Our findings provide evidence that a cardiac surgeon with chronic hepatitis C may have transmitted HCV to five of his patients during open-heart surgery.
We describe a rapid and reproducible method for assessment of the hepatitis C virus (HCV) load in serum samples. The method combines Taqman technology (Roche) and the ABI Prism 7700 (Perkin Elmer) real-time sequence detection system. We have optimized a single-tube reverse transcription-PCR (RT-PCR) that contains a dual-labeled fluorogenic probe to quantify the 5′ noncoding region (5′ NCR) of HCV. The probe contains a fluorescent reporter at the 5′ end and a fluorescent quencher at the 3′ end. The use of such a probe combined with the 5′-3′ nuclease activity of Taq polymerase allows direct quantitation of the PCR product by the detection of a fluorescent reporter released in the course of the exponential phase of the PCR. For accurate quantitation of the number of copies of HCV in samples containing unknown quantities, we have used serial dilutions of a synthetic 5′ NCR RNA standard of HCV that was previously quantified with an isotopic tracer. The method has a 5-log dynamic range (103 to 107). The coefficient of regression of the standard curve was, on average, 0.98. The intra-assay and the interassay coefficients of variation of the threshold cycle were 1% and 6.2%, respectively. Seventy-nine RNA samples from the sera of infected patients were quantified by this method. Comparison of the results with those obtained by other quantitation methods (the Quantiplex 2.0 branched-DNA assay and the Superquant assay from the National Genetics Institute) revealed a significant correlation with all of the results. The mean values were also statistically comparable. In conclusion, the high sensitivity, simplicity, and reproducibility of the real-time HCV RNA quantitation which allows the screening of large numbers of samples, combined with its wide dynamic range, make this method especially suitable for monitoring of the viral load during therapy and tailoring of treatment schedules.
The quasispecies nature of the hepatitis C virus (HCV) is thought to play a central role in maintaining and modulating viral replication. Several studies have tried to unravel, through the parameters that characterize HCV circulating quasispecies, prognostic markers of the disease. In a previous work we demonstrated that the parameters of circulating viral quasispecies do not always reflect those of the intrahepatic virus. Here, we have analyzed paired serum and liver quasispecies from 39 genotype 1b-infected patients with different degrees of liver damage, ranging from minimal changes to cirrhosis. Viral level was quantified by real-time reverse transcription-PCR, and viral heterogeneity was characterized through the cloning and sequencing of 540 HCV variants of a genomic fragment encompassing the E2-NS2 junction. Although in 95% of patients, serum and liver consensus HCV amino acid sequences were identical, quasispecies complexity varied considerably between the viruses isolated from each compartment. Patients with HCV quasispecies in serum more complex (26%) than, less complex (28%) than, or similarly complex (41%) to those in liver were found. Among the last, a significant correlation between fibrosis and all the parameters that measure the viral amino acid complexity was found. Correlation between fibrosis and serum viral load was found as well (R ؍ 0.7). With regard to the origin of the differences in quasispecies complexity between serum and liver populations, sequence analysis argued against extrahepatic replication as a quantitatively important contributing factor and supported the idea of a differential effect or different selective forces on the virus depending on whether it is circulating in serum or replicating in the liver. Flaviviridae (7,29,45). Its genome consists of a single-stranded RNA, with plus polarity, of 9,600 nucleotides, which does not integrate in the host genome, yet persistence is the rule. The damage caused during infection ranges from minimal changes to cirrhosis of the liver and hepatocarcinoma, but little is known about the mechanism of hepatocyte injury due to chronic infection. It seems very likely that the pathogenesis of HCV infection is directly related to a strong interplay between the host defense mechanisms and the virus's ability to evade them efficiently. Moreover, in order to persist, HCV must regulate its lytic potential and avoid elimination by the host immune system. Due to the quasispecies structure of the HCV viral population infecting single patients (39), the virus may use a variety of strategies to fulfill both requirements (11,17). Hepatitis C virus (HCV) is an enveloped virus classified in the familyThe dynamic component of the quasispecies structure is responsible for the rapid virus evolution (12). It works through a complex mixture of genomic sequences (quasispecies) which behaves as a single unit when facing changes in the environment. The genetic interaction within the viral population allows the system to distinguish the best possibility at any given...
We have found that RNase P from HeLa cells specifically and efficiently cleaves hepatitis C virus (HCV) transcripts in vitro. The evidence includes identification of the 5-phosphate polarity of the newly generated termini at position A 2860 as well as immunological and biochemical assays. Active cleavage has been shown in five dominant sequences of HCV "quasispecies" differing at or near the position of cleavage, demonstrating that this is a general property of HCV RNA. During the analysis, a second cleavage event was found in the 3 domain of the internal ribosome entry site. We have found that HCV RNA competitively inhibits pre-tRNA cleavage by RNase P, suggesting that HCV RNA has structural similarities to tRNA. This finding sets HCV apart from other pathogens causing serious human diseases and represents the first description of human RNase P-viral RNA cleavage. Here we discuss the possible meaning of these RNase P-accessible structures built into the viral genome and their possible role in vivo. Moreover, such structures within the viral genome might be vulnerable to attack by therapeutic strategies.
Analysing significant numbers of cDNA clones of the hepatitis C virus (HCV) from single isolates provides unquestionable proof that the viral genome cannot be defined by a single sequence, but rather by a population of variant sequences closely related to one another. This way of organizing the genetic information is referred to as quasispecies. Throughout HCV infection, the number and composition of the variants in the viral population keeps changing owing to environmental influences, resulting in a virus that is constantly redefining itself both genetically and phenotypically. Therefore, the virus has often been investigated in population terms. Many clinical studies have tried to unravel, through the parameters that characterize the HCV quasispecies, prognostic markers of the disease and its response to treatment. Other investigations have focused on discovering how the virus and host interact during chronic infection. The consensus sequence, the rate of fixation of mutations and the complexity of the viral population are useful parameters for describing the viral population behaviour and its interaction with the host. In addition to sequencing, several other methods, based on electrophoretic mobility, have been used to study these parameters, such as temperature gradient-gel electrophoresis, single-strand conformation polymorphism and gel-shift analysis. The viral region examined, the source of clinical specimen, as well as the methodology employed, will be decisive in interpreting the information obtained.
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