We are studying the pathogenesis of viral hepatitis and the molecular basis for virulence and attenuation of these important pathogens. In collaborative studies with Dr. Frank Chisari (Scripps Institute) we have studied in chimpanzees the mechanism by which the host clears a hepatitis B virus infection and the relationship of these mechanisms to clinical disease. We demonstrated that the clearance of the template for HBV synthesis, covalently closed circular HBV DNA, is eliminated from hepatocytes by non-cytolytic mechanisms mediated principally by interferon gamma in the liver. Elimination of residual hepatocytes containing HBV antigens is a later event that is mediated by cytolytic CD8 positive T cells and is temporally related to the hepatitis phase of the infection. The spectrum of virus-induced and immune response-related genes involved in acute hepatitis B were further studied by microarray analysis of intrahepatic messenger RNAs up-regulated and down-regulated during the course of hepatitis B infections in chimpanzees. Surprisingly, we could not detect evidence of an innate immune response to infection, suggesting that HBV can subvert the host immune response, but we did detect a strong adaptive immune response during the clearance phase of infection;this correlated with the inhibition of viral replication and removal of infected cells described above. Interestingly, in additional studies of chronic HBV infection in chimpanzees, we found an innate immune response that was missing in acute, self-limiting infections of HBV. This occurred at a time of liver damage, suggesting that viral and cellular products released from dead and dying hepatocytes could trigger other innate host defenses, such as TLR-3. However, the up-regulated innate immune responses were weak and insufficient to affect virus replication. The genetic heterogeneity of hepatitis C virus is believed to play an important role in its pathogenicity. We have previously examined this relationship by determining the genetic heterogeneity of HCV isolates that were recovered from patients who were infected following transfusion in order to study the early phase of infection and from patients undergoing interferon therapy in order to study changes during the later phase of chronic infection (these may be important in understanding late sequelae, such as liver cancer). Distinctive patterns of dynamic change in the sequence of viral clones during the first several weeks of infection were observed and these correlated with the outcome of infection. Similarly, the pattern of dynamic changes in sequence during interferon therapy was predictive of the outcome. These findings may be useful in predicting the outcome of therapy with interferon early in the course of treatment. Although considerable information has been gained from these longitudinal studies of patients, it is difficult to study the mechanisms of pathogenesis in such systems. Chimpanzees, which are the only animals other than man that are susceptible to infection with HCV, provide an experimental model for studying the interactions of the host and the virus in the pathogenesis of hepatitis C. Recent studies in chimpanzees suggest that even late sequelae like liver cancer can be studied in the chimpanzee. Collaborative studies with Frank Chisari have demonstrated that, as in hepatitis B virus infections, in hepatitis C virus infections the cellular immune response plays an important role in noncytolytic down-regulation of viral replication and cytolytic removal of residual infected cells. These two mechanisms are sequential and overlapping and the former appears to be mediated by interferon gamma and the latter by CD8 positive cells and, perhaps by interferon gamma through its proinflammatory activity. These studies have also revealed that type 1 interferon (interferon alpha/beta)-activated antiviral proteins are expressed in response to the viral infections, but that HCV is resistant to the antiviral activity of this innate immune response. Microarray studies of the host immune responses to viral hepatitis and how the hepatitis viruses attempt to circumvent the responses, are yielding important information on pathogenesis of these diseases, and the studies are being extended to the other hepatitis viruses in order to delineate the comparative pathogenesis of these agents in a single host, the chimpanzee, which is the only non-human host that is susceptible to all human hepatitis viruses. In 2010, we completed a microarray analysis of HCV and HEV infections of multiple chimpanzees, comparing the sequence of human and chimpanzee genomes for suitability in interpreting Affimetrics microarray data obtained from serial clinical samples of chimpanzees infected with one or the other of the two viruses. We found that the human genome sequence was more sensitive and specific for identifying up-regulated and down-regulated genes, probably because it is better curated than the more recently sequenced chimpanzee genome. We also compared two analytic methods, a method utilizing Affymetrics probe sets and correlation coefficients with one utilizing individual perfectly matched probes and t-test analysis. Both analyses demonstrated similarities and differences in the host immune response to these two RNA viruses. This information will be useful for a better understanding of the pathogenesis of viral hepatitis. Currently, we are also studying the pathogenesis of HDV infections by microarray analysis and have identified both innate and adaptive immune responses to such infections. Immune responses to HDV infection were similar to those we observed during HCV infection: both a strong innate and a strong adaptive immune response. The innate immune response was sufficient to down-regulate HBV replication in HBV chronically infected chimpanzees that were superinfected with HDV. Thus, HBV, although unable to trigger an innate immune response, is highly sensitive to such a response when provided by another virus. In FY 2009, we have attempted to confirm (or refute) reports by others that HCV blocked certain aspects of the host's innate immune response to improve its replicative edge. In particular, we wished to examine claims that the HCV protease cleaved important proteins in major anti-viral pathways, rendering cells susceptible to infection. These observations were made in cell cultures, which do not always reflect in vivo biology. In experimental HCV infections of chimpanzees, the innate immune response was robust and broad-based. Thus, we could not confirm the previous findings. To make sure that the difference was not a difference between humans and chimpanzees, we collaborated with Dr. Darius Moradpour, who had established a sensitive Western blot assay for measuring HCV protease-mediated cleavage. Dr. Moradpour could not confirm the cleavage phenomenon in liver biopsies from chimpanzees or humans, suggesting that the in vitro findings may be artifactual, or that, in vivo, the host innate immune response has more tools at its disposal than currently appreciated.

Project Start
Project End
Budget Start
Budget End
Support Year
4
Fiscal Year
2010
Total Cost
$706,246
Indirect Cost
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State
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