Determination of hepatitis C virus genotype by direct sequence analysis of products generated with the Amplicor HCV test.

Consistent with other members of the family Flaviviridae, hepatitis C virus (HCV) demonstrates a high degree of sequence variation throughout the coding regions of its genome. However, there is a high degree of sequence conservation found within the 5' untranslated region (UTR) of the genome, making this region a target of choice for most nucleic acid amplification-based detection assays. In this study, the Amplicor HCV test, a commercially available assay which detects the 5'UTR, was used for the detection of HCV RNA in 669 serum samples obtained from a cohort of liver transplantation patients. Amplification products obtained from the HCV-positive cases were subjected to direct sequencing and genotyping based upon seven phylogenetically informative regions within the 5'UTR. Of the 669 specimens, 416 (62.2%) tested positive for the presence of HCV RNA. Of these, 372 (89.4%) specimens were successfully classified into 11 HCV genotypes and subtypes after computer-assisted analysis of the sequence data. Forty-four (10.6%) of the HCV RNA-positive specimens were not classifiable, the majority corresponding to low-titer specimens as determined by the Chiron Quantiplex HCV RNA 2. 0 assay. Additional comparative studies targeting the NS-5 region of the viral genome generally confirmed the accuracy and sensitivity of the 5'UTR-based classifications, with the exception of the misclassification of a small number of type 1a cases as type 1b. We conclude that although the high sequence conservation within the 5'UTR results in the misclassification of a small number of HCV subtypes, the overall gains of efficiency, the shorter turnaround time, the inclusion of contamination control measures, and the low rate of test failure compared to that of methods based on the NS-5 gene together constitute significant advantages over other techniques.     

Hepatitis C virus genotyping: interrogation of the 5' untranslated region cannot accurately distinguish genotypes 1a and 1b

Although the 5' untranslated region (5' UTR) is the most conserved region of the hepatitis C virus (HCV) genome, it has been suggested that interrogation of this region is sufficient for determination of the HCV genotype. We compared two methods of determination of the HCV genotype: (i) direct sequencing of the DNA of the NS-5b region and (ii) reverse line probe assay (LiPA; INNO-LiPA HCV II; Innogenetics N.V.) of the 5' UTR. There was 100% concordance between the two methods for genotype but only 80% concordance for subtype. A significant percentage of genotype 1a isolates were misclassified by LiPA as genotype 1b. Sequence analysis revealed that the only consistent difference in the 5' UTR for these genotype 1a isolates misclassified as genotype 1b was a single nucleotide (A/G) at position -99 of the HCV genome. All isolates with discordant results analyzed had a G at this position, consistent with LiPA determination of these samples as subtype 1b. However, sequence analysis of 222 nucleotides in the NS-5b region clearly identified all of these isolates as subtype 1a. Population distribution data from the University of Pittsburgh Medical Center of over 200 samples analyzed by sequencing of the NS-5b region and over 1,000 samples analyzed by LiPA also indicated that INNO-LiPA HCV II cannot accurately differentiate HCV genotype 1a isolates from HCV genotype 1b isolates. We provide evidence that the A/G at position -99 represents a sequence polymorphism in the HCV genome that cannot differentiate subtype 1a from subtype 1b isolates. In conclusion, the 5' UTR is not heterogeneous enough for use in determination of the HCV subtype and cannot be used for differentiation of HCV genotypes 1a and 1b.     

Genotyping hepatitis C virus by heteroduplex mobility analysis using temperature gradient capillary electrophoresis

The genotype of the infecting hepatitis C virus (HCV) helps determine the patient's prognosis and the duration of treatment. Heteroduplex mobility analysis (HMA) is a rapid, inexpensive method for genotyping of HCV that does not require sequencing. We developed an HMA that uses temperature gradient capillary electrophoresis (TGCE) to differentiate HCV genotypes. A 56-bp region of the HCV 5' untranslated region (UTR) that was conserved within a genotype yet whose sequence differed between genotypes was amplified for HMA-TGCE analysis. HCV amplicons of types 1, 2a, 2b, 3a, 4, and 6a were hybridized in pairs and analyzed by TGCE. Amplicons hybridized to the same subtype yielded one homoduplex peak, while hybridization of different subtypes resulted in heteroduplexes and generated multiple TGCE peaks. Heteroduplexes contain thermodynamically unstable nucleotide mismatches that reduced their TGCE mobilities compared to those of homoduplexes. Three HCV subtypes (subtypes 1a, 3a, and 4) generated unique peak patterns when they were combined with each genotype analyzed and were chosen as the reference genotypes. A blinded study with 200 HCV-infected samples was 97% accurate compared to genotyping by 5' UTR sequence analysis. The majority of discordant results were unexpected sequence variants; however, five of nine sequence variants were correctly genotyped. The assay also detected and correctly genotyped mixed HCV infections. Compared to conventional HMA, TGCE improves the resolution, with better separation of heteroduplexes and homoduplexes. All common HCV genotypes can be detected and differentiated by this HMA-TGCE assay.     

2a型丙型肝炎病毒5’非编码区的RACE护增及二级结构的分析

目的：获得真全长中国大陆2a型丙型肝炎病毒（HCV）5’非编码区（5’UTR）cDNA，并分析其一级结构和二级结构，为进一步研究其在HCR复制、翻译中的调控机制、开发新的抗HCV药物奠定基础。方法：利用逆转录套式聚合酶链反应（RT－PCR）联合限制性内切酶长度多态性分析（RFLP）初步筛选出1例2a型HCV感染者，采用cDNA末端快速扩增技术（RACE）扩增出一条约800bp的cDNA片段，A－T克隆，用RFLP与PCR鉴定重组子，全自动序列分析仪测定插入子序列，RNAdraw预测二级结构。结果：RACE法获得真全长2a型HCV 5’端序列。5个克隆中，3个克隆含全长5’UTR序列，与HCV－1，HC－C2，HC－J6，HC－J8相比，同源性分别为93．6％－94．4％，92．1％－93．0％，98．8％－99．7％，96．2％－96．5％，与2a型标准株HC－J6相比，21，170，222，247，339位不同，分别为G，A，C，C，T,但这些突变不影响其二级结构。另外2个克隆为5’端缺失突变株，分别缺失54bp和144bp。结论：RACE技术快速、有效、实用，可用效获得病毒基因组的末端序列；依此获得中国大陆2a型HCV的5’UTR cDNA；在感染者血液中存在5’端部分缺失的HCV基因片段。     

Non-genotype-specific role of the hepatitis C virus 5' untranslated region in virus production and in inhibition by interferon

The 5′ untranslated region (5′UTR) of hepatitis C virus (HCV) is structured into four domains (I-IV) with numerous genotype-specific nucleotides. It is unknown whether the polymorphisms confer genotype-specific functions to the 5′UTR. Using viable JFH1-based Core-NS2 recombinants, we developed and characterized HCV genotypes 1-7 recombinants with highly diverse 5′UTRs (genotypes 1a and 3a), 2a recombinants (J6/JFH1) with 5′UTR of genotypes 1-6 or with heterotypic chimeric (1a/3a and 3a/1a) 5′UTR domains I, II or III, and 1a recombinants with 5′UTR domain I of genotypes 1-6. All were fully functional in Huh7.5 cells; therefore, the 5′UTR apparently functions in a non-genotype-specific manner in HCV production in vitro. However, adenine at the 5′-terminus was required. We demonstrated that J6/JFH1 with 5′UTR of genotypes 1-6 responded similarly to interferon-α2b. This study provides novel insight into the role of the 5′UTR in the HCV life cycle and facilitates HCV basic research and testing of 5′UTR-targeting antivirals.     

Towards a better resolution of hepatitis C virus variants: CLIP sequencing of an HCV core fragment and automated assignment of genotypes and subtypes

Commercially available assays for typing of hepatitis C virus (HCV) isolates satisfy the current clinical needs. They are, however, limited in their ability to identify the multitude of existing HCV subtypes correctly. Therefore, these kits should only be used cautiously in epidemiological studies and will also not meet future clinical demands which might arise, e.g., from the application of HCV subtype-specific antiviral compounds. In an attempt to overcome the drawbacks of commercial typing procedures based on the analysis of the 5' untranslated region (5' UTR), an approach was developed which relies on CLIP sequencing of an HCV core fragment with automated assignments of types and subtypes via an originally created "core-specific" sequence database. The performance characteristics of the new technique were evaluated in comparison to the Trugene 5' NC Genotyping Kit. The core-based sequencing method could regularly detect HCV isolates of genotypes 1-6 with an analytical sensitivity of 5000 IU/ml. The accuracy of typing results obtained by the Trugene test was 97% (genotypes) and 81% (subtypes). The core-linked approach classified all HCV strains correctly on the level of genotypes and led to an adequate subtype assignment in 96% of all cases. This analytical performance characteristics recorded for the newly devised typing technique was superior to those reported for all commercially available assays, including a most recently released new generation of the line probe assay. Consequently, CLIP sequencing of an HCV core fragment with subsequent automated assignment of types and subtypes can be confidently used in clinical laboratory practice to answer current and also future questions in the context of HCV typing.     

Genome analysis of hepatitis C virus strain 274933RU isolated in Russian Federation

Five overlapping cDNA fragments of hepatitis C virus (HCV) isolate 274933RU, obtained by RT-PCR, were amplified and cloned. Complete nucleotide RNA sequence has been determined. The genomic organization of 274933RU was, from 5' to 3' terminals, 5' UTR (341 nt), polyprotein ORF (9033 nt), 3' UTR (40 nt except for the poly(U-UC) and polypyrimidine stretch), and X-tail (98 nt). Phylogenetic analysis of the core and NS5 genes showed that the isolated strain belonged to HCV 1b subtype.     

Genotyping hepatitis C viruses from Southeast Asia by a novel line probe assay that simultaneously detects core and 5' untranslated regions

Hepatitis C viruses (HCVs) display a high level of sequence diversity and are currently divided into six genotypes. A line probe assay (LiPA), which targets the 5' untranslated region (5'UTR) of the HCV genome, is widely used for genotyping. However, this assay cannot distinguish many genotype 6 subtypes from genotype 1 due to high sequence similarity in the 5'UTR. We investigated the accuracy of a new generation LiPA (VERSANT HCV genotype 2.0 assay), in which genotyping is based on 5'UTR and core sequences, by testing 75 selected HCV RNA-positive sera from Southeast Asia (Vietnam and Thailand). For comparison, sera were tested on the 5'UTR based VERSANT HCV genotype assay and processed for sequence analysis of the 5'UTR-to-core and NS5b regions as well. Phylogenetic analysis of both regions revealed the presence of genotype 1, 2, 3, and 6 viruses. Using the new LiPA assay, genotypes 6c to 6l and 1a/b samples were more accurately genotyped than with the previous test only targeting the 5'UTR (96% versus 71%, respectively). These results indicate that the VERSANT HCV genotype 2.0 assay is able to discriminate genotypes 6c to 6l from genotype 1 and allows a more accurate identification of genotype 1a from 1b by using the genotype-specific core information.     

Hepatitis C virus genotyping based on 5' noncoding sequence analysis (Trugene)

Hepatitis C virus (HCV) genotyping of samples from 184 patients with chronic HCV infection by the Trugene 5'NC genotyping kit, based on sequence analysis of the 5' noncoding region (5' NCR), and the InnoLiPA assay was evaluated. In addition to these methods, the 184 samples were also analyzed by sequencing of part of the NS5B of the HCV genome after in-house PCR amplification, as a means of validating results obtained with the 5' NCR. The distribution of the genotypes typed by NS5B sequence analysis was as follows: 1a, 41 samples; 1b, 58 samples; 1d, 1 sample; 2a, 5 samples; 2b, 2 samples; 2c, 7 samples; 3a, 46 samples; 4a, 7 samples; 4c, 1 samples; 4e, 9 samples; 5a, 6 samples; 6a, 1 sample. The Trugene and InnoLiPA assays gave concordant results within HCV types in 100% of cases. The ability to discriminate at the subtype level was 76 and 74% for the Trugene and the InnoLiPA assays, respectively.     

Evaluation of a new assay for hepatitis C virus genotyping and viral load determination in patients with chronic hepatitis C

A new method for hepatitis C virus (HCV) genotyping that analyzes products generated with the HCV Amplicor Monitor Test has been developed. One hundred and sixty-two Japanese patients with chronic hepatitis C, including 59 patients with hemophilia, were tested for HCV genotypes and viral loads with this new test, and the results were compared with those of a genotyping assay that involved direct sequencing of the E1 region. HCV genotypes and viral loads were also compared between patients with and without hemophilia. There were no discrepancies between the two methods in determining genotypes 2a, 2b, and 3a. However, two patients infected with 1a were mistyped as 1b with the new assay. One patient not classified by this assay was genotype 4. Genotypes found in patients without hemophilia were 1b, 2a, and 2b. Genotypes 1a, 3a, and 4, which were minor variants in Japan, were detected only in patients with hemophilia. In addition, J type, which is a subtype of 1b that originated in Japan, was found at low frequency in hemophiliacs. Thus, the HCV genotypes in patients with hemophilia are likely to be of foreign origin. Overall, this new assay was accurate except for genotype 1a and 4, and allowed simultaneous assessment of genotype and viral load.     

Nested restriction site-specific PCR to detect and type hepatitis C virus (HCV): a rapid method to distinguish HCV subtype 1b from other genotypes

Genotypic differentiation of hepatitis C virus (HCV) has become an integral part of clinical management and epidemiologic studies of hepatitis C infections. Thus, it is extremely important in areas such as the Czech Republic, where current instrumentation and kits for assessing HCV infection are too costly for widespread use. We describe a new and relatively inexpensive method called nested restriction site-specific PCR (RSS-PCR) that generates a "fingerprint" pattern to represent an HCV genotype without the use of restriction endonucleases and that specifically differentiates HCV genotype 1b from the other HCV genotypes. The RSS-PCR method was applied directly to serum samples from patients with hepatitis C from the Czech Republic and from patients with known HCV genotypes from the United States. The method was validated by comparison of the subtype determined by RSS-PCR to the subtype determined from analysis of the 5' noncoding region (NC) or the nonstructural protein gene (NS5b) nucleotide sequence of HCV in these clinical samples. From 75 Czech samples containing HCV RNA, three distinct RSS-PCR patterns were observed; 54 were predicted to contain subtype 1b, 19 were predicted to contain subtype 1a, and 2 were predicted to contain subtype 3a. Among 54 samples predicted to contain HCV genotype 1b, all were confirmed by their 5' NC or NS5b sequences to be subtype 1b. Thus, both the sensitivity and specificity of the RSS-PCR test for the differentiation of HCV subtype 1b from the others were 100%. While the assay described here was designed to specifically differentiate HCV subtype 1b from the other HCV genotypes, the RSS-PCR method can be modified to differentiate any HCV genotype or subtype of interest. Its simplicity and speed may provide new opportunities to study the epidemiology of HCV infections and the relationship between HCV genotypes and clinical outcome by more laboratories throughout the world.     

Discrepancy of hepatitis C virus genotypes as determined by phylogenetic analysis of partial NS5 and core sequences

The use of phylogenetic analyses of partial NS5 and core regions for hepatitis C virus (HCV) genotyping was evaluated by analysing seven Honduran and 24 European HCV strains. Core primers were designed with which HCV genotypes 1, 2, and 3 were readily amplified. The reliability of phylogenetic analysis of a 111-bp core sequence was verified by comparing the typing results with those obtained using the whole core gene of 52 reference strains. Accordant genotypes (1a, 1b, 2b, and 3a) were obtained when phylogenetic analyses were undertaken on both the partial core and a 222-bp NS5 sequence in all of the European HCV strains. Genotypes 1a, 1b, and 3a were identified among the Honduran strains by phylogenetic analysis of the partial NS 5 sequence. Interestingly, two of three Honduran type 3a strains, as determined by the NS5 sequence analysis, turned out to be type 1a by core sequence analysis. These two strains were also classified as type 1a, but not 3a, by a core type-specific PCR. Furthermore, the R2/NS1 regions were similar to HCV-PT, a representative strain of genotype 1a. The results indicate that chimeral HCV strains exist, although in most cases a good concordance is found when phylogenetic analysis of partial core and NS5 sequences are used for genotyping. This finding should be taken into account when HCV is genotyped by a phylogenetic analysis of a partial HCV sequence from a single genomic region. © 1996 Wiley-Liss, Inc.     

Molecular characterization,distribution, and dynamics of hepatitis C virus genotypes in blood donors in Colombia

Hepatitis C virus (HCV) is a frequent cause of acute and chronic hepatitis and a leading cause for cirrhosis of the liver and hepatocellular carcinoma. HCV is classified in six major genotypes and more than 70 subtypes. In Colombian blood banks, serum samples were tested for anti‐HCV antibodies using a third‐generation ELISA. The aim of this study was to characterize the viral sequences in plasma of 184 volunteer blood donors who attended the “Banco Nacional de Sangre de la Cruz Roja Colombiana,” Bogotá, Colombia. Three different HCV genomic regions were amplified by nested PCR. The first of these was a segment of 180 bp of the 5′UTR region to confirm the previous diagnosis by ELISA. From those that were positive to the 5′UTR region, two further segments were amplified for genotyping and subtyping by phylogenetic analysis: a segment of 380 bp from the NS5B region; and a segment of 391 bp from the E1 region. The distribution of HCV subtypes was: 1b (82.8%), 1a (5.7%), 2a (5.7%), 2b (2.8%), and 3a (2.8%). By applying Bayesian Markov chain Monte Carlo simulation, it was estimated that HCV‐1b was introduced into Bogotá around 1950. Also, this subtype spread at an exponential rate between about 1970 to about 1990, after which transmission of HCV was reduced by anti‐HCV testing of this population. Among Colombian blood donors, HCV genotype 1b is the most frequent genotype, especially in large urban conglomerates such as Bogotá, as is the case in other South American countries. J. Med. Virol. 82:1889–1898, 2010. © 2010 Wiley‐Liss, Inc.     

Comparison of different methods of hepatitis C virus genotyping

In order to introduce the approach of HCV genotyping in our laboratory, a comparative study of 3 molecular and 1 serological methods, was conducted on 62 HCV RNA positive sera. The molecular genotyping methods target the 5'untranslated (UTR) region of the virus genome and are based on an amplification of the viral genome, followed by partial sequencing, analyses of restriction fragment length polymorphisms (RFLP) or molecular hybridation (Inno LiPA, Innogenetics). The serological method or serotyping is based on the detection of antibodies to genotype specific epitopes derivated from the Non Structural (NS) 4 region of the viral genome (HCV 1-6 Serotyping Assay, Murex Biotech). "In house" methods, sequencing and RFLP, identified the genotype for 13 samples classified as non-typables by commercial kits Inno LiPA test and HCV 1-6 Serotyping Assay. Mixed infections revealed, especially by Inno LiPA, could not be identified by partial sequencing, which seems to detect only predominant genotype. For 4 samples, genotyping results of the methods targeting the 5'UTR were discordant with those of the serotyping of the NS4 region. Commercial kits are efficient to determine HCV genotypes, particularly in the context of antiviral therapy and patient's follow-up, sequencing remains the best alternative for more complete characterisation of viral strains and for epidemiological investigations.