Identification Of Interferon Stimulated Genes That Limit HCV Replication And Predict Therapeutic Outcome
Funder
National Health and Medical Research Council
Funding Amount
$389,224.00
Summary
The only treatment for hepatitis C is Interferon-ribavirin combination therapy. Interferon works by stimulating the liver cells to produce antiviral proteins that can control hepatitis C virus replication, however we do not know which proteins are responsible. The aim of this proposal is to identify those proteins that can limit HCV replication using both a laboratory based and clinical approach and to identify markers that will predict treatment outcome.
Characterization Of A Novel IFNbeta Signaling Axis Mediated Via IFNAR1
Funder
National Health and Medical Research Council
Funding Amount
$353,754.00
Summary
Type I interferons (IFNs) play an important role in regulating immune responses to pathogens and tumors and are used therapeutically. This project will investigate a novel IFN signaling axis that we have recently characterized that is mediated via the low affinity IFN receptor, IFNAR1. This signaling axis occurs independently of the high affinity IFN receptor IFNAR2 and contributes to lethality in a model of septic shock.
Despite recent advances in therapeutic options, chronic viral infections, including infection with hepatitis C virus and hepatitis B virus, continue to be a significant cause of morbidity and mortality in Australia and affecting hundreds of millions of people worldwide. This R&D program aims to develop a cheaper drug formulation that is easier to deliver and more stable for transport to remote areas.
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
New Mechanisms Of Immunomodulation By Interferon Transsignaling
Funder
National Health and Medical Research Council
Funding Amount
$540,441.00
Summary
The aim of this project is to characterise a new discovery of how the body can regulate its response to disease such as infections and cancer. Interferons are produced by the body to stimulate immune reactions to these diseases. We have dicovered that a circulating form of an interferon binding protein or receptor can change the nature of an immune response. We plan to study how this is achieved and whether this information can be used therapeutically.
Regulating Interferon Signalling In Innate Immunity
Funder
National Health and Medical Research Council
Funding Amount
$547,428.00
Summary
Our innate immune system evolved as the front line defence against infection. However an uncontrolled response can lead to serious diseases such as septic shock, chronic inflammation as in hepatitis, autoimmune diseases such as systemic lupus erythematosus. The immune respnse is regulated by important hormones such as interferon produced by the body in these situations. This project aims to understand the negative or inhibitory mechanisms that prevent dangerous side effects of interferons withou ....Our innate immune system evolved as the front line defence against infection. However an uncontrolled response can lead to serious diseases such as septic shock, chronic inflammation as in hepatitis, autoimmune diseases such as systemic lupus erythematosus. The immune respnse is regulated by important hormones such as interferon produced by the body in these situations. This project aims to understand the negative or inhibitory mechanisms that prevent dangerous side effects of interferons without restricting their postive or beneficial effects. We will examine the actions of a molecule called the Suppressor of cytokin Signaling 1 (socs1) which we have recently discovered to modulate the actions of interferon in the mouse. Initially our studies will determine which molecules SOCS1 binds to inside a cell and the consequences for cell activation pathways. The next step will be to specifically block this interaction in the mouse and determine the effects on models of viral infection and inflammatory disease. The outcome of these studies will be a better understanding of how the body fights disease via the immune response and potential new approaches to develop therapeutic drugs.Read moreRead less
Investigating Type I Interferon-mediated Immune-suppression During Plasmodium Infection
Funder
National Health and Medical Research Council
Funding Amount
$561,617.00
Summary
Some infections tend to afflict us only once in our lifetimes, for example chickenpox. This is because our bodies develop immunity to these infections relatively easily. The same is not true for malaria. It is thought that our immune systems are somehow suppressed during this disease. This project aims to understand how the immune system is suppressed during malaria infection, in order that we can block this process, and help our bodies fight this disease more effectively.
I work on the molecular mechanisms of innate immunity. Priorities of my work are the immune response to pathogens such as viruses and bacteria and to cancer.