cDNA sequencing of the 5' noncoding region (5' NCR) to determine hepatitis C genotypes in patients with chronic hepatitis C

[High prevalence of genotype 1 in individuals with hepatitis C in Belo Horizonte, MG]

The hepatitis C virus is characterized by significant genetic heterogeneity. It is currently classified into six main genotypes and several subtypes. Determining the genotype of the virus is important in clinical practice for guiding the treatment for individuals with chronic hepatitis C. The prevalence of different genotypes and subtypes of the hepatitis C virus has not been fully studied in some regions of Brazil. In this study, 788 samples from patients with chronic hepatitis C who were attended at the Viral Hepatitis Reference Centers in Belo Horizonte were analyzed between 2002 and 2006. The genotyping of the virus was performed by direct sequencing of the 5 UTR region. Additionally, phylogenetic analysis was performed, including all of the genotypic variants obtained. High prevalence of genotype 1 (78.4%; 1b [40.4%], 1a [37.5%] and 1a/b [0.5%]) was observed, followed by genotypes 3a (17.9%) and 2b (3.1%). Three samples were identified as genotype 2a/c (0.4%) and two as genotype 4 (0.2%). The phylogenetic analysis showed the expected segregation of the sequences obtained, with regard to the reference sequences for genotypes 1, 2, 3 and 4, except for two samples of genotype 1a. The high prevalence of genotype 1 (78.4%) found in this population from Belo Horizonte was similar to previous reports from other cities such as Rio de Janeiro, but it was higher than what has been described in São Paulo and in the south of the country. The presence of rare atypical sequences from the 5 UTR region suggests that variants in the hepatitis C virus exist in this population.

Investigation of putative multisubtype hepatitis C virus infections in vivo by heteroduplex mobility analysis of core/envelope subgenomes

The frequency that multiple different subtypes of hepatitis C virus (HCV) simultaneously infect a given individual is controversial. To address this question, heteroduplex mobility analysis (HMA) of portions of the HCV core and envelope 1 region was optimized for sensitive and specific detection of mixtures of HCV genomes of different genotype or subtype. Using the standard HCV genotyping approach of 5'-untranslated region (UTR) analysis, 28 of 374 (7.5%) chronic hepatitis C research subjects were classified as having either multiple-subtype HCV infections (n = 21) or switching HCV subtypes over time (n = 7), the latter pattern implying viral superinfection. Upon retesting of specimens by HMA, 25 of 28 multiple-subtype results could not be reproduced. All three patients with positive results were injection drug users with potential multiple HCV exposures. To address the hypothesis of tissue sequestration of multiple-subtype HCV infections, liver (n = 22), peripheral blood mononuclear cell (n = 13), perihepatic lymph node (n = 16), and serum (n = 19) specimens from 23 subjects with end-stage hepatitis C were collected and analyzed by the HMA technique. Whereas 5'-UTR results implicated mixed-subtype HCV infections in 2 subjects, HMA testing revealed no evidence of a second HCV subtype in any tissue compartment (0 of 70 compartments [0%]) or within any given subject (0 of 23 subjects [0%]). In summary, a large proportion of mixed-genotype and switching-genotype patterns generated by 5'-UTR analysis were not reproducible using the HMA approach, emphasizing the need for additional study.

Transmission of human hepatitis C virus from patients in secondary cells for long term culture

Infection by human hepatitis C virus (HCV) is the principal cause of post-transfusion hepatitis and chronic liver diseases worldwide. A reliable in vitro culture system for the isolation and analysis of this virus is not currently available, and, as a consequence, HCV pathogenesis is poorly understood. We report here the first robust in vitro system for the isolation and propagation of HCV from infected donor blood. This system involves infecting freshly prepared macrophages with HCV and then transmission of macrophage-adapted virus into freshly immortalized B-cells from human fetal cord blood. Using this system, newly isolated HCV have been replicated in vitro in continuous cultures for over 130 weeks. These isolates were also transmitted by cell-free methods into different cell types, including B-cells, T-cells and neuronal precursor cells. These secondarily infected cells also produced in vitro transmissible infectious virus. Replication of HCV-RNA was validated by RT-PCR analysis and by in situ hybridization. Although nucleic acid sequencing of the HCV isolate reported here indicates that the isolate is probably of type 1a, other HCV types have also been isolated using this system. Western blot analysis shows the synthesis of major HCV structural proteins. We present here, for the first time, a method for productively growing HCV in vitro for prolonged periods of time. This method allows studies related to understanding the replication process, viral pathogenesis, and the development of anti-HCV drugs and vaccines.

Evaluation of a prototype HCV NS5b assay for typing strains of hepatitis C virus isolated from Tunisian haemodialysis patients

Hepatitis C virus (HCV) strains isolated from 68 haemodialysis Tunisian patients exhibiting chronic infection were genotyped targeting the NS5b region of the HCV genome using a prototype assay developed by Bayer HealthCare-Diagnostics (TRUGENE NS5b HCV). The overall results were compared to those obtained with another assay of the same company based on sequencing of the 5' non-coding region (TRUGENE HCV 5'NC genotyping kit). All strains could be typed by the 5'NC typing kit, but only 62 (91; 2%) by the NS5b prototype assay. All the 62 strains typed by both methods exhibited the same pattern at the type level: 57 were type 1, 3 were type 2, and 2 were type 4. At the subtype level, eight strains that gave undetermined results by the 5'NC kit were successfully typed by the NS5b kit; eight additional strains exhibited discrepant results. The overall agreement between the two assays was 74.2% at the subtype level. In conclusion, the NS5b region appears to be much more accurate than the 5'NC region to subtype HCV strains, especially in those isolated from patients attending haemodialysis centres where the subtype distribution suggests frequent nosocomial transmissions.

Determining hepatitis C genotype by analyzing the sequence of the NS5b region

Assays to determine the hepatitis C virus (HCV) genotype have recently become useful for clinical decision making and may be suitable for epidemiological investigations, such as identifying HCV outbreaks in a given population. Molecular assays are the most common diagnostic tools for HCV genotyping. This study compares two genome typing assays, one, the Trugene 5'NC genotyping kit, uses the sequence of the 5' non-coding (5'NC) region and the other, a non-commercial assay, uses the non-structural 5b (NS5b) region. Serum samples from 203 chronically HCV-infected patients were tested. The 5'NC and the NS5b assays were both very effective in identifying the genotype (99 and 98.5%) and the results with the two methods were always concordant for the genotype. The NS5b analysis permitted the identification of the subtype in all samples, whereas the 5'NC region assay did not in 33% of samples. The NS5b analysis showed that one patient had a mixed infection with HCV subtypes 1a and 2c, while the 5'NC assay did not. It is concluded that phylogenetic analysis using both the 5'NC and the NS5b regions are reliable and convenient methods for HCV typing in clinical practice. But analysis of the NS5b region may be more useful for tracing the source of an HCV infection.

Distribution of HCV genotypes among risk groups in Serbia

Blood samples from 190 patients that were anti-hepatitis C virus (HCV) positive were genotyped and 165 were found to contain HCV-RNA. Genotyping was performed by PCR based on type-specific primers (117 isolates) and LiPA test (48 isolates) and verifying by sequencing. In Serbia, the most frequent genotype was 1b (49.1%), followed by genotype 3 (21.2%) and genotype 1a (8.5%). The frequency of genotypes 2 and 4 was below 5% and mixed infections were encountered in 9.1% of cases. Distribution of genotypes was monitored in different risk groups: intravenous drug abusers, patients under blood transfusion, patients with previous history of surgery, patients undergoing hemodialysis and those with unknown risk factors. Genotype distribution is essentially the same in all the groups, except for the patients undergoing hemodialysis and those with previous history of surgery where significant difference exists compared with the group with unknown route of transmission (p < 0.001 and p < 0.05, respectively). There exists significant age-dependent genotype 3 distribution in Serbian population (p < 0.01).

Analysis of 5' non-coding region in hepatitis C virus by single-strand conformation polymorphism and low-stringency single specific primer PCR

Single-strand conformation polymorphism (SSCP) and low-stringency single specific primer (LSSP)-PCR in hepatitis C virus (HCV) genotyping were examined for informativeness and reliability. The analysis of HCV isolates included seven type 1 isolates, two type 2 isolates, and two type 3 isolates. We also analyzed five isolates that presented as mixed infections determined by type-specific PCR. Among mixed isolates, one isolate was 1a/1b and four isolates were 1b/3a. SSCP and LSSP-PCR were applied to the analysis of 5' non-coding region of HCV (-289 to -5) that contains genotype-specific sequences. Direct cycle sequencing of this region determined sequence divergences that define genotype and sequence alterations within the same genotype. Optimized conditions for the SSCP analysis clearly distinguished between genotypes 1, 2 and 3. In addition, the SSCP analysis detected sequence variants within the same genotype. However, the SSCP analysis and DNA sequencing did not confirm the presence of mixed infections. LSSP analysis, not previously employed in HCV genotyping, enabled clear distinction between genotypes 1, 2 and 3, however, this method did not differentiate between sequence variants within a genotype. Importantly, the LSSP profile demonstrated distinction between mixed infection isolates.

A pilot trial of recombinant interleukin-12 in patients with chronic hepatitis C who previously failed treatment with interferon-alpha

OBJECTIVE

Interleukin-12 is a cytokine with a multitude of immunomodulatory actions. Currently, interferon-alpha (IFN-alpha) monotherapy and combination treatment with IFN and ribavirin are the only therapies with proven efficacy against chronic hepatitis C infection. The purpose of this study was to assess the safety and antiviral activity of recombinant interleukin-12 (rhIL-12) in adults with chronic hepatitis C who did not achieve a sustained response to previous IFN-alpha therapy.

METHODS

This was a randomized, placebo-controlled, double-blind trial. We randomized 24 patients to one of three dose groups: 30 ng/kg, 100 ng/kg, and 300 ng/kg. Within each group, six patients received rhIL-12, and two patients received placebo administered s.c. twice a week for 12 wk.

RESULTS

Three of six patients treated with rhIL-12 at a dose of 300 ng/kg had loss of detectable hepatitis C RNA by reverse transcription-polymerase chain reaction compared with the placebo group (p = 0.05). All patients relapsed at the end of the 3-month treatment period. No other dose group demonstrated a loss of detectable hepatitis C RNA.

CONCLUSIONS

RhIL-12 at 300 ng/kg can suppress hepatitis C RNA to undetectable levels by reverse transcription-polymerase chain reaction, although relapse occurred when treatment was stopped. RhIL-12 was well tolerated with the most common side effects being flu-like symptoms and headaches.

Genotyping of hepatitis C virus isolates using CLIP sequencing

Determination of hepatitis C virus (HCV) genotypes and subtypes has become increasingly important for the clinical management and prognosis of HCV infections. The aim of the present study was to assess the specificity and reliability of a newly developed, commercially available HCV genotyping kit (TRUGENE HCV 5'NC genotyping kit). This technique utilizes PCR fragments previously generated by the diagnostic Roche AMPLICOR HCV test, which are subsequently subjected to simultaneous PCR amplification and direct sequencing (CLIP sequencing) of the 5' noncoding region (5'NCR). HCV isolates from 100 randomly chosen patients were genotyped by both the TRUGENE HCV 5'NC genotyping kit and DNA enzyme immunoassay (DEIA). Typing results obtained by both methods were in complete concordance in 91% of the cases. HCV RNA from the samples with discordant genotype assignment in both assays was additionally amplified with primers from the HCV core and NS5B regions. Phylogenetic analysis of the obtained sequences supported the results obtained from DEIA in six cases and CLIP sequencing in two cases. In the former six cases, the TRUGENE HCV 5'NC genotyping kit could not correctly differentiate between subtypes of genotypes 1 and 2 due to the high conservation of the 5'NCR. However, since there was not any misclassification between HCV genotypes 1 and non-1 types, the results obtained with this system are, in general, reliable and can be used in clinical practice. The TRUGENE HCV 5'NC genotyping kit in our hands proved to be a fast and convenient technique that might be an attractive option for HCV genotyping in laboratories already using the Roche AMPLICOR HCV test for diagnostic reverse transcription-PCR.

Simplified hepatitis C virus genotyping by heteroduplex mobility analysis

Heteroduplex mobility analysis (HMA) was used to genotype hepatitis C viruses (HCV) with PCR fragments derived from the 5' untranslated region (5'-UTR) or the NS5b region. HCV 5'-UTR fragments were amplified from 296 serum samples by use of a combined reverse transcription-PCR assay, and the genotypes of isolates were determined by sequencing. HCV genotype distributions in Australia were 39% for genotype 1a, 15% for 1b, 3% for 1a/b, <1% for 2a/c, 5% for 2b, 34% for 3a, <1% for 3b, and 1% for 4, and 1% of patients were infected with more than one genotype. Pairwise HMA of subtypes 1a, 1b, 2a/c, 2b, 3a, 3b, 4a, and 6a demonstrated that five distinct heteroduplex patterns were formed between the eight subtypes. A reference panel that contained a representative of each pattern (1a, 2b, 3a, 4a, and 6a) was used for genotyping. The pattern of heteroduplexes formed when a test isolate was mixed with the five reference isolates was correlated with the genotype, as determined by sequencing. Genotypes determined by HMA correlated exactly with sequencing results within the groups 1, 2, 3a, 3b/4, and 6. HMA was also used to simplify the identification of mixed infection with two HCV genotypes. In further studies, with amplicons from the NS5b region, HMA classified isolates into their respective subtypes, and the heteroduplex mobility ratio correlated closely with nucleotide sequence variation at the isolate, subtype, and genotype levels. HMA provides an adaptable, inexpensive, and rapid method of genotyping HCV that requires fewer resources than DNA sequencing.

Hepatitis C virus genotypes in hemophiliacs in the state of Minas Gerais, Brazil

BACKGROUND

Hepatitis C virus (HCV) is a positive-strand RNA virus composed of at least 10 genotypes and dozens of subtypes. Six major genotypes can be distinguished by restriction fragment length polymorphism (RFLP) analysis of the amplified 5' noncoding region (NCR) of the genome. The genotypes are unequally distributed throughout the world. Types 1 and 3 are most common in Europe and the United States. Although fewer studies have been performed in Brazil, the pattern seems to mirror that in the other areas. HCV infection is highly prevalent among hemophiliacs and is a major cause of chronic liver disease.

STUDY DESIGN AND METHODS

This study investigated a sample of the hemophiliac population in the state of Minas Gerais, Brazil, by RFLP analysis of the 5' NCR.

RESULTS

It was observed that 84.1 percent were of genotype 1 and 13.6 percent of genotype 3. Sequence analysis of nine isolates confirmed the RFLP results and determined that all of the type 1 isolates belonged to subtype 1a. Phylogenetic analysis by parsimony and distance revealed that lineages of genotypes 1, 2, and 3, and 4 could be separated. The isolates of type 3 from this study were distinct from published sequences, which possibly indicated their different geographical origin.

CONCLUSION

Although the frequency of genotypes observed (types 1 and 3) among hemophiliacs in the state of Minas Gerais was higher than that in the southern part of the country, these frequencies were not different from those in other groups of patients in Brazil and other countries studied. Further investigation is needed of the evidence that the type 3 isolates observed in these studies are significantly different from other isolates previously characterized by sequence analysis.

Mutations in nonstructural protein 5A gene and response to interferon in hepatitis C virus genotype 2 infection

An association has been reported between mutations in the amino acid residues 2209-2248 of the nonstructural protein 5A (NS5A) gene (interferon-sensitivity determining region [ISDR]) and interferon efficacy in hepatitis C virus (HCV)-1b infection. This relationship was analyzed in chronic HCV-2 infection. Forty patients with HCV-2a and 35 with HCV-2b were treated with interferon alfa for 6 months with a total dose of 468 to 860 million units. Pretreatment NS5A sequences were determined by direct sequencing. A higher complete and sustained response rate was observed in HCV-2a than in HCV-2b (70% vs. 34%; P =.003). Serum HCV-RNA levels were lower in complete responders than nonresponders in HCV-2a (P =.049) and HCV-2b (P =. 02). The number of amino acid mutations was greater in complete responders than nonresponders in NS5A2193-2228 (the region corresponding to the ISDR of HCV-1b) alone (P =.049), or NS5A2163-2228 consisting of NS5A2193-2228 plus its upstream region (P =.02) in HCV-2a, but not in HCV-2b. A significant inverse correlation was observed between serum HCV-RNA levels and the number of amino acid mutations in NS5A2193-2228 (P =.003) or NS5A2163-2228 (P =.005) in HCV-2a. With multivariate analysis, the number of substitutions in NS5A was an independent predictor for complete response in HCV-2a (odds ratio: 6.4; P =.03). Interferon efficacy is associated with amino acid variations in the NS5A protein in HCV-2a infection.

Comparative study of a modified competitive RT-PCR and Amplicor HCV monitor assays for quantitation of hepatitis C virus RNA in serum

A modified competitive RT-PCR (mcRT-PCR) to measure HCV RNA in serum and the Amplicor HCV Monitor assay were compared. For mcRT-PCR, the RNA extracted was retrotranscribed and coamplified in one step with a known amount of a DNA internal control (IC). Digoxigenin-labeled amplified products were hybridized to specific HCV DNA and IC-DNA probes and quantified by colorimetry. HCV RNA concentration was calculated by plotting the ratio of HCV/IC ODs against a calibration curve. Multiple samples were analyzed in the same round and tedious titration of each sample with a competitor was unnecessary. The mcRT-PCR assay was linear from 6 x 10(3) to 6 x 10(7) copies/ml, whereas Amplicor was linear up to 1-2 x 10(6) copies/ml. HCV RNA was measured in samples from 75 carriers. There was agreement between both methods in type 1 infections but not in type 2 or type 3 infections, in which the values measured by Amplicor were, on average, 15 times lower than those measured by the mcRT-PCR. HCV RNA measured by Amplicor was higher in type 1 infections than in type 2 or 3 infections, but no differences were found when viral load was assessed by mcRT-PCR. The binding efficiency of the Amplicor-probe was greater for type 1 than for types 2 or 3, suggesting Amplicor underestimates the viral load in the latter types. In contrast, the mcRT-PCR is not affected by genotype-related variation of HCV. This study suggests that mcRT-PCR assay is reliable for sensitive and accurate measurement of HCV RNA over a broad range of values independently of the HCV genotype.

Quantitative assessment of hepatitis C virus RNA in peripheral blood mononuclear cells during therapy with interferon-alpha2a

A significant number of patients with hepatitis C (HCV) treated with interferon (IFN) will initially clear their serum of HCV RNA, but will then have recurrence of viraemia either during or after therapy. One proposed mechanism for relapse is that HCV may persist in peripheral blood mononuclear cells (PBMCs) and that the PBMCs serve as a 'viral reservoir' that is resistant to IFN. To address this hypothesis, we performed serial, quantitative polymerase chain reaction (PCR) of HCV RNA in serum and PBMCs from 26 consecutive patients treated with IFN-alpha2a. Of the 26 patients, 11 (42%) did not clear virus from their serum during therapy and were termed non-responders. Five patients (19%) had sustained clearance of virus from serum and were termed complete responders. The remaining 10 patients (39%) initially eliminated HCV RNA from their serum, but had relapse of viraemia. They were termed partial responders. In all 10 partial responders HCV RNA was undetectable in PBMCs at the same time that it was undetectable in serum. When virus recurred in serum, it was preceded by or occurred at the same time as the return of virus in PBMCs. The results of our study indicate that PBMCs did not serve as an IFN-resistant 'viral reservoir' during therapy. Partial responders who transiently cleared virus from serum also cleared virus from PBMCs and the presence or titre of HCV RNA in PBMCs at the initiation of therapy did not predict response to therapy.