Structure of replicating hepatitis C virus (HCV) quasispecies in the liver may not be reflected by analysis of circulating HCV virions

The Structural Basis of African Swine Fever Virus pS273R Protease Binding to E64 through Molecular Dynamics Simulations

Identification of novel drugs for anti-African swine fever (ASF) applications is of utmost urgency, as it negatively affects pig farming and no effective vaccine or treatment is currently available. African swine fever virus (ASFV) encoded pS273R is a cysteine protease that plays an important role in virus replication. E64, acting as an inhibitor of cysteine protease, has been established as exerting an inhibitory effect on pS273R. In order to obtain a better understanding of the interaction between E64 and pS273R, common docking, restriction docking, and covalent docking were employed to analyze the optimal bonding position between pS273R-E64 and its bonding strength. Additionally, three sets of 100 ns molecular dynamics simulations were conducted to examine the conformational dynamics of pS273R and the dynamic interaction of pS273R-E64, based on a variety of analytical methods including root mean square deviation (RMSD), root mean square fluctuation (RMSF), free energy of ligand (FEL), principal component analysis (PCA), and molecular mechanics/Poisson-Boltzmann surface area (MM/PBSA) analysis. The results show that E64 and pS273R exhibited close binding degrees at the activity center of ASFV pS273R protease. The data of these simulations indicate that binding of E64 to pS273R results in a reduction in flexibility, particularly in the ARM region, and a change in the conformational space of pS273R. Additionally, the ability of E64 to interact with polar amino acids such as ASN158, SER192, and GLN229, as well as charged amino acids such as LYS167 and HIS168, seems to be an important factor in its inhibitory effect. Finally, Octet biostratigraphy confirmed the binding of E64 and pS273R with a KD value of 903 uM. Overall, these findings could potentially be utilized in the development of novel inhibitors of pS273R to address the challenges posed by ASFV.

Characterization of Hepatitis C Virus IRES Quasispecies - From the Individual to the Pool

Hepatitis C virus (HCV) is a single-stranded positive-sense RNA virus from the genus Hepacivirus. The viral genomic +RNA is 9.6 kb long and contains highly structured 5′ and 3′ untranslated regions (UTRs) and codes for a single large polyprotein, which is co- and post-translationally processed by viral and cellular proteases into at least 11 different polypeptides. Most of the 5′ UTR and an initial part of the polyprotein gene are occupied by an internal ribosome entry site (IRES), which mediates cap-independent translation of the viral proteins and allows the virus to overcome cellular antiviral defense based on the overall reduction of the cap-dependent translation initiation. We reconsidered published results concerning a search for possible correlation between patient response to interferon-based antiviral therapy and accumulation of nucleotide changes within the HCV IRES. However, we were unable to identify any such correlation. Rather than searching for individual mutations, we suggest to focus on determination of individual and collective activities of the HCV IRESs found in patient specimens. We developed a combined, fast, and undemanding approach based on high-throughput cloning of the HCV IRES species to a bicistronic plasmid followed by determination of the HCV IRES activity by flow cytometry. This approach can be adjusted for measurement of the individual HCV IRES activity and for estimation of the aggregate ability of the whole HCV population present in the specimen to synthesize viral proteins. To detect nucleotide variations in the individual IRESs, we used denaturing gradient gel electrophoresis (DGGE) analysis that greatly improved identification and classification of HCV IRES variants in the sample. We suggest that determination of the collective activity of the majority of HCV IRES variants present in one patient specimen in a given time represents possible functional relations among variant sequences within the complex population of viral quasispecies better than bare information about their nucleotide sequences. A similar approach might be used for monitoring of sequence variations in quasispecies populations of other RNA viruses in all cases when changes in primary sequence represent changes in measurable and easily quantifiable phenotypes.

Vertical Transmission of Hepatitis C Virus: Variable Transmission Bottleneck and Evidence of Midgestation In Utero Infection

Hepatitis C virus (HCV) can be transmitted from mother to child during pregnancy and childbirth. However, the timing and precise biological mechanisms that are involved in this process are incompletely understood, as are the determinants that influence transmission of particular HCV variants. Here we report results of a longitudinal assessment of HCV quasispecies diversity and composition in 5 cases of vertical HCV transmission, including 3 women coinfected with human immunodeficiency virus type 1 (HIV-1). The population structure of HCV variant spectra based on E2 envelope gene sequences (nucleotide positions 1491 to 1787), including hypervariable regions 1 and 2, was characterized using next-generation sequencing and median-joining network analysis. Compatible with a loose transmission bottleneck, larger numbers of shared HCV variants were observed in the presence of maternal coinfection. Coalescent Bayesian Markov chain Monte Carlo simulations revealed median times of transmission between 24.9 weeks and 36.1 weeks of gestation, with some confidence intervals ranging into the 1st trimester, considerably earlier than previously thought. Using recombinant autologous HCV pseudoparticles, differences were uncovered in HCV-specific antibody responses between coinfected mothers and mothers infected with HCV alone, in whom generalized absence of neutralization was observed. Finally, shifts in HCV quasispecies composition were seen in children around 1 year of age, compatible with the disappearance of passively transferred maternal immunoglobulins and/or the development of HCV-specific humoral immunity. Taken together, these results provide insights into the timing, dynamics, and biologic mechanisms involved in vertical HCV transmission and inform preventative strategies.IMPORTANCE Although it is well established that hepatitis C virus (HCV) can be transmitted from mother to child, the manner and the moment at which transmission operates have been the subject of conjecture. By carrying out a detailed examination of viral sequences, we showed that transmission could take place comparatively early in pregnancy. In addition, we showed that when the mother also carried human immunodeficiency virus type 1 (HIV-1), many more HCV variants were shared between her and her child, suggesting that the mechanism and/or the route of transmission of HCV differed in the presence of coinfection with HIV-1. These results could explain why cesarean section is ineffective in preventing vertical HCV transmission and guide the development of interventions to avert pediatric HCV infection.

Identification of HCV Resistant Variants against Direct Acting Antivirals in Plasma and Liver of Treatment Naïve Patients

Current standard-of-care treatment of chronically infected hepatitis C virus (HCV) patients involves direct-acting antivirals (DAA). However, concerns exist regarding the emergence of drug -resistant variants and subsequent treatment failure. In this study, we investigate potential natural drug-resistance mutations in the NS5B gene of HCV genotype 1b from treatment-naïve patients. Population-based sequencing and 454 deep sequencing of NS5B gene were performed on plasma and liver samples obtained from 18 treatment- naïve patients. The quasispecies distribution in plasma and liver samples showed a remarkable overlap in each patient. Although unique sequences in plasma or liver were observed, in the majority of cases the most dominant sequences were shown to be identical in both compartments. Neither in plasma nor in the liver codon changes were detected at position 282 that cause resistance to nucleos(t)ide analogues. However, in 10 patients the V321I change conferring resistance to nucleos(t)ide NS5B polymerase inhibitors and in 16 patients the C316N/Y/H non-nucleoside inhibitors were found mainly in liver samples. In conclusion, 454-deep sequencing of liver and plasma compartments in treatment naïve patients provides insight into viral quasispecies and the pre-existence of some drug-resistant variants in the liver, which are not necessarily present in plasma.

NS3 protease resistance-associated substitutions in liver tissue and plasma samples from patients infected by hepatitis C virus genotype 1A or 1B

The presence of naturally occurring resistance-associated substitutions (RASs) in the HCV-protease domain has been poorly investigated in the liver, the main site of HCV replication. We evaluated the natural resistance of the virus to NS3 protease inhibitors in liver tissue and plasma samples taken from HCV-infected patients. RASs were investigated by means of viral population sequencing in liver tissue samples from 18 HCV-infected patients harbouring genotype 1a or genotype 1b; plasma samples from 12 of these patients were also available for virological investigation. A discordant genotype was found in two of the 12 patients (16.6%) who provided samples from both compartments. Sequence analysis of the NS3 protease domain showed the presence of RASs in four of the 18 liver tissue samples (22.2%), two of which showed cross-resistance to protease inhibitors in clinical use or phase 2-3 trials. The analysis of the 12 paired tissues and plasma samples excluded the presence of RASs in the plasma compartment. The dominance of discordant genotypes in the paired liver and plasma samples of some HCV-infected patients suggests mixed infection possibly leading to the selective advantage of different genotype in the two compartments. The presence of RASs at intra-hepatic level is not uncommon and may lead to the early emergence of cross-resistant strains.

Inter and intra-host variability of hepatitis C virus genotype 1a hypervariable envelope coding domains followed for a 4-11 year of human immunodeficiency virus coinfection and highly active antiretroviral therapy

The evolution of hepatitis C virus (HCV) quasispecies in patients with HIV-1 coinfection is not fully understood. The HCV-1a quasispecies heterogeneity was analyzed at inter and intra-host levels along 7.6 years in 21 coinfected patients that showed different virological and immunological responses to highly active antiretroviral therapy (HAART). Two to nine serial samples were subjected to direct and clonal sequence analyses of the envelope glycoprotein 2 (E2) gene. E2-based phylogenies, intra-host HCV evolution and evolutionary rates, as well as dynamics of the quasispecies heterogeneity parameters were evaluated. Bayesian coalescent phylogenies indicated complex evolutionary histories, revealing some viral lineages that persisted along the follow up and others that were detectable at a single or some sampling times, suggesting the occurrence of emergence-extinction cycles. HCV quasispecies underwent very rapid evolution in HAART-treated patients (~3.1 × 10(-2) sub/site/year) following the recovery of the host immunocompetence irrespectively of the virological response to HAART.

Determining the cellular diversity of hepatitis C virus quasispecies by single-cell viral sequencing

Single-cell genomics is emerging as an important tool in cellular biology. We describe for the first time a system to investigate RNA virus quasispecies diversity at the cellular level utilizing hepatitis C virus (HCV) replicons. A high-fidelity nested reverse transcription (RT)-PCR assay was developed, and validation using control transcripts of known copy number indicated a detection limit of 3 copies of viral RNA/reaction. This system was used to determine the cellular diversity of subgenomic JFH-1 HCV replicons constitutively expressed in Huh7 cells. Each cell contained a unique quasispecies that was much less diverse than the quasispecies of the bulk cell population from which the single cells were derived, suggesting the occurrence of independent evolution at the cellular level. An assessment of the replicative fitness of the predominant single-cell quasispecies variants indicated a modest reduction in fitness compared to the wild type. Real-time RT-PCR methods capable of determining single-cell viral loads were developed and indicated an average of 113 copies of replicon RNA per cell, correlating with calculated RNA copy numbers in the bulk cell population. This study introduces a single-cell RNA viral-sequencing method with numerous potential applications to explore host-virus interactions during infection. HCV quasispecies diversity varied greatly between cells in vitro, suggesting different within-cell evolutionary pathways. Such divergent trajectories in vivo could have implications for the evolution and establishment of antiviral-resistant variants and host immune escape mutants.

Human cell types important for hepatitis C virus replication in vivo and in vitro: old assertions and current evidence

Hepatitis C Virus (HCV) is a single stranded RNA virus which produces negative strand RNA as a replicative intermediate. We analyzed 75 RT-PCR studies that tested for negative strand HCV RNA in liver and other human tissues. 85% of the studies that investigated extrahepatic replication of HCV found one or more samples positive for replicative RNA. Studies using in situ hybridization, immunofluorescence, immunohistochemistry, and quasispecies analysis also demonstrated the presence of replicating HCV in various extrahepatic human tissues, and provide evidence that HCV replicates in macrophages, B cells, T cells, and other extrahepatic tissues. We also analyzed both short term and long term in vitro systems used to culture HCV. These systems vary in their purposes and methods, but long term culturing of HCV in B cells, T cells, and other cell types has been used to analyze replication. It is therefore now possible to study HIV-HCV co-infections and HCV replication in vitro.

Hepatitis C virus compartmentalization and infection recurrence after liver transplantation

Hepatitis C virus (HCV) compartmentalization may have important implications in the pathogenesis of HCV infection. The aim of this study was to investigate the presence and relevance of HCV compartmentalization in the setting of liver transplantation (LT). We collected samples of serum, peripheral blood mononuclear cells (PBMC), perihepatic lymph nodes (PLN) and liver explant at the time of LT, and serum and PBMC after transplantation from 57 HCV-infected cirrhotic patients undergoing LT: 38 individuals received antiviral treatment before LT and 19 were untreated controls. HCV-RNA levels were determined by real-time PCR and the hypervariable region 1 (HVR-1) was sequenced. HCV-RNA was detected in all samples from control patients. In virological responders, recurrence after LT was associated with residual HCV-RNA in the liver explant. Within the entire cohort, 47% of patients harbored differences in direct sequences from distinct compartments. Quasispecies analysis revealed that in most cases, HVR-1 sequences recovered after infection recurrence were identical or closely related to those isolated from the liver explant and serum at the time of LT. Our study shows that a significant proportion of HCV-infected cirrhotic patients exhibit compartmentalization. Viral variants originating within the liver appear to be the main cause of HCV recurrence after LT.

Genetic divergence of hepatitis C virus: the role of HIV-related immunosuppression

BACKGROUND

We tested the hypothesis that HIV-related immunosuppression alters the host-hepatitis C virus (HCV) interaction, resulting in fewer amino acid-changing substitutions in HCV viral variants. Higher HCV RNA levels in persons coinfected with HIV compared with HCV infection alone suggest increased viral replication. If this increase is dependent on decreased immune selective pressure, then a reduced rate of nucleotide changes resulting in amino acid replacements (nonsynonymous changes, dN) would be expected.

METHODS

We investigated HCV envelope sequences over time in 79 persons with chronic HCV infection who were HIV negative (group 1) or HIV positive with (group 3) or without (group 2) severe immunodeficiency. We amplified a 1026-nt region of the HCV genome, which encodes a portion of the envelope glycoproteins E1 and E2, including hypervariable region-1 for direct sequence analysis.

RESULTS

The overall divergence between paired sequences, dS, dN, and dN/dS, all showed no significant differences among the 3 groups.

CONCLUSIONS

By measuring nucleotide substitutions in HCV sequences over time, we found no significant differences in the genetic divergence between HCV-monoinfected control subjects and HIV/HCV-coinfected subjects with various levels of immunodeficiency as measured by CD4+ T-cell counts.

IRES complexity before IFN-alpha treatment and evolution of the viral load at the early stage of treatment in peripheral blood mononuclear cells from chronic hepatitis C patients

At the early stage of treatment, IFN alpha-2a induces inhibition of HCV replication. The viral load reflects mainly the degradation rate of the viruses. However, differences in the behavior of the viral population depend on changes, which occurred in the HCV-IRES genome. In this study, cloning and sequencing strategies permitted the generation of a large number of IRES sequences from the PBMCs of 18 patients (5 women, 13 men) with chronic hepatitis C. The HCV IRES appeared to be highly conserved structurally. However, some variability was found between the different isolates obtained: 467 substitutions with a median of 7 variants/patients. No relationship was observed between pre-treatment IRES complexity and the viral load at the beginning. However, on review of the evolution of viral load in the PBMCs during the first 3 days of IFN alpha-2a treatment, patients could be classified into two groups: Group 1, in which the viral population continued to replicate and Group 2, in which the viral load decreased significantly (P = 0.01727). Positioning of the mutations on the predicted IRES secondary structure showed that the distribution of the mutations and their apparition frequency were different between the two groups. At the early stage of treatment, IFN alpha-2a was efficient in reducing the viral replication in a significant number of patients; mechanisms of response might affect the virus directly. However, pre-treatment genomic variations observed in the 5'NCR of HCV were not a parameter of a later response to antiviral therapy in chronic hepatitis C patients. (244)

Molecular mechanism of a thumb domain hepatitis C virus nonnucleoside RNA-dependent RNA polymerase inhibitor

A new pyranoindole class of small-molecule inhibitors was studied to understand viral resistance and elucidate the mechanism of inhibition in hepatitis C virus (HCV) replication. HCV replicon variants less susceptible to inhibition by the pyranoindoles were selected in Huh-7 hepatoma cells. Variant replicons contained clusters of mutations in the NS5B polymerase gene corresponding to the drug-binding pocket on the surface of the thumb domain identified by X-ray crystallography. An additional cluster of mutations present in part of a unique beta-hairpin loop was also identified. The mutations were characterized by using recombinant replicon variants engineered with the corresponding amino acid substitutions. A single mutation (L419M or M423V), located at the pyranoindole-binding site, resulted in an 8- to 10-fold more resistant replicon, while a combination mutant (T19P, M71V, A338V, M423V, A442T) showed a 17-fold increase in drug resistance. The results of a competition experiment with purified NS5B enzyme with GTP showed that the inhibitory activity of the pyranoindole inhibitor was not affected by GTP at concentrations up to 250 microM. Following de novo initiation, the presence of a pyranoindole inhibitor resulted in the accumulation of a five-nucleotide oligomer, with a concomitant decrease in higher-molecular-weight products. The results of these studies have confirmed that pyranoindoles target the NS5B polymerase through interactions at the thumb domain. This inhibition is independent of GTP concentrations and is likely mediated by an allosteric blockade introduced by the inhibitor during the transition to RNA elongation after the formation of an initiation complex.

Do Taq-generated RT-PCR products from RNA viruses accurately reflect viral genetic heterogeneity?

Since the first report of genetically heterogeneous, or quasispecies, populations of RNA viruses, the genetic heterogeneity of the RNA genomes of major viral pathogens has been extensively studied. These studies aim to provide insights into the evolutionary pressures that act upon viruses, in order to define windows where anti-viral therapies will be most effective, to take prognostic values from viral genetic distributions at a given time, and to aid the development of novel therapeutic compounds that may tilt viral replication towards information loss. Many methodologies are employed to analyse genetic distributions of a virus in a given sample, but all involve the generation, and subsequent analysis, of the sequence information contained in a reverse-transcription-polymerase chain reaction (RT-PCR) product. Despite the fact that the aim of these RT-PCRs is to obtain sequence information from viral genomes, their application to this task is approached without adequate consideration of this end-goal. The establishment of an RT-PCR for a specific viral target genome generally proceeds in the same fashion as one would apply to establishing a PCR to determine the presence or absence of a specific target sequence in a given sample. However, it is becoming increasingly apparent that RT-PCR products generated by amplification with the ubiquitous thermostable DNA polymerase Taq, coupled with standard cloning and sequencing methodologies, has the potential to yield inaccurate and misleading data as pertains to the information content of populations of RNA viral genomes. This review discusses varying approaches employed to analyse heterogeneous populations of hepatitis C virus RNA genomes.

Liver transplantation with hepatitis C virus-infected graft: interaction between donor and recipient viral strains

Superinfection of different viral strains within a single host provides an opportunity for studying host-virus and virus-virus interactions, including viral interference and genetic recombination, which cannot be studied in infections with single viral strains. Hepatitis C virus (HCV) is a positive single-strand RNA virus that establishes persistent infection in as many as 85% of infected individuals. However, there are few reports regarding coinfection or superinfection of HCV. Because of the lack of tissue culture systems and small animal models supporting efficient HCV replication, we explored these issues in the setting of liver transplantation where both recipient and donor were infected with different HCV strains and therefore represent a distinct model for HCV superinfection. Serial serum samples collected at multiple time points were obtained from 6 HCV-positive liver donor/recipient pairs from the National Institute of Diabetes and Digestive and Kidney Diseases liver transplantation database. At each time point, HCV genotype was determined by both restriction fragment length polymorphism analysis and phylogenetic analysis. Furthermore, we selectively sequenced 3 full-length HCV isolates at the earliest time points after liver transplantation, including both 5' and 3' ends. Detailed genetic analyses showed that only one strain of HCV could be identified at each time point in all 6 cases. Recipient HCV strains took over in 3 cases, whereas donor HCV strains dominated after liver transplantation in the remaining 3 cases. In conclusion, in all 6 cases studied, there was no genetic recombination detected among HCV quasispecies or between donor and recipient HCV strains.

Quasispecies heterogeneity and constraints on the evolution of the 5' noncoding region of hepatitis C virus (HCV): relationship with HCV resistance to interferon-alpha therapy

Hepatitis C virus (HCV) polyprotein translation depends on direct internal entry of the 40S ribosomal subunit mediated by an internal ribosome entry segment (IRES) located in the 5' noncoding (5'NC) region of the viral genome. HCV is genetically heterogeneous and is characterized by the existence of a quasispecies distribution of the virus population within a single infected individual. Cloning and sequencing strategies were used to characterize 5'NC quasispecies genetically. Similar to coding regions, the HCV 5'NC region was distributed as a quasispecies, but it appeared to be subjected to stronger conservatory constraints than other regions of the HCV genome, probably due to the need for structural (and functional) conservation of the IRES. Indeed, most of the quasispecies substitutions were in unpaired regions of the IRES or clustered such that base-pairing was maintained, whereas only 21% were expected to result in a loss of base-pairing. Quasispecies-related structural changes could be predicted in the core cruciform of IRES domain III composed of the RNA helices which extend from the four-way junction JIIIabc, mostly in minor variants, but sometimes in major ones. The results presented here suggest the simultaneous presence in infected patients of a mixture of genetically distinct but closely related IRES sequences that may have different structures. No significant genetic changes of 5'NC quasispecies were observed after interferon-alpha treatment, except in patients with mixed genotype infection who cleared one of the infecting strains during therapy, suggesting that the quasispecies distribution of IRES sequences does not play a role in HCV resistance to interferon-alpha therapy. In contrast, the overall quasispecies distribution of HCV genomes (including IRES sequences) might participate in regulation of hepatic and extrahepatic HCV replication.

Genetic complexity and serum reactivity of HVR1 quasispecies of hepatitis C virus in patients with cirrhosis

OBJECTIVE

The RNA genome of hepatitis C virus varies considerably, especially within the hypervariable region 1 (HVR1), a domain located on the 5' end of the E2/NS1 envelope region. Our previous study has suggested there were greater numbers of quasispecies in the liver than in matched serum, independent of the viral load. However, the significance of this finding has not been examined extensively at genetic and serological levels.

METHODS

By large scale cloning and sequencing, we studied the genetic complexity of HVR1 quasispecies in two selected patients with cirrhosis. The serum reactivity of peptides representing different HVR1 quasispecies isolated from these cases was also estimated by standard ELISA format.

RESULTS

We found the same major (dominant and/or subdominant) viral quasispecies variants in serum and in the cirrhotic liver. Genetic analysis suggested that the evolutionary pressure on HVR1 was higher than on its flanking region in quasispecies derived from the liver, whereas this trend is attenuated in quasispecies from serum. The immunoreactivity to peptides representing different HVR1 quasispecies variants showed considerable cross-reactivity with heterologous sera, whereas the reactivity was strongest against the dominant HVR1 peptide over time in homologous sera.

CONCLUSIONS

These findings indicate that the formation and selection of HVR1 quasispecies may not be driven solely by humoral immune pressure, at least in these two cases.

Dendritic cell susceptibility to hepatitis C virus genotype 1 infection

In vitro infection of human monocyte-derived dendritic cells was carried out to study their susceptibility to hepatitis C virus (HCV) infection. Immature dendritic cells and mature dendritic cells were incubated overnight at 37 degrees C with HCV-positive (genotype 1) serum samples; the presence of the viral genome associated with the production of its replicative intermediate was used as evidence of infection. In immature dendritic cells, HCV RNA was detectable from days 1-10 post-infection (p.i.), and de novo synthesis of negative-strand HCV RNA could be demonstrated by a strand-specific rTth reverse transcription-polymerase chain reaction at day 2. In mature dendritic cells, the positive-strand form was detectable from days 1-5 p.i., while the negative-strand HCV RNA appeared at days 1 and 2 p.i. Quasispecies present in the inoculum and 6 days p.i. were analyzed by sequencing hypervariable region 1 of the E2 protein. Only two of seven HVR variants present in the inoculum were found in HCV-infected immature dendritic cells. Another two HVR variants not found in the inoculum were recovered from infected immature dendritic cells, suggesting serum minor variants selection or virus evolution during in vitro replication. Analysis by single-strand conformation polymorphism assay of 5' untranslated region of HCV sequences showed that the patterns obtained from the inoculum and infected immature dendritic cells and mature dendritic cells differed slightly. These findings indicate that both immature dendritic cells and mature dendritic cells are susceptible to HCV genotype 1 infection, supporting at least HCV RNA replication. This model should be a valuable tool for the study of modulation of dendritic cell functions in HCV infection.

Longitudinal evaluation of the structure of replicating and circulating hepatitis C virus quasispecies in nonprogressive chronic hepatitis C patients

In previous cross-sectional studies, we demonstrated that, in most patients with chronic hepatitis C, the composition and complexity of the circulating hepatitis C virus (HCV) population do not coincide with those of the virus replicating in the liver. In the subgroup of patients with similar complexities in both compartments, the ratio of quasispecies complexity in the liver to that in serum (liver/serum complexity ratio) of paired samples correlated with disease stage. In the present study we investigated the dynamic behavior of viral population parameters in consecutive paired liver and serum samples, obtained 3 to 6 years apart, from four chronic hepatitis C patients with persistently normal transaminases and stable liver histology. We sequenced 359 clones of a genomic fragment encompassing the E2(p7)-NS2 junction, in two consecutive liver-serum sample pairs from the four patients and in four intermediate serum samples from one of the patients. The results show that the liver/serum complexity ratio is not stable but rather fluctuates widely over time. Hence, the liver/serum complexity ratio does not identify a particular group of patients but a particular state of the infecting quasispecies. Phylogenetic analysis and signature mutation patterns showed that virtually all circulating sequences originated from sequences present in the liver specimens. The overall behavior of the circulating viral quasispecies appears to originate from changes in the relative replication kinetics of the large mutant spectrum present in the infected liver.

Detection of the negative-strand hepatitis C virus RNA in tissues: implications for pathogenesis

The replication of hepatitis C virus (HCV) RNA is believed to occur via its transcription into a complementary, genomic-length RNA, the so-called negative-strand HCV RNA. This is based on the comparison with the replication of other members of the Flaviviridae family. Detection of the negative-strand HCV RNA in human tissues by semi-quantitative, strand-specific RT-PCR has contributed to the understanding of the HCV cell tropism and of the pathogenesis of HCV-associated disease manifestations. In particular, it was shown that the levels of intrahepatic HCV RNA are not correlated to the extent of the necroinflammation, but that a significant correlation was found with the liver steatosis. These results suggest that most liver disease associated with HCV infection is mediated by the host immune response. However, in some patients, most notably those infected with HCV genotype 3, HCV may cause a cytopathic effect, consisting in the lipid accumulation within hepatocytes.

Analysis of HCV-IG isotype complexes by a novel immuno-capture RT-PCR method

HCV can be present in the circulating blood either as a free virus or as a virion-immunoglobulin (Ig) complex. All isotypes of Igs may form the virus complexes, but it remains unclear what specific role of each Ig plays in the clearance of HCV. In the present study, we have combined immuno-capture and RT-PCR, and developed a quick double-specificity method for detecting and distinguishing different HCV-Ig complexes. We compared our new method, the immuno-capture RT-PCR (iRT-PCR), with the conventional RT-PCR (cRT-PCR) for the sensitivity of detecting HCV in 35 clinically diagnosed patients with HCV infection. The results showed that 31 patients were detected to be positive by using iRT-PCR, whereas 16 patients were positive with the use of cRT-PCR. HCV-IgM, HCV-IgG, HCV-IgA could separately be detected by iRT-PCR and their positive rates were 66.7%, 51.0%, 62.7%, respectively. HCV bound to antibody was a common feature of hepatitis C (HC) and 86.3% of patients were positive at least by one of the HCV-Ig tests. The patterns of HCV RNA constituents varied according to disease categories. In summary, iRT-PCR is a valuable method for analysis of the composition of the immune complexes, which may provide new and valuable insights into HCV pathogenesis.

Conservation of the conformation and positive charges of hepatitis C virus E2 envelope glycoprotein hypervariable region 1 points to a role in cell attachment

Chronic hepatitis C virus (HCV) infection is a major cause of liver disease. The HCV polyprotein contains a hypervariable region (HVR1) located at the N terminus of the second envelope glycoprotein E2. The strong variability of this 27-amino-acid region is due to its apparent tolerance of amino acid substitutions together with strong selection pressures exerted by anti-HCV immune responses. No specific function has so far been attributed to HVR1. However, its presence at the surface of the viral particle suggests that it might be involved in viral entry. This would imply that HVR1 is not randomly variable. We sequenced 460 HVR1 clones isolated at various times from six HCV-infected patients receiving alpha interferon therapy (which exerts strong pressure towards quasispecies genetic evolution) and analyzed their amino acid sequences together with those of 1,382 nonredundant HVR1 sequences collected from the EMBL database. We found that (i) despite strong amino acid sequence variability related to strong pressures towards change, the chemicophysical properties and conformation of HVR1 were highly conserved, and (ii) HVR1 is a globally basic stretch, with the basic residues located at specific sequence positions. This conservation of positively charged residues indicates that HVR1 is involved in interactions with negatively charged molecules such as lipids, proteins, or glycosaminoglycans (GAGs). As with many other viruses, possible interaction with GAGs probably plays a role in host cell recognition and attachment.

Rapid changes in hepatitis C virus quasispecies produced by a single dose of IFN-alpha in chronically infected patients

The effects of a single dose of 3 international megaunits of interferon-alpha2b (IFN-alpha2b) on hepatitis C virus (HCV) load and quasispecies were examined 24 h after administration in 12 previously untreated, chronically infected patients. All patients had viremia loads appreciably reduced relative to baseline values, thus confirming that the viral load is rapidly affected by IFN-alpha2b. Five patients also exhibited changes in plasma HCV quasispecies composition that were clearly evident by single-strand conformation polymorphism, analysis, thus indicating that one dose of IFN-alpha2b may suffice to produce rapid perturbations in the genetic heterogeneity of circulating HCV. Prior to IFN-alpha2b administration, 3 patients exhibited viral quasispecies differences between plasma and peripheral blood mononuclear cells (PBMC). Interestingly, in 2 such patients, the viral quasispecies found in the 24-h plasma resembled that in the pre-IFN PBMC. The latter finding raises the possibility that in these patients, the differences in quasispecies composition between pre-IFN and post-IFN plasma resulted from increased representation of lymphoid tissue-originated variants in the latter sample, possibly because of poor sensitivity to IFN-alpha2b of HCV replication in the lymphoid compartment.

Impaired allostimulatory function of dendritic cells in chronic hepatitis C infection

BACKGROUND & AIMS

Dendritic cells (DC), which play an essential role in the triggering of primary antiviral immune reactions, may also contribute, in some viral models, to the propagation of viral infection and the pathogenesis of viral disease. During natural infection with hepatitis C virus (HCV), the interactions between the virus and DC may contribute to viral persistence, a general feature of HCV infection.

METHODS

We compared the phenotypical and biological functions of monocyte-derived DC from patients with chronic hepatitis C (HCV-DC; n = 6), seronegative individuals (naive-DC; n = 8), long-term responders to antiviral therapy (LTR-DC; n = 8), and a group of patients with non-HCV-hepatic disorders (n = 11). The presence and the nature of HCV sequences during the DC cultures was assessed by reverse transcription-polymerase chain reaction and the analysis of the viral quasispecies distribution.

RESULTS

Although HCV-DC displayed a normal morphology, phenotype, and capacity to capture antigen, their ability to stimulate the proliferation of allogeneic T cells was dramatically impaired in comparison with naive-DC (P = 0.0013). Mixing experiments revealed that HCV-DC did not affect the proliferation of T cells induced by naive-DC. Remarkably, the allostimulatory function of LTR-DC or DC from patients with non-HCV-hepatic disorders did not show any impairment. The presence of HCV genomic sequences could be documented for 5 of 6 HCV carriers either in the cells and/or the supernatants of the DC cultures. The presence of HCV sequences was found in the DC cultures from one patient showing a dramatic allostimulation defect. For that patient, extensive analysis of the viral quasispecies distribution revealed the presence, in the DC cultures, of genomic sequences of a unique nature, distinct from those identified in the patient's mononuclear cells, serum, or liver.

CONCLUSIONS

Overall, these results indicate that chronic infection by HCV is associated with an allostimulatory defect of monocyte-derived DC, possibly because these cells constitute an extrahepatic reservoir for the virus. Although the exact mechanism responsible for such an alteration remains to be unraveled, our observations argue against an active immunosuppression-based mechanism.

Low cell binding ability of HCV is closely related to interferon treatment especially in patients with HCV genotype 2a/2b. A large series prospective study on Japanese patients with chronic hepatitis C

BACKGROUND/AIMS

We have previously shown that the quantity of antibody-free virion in the pre-treatment sera of the patients with chronic hepatitis C is a good predictive factor for the efficacy of interferon treatment. However, the biological significance of the free virion should be verified by a prospective study.

METHODS

We prospectively evaluated 152 consecutive patients with chronic hepatitis C who received a standardized interferon treatment, and analyzed the free virion and the binding titers, the ability of hepatitis C virus (HCV) to bind to the human lymphocytic cell line.

RESULTS

Sixty-five patients achieved a long-term sustained remission, 76 patients did not respond to the interferon therapy, and 11 patients dropped out. The sera from the patients with genotype 2a/2b had significantly lower free virion and cell binding titers than those with genotype 1b. A multivariate analysis showed three independent variables associated with the interferon response; cell binding titer <10(0.5)/ml, viral load <10(4.5) copies/50 microl, and genotype 2a/2b with odds ratios of 14.6, 11.8, and 9.8, respectively.

CONCLUSIONS

The low level of in vitro cell binding ability of HCV helped to clarify the good responsiveness to interferon observed in patients especially with a high viral load of genotype 2a/2b.

The HCV core protein acts as a positive regulator of fas-mediated apoptosis in a human lymphoblastoid T cell line

Hepatitis C virus (HCV) is a major human pathogen causing mild to severe liver disease worldwide and is remarkably efficient at establishing persistent infections. Previously, we have shown that the core protein has an immunomodulatory function including the suppression of T lymphocyte responses to viral infection. To investigate the underlying mechanism for the role of core protein in immune modulation, we examined the effect of core on the sensitivity of the human T cell line, Jurkat, to Fas-mediated apoptosis. The transient and stable expression of core protein in Jurkat cells increased the sensitivity of cells to Fas-mediated apoptosis when compared to control cells expressing vector DNA alone. In addition, we demonstrated that the core protein binds to the cytoplasmic domain of Fas which may enhance the downstream signaling event of Fas-mediated apoptosis. The expression of core protein did not alter the cell surface expression of Fas, indicating that the increased sensitivity of core-expressing cells to Fas ligand was not due to upregulation of Fas. Furthermore, we observed the augmentation of caspase-3 activity in core-expressing cells. These results suggest that the core protein may promote the apoptosis of immune cells during HCV infection via the Fas signaling pathway, thus facilitating HCV persistence.

Pretransplantation hepatitis C virus quasispecies may be predictive of outcome after liver transplantation

The evolution of hepatitis C virus (HCV) envelope variation was studied using a liver-transplant model to evaluate the role of HCV quasispecies for hepatocyte infection. Twelve HCV polymerase chain reaction (PCR)-positive liver-transplant recipients (6 with posttransplantation biochemical hepatitis and 6 without hepatitis [controls]) were prospectively evaluated and underwent detailed quasispecies analysis of pre- and postoperative serum samples. HCV amino acid sequence diversity and complexity at the first hypervariable region (HVR1) of the second envelope protein (E2) was correlated with outcome. Recurrence of HCV-induced allograft injury was defined by persistently elevated serum alanine transaminase (ALT) levels. The major variant (sequences >10% of all clones) of recipients with hepatitis accounted for a significantly smaller percent of all preoperative clones compared with controls (41% +/- 6% vs. 69% +/- 8%; P <.015). Recipients with hepatitis had an increased number of pretransplantation major variants (2.5 +/- 0.3 vs. 1.1 +/- 0.2; P <.006). Eighty-three percent of controls had a predominant variant (accounting for >50% of clones) compared with 17% of those with recurrence (P <.05). These differences did not persist postoperatively. In addition, recipients without a pretransplantation predominant variant demonstrated an increased allograft fibrosis score (2.3 +/- 0.3 vs. 0.5 +/- 0.3; P <.015) at 181 to 360 days posttransplantation compared with those in whom a predominant variant was present. Increased HCV envelope complexity may act as a stronger antigenic stimulus or improve hepatocyte receptor binding and lead to allograft hepatitis and fibrosis. Although pretransplantation differences in HCV quasispecies did not persist postoperatively, pretransplantation quasispecies may be a predictor of HCV-induced hepatitis and graft fibrosis after liver transplantation.

Assessment of genotype and molecular evolution of hepatitis C virus in formalin-fixed paraffin-embedded liver tissue from patients with chronic hepatitis C virus infection

Drawbacks of hepatitis C virus (HCV) RNA detection in paraffin-embedded liver tissue have satisfactorily been solved by RT-PCR amplification of the 5'non-coding region (5'NCR). However, detection of this highly conserved region does not provide information on epidemiological or pathogenetic aspects of HCV infection. This study explores whether other functionally important genetic regions of HCV, such as the hypervariable region 1 (HVR-1) and the interferon sensitivity-determining region (ISDR), can be retrieved from paraffin-embedded liver specimens by RT-PCR, and whether the amplified material is suitable for further molecular analyses. RT-PCR amplification of 5'NCR, HVR-1, and ISDR was assessed in RNA extracted from 50 formalin-fixed, paraffin-embedded liver specimens, including 23 needle liver biopsies (11 from patients with non-A, non-B chronic hepatitis diagnosed between 1971 and 1985, 8 from subjects with normal liver histology and 4 from sequential biopsies from a patient with HCV recurrence after liver transplantation), and 27 liver explants from patients undergoing transplantation between 1988 and 1996 (16 with HCV-related cirrhosis and 11 with other disorders). The 5'NCR was successfully amplified in 8 of 11 (73%) non-A, non-B chronic hepatitis biopsies and in all of the specimens from patients with serological documentation of HCV infection. There were no false-positive results. HCV genotype was identified by RFLP analysis of the 5'NCR in the 13 cases analyzed. HVR-1 and ISDR were amplified in 24 of 28 (86%) samples, which were positive for the 5'NCR. Efficient amplification was inversely related to the time of storage. The evolutionary changes of HVR-1 and ISDR were successfully analyzed by direct sequencing of amplificates from the explanted liver and from the sequential liver biopsies in a patient with HCV infection recurrence after transplantation. These observations indicate that paraffin-embedded liver tissue, even when stored for more than 20 years, is appropriate for advanced studies on the molecular biology of HCV.

Uneven distribution of hepatitis C virus quasispecies in tissues from subjects with end-stage liver disease: confounding effect of viral adsorption and mounting evidence for the presence of low-level extrahepatic replication

We have found differences among the populations of hepatitis C virus sequences in serum, peripheral blood mononuclear cells (PBMCs), and various tissues in patients with chronic hepatitis C. These results are compatible with the existence of independent viral compartments in the infected host. Our results also suggest that PBMCs, and probably various tissues, can selectively adsorb viral subpopulations differing in the E2 region.

Nucleotide and amino acid complexity of hepatitis C virus quasispecies in serum and liver

The quasispecies nature of the hepatitis C virus (HCV) is thought to play a central role in maintaining and modulating viral replication. Several studies have tried to unravel, through the parameters that characterize HCV circulating quasispecies, prognostic markers of the disease. In a previous work we demonstrated that the parameters of circulating viral quasispecies do not always reflect those of the intrahepatic virus. Here, we have analyzed paired serum and liver quasispecies from 39 genotype 1b-infected patients with different degrees of liver damage, ranging from minimal changes to cirrhosis. Viral level was quantified by real-time reverse transcription-PCR, and viral heterogeneity was characterized through the cloning and sequencing of 540 HCV variants of a genomic fragment encompassing the E2-NS2 junction. Although in 95% of patients, serum and liver consensus HCV amino acid sequences were identical, quasispecies complexity varied considerably between the viruses isolated from each compartment. Patients with HCV quasispecies in serum more complex (26%) than, less complex (28%) than, or similarly complex (41%) to those in liver were found. Among the last, a significant correlation between fibrosis and all the parameters that measure the viral amino acid complexity was found. Correlation between fibrosis and serum viral load was found as well (R = 0.7). With regard to the origin of the differences in quasispecies complexity between serum and liver populations, sequence analysis argued against extrahepatic replication as a quantitatively important contributing factor and supported the idea of a differential effect or different selective forces on the virus depending on whether it is circulating in serum or replicating in the liver.

Nonrandom distribution of hepatitis C virus quasispecies in plasma and peripheral blood mononuclear cell subsets

The existence of an extrahepatic reservoir of hepatitis C virus (HCV) is suggested by differences in quasispecies composition between the liver, peripheral blood mononuclear cells, and serum. We studied HCV RNA compartmentalization in the plasma of nine patients, in CD19(+), CD8(+), and CD4(+) positively selected cells, and also in the negatively selected cell fraction (NF). HCV RNA was detected in all plasma samples, in seven of nine CD19(+), three of eight CD8(+), and one of nine CD4(+) cell samples, and in seven of eight NF cells. Cloning and sequencing of HVR1 in two patients showed a sequence grouping: quasispecies from a given compartment (all studied compartments for one patient and CD8(+) and NF for the other) were statistically more genetically like each other than like quasispecies from any other compartment. The characteristics of amino acid and nucleotide substitutions suggested the same structural constraints on HVR1, even in very divergent strains from the cellular compartments, and homogeneous selection pressure on the different compartments. These findings demonstrate the compartmental distribution of HCV quasispecies within peripheral blood cell subsets and have important implications for the study of extrahepatic HCV replication and interaction with the immune system.

Quasispecies of hepatitis C virus in serum and in three different parts of the liver of patients with chronic hepatitis

Hepatitis C virus (HCV) has been known to infect hosts as a quasispecies. Several reports have shown this using serum samples, but there is little information about quasispecies in the liver. In this study, we evaluated quasispecies in serum and in 3 different parts of the liver in 8 patients with varying severity of chronic hepatitis C by calculating nucleotide diversity, entropy, type of substitution and by phylogenetic analysis. Nucleotide diversity of HCV was different in each sample and ranged from 0.37% +/- 0.31% to 4.10% +/- 1.06%. However, the degree of HCV diversity in serum correlated with that in the liver in each patient (P <.01). Common HCV clones were found both in serum and liver samples in all 6 noncirrhotic patients, but all serum clones were different from the clones from the 2 cirrhotic livers. Phylogenetic analysis showed that the degree of genetic diversity of HCV among the 3 liver samples was significantly high in the 4 patients with fibrosis. These genetic compartmentalizations of HCV did not depend on the type of substitution or the viral load of each liver sample. HCV quasispecies within the liver may be closely related to the viral life cycle and the pathogenesis of persistent infection of HCV.

Comparison of genetic heterogeneity of hepatitis C viral RNA in liver tissue and serum

OBJECTIVE

Hepatitis C virus (HCV) is known to be heterogeneous and to circulate as a group of closely related quasispecies in individual patients, although hepatic viral genetic characteristics have not been well documented.

METHODS

Matched serum and liver samples were tested by reverse transcription polymerase chain reaction amplification and single stranded conformation polymorphism analysis of the hypervariable portion of the E2/NS1 region of the HCV genome. The number of quasispecies was compared with the amount of HCV RNA, HCV genotyping, and infection with the hepatitis G virus.

RESULTS

Sixteen of 40 patients had HCV RNA detectable in serum and liver. The HCV genotype was identical in serum and liver of all but one case. HCV RNA levels were approximately 10-fold higher in liver than serum. The number of HCV quasispecies in serum ranged between two and six (median 3.0) and in the liver between 2 and 19 (median 3.5, mean liver/serum ratio 1 to 6.3, median 1.8). The number of quasispecies in liver was equal to or greater than that in serum in all cases. HGV infection was found in 14 cases and did not influence serum or hepatic levels of HCV RNA.

CONCLUSIONS

The number of hepatic HCV quasispecies usually exceeds that in serum, independent of the amount of HCV RNA and HCV genotype. This finding is compatible with clearance of some quasispecies from serum, but not liver, by putative neutralizing antibodies.

Hepatitis G virus/GBV-C persistence: absence of hypervariable E2 region and genetic analysis of viral quasispecies in serum and lymphocytes

Persistent infection with hepatitis G virus (HGV) or GB virus-C (GBV-C) is common and may last for years. In addition, the principal site of virus replication remains undefined. Sequencing studies of E2 in four patients showed that a hypervariable region equivalent to that of hepatitis C virus (HCV) was absent and that viral quasispecies were less frequent than in HCV infection, particularly with respect to amino acid variation. Recurrence of viraemia following interferon treatment did not result in the emergence of new quasispecies. Virus persistence therefore does not appear to be related to immune escape by strains bearing a hypervariable E2 region. We also investigated whether virus replication occurred in peripheral blood mononuclear cells. The positive-RNA strand of the virus, but no negative strand, was detected in both serum and lymphocytes. The lymphocytes harbouring the virus were CD4 and CD19 positive. Direct sequencing and cloning of amplicons from the region of the non-structural 3 (NS3) protein showed that the nucleotide sequences in lymphocytes were different from those in serum and did not represent any of the minor serum quasispecies. Although evidence of replication in lymphocytes has not been forthcoming, the differences in sequences between serum and lymphocytes suggest that circulating virus originates from a non-hepatic site, other than lymphocytes.

Assay for hepatitis C virus in peripheral blood mononuclear cells enhances sensitivity of diagnosis and monitoring of HCV-associated hepatitis

Hepatitis C virus (HCV) is a major etiological factor in chronic hepatitis affecting up to 24% of blood donors in Egypt. Since fluctuating levels of HCV RNA loads, including undetectable values, have been frequently observed in sera of chronic hepatitis patients, this study was designed to assess the sensitivity of PCR amplification for the plus- and minus-RNA strands in peripheral blood mononuclear cells (PBMC) compared to single serum PCR assay. Since the latter test detects viremia in only 79.5% of seropositive cases, the highest sensitivity for HCV diagnosis was achieved (93.20% when applying the combined triple test including PCR amplification of plus-strand in serum, together with plus-strand in PBMC and minus-strand in PBMC. The results of this study indicate that the triple test provides significant information on extrahepatic replication of HCV in a sizable sample of seropositive subjects (429 cases) and improves the assessment of HCV viremia. The cost/effectiveness and speed were upgraded by using capillary/air rapid thermal cycler. The use of the triple assay in HCV diagnosis and post-therapy monitoring is recommended.

Antisense oligonucleotide inhibition of hepatitis C virus (HCV) gene expression in livers of mice infected with an HCV-vaccinia virus recombinant

Hepatitis C virus (HCV) is the major cause of non-A, non-B hepatitis worldwide. Current treatments are not curative for most infected individuals, and there is an urgent need for both novel therapeutic agents and small-animal models which can be used to evaluate candidate drugs. A small-animal model of HCV gene expression was developed with recombinant vaccinia virus vectors. VHCV-IRES (internal ribosome entry site) is a recombinant vaccinia viral vector containing the HCV 5' nontranslated region (5'-NTR) and a portion of the HCV core coding region fused to the firefly luciferase gene. Intraperitoneal injection of VHCV-IRES produced high levels of luciferase activity in the livers of BALB/c mice. Antisense oligonucleotides complementary to the HCV 5'-NTR and translation initiation codon regions were then evaluated for their effects on the expression of these target HCV sequences in BALB/c mice infected with the vaccinia virus vector. Treatment of VHCV-IRES-infected mice with 20-base phosphorothioate oligonucleotides complementary to the sequence surrounding the HCV initiation codon (nucleotides 330 to 349) specifically reduced luciferase expression in the livers in a dose-dependent manner. Inhibition of HCV reporter gene expression in this small-animal model suggests that antisense oligonucleotides may provide a novel therapy for treatment of chronic HCV infection.

Detection of genomic- and minus-strand of hepatitis C virus RNA in the liver of chronic hepatitis C patients by strand-specific semiquantitative reverse-transcriptase polymerase chain reaction

Studies aimed at correlating the intrahepatic hepatitis C virus (HCV)-RNA level and anatomo-clinical features have been difficult because of sensitivity and specificity shortcomings of available techniques. We titered the genomic- and minus-strand HCV RNAs by a strand-specific, semiquantitative, genotype-independent reverse-transcriptase polymerase chain reaction (RT-PCR) in the liver tissue of 61 patients with chronic hepatitis C. Findings were correlated with the levels of HCV RNA in the serum, the HCV genotype, the expression of intrahepatic HCV antigens, the histological activity (using separate scores for the lobular and the portal/periportal necroinflammatory activity and for the fibrosis), and the response to interferon alfa (IFN-alpha) treatment. Genomic- and minus-strand HCV RNA were detected in 59 and 57 liver specimens, respectively. The HCV-RNA level in the serum correlated with the genomic-strand, but not with the minus-strand, HCV-RNA titer in the liver. No correlations were found between either strand of the intrahepatic HCV RNA and the level of expression of HCV antigens in the liver, or with the grading/staging of the underlying liver disease. The response to IFN-alpha treatment could be predicted by the serum HCV-RNA level and genotype, but not by the intrahepatic level of genomic- or minus-strand HCV RNA. These results suggest that, although the detection of the minus-strand HCV RNA reliably identifies the presence of replicating HCV in its target organ, the quantitative measurement of viremia remains the clinically meaningful "golden standard" for assessing the level of HCV replication.

Comparison of serum and liver hepatitis C virus quasispecies in HCV-related hepatocellular carcinoma

BACKGROUND/AIMS

The hepatitis C virus (HCV) genome consists of quasispecies populations of heterogeneous variants, especially in the hypervariable region. To assess the profiles of viral quasispecies in HCV-related hepatocellular carcinoma, we studied the viral population patterns in serum and liver tissues of 13 HCV-positive patients with hepatocellular carcinoma developed on cirrhotic and non-cirrhotic livers (5 and 8 cases, respectively).

METHODS

HCV genome heterogeneity was analyzed by polymerase chain reaction-mediated single-strand conformation polymorphism analysis, which showed multiple DNA bands representing different hypervariable region sequences.

RESULTS

The HCV populations were different between tumorous and nontumorous tissues in 3/5 hepatocellular carcinomas with cirrhosis and in 6/8 without cirrhosis. At least one or more than one common band was detected in both compartments in all but one case. No significant differences in the complexity of HCV quasispecies were found in hepatocellular carcinoma with or without underlying cirrhosis. Comparison of the HCV quasispecies profiles in serum and liver tissues showed a different distribution of HCV variants between these two compartments in 6/7 patients. In four cases, both common and compartmentalized sequences were detected, whereas in two cases, both without cirrhosis, the HCV population in serum was completely different from that found in the liver.

CONCLUSIONS

These results suggest that the complexity of HCV populations is influenced by the presence of hepatocellular carcinoma rather than by the severity of the underlying chronic liver disease. The different quasispecies patterns found in serum and liver may reflect different biological properties of circulating and intrahepatic HCV particles or the existence of extrahepatic sites of replication.

Hepatitis C virus quasispecies in patients infected with HIV-1: correlation with extrahepatic viral replication

Hepatitis C virus (HCV) sequences recovered from serum, peripheral blood mononuclear cells (PBMCs), and various tissues from human immunodeficiency virus type 1 (HIV-1) positive patients were compared by single strand conformational polymorphism (SSCP) and sequencing. In five patients, paired serum and PBMCs samples were analyzed while in two other patients multiple autopsy tissues were studied. Sequences amplified from the NS5 and E2 regions were consistently identical in the same patient; however, three PBMCs samples and three different tissue samples (pancreas and adrenal gland in one patient and lymph node in the other patient) contained 5' untranslated region (5'UTR) sequences that were different from circulating sequences. The presence of 5' UTR sequences differing from circulating sequences correlated with the presence of HCV RNA negative strand, as the latter was detected by a Tth-based strand-specific assay in all but one of these samples. These two independent lines of evidence: viral sequence differences and the presence of RNA negative strand in the same tissues strongly argue for the genuine presence of extrahepatic HCV replication, at least in the setting of HIV-1 infection.

Rapid genotyping of hepatitis C virus by direct cycle sequencing of PCR-amplified cDNAs and capillary electrophoresis analysis

There is an increasing demand for the genotyping of hepatitis C virus (HCV), since it has been shown that different HCV genotypes are associated with distinct profiles of pathogenicity and responses to antiviral treatment. Hence, there is a need for a simple and precise genotyping assay for routine diagnosis of HCV types and subtypes. Here we show that direct sequencing, considered as the reference method, can provide an accurate and rapid method for large-scale screening of HCV genotypes. PCR-amplified cDNAs of the HCV 5' non-coding region (5' NCR) were obtained from the widespread "Amplicor" HCV detection system. Semi-purified PCR products were directly cycle-sequenced in a single tube using multicolour dye terminator chemistry. Sample loading, electrophoresis and sequence analysis were automatically achieved by a capillary electrophoresis-based genetic analyser. Out of a total of 500 samples, HCV subtype 1b accounted for the majority of the infections (41%), followed by HCV 3 (31%) and HCV 1a (22%). This procedure failed to identify a genotype in only 3 samples. In addition, several cases of mixed HCV infection were also documented. The combination of direct cycle sequencing of PCR products with capillary electrophoresis provides a simple and rapid method convenient for routine HCV genotyping analysis.

Genetic diversity and tissue compartmentalization of the hepatitis C virus genome in blood mononuclear cells, liver, and serum from chronic hepatitis C patients

The degree of genetic variability in the hypervariable region 1 of hepatitis C virus (HCV) was analyzed by cloning and sequencing HCV genomes obtained in paired samples of serum, liver tissue, and peripheral blood mononuclear cells (PBMC) from four chronic hepatitis C patients. Genetic variability in serum was higher than in liver tissue or PBMC at the level of complexity (the number of different sequences obtained from each type of tissue) as well as at the level of genetic distance between all pairs of sequences within each tissue (compared by the Student t test; P < 0.001 for two patients and P < 0.01 for another). The spectrum of viral genomes differed among the three types of tissue, as shown by segregation of sequences according to their tissue of origin in phylogenetic analysis and by statistical analysis of mean genetic distances observed between sequences obtained from different tissues (P < 0.001), but sequences from liver tissue and PBMC were more closely related to each other than to those from serum.

Pathogenesis of dengue virus diseases: missing pieces in the jigsaw

The mechanisms involved in the pathogenesis of dengue hemorrhagic fever and dengue shock syndrome remain unresolved. Antibody-dependent enhancement of infection has long been thought to play a central role; however, this remains unverified. The alternative hypothesis that virus variation, virulence and dynamics may account for severe dengue disease, particularly in children, should be considered.

Sequence analysis of the hepatitis C virus genome recovered from serum, liver, and peripheral blood mononuclear cells of infected chimpanzees

Of 13 different strains of hepatitis C virus (HCV) in the inoculum used, only 1 persisted in human lymphocyte cell lines infected in vitro (N. Nakajima, M. Hijikata, H. Yoshikura, and Y. K. Shimizu, J. Virol. 70:3325-3329, 1996). To determine whether that particular strain (designated H1-2) has a tropism for lymphocytes in vivo, we sequenced hypervariable region 1 (HVR1) of the genome of HCV recovered from the sera, livers, and peripheral blood mononuclear cells (PBMC) of chimpanzees infected with plasma H77, the same inoculum used for the in vitro studies. In the PBMC collected from two chimpanzees during the early phase of infection, H1-2 was detected as the only or predominant HVR1 sequence. H1-2 was also detected in PBMC obtained during persistent infection from a chimpanzee that had been treated with immunosuppressants. From the livers of these chimpanzees, two to six different strains were recovered but H1-2 was not detected. Thus, H1-2 appeared to have an affinity for lymphocytes not only in vitro but also in vivo. In samples collected from a chimpanzee after 6 years of infection, however, such tissue compartmentalization of the HCV genome was not observed; a single strain became predominant in the serum, liver, and PBMC. An HCV strain capable of replicating in both the liver and PBMC probably emerged during in vivo replication and persisted.