The aim of this project is to develop mathematical models and computer software capable of predicting immune responses to infection and disease. This “artificial immune system” should lead to improved vaccine design and better understanding of what causes the immune system to attack its own body, causing autoimmune disease, or fail to respond, causing immunodeficiency. This enabling science could then lead to improvements in treatment for a range of conditions of clinical importance.
Development Of Novel Vaccine Strategies To Prevent Genital Tract Chlamydial Infections
Funder
National Health and Medical Research Council
Funding Amount
$33,626.00
Summary
Chlamydia trachomatis is one of the most common sexually transmitted diseases in the developed world. Because an infection can remain undetected it can cause severe long term problems such as infertility. The aim of this project is to develop a successful vaccine using novel immunization regimes that not only protects from infection but also prevents the development of any long term problems.
The Role Of The Dendritic Cell Surface Molecule Clec9A In Dendritic Cell Subset Function And Dead Cell Recognition
Funder
National Health and Medical Research Council
Funding Amount
$526,878.00
Summary
Dendritic cells (DC) are sentinels of the immune system. DC monitor the environment and regulate tolerance to self versus immunity to dangerous material. Different types of DC perform different jobs. We have identified a new surface molecule, Clec9A, on some mouse and human DC. We will investigate the function of Clec9A in the immune response. We will also use Clec9A to help unite mouse and human DC biology, since until now there have been few useful marker molecules common to both species.
Investigating The Potential Effect Of A Novel Immune Regulator (JET) In Preventing Graft Versus Host Disease
Funder
National Health and Medical Research Council
Funding Amount
$82,895.00
Summary
Graft Versus Host Disease (GVHD) is the primary complication of bone marrow transplants, in which the donor T-cells react with the recipient’s cells causing organ damage. Current treatments are not specific and cause further health problems. This research aims to test the therapeutic potential of a newly discovered molecule (JET) in treating and preventing GVHD. If successful, JET has the potential for treating other conditions such as rheumatoid arthritis, multiple sclerosis and miscarriages.
Neonatal Immunization With Pneumococcal Conjugate Vaccine In Papua New Guinea
Funder
National Health and Medical Research Council
Funding Amount
$1,181,966.00
Summary
One million children die every year of pneumococcal (Pnc) disease, the majority in the third world. Many die in early infancy and babies may benefit from immunisation with a Pnc conjugate vaccine (PrevenarTM) at birth. The Papua New Guinea (PNG) Insatiate of Medical Research; Telethon Institute for Child Health Research and the Department of Paediatrics, University of Western Australia, will collaborate to closely examine the safety of this approach, particularly with regard to impact on the dev ....One million children die every year of pneumococcal (Pnc) disease, the majority in the third world. Many die in early infancy and babies may benefit from immunisation with a Pnc conjugate vaccine (PrevenarTM) at birth. The Papua New Guinea (PNG) Insatiate of Medical Research; Telethon Institute for Child Health Research and the Department of Paediatrics, University of Western Australia, will collaborate to closely examine the safety of this approach, particularly with regard to impact on the development of immunity and response to other vaccines given to infants. This study will also provide a unique opportunity for training of PNG and Australian scientists in both countries; transfer state-of-the-art immunological technology and stimulate further collaborations on respiratory infections in the region.Read moreRead less
Behavioural, Virological And Immunological Factors Influencing Hepatitis C Virus Infection In Injecting Drug Users
Funder
National Health and Medical Research Council
Funding Amount
$963,437.00
Summary
The hepatitis C virus (HCV) is a major public health problem affecting over 170 million people worldwide. In Australia an estimated 157,000 people have HCV and are at risk of serious disease, and 16,000 new infections occur each year. Treating HCV-related disease is expensive, and this healthcare burden is projected to grow significantly in coming years. Almost all new HCV infections in Australia occur among injecting drug users (IDUs), and despite our world-leading prevention programs, the viru ....The hepatitis C virus (HCV) is a major public health problem affecting over 170 million people worldwide. In Australia an estimated 157,000 people have HCV and are at risk of serious disease, and 16,000 new infections occur each year. Treating HCV-related disease is expensive, and this healthcare burden is projected to grow significantly in coming years. Almost all new HCV infections in Australia occur among injecting drug users (IDUs), and despite our world-leading prevention programs, the virus is spreading. Consensus is emerging that the best hope for control of HCV and related disease lies in a vaccine; our research will lay much of the groundwork for its development. The applicants' research to date shows that IDUs are being infected with HCV more frequently than previously assumed, that many carry multiple strains, and that dominant strains vary rapidly in individuals over time. These results reinforce the view that our prevention methods will not reduce infection rates and that current anti-viral treatments are not the solution. Nevertheless, we also found that some IDUs remain free of HCV infection despite risky behaviour with infected associates; intensive study of the immune functioning of these persistently non-infected individuals holds promise for vaccine development. In our proposed research, a collaboration of leading Australian epidemiologists, virologists and immunologists, we will recruit 210 young IDUs and follow them regularly for two years. Recruits will describe their social networks and nominate IDUs with whom they inject, provide blood samples and be interviewed about their behaviour at 3-month intervals. Individuals with recent and resolved HCV infection, change of dominant strain and lack of infection despite risky behaviour will be identified and their blood analysed for genetic factors that may be linked to immune protection. The outcomes will be crucial to the development and trialling of a vaccine against HCV.Read moreRead less
Role Of Cytomegalovirus Class I Homologue In Interference With Host NK Cell Responses - A Potential Antiviral Target
Funder
National Health and Medical Research Council
Funding Amount
$428,020.00
Summary
A common property of herpesviruses such as cytomegalovirus is their ability to establish lifelong infection in their hosts. In humans, cytomegalovirus infection can lead to tissue damage in normal individuals and may cause severe disease and even be fatal in individuals with immature or compromised immune systems, such as newborns, AIDS patients, transplant recipients and people treated with chemotherapeutic drugs. The ability of these viruses to establish persistent infection and remain in asso ....A common property of herpesviruses such as cytomegalovirus is their ability to establish lifelong infection in their hosts. In humans, cytomegalovirus infection can lead to tissue damage in normal individuals and may cause severe disease and even be fatal in individuals with immature or compromised immune systems, such as newborns, AIDS patients, transplant recipients and people treated with chemotherapeutic drugs. The ability of these viruses to establish persistent infection and remain in association with the host for its lifetime is a consequence of their capacity to subvert normal host immune responses. This is achieved by destroying or mimicking the functions of molecules and-or pathways critical to normal host defence mechanisms. The viral gene product under investigation is similar to a cellular protein critical for the ability of immune cells to kill foreign and-or infectious agents. We will investigate the mechanisms by which this viral gene product interferes with the host's first line of defence against viral pathogens. The proposed studies will improve our understanding of the strategies used by viruses to escape normal host immune responses and hence provide insights into the rational design of antiviral drugs and vaccines. Since the viral protein under investigation is similar to a cellular protein essential for the ability of immune cells to kill foreign or infectious agents, an improved understanding of the mechanisms of action of this protein will continue to improve our understanding of cellular events which play a crucial role in immune responses involved not only in control of infection, but also in tumour growth and transplant survival. Thus, the proposed studies will provide valuable insight towards the development of new therapies for pathological conditions associated with the above.Read moreRead less