The human hepatitis B virus (HBV) is a member of the hepadnavirus family that includes a number of other very similar host-specific viruses. Acute HBV infection can produce extreme variation in disease, ranging from asymptomatic infection, to acute transient hepatitis with jaundice, or fulminant hepatitis leading to liver failure (Hollinger, 1996). The identification of viral genes that affect the severity of disease is a major current goal in medical virology. For example, there is considerable ....The human hepatitis B virus (HBV) is a member of the hepadnavirus family that includes a number of other very similar host-specific viruses. Acute HBV infection can produce extreme variation in disease, ranging from asymptomatic infection, to acute transient hepatitis with jaundice, or fulminant hepatitis leading to liver failure (Hollinger, 1996). The identification of viral genes that affect the severity of disease is a major current goal in medical virology. For example, there is considerable interest in identifying the genes of the influenza genome responsible for high mortality outbreaks; with the human immunodeficiency virus, the virus that causes AIDS, variants deleted in the nef gene region cause a less rapidly progressing infection and have attracted attention as a possible prototype for an attenuated vaccine. We propose to investigate how the different genes of hepadnaviruses affect the course of infection and type of disease produced. Studies will be performed in ducks infected with the duck hepatitis B virus (DHBV) as these animals provide the only model system available in Australia. We will study both experimentally and naturally derived DHBV variants to explore the effects of genetic changes on the outcome of infection. This will enhance our understanding of this virus family and will provide models for comparison with HBV infection. This knowledge may then contribute to our ability to manage and control HBV disease in humans.Read moreRead less
Herpesviruses infect most Australians and cause recurrent ulcers, birth defects and cancer. Infection lasts lifelong, and spreads to close contacts without obvious clinical signs. Thus disease is hard to prevent. However we can learn much from related animal infections. We have shown that both mouse and human herpesviruses enter mice via cells in the nose. Thus human infections might follow the same route. We will define what body defences work here and whether vaccines can prevent infection.
Human ?-herpesviruses persist for life, cause cancers and emerge with particular virulence when the immune system is weak. Vaccination against them is therefore an important health priority. We have shown for a related ?-herpesvirus of mice that live vaccines protect. Antibody seems to play a major role. We will test whether safer, recombinant vaccines are also sufficient to elicit protective antibody. Thus we can establish a viable strategy for preventing virus-induced human cancers.
Viral infections of the gut are one of the most debilitating infections one can suffer from. Noroviruses are the most common causative agents of viral-associated gastroenteritis but unfortunately little is known regarding their biology and pathogenesis. Our study aims to investigate the replication and pathogenesis of a mouse norovirus to shed light on similar aspects relating to human norovirus infection. We aim to understand how virus infection in cells leads to disease symptoms.
Defining The Requirement For The Inhibition Of Bak To The Pathogenesis Of Cytomegalovirus Infection
Funder
National Health and Medical Research Council
Funding Amount
$592,661.00
Summary
Apoptosis, or programmed cell death is a powerful defence mechanism against viral infection. Thus, to replicate efficiently viruses have evolved means to inhibit apoptosis. The central aim of this work is to understand how cytomegalovirus prevents cell death protein during infection. The proposed studies will improve our understanding of the mechanisms that regulate viral replication and will contribute insights into the normal processes that control cell survival.
Influenza A Virus PB1-F2 Protein: A Putative Virulence Factor And Initiator Of Inflammation
Funder
National Health and Medical Research Council
Funding Amount
$474,718.00
Summary
Influenza virus produces a protein of undefined function called PB1-F2. Infection of mice with virus expressing PB1-F2 from virulent strains causes severe lung inflammation, while PB1-F2 from milder seasonal viruses does not. We will examine how PB1-F2 influences virulence of human influenza in the ferret, which exhibits the same illness as humans. This work will help understand the disease severity of newly evolved influenza viruses of humans and the role of PB1-F2 in mediating this.
Understanding HIV Resistance To Entry Inhibitors To Advance The Development Of Novel Antivirals
Funder
National Health and Medical Research Council
Funding Amount
$877,585.00
Summary
We cannot afford to be complacent in the search for improved anti HIV drugs for 2 principal reasons; First, worldwide a staggering 66% of infected individuals who need treatment are still unable to access therapy; and Second, the main reason why most treated patients are now living longer and more healthy lives is because we have never stopped developing newer therapies to provide options for patients. In this study we will develop and test newer drugs that block HIV infection of cells.
Current combination antiviral therapy can't cure an HIV infection because long-lived T-cells carrying latent HIV DNA can rekindle the infection when drugs are removed. We will study elements in HIV genetic code that control expression of HIV proteins from latent HIV. A detailed molecular understanding of the structure and function of these HIV RNA elements and the viral and host cell factors that interact with them will expose new targets for therapy of latent HIV.