We seek to gain a detailed understanding of how interactions between the West Nile virus proteins and host factors involved in the IFN response determine the outcome of virus infection. Better understanding of the mechanisms employed by this highly pathogenic virus to disable the mammalian host's IFN response will have wider implications for our understanding of other human diseases such as cancer, autoimmunity and provide new avenues for design of efficient antiviral and anticancer therapies.
Several members of the Flaviviridae family are major pathogens of humans including dengue (DEN), yellow fever (YF), tick-borne encephalitis (TBE), Murray valley encephalitis (MVE), Japanese encephalitis (JE), and hepatitis C virus (HCV). An Australian flavivirus Kunjin (KUN), however, appears to be naturally attenuated and does not cause an overt disease in humans. In contrast, genetically and antigenically closely related to KUN, New York strain of West Nile virus (NY WN) has already caused ~50 ....Several members of the Flaviviridae family are major pathogens of humans including dengue (DEN), yellow fever (YF), tick-borne encephalitis (TBE), Murray valley encephalitis (MVE), Japanese encephalitis (JE), and hepatitis C virus (HCV). An Australian flavivirus Kunjin (KUN), however, appears to be naturally attenuated and does not cause an overt disease in humans. In contrast, genetically and antigenically closely related to KUN, New York strain of West Nile virus (NY WN) has already caused ~500 deaths and over 20,000 registered infections since its emergence in North America in 1999, including 223 deaths and 9122 infections in 2003 alone. Recent studies with DEN indicated that flaviviruses may interfere with early steps of IFN-signalling pathway. The type I Interferon (IFN) response is the first line of defence against viral infections and many viruses have developed different strategies to counteract this response in order to ensure their survival in the infected host. In this grant we seek to exploit our extensive understanding of the molecular biology of KUN virus and the contrasting behaviour of KUN and NY WN viruses to gain an understanding of the role of flavivirus-mediated suppression of host anti-viral IFN response in virus-host relationships and its importance in determining virus virulence.Read moreRead less
I am a molecular virologist studying the events of virus replication and virus-host interactions with the ultimate goal to understand the mechanisms determining viral pathogenesis and develop safe and effective vaccines.
Cellular Microenvironments Facilitating The Replication And Propagation Of Flaviviruses
Funder
National Health and Medical Research Council
Funding Amount
$505,279.00
Summary
Flaviviruses are the agents of many mosquito-transmitted infections and many deaths globally each year. The emerging virus West Nile virus (strain New York) is a member of this virus family and shares 99% amino acid homology with the endemic Australian virus Kunjin virus. During virus growth in cells, cellular membrane structures are induced or rearranged by these viruses for their own purpose. That being the production of more virus particles for reinfection of other cells. Using Kunjin virus a ....Flaviviruses are the agents of many mosquito-transmitted infections and many deaths globally each year. The emerging virus West Nile virus (strain New York) is a member of this virus family and shares 99% amino acid homology with the endemic Australian virus Kunjin virus. During virus growth in cells, cellular membrane structures are induced or rearranged by these viruses for their own purpose. That being the production of more virus particles for reinfection of other cells. Using Kunjin virus as a model, and advanced techniques in biochemistry and electron microscopy, we have identified for the first time these membrane structures as the apparent sites of replication of the viral RNA or genetic material, and of the viral proteins involved. We have also observed how new virus particles are able to get out of infected cells and shown how some drugs can prevent this occurring thus limiting their transmission. This research will focus on how the membrane structures are formed in infected cells. The research will determine what cellular components are required by the virus to help it propagate. In particular specific cellular proteins and membrane components that are captured by the virus and moved to different sites in the infected cells. These apparent requirements could possibly lead us to a greater understanding of the complex interactions that occur between the invading virus and the host cells. We aim to directly visualize the process of infection within living cells using new and innovative microscopic techniques. Another of our objectives is to determine the effects of infection on normal cells. The question being whether flavivirus infection disrupts normalcell fuctions like secretion etc. An understanding of these processes, and how the viral RNA is copied into new RNA for more virus particles, will assist in the development of antiviral drugs for treatment of this pathogenic group of viruses.Read moreRead less
Viral Factors Involved In Flavivirus Replication And Virus-host Interactions
Funder
National Health and Medical Research Council
Funding Amount
$743,696.00
Summary
With our increased understanding of virus-host interactions it has become apparent that small, non-structural proteins and small RNAs of most viruses are vital for numerous, often multiple, functions in the viral life cycle. In the proposed project, we seek to gain a detailed understanding of the functions of small nonstructural protein NS2A and small abundant viral RNAs of medicaly important encephalitic flaviviruses, which have remained so far elusive and are at the cutting-edge in the researc ....With our increased understanding of virus-host interactions it has become apparent that small, non-structural proteins and small RNAs of most viruses are vital for numerous, often multiple, functions in the viral life cycle. In the proposed project, we seek to gain a detailed understanding of the functions of small nonstructural protein NS2A and small abundant viral RNAs of medicaly important encephalitic flaviviruses, which have remained so far elusive and are at the cutting-edge in the research field. We anticipate that with a better understanding of the roles of these factors in flaviviral replication and pathogenesis, novel targets for antiviral therapies and-or molecular determinants for inclusion in candidate vaccines will be identified.Read moreRead less
Immunopathogenesis Of West Nile Virus Encephalitis - Requirement For Interferon-gamma-dependent Soluble Mediators
Funder
National Health and Medical Research Council
Funding Amount
$250,500.00
Summary
Flaviviruses transmitted by arthropods cause considerable illness and death world-wide by their propensity to cause encephalitis. In August 1999, an outbreak of West Nile virus (WNV) encephalitis occurred in New York for the first time, indicating that these viruses are spreading beyond endemic areas. However, the mechanisms by which these viruses kill people are not at all clear. How the immune system deals with them is controlled by a complex network of interactions involving cells and soluble ....Flaviviruses transmitted by arthropods cause considerable illness and death world-wide by their propensity to cause encephalitis. In August 1999, an outbreak of West Nile virus (WNV) encephalitis occurred in New York for the first time, indicating that these viruses are spreading beyond endemic areas. However, the mechanisms by which these viruses kill people are not at all clear. How the immune system deals with them is controlled by a complex network of interactions involving cells and soluble mediators such as cytokines, chemokines, and nitric oxide, many induced or modulated by the cytokine, inteferon-gamma. Evidence suggests that these agents together influence both the types of cells that are mobilised to eradicate virus and also disease outcomes. Our hypothesis is that the host's own immune system is inadvertently responsible for encephalitis through an over-vigorous attempt to destroy the infecting virus, resulting in damage to the brain. To study WNV encephalitis, we are using a mouse model developed in this laboratory that reproduces the features of human disease. Another strain of these mice has the gene for interferon-gamma (IFN) inactivated or 'knocked out', so they cannot respond in the conventional way to virus infection. This mouse survives WNV infection significantly better than normal mice and becomes immune. Therefore we will compare cellular and soluble mediator responses of these mice during WNV infection to those of normal mice. We will also delete specific cell types making interferon-gamma in normal mice, as well as transfering such cells into knockout mice. Experiments will indicate which cell types are responsible and when particular components cause most damage. Thus, we will better understand how interferon-gamma recruits cells that mediate immune brain damage in this model. By understanding the events that lead to death in encephalitis, it may be possible to prevent or ameliorate them by means of immune intervention.Read moreRead less
Coordinated Cleavages In The Flavivirus Structural Polyprotein: Role In Virus Assembly And Host-pathogen Interaction
Funder
National Health and Medical Research Council
Funding Amount
$285,000.00
Summary
Flaviviruses are important human pathogens responsible for epidemics of hemorrhagic fever or encephalitis, world-wide. This project aims to investigate unique aspects in the biology of the flaviviruses with wider cell biological and immunological implications. First, we propose to test a mechanism important for the efficient assembly of virus particles. An understanding of this stage of the virus life-cycle will benefit research applying recombinant DNA technology in order to produce replication ....Flaviviruses are important human pathogens responsible for epidemics of hemorrhagic fever or encephalitis, world-wide. This project aims to investigate unique aspects in the biology of the flaviviruses with wider cell biological and immunological implications. First, we propose to test a mechanism important for the efficient assembly of virus particles. An understanding of this stage of the virus life-cycle will benefit research applying recombinant DNA technology in order to produce replication-incompetent viruses for use in vaccination and gene delivery. Second, we have recently discovered a mechanism for immune-modulation, so far unique to the flaviviruses, which interferes with the immune response important in the destruction of virus-infected cells. This project aims to identify the viral gene products responsible for this phenomenon.Read moreRead less
The Role Of Subgenomic Non-coding Viral RNA In Flavivirus Pathogenicity
Funder
National Health and Medical Research Council
Funding Amount
$555,325.00
Summary
Flaviviruses are transmitted by insects and pose a serious health threat to the Australian population. They can cause fever syndromes, encephalitis and death. We aim at better understanding of how these viruses cause disease. We are particularly interested in elucidating the role of small non-coding nucleic acid produced by flaviviruses in the viral pathogenicity. Ultimately, this deeper understanding should lead to the development of effective vaccines and antiviral therapies.
Viral Factors Contributing To Flavivirus-induced Cell Death And Pathogenicity
Funder
National Health and Medical Research Council
Funding Amount
$612,885.00
Summary
West Nile virus is a mosquito-transmitted pathogen that causes severe and fatal neurological disease in humans. There are currently no effective treatments or vaccines for this disease. In this project, we will investigate how West Nile virus and other viruses of the same group use a novel translational regulatory mechanism to modulate the host antiviral response and facilitate viral pathogenicity. This will provide valuable information for the development of effective treatments against this me ....West Nile virus is a mosquito-transmitted pathogen that causes severe and fatal neurological disease in humans. There are currently no effective treatments or vaccines for this disease. In this project, we will investigate how West Nile virus and other viruses of the same group use a novel translational regulatory mechanism to modulate the host antiviral response and facilitate viral pathogenicity. This will provide valuable information for the development of effective treatments against this medically important group of viral pathogens.Read moreRead less
The Role Of Noncoding Viral RNAs In Flavivirus Infection And Exosomal Signalling
Funder
National Health and Medical Research Council
Funding Amount
$683,447.00
Summary
The application is aimed at investigating the novel role for viral noncoding RNAs in exosomal antiviral signalling and associated outcome of infection with West Nile virus. We will identify host enzymes involved in generation of viral noncoding RNAs, determine which host proteins they interact with and how these interactions determine their incorporation into secreted exosomes to influence outcome of infection.