Substrate determinants for cleavage in cis and in trans by the hepatitis C virus NS3 proteinase

Reconstitution of hepatitis C virus protease activities in yeast

The hepatitis C virus (HCV) protease genes (NS2/3 and NS3) were expressed in yeast with their natural substrates fused to a ligand-dependent transcriptional activator, the retinoic acid receptor (RARbeta). RARbeta can activate transcription in yeast cells in response to retinoic acids. We hypothesized that cis-cleavage at the NS2-3 or NS3-4A junctions by the appropriate HCV proteases would release RARbeta, thereby activating transcription of a reporter gene. Our results from Western blot analyses and reporter gene activation indicate that the wild-type NS2/3 and NS3 enzymes are catalytically active in yeast cells, whereas mutations in the catalytic domain of NS2(C993V) and NS3(S1165A) lead to inactive enzymes. We conclude that HCV NS2/3 and NS3 protease activities can be reconstituted in yeast.

Genome of human hepatitis C virus (HCV): gene organization, sequence diversity, and variation

Hepatitis C virus (HCV) is the major etiologic agent of non-A, non-B hepatitis. HCV infection frequently causes chronic hepatitis, which progresses to liver cirrhosis and hepatocellular carcinoma. Since the discovery of HCV in 1989, a large number of genetic analyses of HCV have been reported, and the viral genome structure has been elucidated. An enveloped virus, HCV belongs to the family Flaviviridae, whose genome consists of a positive-stranded RNA molecule of about 9.6 kilobases and encodes a large polyprotein precursor (about 3000 amino acids). This precursor protein is cleaved by the host and viral proteinase to generate at least 10 proteins: the core, envelope 1 (E1), E2, p7, nonstructural (NS) 2, NS3, NS4A, NS4B, NS5A, and NS5B. These HCV proteins not only function in viral replication but also affect a variety of cellular functions. HCV has been found to have remarkable genetic heterogeneity. To date, more than 30 HCV genotypes have been identified worldwide. Furthermore, HCV may show quasispecies distribution in an infected individual. These findings may have important implications in diagnosis, pathogenesis, treatment, and vaccine development. The hypervariable region 1 found within the envelope E2 protein was shown to be a major site for the genetic evolution of HCV after the onset of hepatitis, and might be involved in escape from the host immunesurveillance system.

A personal account of the role of peptide research in drug discovery: the case of hepatitis C

Although peptides themselves are not usually the end products of a drug discovery effort, peptide research often plays a key role in many aspects of this process. This will be illustrated by reviewing the experience of peptide research carried out at IRBM in the course of our study of hepatitis C virus (HCV). The target of our work is the NS3/4A protease, which is essential for maturation of the viral polyprotein. After a thorough examination of its substrate specificity we fine-tuned several substrate-derived peptides for enzymology studies, high-throughput screening and as fluorescent probes for secondary binding assays. In the course of these studies we made the key observation: that the protease is inhibited by its own cleavage products. Single analog and combinatorial optimization then derived potent peptide inhibitors. The crucial role of the NS4A cofactor was also addressed. NS4A is a small transmembrane protein, whose central domain is the minimal region sufficient for enzyme activation. Structural studies were performed with a peptide corresponding to the minimal activation domain, with a series of product inhibitors and with both. We found that NS3/4A is an induced fit enzyme, requiring both the cofactor and the substrate to acquire its bioactive conformation; this explained some puzzling results of 'serine-trap' type inhibitors. A more complete study on NS3 activation, however, requires the availability of the full-length NS4A protein. This was prepared by native chemical ligation, after sequence engineering to enhance its solubility; structural studies are in progress. Current work is focused on the P' region of the substrate, which, at variance with the P region, is not used for ground state binding to the enzyme and might give rise to inhibitors showing novel interactions with the enzyme.

In vivo selection of protease cleavage sites by using chimeric Sindbis virus libraries

Identifying protease cleavage sites contributes to our understanding of their specificity and biochemical properties and can help in designing specific inhibitors. One route to this end is the generation and screening of random libraries of cleavage sites. Both synthetic and phage-displayed libraries have been extensively used in vitro. We describe a novel system based on recombinant Sindbis virus which can be used to identify cleavage sites in vivo, thus eliminating the need for a purified enzyme and overcoming the problem of choosing the correct in vitro conditions. As a model we used the serine protease of the hepatitis C virus (HCV). We engineered the gene coding for this enzyme and two specific cleavage sites in the Sindbis virus structural gene and constructed libraries of viral genomes with a random sequence at either of the cleavage sites. The system was designed so that only viral genomes coding for sequences cleaved by the protease would produce viable viruses. With this system we selected viruses containing sequences mirroring those of the natural HCV protease substrates which were cleaved with comparable efficiencies.

In vivo determination of substrate specificity of hepatitis C virus NS3 protease: genetic assay for site-specific proteolysis

Hepatitis C virus (HCV) NS3 protease is responsible for the processing of the viral polyprotein and is considered as a primary target for the development of anti-HCV therapy. We have developed a genetic method in yeast to screen for good substrate sequences of the NS3 protease. A library of fusion proteins was constructed with a transcription factor, GAL4, linked to the intracellular domain of an integral membrane protein, STE2, by a randomized protease substrate sequence. In yeast cells expressing NS3 protease, the substrate sequences in the fusion proteins were specifically recognized and cleaved. This cleavage resulted in the release of GAL4 from the cytoplasmic membrane and the subsequent activation of reporter genes by GAL4, which was detected by the growth of yeast cells on selective media. Based on the analysis of 69 isolated substrate sequences, a consensus sequence was deduced: (Glu/Asp)-X-Val-Val-(Leu/Pro)-Cys / (Ser/Ala), with the scissile bond being located between Cys and Ser or Ala and X not being determined. This is largely consistent with the previous results obtained by biochemical methods. An oligopeptide containing the deduced sequence was highly efficiently cleaved in vitro by the purified NS3 protease. These data demonstrated that the present genetic method could be used as an efficient tool for the in vivo determination of substrate specificity of proteases.

NS3 serine protease of bovine viral diarrhea virus: characterization of active site residues, NS4A cofactor domain, and protease-cofactor interactions

The gene expression of bovine viral diarrhea virus (BVDV), a pestivirus, occurs via translation of a hypothetical polyprotein that is processed cotranslationally and posttranslationally by viral and cellular enzymes. A protease located in the N-terminal region of nonstructural (NS) protein NS3 catalyzes the cleavages, leading to the release of NS4A, NS4B, NS5A, and NS5B. Our study provides experimental evidence that histidine at position 1658 and aspartic acid at position 1686 constitute together with the previously identified serine at position 1752 (S1752) the catalytic triad of the pestiviral NS3 serine protease. Interestingly, a mutant protease encompassing an exchange of the active site S1752 to threonine still showed residual activity. This finding links the NS3 protease of pestiviruses to the capsid protease of Sindbis virus. Furthermore, we observed that the minimal protease domain of NS3 encompasses about 209 amino acids. The NS3 protease was found to be sensitive to N-terminal truncation because a deletion of 6 amino acids significantly reduced the cleavage efficiency at the NS4A/4B site. Larger N-terminal deletions also impaired the activity of the enzyme with respect to the other cleavage sites but to a different degree at each site. The NS3 protease of BVDV has previously been shown to depend on NS4A as cofactor. We demonstrate here that the central region of NS4A represents the cofactor domain. Furthermore, coprecipitation studies strongly suggest an interaction between NS4A and the N-terminal region of NS3. Besides the remarkable similarities observed between the pestiviral NS3 protease and the corresponding enzyme of hepatitis C virus (HCV), our results suggest a common ancestry between these enzymes and the capsid protease of Sindbis virus.

Internal cleavage of hepatitis C virus NS3 protein is dependent on the activity of NS34A protease

The nonstructural protein NS3 of the hepatitis C virus (HCV) is indispensable for virus replication and a multifunctional enzyme that contains three catalytic activities such as serine protease, helicase, and NTPase. Here, we demonstrated that the internal cleavage of the HCV NS3 protein occurs in various mammalian cells such as HepG2, COS-7, and NIH3T3. As is observed for the internal cleavage mechanism of the NS3 protein of dengue virus 2, the internal processing of HCV NS3 protein was catalyzed by the active NS3 serine protease and NS4A, but not NS3 alone. From the data acquired from extensive site-directed mutagenesis, we observed that the NS3 protein was internally cleaved at two different sites, FCH(1395) ||S(1396)KK and IPT(1428) ||S(1429)GD, within RNA helicase domain. The internal cleavage of NS3 protein by NS34A protease was also confirmed in a different isolate of HCV-1b strain. In addition, in vitro transforming assays demonstrated that the internal cleavage product of NS3, NS3a-1, appeared to have higher oncogenic potential than does intact NS3. Taken together, our results suggest that the internal cleavage of NS3 may be associated with the replication and oncogenesis of HCV.

The non-structural 5A protein of hepatitis C virus

The non-structural (NS)5A protein of hepatitis C virus (HCV) is cleaved, after translation, by the NS3-encoded zinc-dependent serine proteinase, from the NS4B protein upstream and the NS5B protein downstream. The released, mature NS5A protein is a 56 000 MW phosphoprotein (p56), which also exists within infected cells in a hyperphosphorylated form (p58). The NS5A gene has a quasispecies distribution, meaning that various NS5A sequences co-exist, in various proportions, in infected individuals. HCV NS5A appears to be located in cytoplasmic membranes surrounding the nucleus. Its precise functions are not known. HCV non-structural proteins, including NS5A, form a large multiprotein replication complex, which probably directs the replication of the HCV genome. HCV NS5A lacking the 146 N-terminal amino acids is a potent transcriptional activator in vitro. NS5A can also bind to single-strand RNA-dependent protein kinase (PKR) and inhibit its antiviral function. An 'interferon (IFN) sensitivity-determining region' has recently been postulated in the NS5A protein central region in hepatitis C virus (HCV) genotype 1b, but strongly conflicting evidence has been published. In fact, there would seem to be no such region in the NS5A protein, even though NS5A plays an important and complex role in HCV resistance to IFN. Structure-function studies are required to identify precisely how NS5A and IFN interact.

Mutagenesis of amino acids at two tomato ringspot nepovirus cleavage sites: effect on proteolytic processing in cis and in trans by the 3C-like protease

Tomato ringspot nepovirus (ToRSV) encodes two polyproteins that are processed by a 3C-like protease at specific cleavage sites. Analysis of ToRSV cleavage sites identified previously and in this study revealed that cleavage occurs at conserved Q/(G or S) dipeptides. In addition, a Cys or Val is found in the -2 position. Amino acid substitutions were introduced in the -6 to +1 positions of two ToRSV cleavage sites: the cleavage site between the protease and putative RNA-dependent RNA polymerase, which is processed in cis, and the cleavage site at the N-terminus of the movement protein, which is cleaved in trans. The effect of the mutations on proteolytic processing at these sites was tested using in vitro translation systems. Substitution of conserved amino acids at the -2, -1, and +1 positions resulted in a significant reduction in proteolytic processing at both cleavage sites. The effects of individual substitutions were stronger on the cleavage site processed in trans than on the one processed in cis. The cleavage site specificity of the ToRSV protease is discussed in comparison to that of related proteases.

The NS3/4A proteinase of the hepatitis C virus: unravelling structure and function of an unusual enzyme and a prime target for antiviral therapy

The hepatitis C virus (HCV) is a major causative agent of transfusion-acquired and sporadic non-A, non-B hepatitis worldwide. Infections most often persist and lead, in approximately 50% of all patients, to chronic liver disease. As is characteristic for a member of the family Flaviviridae, HCV has a plus-strand RNA genome encoding a polyprotein, which is cleaved co- and post-translationally into at least 10 different products. These cleavages are mediated, among others, by a virally encoded chymotrypsin-like serine proteinase located in the N-terminal domain of non-structural protein 3 (NS3). Activity of this enzyme requires NS4A, a 54-residue polyprotein cleavage product, to form a stable complex with the NS3 domain. This review will describe the biochemical properties of the NS3/4A proteinase, its X-ray crystal structure and current attempts towards development of efficient inhibitors.

Hepatitis C virus NS3/4A protease

Despite an urgent medical need, a broadly effective anti-viral therapy for the treatment of infections with hepatitis C viruses (HCVs) has yet to be developed. One of the approaches to anti-HCV drug discovery is the design and development of specific small molecule drugs to inhibit the proteolytic processing of the HCV polyprotein. This proteolytic processing is catalyzed by a chymotrypsin-like serine protease which is located in the N-terminal region of non-structural protein 3 (NS3). This protease domain forms a tight, non-covalent complex with NS4A, a 54 amino acid activator of NS3 protease. The C-terminal two-thirds of the NS3 protein contain a helicase and a nucleic acid-stimulated nucleoside triphosphatase (NTPase) activities which are probably involved in viral replication. This review will focus on the structure and function of the serine protease activity of NS3/4A and the development of inhibitors of this activity.

The Hepatitis C Virus NS3 Proteinase: Structure and Function of a Zinc-Containing Serine Proteinase

The hepatitis C virus (HCV) NS3 protein contains a serine proteinase domain implicated in the maturation of the viral polyprotein. NS3 forms a stable heterodimer with NS4A, a viral memebrane protein that acts as an activator of the IMS3 proteinase. The three-dimensional structure of the NS3 proteinase complexed with an NS4A-derived peptide has been determined. The NS3 proteinase adopts a chymotrypsin-like fold. A β-strand contributed by NS4A is clamped between two β-strands within the N terminus of NS3. Consistent with the requirement for extraordinarily long peptide substrates (P6-P4’), the structure of the NS3 proteinase reveals a very long, solvent-exposed substrate-binding site. The primary specificity pocket of the enzyme is shallow and closed at its bottm by Phe-154, explaining the preference of the NS3 proteinase for cysteine residues in the substrate P, position. Another important feature of the NS3 proteinase is the presence of a tetrahedral zinc-binding site formed by residues Cys-97, Cys-99, Cys-145 and His-149. The zinc-binding site has a role in maintaining the structural stability and guiding the folding of the NS3 serine proteinase domain. Inhibition of the NS3 proteinase activity is regarded as a promising strategy to control the disease caused by HCV. Remarkably, the NS3 proteinase is susceptible to inhibition by the N-terminal cleavage products of substrate peptides corresponding to the NS4A/NS4B, NS4B/NS5A and NS5A/NS5B cleavage sites. The Ki values of the inhibitory products are lower than the Km values of the respective substrates and follow the order NS4A<NS5A<NS4B. Starting from the observation that the NS3 proteinase undergoes product inhibition, very potent, active site-directed inhibitors have been generated using a combinatorial peptide chemistry approach.

Determinants of substrate specificity in the NS3 serine proteinase of the hepatitis C virus

Processing of the nonstructural polyprotein of the hepatitis C virus (HCV) requires the serine-type proteinase located in the amino-terminal domain of NS3. To identify residues within NS3 determining substrate specificity, a mutation analysis was performed. Using sequence alignments and three-dimensional structure predictions, amino acids assumed to be important for specificity were replaced and the enzymes were tested in an intracellular trans-processing assay for their effects on cleavage of an NS4B-5B substrate. For some of the substitutions at positions 133, 134, 135, 136, 138, 152, 155, 157, and 169, slightly reduced processing efficiencies were observed but in no case was the substrate specificity altered. In contrast, substitutions of the phenylalanine at position 154 resulted in a modified cleavage pattern, suggesting an important role for this residue in substrate specificity. To substantiate this assumption, a panel of NS4B-5B substrates carrying different P1 residues at the NS4B/5A site were tested for cleavage by these altered proteinases. We found that substitution of Phe-154 by alanine, by valine, and particularly by threonine generated enzymes with the following affinities for aliphatic P1 residues: C > L > I > V for 154 F --> A, C = L > I > V for 154 F --> V and L > C > I > V for 154 F --> T. Neither leucine nor isoleucine nor valine was accepted by the parental NS3 proteinase, showing that Phe-154 is an important determinant for substrate specificity. Furthermore, we present evidence that Ala-157 plays an additional but minor role for this property.

Probing the substrate specificity of hepatitis C virus NS3 serine protease by using synthetic peptides

We probed the substrate specificity of a recombinant noncovalent complex of the full-length hepatitis C virus (HCV) NS3 serine protease and NS4A cofactor, using a series of small synthetic peptides derived from the three trans-cleavage sites of the HCV nonstructural protein sequence. We observed a distinct cleavage site preference exhibited by the enzyme complex. The values of the turnover number (k(cat)) for the most efficient NS4A/4B, 4B/5A, and 5A/5B peptide substrates were 1.6, 11, and 8 min(-1), respectively, and the values for the corresponding Michaelis-Menten constants (Km) were 280, 160, and 16 microM, providing catalytic efficiency values (k(cat)/Km) of 92, 1,130, and 8,300 M(-1) s(-1). An alanine-scanning study for an NS5A/5B substrate (P6P4') revealed that P1 Cys and P3 Val were critical. Finally, substitutions at the scissile P1 Cys residue by homocysteine (Hcy), S-methylcysteine (Mcy), Ala, S-ethylcysteine (Ecy), Thr, Met, D-Cys, Ser, and penicillamine (Pen) produced progressively less efficient substrates, revealing a stringent stereochemical requirement for a Cys residue at this position.

The complete coding sequence of hepatitis C virus genotype 5a, the predominant genotype in South Africa

Hepatitis C virus (HCV) genotype 5a is the predominant genotype in southern Africa with a high prevalence amongst infected blood donors from areas in South Africa. We have determined the nucleotide sequence corresponding to the complete coding region of an HCV isolate, EUH1480, previously classified as genotype 5a, from an Edinburgh haemophiliac. The sequence contained a single open reading frame (ORF) coding for a polyprotein of 3014 amino acids. Comparison with the polyprotein sequences from other HCV genotypes, where the ORF varies from 3008 to 3037 amino acids, showed the observed variation in size was due to differences in lengths of the envelope 2 and the nonstructural 5A proteins. The sequence divergence of HCV genotype 5 ranged from 29.4% nucleotide differences (24.91% amino acid differences) compared with genotype 1c to 32.5% nucleotide differences (30.3% amino acid differences) compared with 2a. Phylogenetic analysis of the available full length nucleotide sequences showed EUH1480 to form a branch distinct from the other HCV types, confirming the classification of type 5a as a separate genotype.

Bovine viral diarrhea virus NS3 serine proteinase: polyprotein cleavage sites, cofactor requirements, and molecular model of an enzyme essential for pestivirus replication

Members of the Flaviviridae encode a serine proteinase termed NS3 that is responsible for processing at several sites in the viral polyproteins. In this report, we show that the NS3 proteinase of the pestivirus bovine viral diarrhea virus (BVDV) (NADL strain) is required for processing at nonstructural (NS) protein sites 3/4A, 4A/4B, 4B/5A, and 5A/5B but not for cleavage at the junction between NS2 and NS3. Cleavage sites of the proteinase were determined by amino-terminal sequence analysis of the NS4A, NS4B, NS5A, and NS5B proteins. A conserved leucine residue is found at the P1 position of all four cleavage sites, followed by either serine (3/4A, 4B/5A, and 5A/5B sites) or alanine (4A/4B site) at the P1' position. Consistent with this cleavage site preference, a structural model of the pestivirus NS3 proteinase predicts a highly hydrophobic P1 specificity pocket. trans-Processing experiments implicate the 64-residue NS4A protein as an NS3 proteinase cofactor required for cleavage at the 4B/5A and 5A/5B sites. Finally, using a full-length functional BVDV cDNA clone, we demonstrate that a catalytically active NS3 serine proteinase is essential for pestivirus replication.

Serine protease of pestiviruses: determination of cleavage sites

The single-stranded genomic RNA of pestiviruses is of positive polarity and encompasses one large open reading frame of about 4,000 codons. The resulting polyprotein is processed co- and posttranslationally by virus-encoded and host cell proteases to give rise to the mature viral proteins. A serine protease residing in the nonstructural (NS) protein NS3 (p80) has been shown to be essential for the release of the NS proteins located downstream of NS3. In this report the NS3 serine protease-dependent cleavage sites for bovine viral diarrhea virus (BVDV) strain CP7 are described. Proteins used for analysis were generated in Escherichia coli or in eukaryotic cells by the use of the T7 vaccinia virus system. The N termini of NS4A, NS4B, NS5A, and NS5B were determined by protein sequencing. Analysis of the data obtained showed that leucine at P1 is the only position conserved for all cleavage sites. At P1' alanine is found at the NS4A-NS4B site, whereas serine resides at this position at the NS3-NS4A, NS4B-NS5A, and NS5A-NS5B cleavage sites. For all cleavage sites the amino acids found at P1 and P1' are conserved for different genotypes of pestiviruses, despite the high degree of sequence variation found between these viruses. It is therefore assumed that the cleavage sites determined for BVDV CP7 are representative of those for all pestiviruses.

Substrate specificity of the hepatitis C virus serine protease NS3

The substrate specificity of a purified protein encompassing the hepatitis C virus NS3 serine protease domain was investigated by introducing systematic modifications, including non-natural amino acids, into substrate peptides derived from the NS4A/NS4B cleavage site. Kinetic parameters were determined in the absence and presence of a peptide mimicking the protease co-factor NS4A (Pep4A). Based on this study we draw the following conclusions: (i) the NS3 protease domain has an absolute requirement for a small residue in the P1 position of substrates, thereby confirming previous modelling predictions. (ii) Optimization of the P1 binding site occupancy primarily influences transition state binding, whereas the occupancy of distal binding sites is a determinant for both ground state and transition state binding. (iii) Optimized contacts at distal binding sites may contribute synergistically to cleavage efficiency.

The NS3 proteinase domain of hepatitis C virus is a zinc-containing enzyme

NS3 proteinase of hepatitis C virus (HCV), contained within the N-terminal domain of the NS3 protein, is a chymotrypsin-like serine proteinase responsible for processing of the nonstructural region of the HCV polyprotein. In this study, we examined the sensitivity of the NS3 proteinase to divalent metal ions, which is unusual behavior for this proteinase class. By using a cell-free coupled transcription-translation system, we found that HCV polyprotein processing can be activated by Zn2+ (and, to a lesser degree, by Cd2+, Pb2+, and Co2+) and inhibited by Cu2+ and Hg2+ ions. Elemental analysis of the purified NS3 proteinase domain revealed the presence of zinc in an equimolar ratio. The zinc content was unchanged in a mutated NS3 proteinase in which active-site residues His-57 and Ser-139 were replaced with Ala, suggesting that the zinc atom is not directly involved in catalysis but rather may have a structural role. Based on data from site-directed mutagenesis combined with zinc content determination, we propose that Cys-97, Cys-99, Cys-145, and His-149 coordinate the structural zinc in the HCV NS3 proteinase. A similar metal binding motif is found in 2A proteinases of enteroviruses and rhinoviruses, suggesting that these 2A proteinases and HCV NS3 proteinase are structurally related.

Chimeric Sindbis viruses dependent on the NS3 protease of hepatitis C virus

The hepatitis C virus (HCV) NS3 protease cleaves the viral polyprotein at specific sites to release the putative components of the HCV replication machinery. Selective inhibition of this enzyme is predicted to block virus replication, and NS3 is thus considered an attractive candidate for development of anti-HCV therapeutics. To set up a system for analysis of NS3 protease activity in cultured cells, we constructed a family of chimeric Sindbis viruses which carry sequences coding for NS3 and its activator, NS4A, in their genomes. HCV sequences were fused to the gene coding for the Sindbis virus structural polyprotein via an NS3-specific cleavage site, with the expectation that processing of the chimeric polyprotein, nucleocapsid assembly, and generation of viable viral particles would occur only upon NS3-dependent proteolysis. Indeed, the chimeric genomes encoding an active NS3 protease produced infectious viruses in mammalian cells, while those encoding NS3 inactivated by alanine substitution of the catalytic serine did not. However, in infected cells chimeric genomes recombined, splicing out HCV sequences and reverting to pseudo-wild-type Sindbis virus. To force retention of HCV sequences, we modified one of the initial chimeras by introducing a second NS3 cleavage site in the Sindbis virus portion of the recombinant polyprotein, anticipating that revertants not encoding an active NS3 protease would not be viable. The resulting chimera produced infectious viruses which replicated at a lower rate than the parental construct and displayed a marked temperature dependence in the formation of lysis plaques yet stably expressed NS3.

Hepatitis C virus: molecular biology and genetic variability

The pathogenetic mechanisms of hepatitis C virus (HCV) infection are poorly known. An understanding of HCV biology and the potential clinical impact of HCV genetic variability is essential to managing, treating, and preventing HCV infections. HCV is a member of the Flaviviridae viral family. Its genome is a positive, single-strand RNA molecule. The structure of the HCV particles is poorly known due to the lack of an efficient cell culture system as well as a striking heterogeneity in density. The core protein may have a regulatory role on both viral and cellular gene expression. The mechanisms of HCV-RNA replication may include synthesis of negative strand intermediates, which drive synthesis of new positive RNA genomes. New procedures have been developed to better identify and characterize the HCV-RNA genome. The mechanisms of HCV persistence are currently unknown, although it is known that HCV chronicity develops despite humoral and cellular responses to HCV proteins. HCV-RNA shows significant genetic variability with an estimated rate of nucleotide change of approximately 10(-3) substitutions/site/year. Currently, three major HCV genotypes and three to seven minor subtypes can be distinguished. The geographical distribution of these genotypes and subtypes varies significantly. It appears that poor clinical response to interferon (IFN) is more common with HCV genotype 1. In addition, some studies have shown an association between chronic infection, severe chronic hepatitis, and cirrhosis with subtype 1b. Further, there is evidence for a potential direct effect of HCV in liver carcinogenesis, with subtype 1b possibly being an independent risk factor for hepatic carcinoma development. HCV-RNA circulates as a population of RNA molecules, which creates a heterogeneity referred to as "quasispecies." It is possible that some HCV strains might have direct clinical implications. It may be that highly heterogeneous populations observed prior to treatment might correlate with a lower rate of response to IFN therapy.

The crystal structure of hepatitis C virus NS3 proteinase reveals a trypsin-like fold and a structural zinc binding site

During replication of hepatitis C virus (HCV), the final steps of polyprotein processing are performed by a viral proteinase located in the N-terminal one-third of nonstructural protein 3. The structure of NS3 proteinase from HCV BK strain was determined by X-ray crystallography at 2.4 angstrom resolution. NS3P folds as a trypsin-like proteinase with two beta barrels and a catalytic triad of His-57, Asp-81, Ser-139. The structure has a substrate-binding site consistent with the cleavage specificity of the enzyme. Novel features include a structural zinc-binding site and a long N-terminus that interacts with neighboring molecules by binding to a hydrophobic surface patch.

In vitro inhibition of hepatitis C virus gene expression by chemically modified antisense oligodeoxynucleotides

We have explored different domains within the hepatitis C virus (HCV) 5' noncoding region as potential targets for inhibition of HCV translation by antisense oligodeoxynucleotides (ODNs). Inhibition assays were performed with two different cell-free systems, rabbit reticulocyte lysate and wheat germ extract, and three types of chemical structures for the ODNs were evaluated: natural phosphodiesters (beta-PO), alpha-anomer phosphodiesters (alpha-PO), and phosphorothioates (PS). A total of six original ODNs, displaying sequence-specific inhibition ranging from 62 to 96%, that mapped in the pyrimidine-rich tract (nucleotides [nt] 104 to 127) and in the initiator AUG codon (nt 338 to 357) were identified. Two ODNs, which were targeted at the initiatory AUG (nt 341 to 367 and 351 to 377) and which had been previously described as active against genotype 1b and 2a sequences, were shown to exhibit inhibition of expression (> 95%) of a type 1a sequence. Control experiments with the irrelevant chloramphenicol acetyltransferase sequence as a marker and randomized ODNs demonstrated that levels of inhibition associated with the use of PS compounds (of as much as 94%) were mainly due to nonspecific effects. Both alpha- and beta-PO ODNs were found equally active, and no difference could be seen in the activity of beta-PO when it was tested in either rabbit reticulocyte lysate or wheat germ extract, suggesting that RNase H-independent mechanisms may be involved in the inhibitions observed. However, specific RNA cleavage products generated from beta-PO inhibition experiments could be identified, indicating that, with these compounds, control of translation also involves RNase H-dependent mechanisms. This study further delimits the existence of favorable target sequences for the action of ODNs within the HCV 5' noncoding region and indicates the possibility of using nuclease-resistant alpha-PO compounds in cellular studies.

Hepatitis B and C viruses and primary liver cancer

The data presented indicate that viral agents (namely, HBV and HCV) are major environmental aetiological factors for human primary liver cancer. It is important to elucidate the molecular mechanisms further because HCC is one of the few examples of virus-related human cancers. In addition, the available evidence points to the possibility of at least partial prevention of the tumour by large-scale vaccination.

Virology of hepatitis C virus

Hepatitis C virus (HCV) has been identified as the main causative agent of posttransfusion non-A, non-B hepatitis. Through recently developed diagnostic assays, routine serologic screening of blood donors has prevented most cases of posttransfusion hepatitis. The purpose of this paper is to comprehensively review current information regarding the virology of HCV. Recent findings on the genome organization, its relationship to other viruses, the replication of HCV ribonucleic acid, HCV translation, and HCV polyprotein expression and processing are discussed. Also reviewed are virus assembly and release, the variability of HCV and its classification into genotypes, the geographic distribution of HCV genotypes, and the biologic differences between HCV genotypes. The assays used in HCV genotyping are discussed in terms of reliability and consistency of results, and the molecular epidemiology of HCV infection is reviewed. These approaches to HCV epidemiology will prove valuable in documenting the spread of HCV in different risk groups, evaluating alternative (nonparenteral) routes of transmission, and in understanding more about the origins and evolution of HCV.

Sequence and genomic organization of GBV-C: a novel member of the flaviviridae associated with human non-A-E hepatitis

Recently, sequences from a novel virus, termed GB virus C (GBV-C), were identified in serum from several patients with cryptogenic hepatitis. In the present study, the nucleotide sequence of this virus has been extended to near-genome length. GBV-C encodes a putative single large polyprotein in which the structural proteins are positioned at the N-terminal end, with the non-structural proteins located at the C-terminal end. Amino acid sequence analysis of this large polyprotein reveals the presence of protease, helicase, and replicase motifs. Sequence alignments of the polyprotein followed by phylogenetic analyses suggest that GBV-C is a member of the Flaviviridae, most closely related to the recently described GB virus A.

Genomic organization of GB viruses A and B: two new members of the Flaviviridae associated with GB agent hepatitis

The genomes of two positive-strand RNA viruses have recently been cloned from the serum of a GB agent-infected tamarin by using representational difference analysis. The two agent, GB viruses A and B (GBV-A and GBV-B, respectively), have genomes of 9,493 and 9,143 nucleotides, respectively, and single large open reading frames that encode potential polyprotein precursors of 2,972 and 2,864 amino acids, respectively. The genomes of these agents are organized much like those of other pestiviruses and flaviviruses, with genes predicted to encode structural and nonstructural proteins located at the 5' and 3' ends, respectively. Amino acid sequence alignments and subsequent phylogenetic analysis of the RNA-dependent RNA polymerases (RdRps) of GBV-A and GBV-B show that they possess conserved sequence motifs associated with supergroup II RNA polymerases of positive-strand RNA viruses. On the basis of similar analyses, the GBV-A- and GBV-B-encoded helicases show significant identity with the supergroup II helicases of positive-strand RNA viruses. Within the supergroup II RNA polymerases and helicases, GBV-A and GBV-B are most closely related to the hepatitis C virus group. Across their entire open reading frames, the GB agents exhibit 27% amino sequence identity to each other, approximately 28% identity to hepatitis C virus type 1, and approximately 20% identity to either bovine viral diarrhea virus or yellow fever virus. The degree of sequence divergence between GBV-A and GBV-B and other Flaviviridae members demonstrates that the GB agents are representatives of two new genera within the Flaviviridae family.