was observed in these two animals during the transient viremia in the acute phase. Three other chimpanzees developed a chronic HCV infection. During follow up, sequence evolution occurred in two animals and their anti-HVR1 response remained at varying but detectable levels. The first mutations occurred immediately after the production of anti-HVR1 during the acute phase. However, IgM anti-HVR1 was not detectable. Remarkably, HVR1 sequences remained conserved for more than 6 years in another chronically infected animal. This correlated with the complete absence of detectable anti-HVR1 during this period. Seven years after inoculation, anti-HVR1 IgG was produced and coincided with an HVR1 alteration. These results strongly suggest the involvement of neutralizing anti-HVR antibodies in sequence evolution of HVR1 through immune selection.     

Interaction between hepatitis C virus core protein and E1 envelope protein.

Hepatitis C virus has three structural genes named C, E1, and E2. The C gene encodes the core (capsid) protein and the E1 and E2 genes encode the envelope proteins. In an immunoprecipitation experiment, the E1 protein was found to be precipitated by an anti-core antibody in the presence but not in the absence of the core protein, indicating that the E1 protein can interact with the core protein. This interaction is independent of whether the E1 and the C genes are linked in cis or separated in different DNA constructs for expression. The interaction between the core and the E1 proteins is confirmed by the observation that a hybrid protein derived from the core protein and the tissue plasminogen activator is localized in the nucleus in the absence of the E1 protein and in the perinuclear region in the presence of the E1 protein. Deletion-mapping studies indicate that the carboxy-terminal sequences of both the core and the E1 proteins are important for their interaction. Since little E1 sequence is exposed on the cytosolic side of the membrane of the endoplasmic reticulum, the interaction between the core and the E1 proteins most likely takes place in the endoplasmic reticulum membrane. The E2 protein could not be coprecipitated with the core protein by the anti-core antibody in a similar assay and likely does not interact with the core protein. The implications of these findings on the morphogenesis of the hepatitis C virus virion are discussed.     

Identification of new functional regions in hepatitis C virus envelope glycoprotein E2

Little is known about the structure of the envelope glycoproteins of hepatitis C virus (HCV). To identify new regions essential for the function of these glycoproteins, we generated HCV pseudoparticles (HCVpp) containing HCV envelope glycoproteins, E1 and E2, from different genotypes in order to detect intergenotypic incompatibilities between these two proteins. Several genotype combinations were nonfunctional for HCV entry. Of interest, a combination of E1 from genotype 2a and E2 from genotype 1a was nonfunctional in the HCVpp system. We therefore used this nonfunctional complex and the recently described structural model of E2 to identify new functional regions in E2 by exchanging protein regions between these two genotypes. The functionality of these chimeric envelope proteins in the HCVpp system and/or the cell-cultured infectious virus (HCVcc) was analyzed. We showed that the intergenotypic variable region (IgVR), hypervariable region 2 (HVR2), and another segment in domain II play a role in E1E2 assembly. We also demonstrated intradomain interactions within domain I. Importantly, we also identified a segment (amino acids [aa] 705 to 715 [segment 705-715]) in the stem region of E2, which is essential for HCVcc entry. Circular dichroism and nuclear magnetic resonance structural analyses of the synthetic peptide E2-SC containing this segment revealed the presence of a central amphipathic helix, which likely folds upon membrane binding. Due to its location in the stem region, segment 705-715 is likely involved in the reorganization of the glycoprotein complexes taking place during the fusion process. In conclusion, our study highlights new functional and structural regions in HCV envelope glycoprotein E2.     

Characterization of hepatitis C virus envelope glycoprotein complexes expressed by recombinant vaccinia viruses.

We constructed recombinant vaccinia virus vectors for expression of the structural region of hepatitis C virus (HCV). Infection of mammalian cells with a vector (vv/HCV1-906) encoding C-E1-E2-NS2 generated major protein species of 22 kDa (C), 33 to 35 kDa (E1), and 70 to 72 kDa (E2), as observed previously with other mammalian expression systems. The bulk of the E1 and E2 expressed by vv/HCV1-906 was found integrated into endoplasmic reticulum membranes as core-glycosylated species, suggesting that these E1 and E2 species represent intracellular forms of the HCV envelope proteins. HCV E1 and E2 formed E1-E2 complexes which were precipitated by either anti-E1 or anti-E2 serum and which sedimented at approximately 15 S on glycerol density gradients. No evidence of intermolecular disulfide bonding between E1 and E2 was detected. E1 and E2 were copurified to approximately 90% purity by mild detergent extraction followed by chromatography on Galanthus nivalus lectin-agarose and DEAE-Fractogel. Immunization of chimpanzees with purified E1-E2 generated high titers of anti-E1 and anti-E2 antibodies. Further studies, to be reported separately, demonstrated that purified E1-E2 complexes were recognized at high frequency by HCV+ human sera (D. Y. Chien, Q.-L. Choo, R. Ralston, R. Spaete, M. Tong, M. Houghton, and G. Kuo, Lancet, in press) and generated protective immunity in chimpanzees (Q.-L. Choo, G. Kuo, R. Ralston, A. Weiner, D. Chien, G. Van Nest, J. Han, K. Berger, K. Thudium, J. Kansopon, J. McFarland, A. Tabrizi, K. Ching, B. Mass, L. B. Cummins, E. Muchmore, and M. Houghton, submitted for publication), suggesting that these purified HCV envelope proteins display native HCV epitopes.     

Functional hepatitis C virus envelope glycoproteins

Hepatitis C virus (HCV) encodes two envelope glycoproteins, E1 and E2, that are released from HCV polyprotein by signal peptidase cleavage. These proteins assemble as a noncovalent heterodimer that is retained in the endoplasmic reticulum. The transmembrane domains of E1 and E2 are multifunctional and play a major role in the biogenesis of E1E2 heterodimer. Because HCV does not replicate efficiently in cell culture, surrogate models have been developed to study some steps of its life cycle. Recently, infectious pseudotype particles (HCVpp) harboring unmodified E1E2 glycoproteins onto retroviral core particles have successfully been generated. They mimic the function of native HCV particles, thus representing a model to study the early steps of its lifecycle. The noncovalent E1E2 heterodimers present at the surface of the HCVpp, which contain complex-type glycans indicating modification by Golgi enzymes, are likely to mediate virus entry. The CD81 tetraspanin and the scavenger receptor SR-BI, two cellular molecules shown to interact with E2, are essential for HCVpp entry. However, these two proteins are not sufficient to provide entry functions in non permissive cells, suggesting that additional unidentified cellular factor(s) are necessary for HCVpp entry. Potential structural homology with other fusion proteins from closely related viruses suggest that HCV envelope glycoproteins belong to class II fusion proteins, but contrary to what is observed for other viral envelope proteins of this class, they are highly glycosylated and are not matured by a cellular endoprotease cleavage.     

Expression of processed envelope protein of hepatitis C virus in mammalian and insect cells.

The putative envelope protein of hepatitis C virus (HCV) was expressed in insect cells by using a baculovirus expression vector and in monkey COS cells under the control of exogenous promoters. The expressed envelope proteins, identified by immunoblot analysis using sera from patients with chronic HCV infection, were a series of glycoproteins of 35 to 24 kDa (gp35-24) in insect cells and a single species of glycoprotein of 35 kDa (gp35) in monkey cells. The size difference of these proteins was due to the different degrees of glycosylation. The envelope proteins expressed in these cells were produced by common specific cleavage from the precursor protein, and cleavage positions of the envelope protein were mapped at about amino acids 190 and 380. The gp35-24 proteins expressed in insect cells were used for detection of antibody against HCV envelope protein in patient sera. The results showed that (i) the antibody is detected in 2 to 17% of various patients with hepatitis C, (ii) three patients were apparently cured after acquiring the antienvelope antibody, and (iii) in sera of patients with more than a 20-year history of infection, the antibody sometimes coexisted with HCV. These results suggest that the antienvelope antibody is neutralizing only in limited number of patients with hepatitis C.     

Characterization of a putative fusogenic sequence in the E2 hepatitis G virus protein

With the aim of better understanding the fusion process mediated by the envelope proteins of the hepatitis G virus (HGV/GBV-C), we have investigated the interaction with model membranes of two overlapping peptides [(267-284) and (279-298)] belonging to the E2 structural protein. The peptides were compared for their ability to perturb lipid bilayers by means of different techniques such as differential scanning calorimetry and fluorescence spectroscopy. Furthermore, the conformational behaviour of the peptides in different membrane environments was studied by Fourier-transform infrared spectroscopy and circular dichroism. The results showed that only the E2(279-298) peptide sequence was able to bind with high affinity to negatively charged membranes, to permeabilize efficiently negative lipid bilayers, to induce haemolysis, and to promote inter-vesicle fusion. This fusogenic activity could be related to the induced peptide conformation upon interaction with the target membrane.     

Glycosylation of hepatitis C virus envelope proteins

Enveloped viruses are surrounded by a membrane derived from the host-cell that contains proteins called "envelope proteins". These proteins play a major role in virus assembly and entry. In most of the enveloped viruses, they are modified by N-linked glycosylation which is supposed to play a role in their stability, antigenicity and biological functions. Glycosylation is also known to play a major role in the biogenesis of proteins by being directly and/or indirectly involved in protein folding. Recent studies on hepatitis C virus (HCV) envelope proteins have revealed a complex interplay between cleavage by signal peptidase, folding and glycosylation. The knowledge that has been accumulated on the early steps of glycosylation of these proteins is presented in this review.     

The membrane-active regions of the hepatitis C virus E1 and E2 envelope glycoproteins

We have identified the membrane-active regions of the full sequences of the HCV E1 and E2 envelope glycoproteins by performing an exhaustive study of membrane leakage, hemifusion, and fusion induced by 18-mer peptide libraries on model membranes having different phospholipid compositions. The data and their comparison have led us to identify different E1 and E2 membrane-active segments which might be implicated in viral membrane fusion, membrane interaction, and/or protein-protein binding. Moreover, it has permitted us to suggest that the fusion peptide might be located in the E1 glycoprotein and, more specifically, the segment comprised by amino acid residues 265-296. The identification of these membrane-active segments from the E1 and E2 envelope glycoproteins, as well as their membranotropic propensity, supports their direct role in HCV-mediated membrane fusion, sustains the notion that different segments provide the driving force for the merging of the viral and target cell membranes, and defines those segments as attractive targets for further development of new antiviral compounds.     

Antigenicity and B-epitope mapping of hepatitis C virus envelope protein E2

Immunogenicity for laboratory animals (rabbits and mice) of the whole hepatitis C virus envelope proteins and their conserved as well as hypervariable HVR1 sites has been investigated. Rabbit immune responses to HCV envelope proteins (both single E2 and E1E2 heterodimer) were shown to be much more efficient than murine immune responses. Rabbit immunization with E2 protein caused formation of antibodies to several highly conserved linear B-epitopes of this protein as well as to the N-terminal fragment of the hypervariable region HVR1. Epitopes in the CR2 region were determined for the first time. There was cross-reactivity between the N-terminal fragment of the protein E2 hypervariable region HVR1 and the octapeptide fragment of the protein E1 conserved region CR1, which shared four identical amino acid residues.     

Cyanovirin-N inhibits hepatitis C virus entry by binding to envelope protein glycans

Inhibition of viruses at the stage of viral entry provides a route for therapeutic intervention. Because of difficulties in propagating hepatitis C virus (HCV) in cell culture, entry inhibitors have not yet been reported for this virus. However, with the development of retroviral particles pseudotyped with HCV envelope glycoproteins (HCVpp) and the recent progress in amplification of HCV in cell culture (HCVcc), studying HCV entry is now possible. In addition, these systems are essential for the identification and the characterization of molecules that block HCV entry. The lectin cyanovirin-N (CV-N) has initially been discovered based on its potent activity against human immunodeficiency virus. Because HCV envelope glycoproteins are highly glycosylated, we sought to determine whether CV-N has an antiviral activity against this virus. CV-N inhibited the infectivity of HCVcc and HCVpp at low nanomolar concentrations. This inhibition is attributed to the interaction of CV-N with HCV envelope glycoproteins. In addition, we showed that the carbohydrate binding property of CV-N is involved in the anti-HCV activity. Finally, CV-N bound to HCV envelope glycoproteins and blocked the interaction between the envelope protein E2 and CD81, a cell surface molecule involved in HCV entry. These data demonstrate that targeting the glycans of HCV envelope proteins is a promising approach in the development of antiviral therapies to combat a virus that is a major cause of chronic liver diseases. Furthermore, CV-N is a new invaluable tool to further dissect the early steps of HCV entry into host cells.     

Detection of divergent hepatitis C virus envelope sequences

The nucleotide sequences of the putative envelope region (E1) and the junction between the E1 and envelope 2/nonstructural 1 (E2/NS1) region of the hepatitis C virus (HCV) genome are divergent among different genotypes. To characterize them, we introduced a set of nested primers that are conserved among four different genotypes (types I–IV) of HCV for polymerase chain reaction (PCR) amplification. The amplified products include the variable full-length E1 region, and the 5 end of the E2/NS1 region, the so-called hypervariable region-1 (HVR-1). Of 53 patients with histologically confirmed chronic liver disease and HCV viremia, type II virus was the most dominant strain as detected by the PCR genotyping method and the envelope region could be amplified in more than half of them irrespective of their genotypes. The specificity was confirmed by subsequent nucleotide sequence analysis. The positivity of envelope region PCR was not correlated with histologic diagnosis and hepatitis activities in these patients. Our results suggest that the nested primers can amplify the variable E1 and hypervariable 5 end of E2/NS1 of the HCV genome with moderate efficiency, and thus will be useful in future studies of HCV infections.     

Occurrence of antibodies reactive with more than one variant of the putative envelope glycoprotein (gp70) hypervariable region 1 in viremic hepatitis C virus-infected patients.

The hepatitis C virus (HCV) is a frequent cause of chronic liver disease. A mechanism proposed as being responsible for virus persistence is evasion of the host immune response through a high mutation rate in crucial regions of the viral genome. We have sequenced the hypervariable region 1 (HVR1) of the virus isolated from three serum samples, collected during 18 months of follow-up, from an asymptomatic HCV-infected patient. A synthetic peptide of 27 amino acids, corresponding to the HVR1 sequence found to be predominant in both the second and third samples, was used as the antigen for detection of antibodies by enzyme-linked immunosorbent assay (ELISA). We observed reactivity against this HVR1 sequence in the first serum sample before the appearance of the viral isolate in the bloodstream; the reactivity increased in the second and third samples while the cognate viral sequence became predominant. Moreover, our results show that antibodies from all three samples recognize a region mapping at the carboxyl-terminal part of the HVR1 and are cross-reactive with the HVR1 sequence previously found in the same patient. The presence of anti-HVR1 antibodies was investigated in a further 142 HCV patients: 121 viremic and 21 nonviremic. Two synthetic peptides were used, the first corresponding to the sequence derived from the patient described above and the second one synthesized according to the sequence of the HCV BK strain. A high frequency of positive reactions against both HVR1 variants was detected in the samples from the viremic individuals. Finally, antibodies cross-reactive with both variants were shown to be present by competitive ELISA in 6 of 10 viremic patients. The potential negative implications of this observation for the host are discussed.     

Role of the large hepatitis B virus envelope protein in infectivity of the hepatitis delta virion.

The hepatitis delta virus (HDV) is coated with large (L), middle (M), and small (S) envelope proteins encoded by coinfecting hepatitis B virus (HBV). To study the role of the HBV envelope proteins in the assembly and infectivity of HDV, we produced three types of recombinant particles in Huh7 cells by transfection with HBV DNA and HDV cDNA: (i) particles with an envelope containing the S HBV envelope protein only, (ii) particles with an envelope containing S and M proteins, and (iii) particles with an envelope containing S, M, and L proteins. Although the resulting S-, SM-, and SML-HDV particles contained both hepatitis delta antigen and HDV RNA, only particles coated with all three envelope proteins (SML) showed evidence of infectivity in an in vitro culture system susceptible to HDV infection. We concluded that the L HBV envelope protein, and more specifically the pre-S1 domain, is important for infectivity of HDV particles and that the M protein, which has been reported to bear a site for binding to polymerized albumin in the pre-S2 domain, is not sufficient for infectivity. Our data also show that the helper HBV is not required for initiation of HDV infection. The mechanism by which the L protein may affect HDV infectivity is discussed herein.     

Genetic drift in hypervariable region 1 of the viral genome in persistent hepatitis C virus infection.

The hypervariable region 1 (HVR1) of the putative second envelope glycoprotein (gp70) of hepatitis C virus (HCV) contains a sequence-specific immunological B-cell epitope that induces the production of antibodies restricted to the specific viral isolate, and anti-HVR1 antibodies are involved in the genetic drift of HVR1 driven by immunoselection (N. Kato, H. Sekiya, Y. Ootsuyama, T. Nakazawa, M. Hijikata, S. Ohkoshi, and K. Shimotohno, J. Virol. 67:3923-3930, 1993). We further investigated the sequence variability of the HCV genomic region that entirely encodes the envelope proteins (gp35 and gp70); these sequences were derived from virus isolated during the acute and chronic phases of hepatitis in one patient, and we found that HVR1 was a major site for genetic mutations in HCV after the onset of hepatitis. We carried out epitope-mapping experiments using the HVR1 sequence derived from the acute phase of hepatitis and identified two overlapping epitopes which are each composed of 11 amino acids (positions 394 to 404 and 397 to 407). The presence of two epitopes within HVR1 suggested that epitope shift happened during the course of hepatitis. Four of six amino acid substitutions detected in HVR1 were located within the two epitopes. We further examined the reactivities of anti-HVR1 antibodies to the substituted amino acid sequences within the two epitopes. HVR1 variants in both epitopes within the HVR1 escaped from anti-HVR1 antibodies that were preexisting in the patient's serum.