At least 12 genotypes of hepatitis C virus predicted by sequence analysis of the putative E1 gene of isolates collected worldwide.

In a previous study we sequenced the 5' noncoding (NC) region of 44 isolates of hepatitis C virus (HCV) and identified heterogeneous domains that provided evidence for additional genetic groups of HCV not previously recognized. In this study we have determined the complete nucleotide sequence of the putative envelope 1 (E1) gene in 51 HCV isolates from around the world and found that they could be grouped into at least 12 distinct genotypes. The E1 gene sequence of 8 of these genotypes has not been reported previously. Although the genetic relatedness of HCV isolates determined by the previous analysis of the 5' NC region predicted the relationships observed in the E1 gene, analysis of the 5' NC sequence alone did not accurately predict all HCV genotypes. The nucleotide and amino acid sequence identities of the E1 gene among HCV isolates of the same genotype were in the range of 88.0-99.1% and 89.1-98.4%, respectively, whereas those of HCV isolates of different genotypes were in the range of 53.5-78.6% and 49.0-82.8%, respectively. The latter differences are similar to those found when comparing the envelope gene sequences of the various serotypes of the related flaviviruses as well as other RNA viruses. We found that some genotypes of HCV were widely distributed around the world, whereas others were identified only in discreet geographical regions. Four genotypes were identified exclusively in Africa and comprised the majority of HCV isolates on that continent. The E1 gene was exactly 576 nucleotides in length in all 51 HCV isolates with no in-frame stop codons. Analysis of the predicted E1 protein identified several conserved domains that may be important for maintaining its biological function: (i) eight invariant cysteine residues, (ii) three potential N-linked glycosylation sites, (iii) a domain of nine amino acids (GHRMAWDMM), and (iv) an amino acid doublet (GV) near the putative cleavage site at the C terminus of the protein. In conclusion, the discovery of at least 12 genotypes of HCV has important implications for HCV diagnosis and vaccine development.     

Genetic organization and diversity of the hepatitis C virus.

The nucleotide sequence of the RNA genome of the human hepatitis C virus (HCV) has been determined from overlapping cDNA clones. The sequence (9379 nucleotides) has a single large open reading frame that could encode a viral polyprotein precursor of 3011 amino acids. While there as little overall amino acid and nucleotide sequence homology with other viruses, the 5' HCV nucleotide sequence upstream of this large open reading frame has substantial similarity to the 5' termini of pestiviral genomes. The polyprotein also has significant sequence similarity to helicases encoded by animal pestiviruses, plant potyviruses, and human flaviviruses, and it contains sequence motifs widely conserved among viral replicases and trypsin-like proteases. A basic, presumed nucleocapsid domain is located at the N terminus upstream of a region containing numerous potential N-linked glycosylation sites. These HCV domains are located in the same relative position as observed in the pestiviruses and flaviviruses and the hydrophobic profiles of all three viral polyproteins are similar. These combined data indicate that HCV is an unusual virus that is most related to the pestiviruses. Significant genome diversity is apparent within the putative 5' structural gene region of different HCV isolates, suggesting the presence of closely related but distinct viral genotypes.     

Characterization of the terminal regions of hepatitis C viral RNA: identification of conserved sequences in the 5'' untranslated region and poly(A) tails at the 3'' end.

We have determined the nucleotide sequence at the extreme 5' and 3' termini of the hepatitis C virus (HCV) genome. Our analyses of these sequences show (i) the nucleotide sequence in the 5' untranslated region is highly conserved among HCV isolates of widely varying geographical origin, (ii) within this region, there are blocks of nucleotide sequence homology with pestiviruses but not with other viruses, (iii) the relative position of short open reading frames present in the same region of the HCV genome is similar to that of the pestiviral genome, (iv) RNAs truncated at the 5' and 3' ends are found, but the origin and functions of these RNAs are unknown, and (v) poly(A) tails appear to be present on 3' subgenomic RNAs. These data differentiate HCV from the flaviviruses and indicate a closer evolutionary relationship of HCV with the pestiviruses. However, HCV also appears to be substantially different from other known pestiviruses. These data are consistent with the assignment of HCV to a separate viral genus.     

Importance of primer selection for the detection of hepatitis C virus RNA with the polymerase chain reaction assay.

We compared four primer sets from conserved regions of the hepatitis C virus (HCV) genome for their ability to detect HCV RNA in a "nested" cDNA polymerase chain reaction assay on sera from 114 anti-HCV antibody-positive individuals from around the world. The different primer sets had equivalent sensitivity, detecting less than 1 chimpanzee ID50 (dose that infects 50%) when tested against reference strain H of HCV. We tested equal amounts of RNA extracted from the serum of each individual with the four primer sets. The set derived from two highly conserved domains within the 5' noncoding (NC) region of the HCV genome, which also share significant similarity with Pestivirus 5' NC sequences, was the most effective at detecting HCV RNA. All samples positive for HCV RNA with any other primer set were also positive with the primer set from the 5' NC region, and the latter was at least 3 times more likely to detect HCV infection than a primer set from within the nonstructural protein 3-like gene region (P less than 0.001). We had no false positive results in greater than 500 negative controls interspersed among the test samples. The 5' NC region primer set detected HCV-specific RNA, verified by high-stringency Southern blot hybridization and DNA sequencing, in 100% of 15 acute and 33 chronic non-A, non-B hepatitis patients from the United States, Europe, and Asia and 10 hepatocellular carcinoma patients from Africa and Asia that tested negative for the hepatitis B virus-encoded surface antigen. In conclusion, use of an appropriate primer set is crucial for detecting HCV RNA in the serum of infected individuals.     

Sequence analysis of the core gene of 14 hepatitis C virus genotypes.

We previously sequenced the 5' noncoding region of 44 isolates of hepatitis C virus (HCV), as well as the envelope 1 (E1) gene of 51 HCV isolates, and provided evidence for the existence of at least 6 major genetic groups consisting of at least 12 minor genotypes of HCV (i.e., genotypes I/1a, II/1b, III/2a, IV/2b, 2c, V/3a, 4a-4d, 5a, and 6a). We now report the complete nucleotide sequence of the putative core (C) gene of 52 HCV isolates that represent all of these 12 genotypes as well as two additional genotypes provisionally designated 4e and 4f that we identified in this study. The phylogenetic analysis of the C gene sequences was in agreement with that of the E1 gene sequences. A major division in the genetic distance was observed between HCV isolates of genotype 2 and those of the other genotypes in analysis of both the E1 and C genes. The C gene sequences of 9 genotypes have not been reported previously (i.e., genotypes 2c, 4a-4f, 5a, and 6a). Our analysis indicates that the C gene-based methods currently used to determine the HCV genotype, such as PCR with genotype-specific primers, should be revised in light of these data. We found that the predicted C gene was exactly 573 nt long in all 52 HCV isolates, with an N-terminal start codon and no in-frame stop codons. The nucleotide and predicted amino acid identities of the C gene sequences were in the range of 79.4-99.0% and 85.3-100%, respectively. Furthermore, we mapped universally conserved, as well as genotype-specific, nucleotide and deduced amino acid sequences of the C gene. The predicted C proteins of the different HCV genotypes shared the following features: (i) high content of proline residues, (ii) high content of arginine and lysine residues located primarily in three domains with 10 such residues invariant at positions 39-62, (iii) a cluster of 5 conserved tryptophan residues, (iv) two nuclear localization signals and a DNA-binding motif, (v) a potential phosphorylation site with a serine-proline motif, and (vi) three conserved hydrophilic domains that have been shown by others to contain immunogenic epitopes. Thus, we have extended analysis of the predicted C protein of HCV to all of the recognized genotypes, confirmed the existence of highly conserved regions of this important structural protein, and demonstrated that the genetic relatedness of HCV isolates is equivalent when analyzing the most conserved (i.e., C) and the most variable (i.e., E1) genes of the HCV genome.     

Nucleotide sequence and mutation rate of the H strain of hepatitis C virus.

Patient H is an American patient who was infected with hepatitis C virus (HCV) in 1977. The patient became chronically infected and has remained so for the past 13 years. In this study, we compared the nucleotide and predicted amino acid sequences of the HCV genome obtained from plasma collected in 1977 with that collected in 1990. We find that the two HCV isolates differ at 123 of the 4923 (2.50%) nucleotides sequenced. We estimate that the mutation rate of the H strain of HCV is approximately 1.92 x 10(-3) base substitutions per genome site per year. The nucleotide changes were exclusively base substitutions and were unevenly distributed throughout the genome. A relatively high rate of change was observed in the region of the HCV genome that corresponds to the non-structural protein 1 gene region of flaviviruses, where 44 of 960 (4.6%) nucleotides were different. Within this region there was a 39-nucleotide domain in which 28.2% of the nucleotides differed between the two isolates. In contrast, relatively few nucleotide substitutions were observed in the 5' noncoding region, where only 2 of 276 (0.7%) nucleotides were different. Our results suggest that the mutation rate of the HCV genome is similar to that of other RNA viruses and that genes appear to be evolving at different rates within the virus genome.     

Genomic structure of the human prototype strain H of hepatitis C virus: comparison with American and Japanese isolates.

Genomic RNA from the human prototype strain H of the hepatitis C virus (HCV-H) has been molecularly cloned and sequenced. The HCV-H sequence reported consists of 9416 nucleotides including the 5' and 3' untranslated regions. HCV-H shows 96% amino acid identity with the American isolate HCV-1 but only 84.9% with the Japanese isolates HCV-J and HCV-BK. In addition to the hypervariable region (region V) previously identified in the putative E2 domain, three other variable domains were identified: region V1 (putative E1), region V2 (putative E2), and region V3 (putative NS5). These regions appear rather conserved (86-100%) among the American isolates (HCV-1 and HC-J1) or among various Japanese isolates (HCV-J, HCV-BK, HCV-JH, and HC-J4) but show striking heterogeneity when the two subgroups are compared (42-87.5% amino acid difference). A structural similarity between the 5'-terminal hairpin structure of HCV and of poliovirus was observed. This study further suggests the existence of at least two genomic subtypes of HCV and confirms a distant relationship between HCV and pestiviruses.     

Complete nucleotide sequence of an Indian strain of Japanese encephalitis virus: sequence comparison with other strains and phylogenetic analysis.

The RNA genome of an Indian strain of Japanese encephalitis virus (JEV), GP78, was reverse transcribed and the cDNA fragments were cloned in bacterial plasmids. Nucleotide sequencing of the cDNA clones covering the entire genome of the virus established that the GP78 genome was 10,976 nucleotides long. An open reading frame of 10,296 bases, capable of coding for a 3,432 amino acid polyprotein, was flanked by 95- and 585-base long 5'- and 3'-non-coding regions, respectively. When compared with the nucleotide sequence of the JaOArS982 strain, the JEV GP78 genome had a number of nucleotide substitutions that were scattered throughout the genome except for the 5'-noncoding region, the sequence of which was fully conserved. Comparison of the complete genome sequences of different JEV isolates showed a 1.3-4.1% nucleotide sequence divergence among them, which resulted in 0.6-1.8% amino acid sequence divergence. Analysis based on the complete genome sequences of different JEV isolates showed that the GP78 isolate from India was phylogenetically closer to the Chinese SA14 isolate.     

Segment-specific inverted repeats found adjacent to conserved terminal sequences in wound tumor virus genome and defective interfering RNAs.

Defective interfering (DI) RNAs are often associated with transmission-defective isolates of wound tumor virus (WTV), a plant virus member of the Reoviridae. We report here the cloning and characterization of WTV genome segment S5 [2613 base pairs (bp)] and three related DI RNAs (587-776 bp). Each DI RNA was generated by a simple internal deletion event that resulted in no sequence rearrangement at the deletion boundaries. Remarkably, although several DI RNAs have been in continuous passage for more than 20 years, their nucleotide sequences are identical to that of corresponding portions of segment S5 present in infrequently passaged, standard, transmission-competent virus. The positions of the deletion breakpoints indicate that the minimal sequence information required for replication and packaging of segment S5 resides within 319 bp from the 5' end of the (+)-strand and 205 bp from the 3' end of the (+)-strand. The terminal portions of segment S5 were found to contain a 9-bp inverted repeat immediately adjacent to the conserved terminal 5'-hexanucleotide and 3'-tetranucleotide sequences shared by all 12 WTV genome segments. The presence of a 6- to 9-nucleotide segment-specific inverted repeat immediately adjacent to the conserved terminal sequences was found to be a feature common to all WTV genome segments. These results reveal several basic principles that govern the replication and packaging of a segmented double-stranded RNA genome.     

Genetic variability and characterization of non-structural region 5 of hepatitis C virus genome from Chinese patients

Sequence variation in the putative nonstructural region 5b (NS5b) of hepatitis C virus (HCV) was analyzed in China. Complementary DNA fragments from sera of 49 Chinese patients were amplified by polymerase chain reaction (PCR) and the products were cloned and sequenced. Based on the comparison in NS5b of 33 clones of genotype 1b and 16 clones of genotype 2a, Chinese isolates of HCV belong to the same subtype as HCV-J, and HC-J6 from Japan. There does exist, however, some heterogeneity in the primary structure of the nucleotide acid. Higher homology was found among Chinese isolates than among Chinese isolates and Japanese isolates. Furthermore, among Chinese isolates, we found some conserved nucleotide acid positions different from those of Japanese isolates. Comparison of average homology among the 33 clones of genotype 1b and the 16 clones of genotype 2a indicated that the average homology among genotype 2a was lower than that among genotype 1b. In addition, a deletion of three nucleotide acids and a frame-shift, resulting in the introduction of an in-frame stop codon, were first observed in the NS5b region. These results indicated geographical differences in the distribution of individual HCV isolates, and the existence of a local variant in the same subtype. Our findings also suggested the need for further study on the sequence of genotype 2a, to improve diagnosis and help to advance the development of a vaccine. Received Mar. 7, 1997; accepted May 23, 1997     

The effects of the conserved extreme 3' end sequence of hepatitis C virus (HCV) RNA on the in vitro stabilization and translation of the HCV RNA genome

BACKGROUND/AIMS: The discovery of an additional 98-base in the extreme 3' end of the hepatitis C virus (HCV) has fueled much speculation as to the role of this sequence on the behavior of the virus. It is now known that this additional 98-base sequence is present and conserved amongst HCV genotypes. This sequence is capable of forming complex and stable high-order structures that may be important in stabilizing the RNA to degradation, facilitating translation and regulating replication of the virus. We have examined the possible role of the HCV extreme 3' end sequence in stabilizing the HCV RNA genome and regulating translation in vitro. METHODS: The extreme 3' end sequence was cloned to downstream of two pre-existing two HCV clones: HCV1 (genotype 1a) and HCV-BK (genotype 1b). The reconstructed full-length clones were then tested in vitro for their stability and translation efficiency. RESULTS: We showed that the addition of the conserved 3' end sequence greatly enhanced the stability of HCV1 RNA but had only minimal effect on HCV-BK RNA in mammalian cytoplasmic extracts, suggesting that the requirements for HCV RNA stability vary amongst isolates. Following the optimization of in vitro translation conditions, it was demonstrated that the addition of this 3' end sequence did not affect the translation level from either HCV clone. CONCLUSIONS: The conserved 3' end of the HCV genome confers differential stabilizing effects on two HCV genotype 1 isolates and has no obvious role in the in vitro translation of either clone.     

Comparison of the chromosomal localization of murine and human glucocerebrosidase genes and of the deduced amino acid sequences.

To study structure-function relationships and molecular evolution, we determined the nucleotide sequence and chromosomal location of the gene encoding murine glucocerebrosidase (glucosylceramidase; D-glucosyl-N-acylsphingosine glucohydrolase, EC 3.2.1.45). In the protein coding region of the murine cDNA, the nucleotide sequence and the corresponding deduced amino acid sequences were 82% and 86% identical to the respective human sequences. All five amino acids presently known to be essential for normal enzymatic activity were conserved between mouse and man. The murine enzyme had a single deletion relative to the human enzyme at amino acid number 273. One ATG translation initiation signal was present in the mouse sequence in contrast to the human sequence, where two start codons have been reported. Nucleotide sequencing of a clone derived from murine genomic DNA revealed that the murine signal for translation initiation was located in exon 2. The locations of all 10 introns were conserved among mouse and man. We mapped the genetic locus for glucocerebrosidase to mouse chromosome 3, at a position 7.6 +/- 3.2 centimorgans from the locus for the beta subunit of nerve growth factor. Comparison of linkage relationships in the human and murine genome indicates that these closely linked mouse genes are also syntenic on human chromosome 1 but in positions that span the centromere.     

Serological response to infection with different isolates of hepatitis C virus

Different isolates of hepatitis C virus (HCV) show nucleotide sequence variability throughout the genome. Detection of antibodies to recombinant proteins derived from hepatitis C virus genotype 1, the prototype HCV clone HCV-PT, constitutes the main method for screening HCV infection. The influence of the genomic variability on the serological diagnosis of HCV by enzyme immunoassay remains poorly defined. The aim of this study was to assess the serological reactivity of a panel of well characterized French HCV isolates typed by sequence analysis from patients with chronic hepatitis. The 73 sera samples were tested in three third generation EIA tests and three confirmatory assays. HCV isolates were determined by RT-PCR and sequencing in NS5B region of the genome. The 73 sera were positive in the three EIA tests. The three confirmatory tests showed a weaker reactivity with NS5 protein whatever the genotype, and a lower reactivity in NS4 antigens of non-type 1 sequences, particularly for genotype 3. Even though the reactivity of the antigens differed among the HCV isolates, the 73 isolates from genotype 1-6 were reactive with the three commercial screening assays. These results demonstrate that using a single test is adequate in the routine diagnosis of HCV infection in clinical laboratory, as recommended by the last French and European consensus conference.     

Secondary structure and hybridization accessibility of the hepatitis C virus negative strand RNA 5'-terminus

Summary.  The positive strand RNA genome of hepatitis C virus (HCV) is transcribed exclusively from a full-length cytoplasmic replication intermediate, the negative strand RNA. Despite this essential role in hepatocellular infection, the negative strand has not yet been subjected to extensive molecular characterization, and in comparison with the HCV genome and proteome, remains relatively unexplored as a target for antiviral therapy. The highly conserved negative strand terminal sequences, complementary to the positive strand 5'- and 3'-untranslated regions, are believed to contribute structural features essential for the initiation of positive strand synthesis and the maintenance of template integrity. We investigated the solution structure of the HCV negative strand 5'-terminal region by endoribonuclease mapping and thermodynamic modelling of RNA secondary structure. The enzymatic probing data are consistent with structural models featuring a large terminal stem loop (SL), which constitutes a mirror image of the complementary 3'-X region SL I structure. Nucleotide positions within the negative strand accessible to hybridization were mapped by RNase H digestion in the presence of combinatorial oligonucleotide libraries. The hybridization data further support the existence of a terminal SL, and reveal target sites within the negative strand 5'-terminus which may be susceptible to antisense-mediated inhibition.     

Short report: genetic heterogeneity of Japanese encephalitis virus assessed via analysis of the full-length genome sequence of a Korean isolate.

We determined the full-length genome sequence of Japanese encephalitis virus (JEV) K94P05 isolated in Korea. Sequence analysis showed that the 10,963-nucleotide-long RNA genome of K94P05 was 13 or 14 nucleotides shorter than the genome of other JEV isolates because of a deletion in the 3' noncoding region of K94P05. Compared with sequences of other JEV isolates, the full-length nucleotide sequence showed 89.0-89.6% homology, and the deduced amino acid sequence showed between 96.4-97.3% homology. A region of approximately 60 nucleotides immediately downstream of the open reading frame stop codon of K94P05 showed high sequence variability as compared with other JEV isolates. K94P05 formed a distinct group within a phylogenetic tree established with the full-length genome sequences. Cross-neutralization studies showed that polyclonal antibodies to Korean isolates were 3 times better at neutralizing the Korean isolates than antibodies to Nakayama-NIH. These findings suggest that Korean JEV K94P05 is genetically and antigenically distinct from other Asian JEV isolates.     

Sequence and Structural Analysis of 3' Untranslated Region of Hepatitis C Virus,Genotype 3a,From Pakistani Isolates

Background

Hepatitis C virus (HCV) is the cause of high morbidity and mortality worldwide, inflicting around one million people in Pakistan alone. The HCV genomic RNA harbors conserved structural elements that are indispensable for its replication. The 3’ untranslated region (UTR) contains several of these elements essentially involved in regulating the major steps of the viral life cycle.

Objectives

Differences in regulatory elements of HCV may contribute towards differential infectivity of local isolates. The present study explicates sequence analysis and secondary structure prediction of HCV 3''UTR region of subtype 3a from Pakistan to characterize this particular region.

Patients and Methods

HCV 3''UTR region was amplified, cloned and sequenced from five different patients. Sequence and structural analysis was performed and phylogenetic analysis was carried out using the 3''UTR sequence reported in NCBI nucleotide data base (http://www.ncbi.nlm.nih.gov/nuccore) by other studies.

Results

Sequence analysis of the amplified fragment from five patients indicated that the 3''UTR is composed of 214-235 nts. Its sequence contains a type-specific variable region followed by a poly U/UC region and a highly conserved X-tail of 98 nts. The variable region reported here has 26 nts and one stem loop at the secondary structure that differentiate it from HCV genotype 1a ( GT1a) 3''UTR which contains additional 14 nts and two stem loops. The poly U/UC region varied in length (100-79 nts) and nucleotide sequence within the Pakistani isolates, and among different genotypes. Some substitutions found in the X-tail do not affect secondary structure of this element suggesting that this region might play an important role in replication, stabilization and packaging of HCV genome. Additionally, U residues are not present at the end of the X-tail in Pakistani 3a isolates as otherwise reported for the variants of genotype 1b.

Conclusions

Sequence and structural diversity of the 3''UTR variable region and Poly U/UC region found in the local isolates indicate specificity in the regulating elements of 3''UTR that might be associated with differential replication efficacy of the HCV Pakistani isolates. The study necessitates functional characterization of these regulating elements to elucidate variable viral efficiency and pathogenicity associated with inter-geographical isolates.