The identification of the neutralization domains of hepatitis C virus (HCV) is essential for the development of an effective vaccine. Here, we show that the hypervariable region 1 (HVR1) of the envelope 2 (E2) protein is a critical neutralization domain of HCV. Neutralization of HCV in vitro was attempted with a rabbit hyperimmune serum raised against a homologous synthetic peptide derived from the HVR1 of the E2 protein, and the residual infectivity was evaluated by inoculation of HCV-seronegative chimpanzees. The source of HCV was plasma obtained from a patient (H) during the acute phase of posttransfusion non-A, non-B hepatitis, which had been titered for infectivity in chimpanzees. The anti-HVR1 antiserum induced protection against homologous HCV infection in chimpanzees, but not against the emergence of neutralization escape mutants that were found to be already present in the complex viral quasispecies of the inoculum. The finding that HVR1 can elicit protective immunity opens new perspectives for the development of effective preventive strategies. However, the identification of the most variable region of HCV as a critical neutralization domain poses a major challenge for the development of a broadly reactive vaccine against HCV.Hepatitis C virus (HCV) is an important cause of morbidity and mortality worldwide (1-3). Infection with HCV becomes chronic in Ͼ80% of the cases and is a major cause of liver cirrhosis (4) and hepatocellular carcinoma (5). Although the development of a broadly reactive vaccine would be the most effective method for its control, concerns have been raised because of the high degree of genetic heterogeneity of HCV (6) and the lack of protective immunity against reinfection (7,8) or superinfection (9, 10) documented both in humans and in chimpanzees. Viral isolate-restricted neutralizing antibodies against HCV have been demonstrated recently in infected individuals (11, 12), but their molecular target is presently unknown.Several observations have suggested that the hypervariable region 1 (HVR1) could be involved in the neutralization of HCV. This assumption is based on the fact that the HVR1, which is located at the N terminus of the envelope glycoprotein 2 (E2) gene and consists of 34 amino acids spanning map position 384-414 (13), is the most variable region of the HCV genome (14, 15), contains linear epitopes that are recognized by patients' antibodies (16-22) and mutates rapidly in vivo (23)(24)(25)(26), suggesting that it is under the selective pressure of the host immune system. This hypothesis is further substantiated by the lack of variability in the HVR1 observed in an agammaglobulinemic patient over a period of 2.5 years (27). Recent data obtained in vitro suggest that antibodies, present in human sera and directed against the HVR1 as well as against the E2 protein of HCV, can prevent the binding of HCV to cells (28,29). The potential importance of the HVR1 for HCV neutralization is also underscored by the analogy with the V3 loop of human immunodeficiency virus, w...
Hepatitis C virus (HCV) is the most important etiologic agent of non-A, non-B hepatitis and is a major cause of chronic liver disease and hepatocellular carcinoma. Development ofan effective vaccine would be the most practical method for prevention of the infection, but whether infection with HCV elicits protective immunity in the host is unclear. Neutralization of HCV in vitro was attempted with plasma of a chronically infected patient, and the residual infectivity was evaluated by inoculation of eight seronegative chimpanzees. The source of HCV was plasma obtained from a patient during the acute phase of posttransfsion non-A, non-B hepatitis, which had previously been titered for infectivity in chimpanzees. Neutralization was achieved with plasma obtained from the same patient 2 yr after the onset of primary infection but not with plasma obtained 11 yr later, although both plasmas contained antibodies against nonstructural and structural (including envelope) HCV proteins. Analysis of sequential viral isolates from the same patient revealed significant genetic divergence as early as 2 yr after infection. However, the HCV recovered from the patient 2 yr after the infection had a striking sequence similarity with the HCV recovered from one of the chimpanzees inoculated with the acute-phase virus, suggesting that the progenitor of the new strain was already present 2 yr earlier. This evidence, together with the different sequences of HCV recovered from the chimpanzees that received the same inoculum, confirms that HCV is present in vivo as a quasispecies. These results provide experimental evidence in vivo that HCV infection elicits a neutralizing antibody response in humans but suggest that such antibodies are isolate-specific. This result raises concerns for the development of a broadly reactive vaccine against HCV.
During the early phase of primary HCV infection, there is a period of several months of sero-negativity during which HCV RNA is the only diagnostic marker of infection. The disappearance of HCV RNA from serum appears to correlate with the resolution of non-A, non-B hepatitis, whereas viremia persists in patients whose disease progresses to chronic hepatitis. In contrast, antibody levels do not necessarily remain elevated in patients with chronic disease.
Some individuals infected with hepatitis C virus (HCV) experience multiple episodes of acute hepatitis. It is unclear whether these episodes are due to reinfection with HCV or to reactivation of the original virus infection. Markers of viral replication and host immunity were studied in five chimpanzees sequentially inoculated over a period of 3 years with different HCV strains of proven infectivity. Each rechallenge of a convalescent chimpanzee with the same or a different HCV strain resulted in the reappearance of viremia, which was due to infection with the subsequent challenge virus. The evidence indicates that HCV infection does not elicit protective immunity against reinfection with homologous or heterologous strains, which raises concerns for the development of effective vaccines against HCV.
Hepatitis E virus (HEV) is a very important public health concern in many developing countries where epidemics of hepatitis E are common. Sporadic cases of clinical hepatitis E not only occur in these countries but also occur uncommonly in patients with no known epidemiological exposure to HEV in industrialized countries. The source of infection in industrialized countries is unknown but it has been suggested that animals might serve as a reservoir for HEV in both settings. We recently identified and characterized an HEV strain (swine HEV) that infects large numbers of pigs in the United States. To assess the potential of pigs to serve as a global reservoir of HEV, we measured the prevalence of HEV antibodies in pigs in two countries where hepatitis E is endemic and two countries where it is not. Swine herds in all four countries contained many pigs that were seropositive for IgG anti-HEV, although the percentage of seropositive pigs varied greatly from herd to herd. A very limited number of pig handlers in the two endemic countries were also tested and most of them were found to be seropositive for HEV. The results from this study suggest that hepatitis E is enzootic in pigs regardless of whether HEV is endemic in the respective human population. J. Med. Virol. 59:297-302, 1999. Published 1999 Wiley-Liss, Inc.
The cytoplasmic antigen and ultrastructural changes we described previously for chimpanzees (Pan troglodytes) infected with hepatitis C virus (HCV) or with hepatitis D virus have recently been shown to be indirect measures of viral replication and appear to represent a host response to the expression or action of interferon. The time of appearance of these changes in hepatocytes during HCV infection, when compared with similar changes in hepatitis D virus infection, suggests a very early replicative phase for HCV. To investigate the early events in HCV infection, we infected two chimpanzees with HCV and obtained blood and liver biopsy samples from them daily during the first 10 days of infection. The early stage of infection with regard to HCV replication, antigen expression, and ultrastructural changes was similar in both chimpanzees. When tested by cDNA/polymerase chain reaction, HCV sequences became detectable in the serum as early as 3 days after inoculation and remained positive through the peak of aminotransferase elevations. In one chimpanzee the peak of virus production appeared to be 7 weeks after inoculation, which was coincident with rising enzyme values. The cytoplasmic antigen, detected by immunofluorescence, and ultrastructural changes, detected by electron microscopy, became positive in hepatocytes 3 and 6 days, respectively, after HCV sequences were first detected in serum. Circulating anti-HCV appeared 13 weeks and 32 weeks after inoculation, respectively, in the chimpanzees. These data indicate a very early replicative phase for HCV and a potentially long period of infectivity before the appearance of anti-HCV.The genome of the parenterally transmitted form of non-A, non-B hepatitis virus, now termed hepatitis C virus (HCV), was recently cloned (1). Synthesis of cDNA by reverse transcription of viral RNA and amplification by polymerase chain reaction (PCR), with primers based on the nucleotide sequences of HCV cDNA clones, has been useful for detecting HCV RNA (2). An immunodiagnostic test for anti-HCV antibody (anti-C100-3 antibody) was also developed (3). Despite development of these tests for HCV, relatively little is known about the replication and pathogenesis of this virus. Previously, we reported characteristic ultrastructural changes (cytoplasmic tubular structures) by EM (4,5) and the appearance ofa cytoplasmic antigen, detected by immunofluorescent staining with a monoclonal antibody (6, 7) in chimpanzees (Pan troglodytes) experimentally infected with HCV or hepatitis D virus (HDV). The expression of both EM changes and antigen appeared to be host-specified responses to infections with these two viruses, but not with hepatitis A virus or hepatitis B virus. Both ultrastructural changes and antigen were subsequently shown to be related to the local expression or action of interferon, presumably produced in response to replication of HCV or HDV (8). The analysis of serial clinical specimens obtained from chimpanzees experimentally infected with HDV has revealed a relatively unifo...
Hemolytic uremic syndrome (HUS) is a potentially life-threatening condition. It often occurs after gastro-intestinal infection with E. coli O157:H7, which produces Shiga toxins (Stx) that cause hemolytic anemia, thrombocytopenia, and renal injury. Stx-mediated changes in endothelial phenotype have been linked to the pathogenesis of HUS. Here we report our studies investigating Stx-induced changes in gene expression and their contribution to the pathogenesis of HUS. Stx function by inactivating host ribosomes but can also alter gene expression at concentrations that minimally affect global protein synthesis. Gene expression profiling of human microvascular endothelium treated with Stx implicated a role for activation of CXCR4 and CXCR7 by their shared cognate chemokine ligand (stromal cell-derived factor-1 [SDF-1]) in Stx-mediated pathophysiology. The changes in gene expression required a catalytically active Stx A subunit and were mediated by enhanced transcription and mRNA stability. Stx also enhanced the association of CXCR4, CXCR7, and SDF1 mRNAs with ribosomes. In a mouse model of Stx-mediated pathology, we noted changes in plasma and tissue content of CXCR4, CXCR7, and SDF-1 after Stx exposure. Furthermore, inhibition of the CXCR4/SDF-1 interaction decreased endothelial activation and organ injury and improved animal survival. Finally, in children infected with E. coli O157:H7, plasma SDF-1 levels were elevated in individuals who progressed to HUS. Collectively, these data implicate the CXCR4/CXCR7/SDF-1 pathway in Stx-mediated pathogenesis and suggest novel therapeutic strategies for prevention and/or treatment of complications associated with E. coli O157:H7 infection.
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