Unravelling The Tetraspanin Web In The Schistosome Tegument.
Funder
National Health and Medical Research Council
Funding Amount
$309,537.00
Summary
Infection with the human blood fluke, Schistosoma mansoni, is a major human ailment affecting almost 200 million people world wide and causing approximately 200 000 deaths per year. Current control efforts rely on anthelminthic drugs but, to sustain their effects, they must be applied for an indefinite period of time due to reinfection. This project will extend recent efforts to develop a vaccine for this organism and decrease the public health burden and mortality associated with infection.
Understanding Pathogenicity And Immunity In An Encephalitic Mouse Model Of Hendra Virus Infection
Funder
National Health and Medical Research Council
Funding Amount
$572,342.00
Summary
Our understanding of Hendra virus infection and immunity is extremely limited and has been hampered by a lack of appropriate animal models of disease and reagents. This Project will employ a newly-established mouse model to study encephalitis, the most life-threatening manifestation of this infection. We will use unique, state-of-the-art infrastructure and a plethora of mouse-specific reagents to investigate the mechanisms involved in regulating the host response to infection.
I am an epidemiologist working in the areas of public health and prevention, with a focus on HIV infection, viral hepatitis and sexually transmitted infections.
Identification And Development Of Novel Vaccine Candidates For Malaria
Funder
National Health and Medical Research Council
Funding Amount
$4,000,000.00
Summary
The aim is to improve methods of preventing and treating malaria by understanding the basic biological mechanisms the pathogen that causes the most severe form of human malaria, uses to invade and survive in the host erythrocyte, and survives in the hostile environment of the blood, as this determines disease outcome. I have outlined an ambitious program for the next five years that will utilize our basic knowledge of how this parasite infects and causes disease to identify novel vaccine candida ....The aim is to improve methods of preventing and treating malaria by understanding the basic biological mechanisms the pathogen that causes the most severe form of human malaria, uses to invade and survive in the host erythrocyte, and survives in the hostile environment of the blood, as this determines disease outcome. I have outlined an ambitious program for the next five years that will utilize our basic knowledge of how this parasite infects and causes disease to identify novel vaccine candidates from the genome of P. falciparum. This represents a major task that will not only provide new information for the malaria field but also identify the most promising candidates that will be pursued into clinical development. I will use two strategies; firstly, a consortium will be formed that brings together expertise that will credential the P. falciparum genome. This provides our experience in functional genomics with EHIME University who have developed methods to express correctly folded P. falciparum proteins in a high throughput system using wheat germ in vitro translation and University of Pennsylvania who have expertise in bioinformatics of the malaria genome. It provides the critical mass and expertise required for a major project. We have developed novel methods for expression of protein domains on the surface of the P. falciparum-infected erythrocyte and this has important utility for analysis of function and immune responses to these proteins. To utilize and develop these tools I will build a critical mass of expertise by forming a consortium between Australian scientists together with Papua New Guinea Institute of Medical Research, KEMRI Institute for Geographic Medicine (Kenya), Harvard University and the Swiss Tropical Institute (Switzerland). This consortium will provide access to malaria endemic areas and the expertise in fieldwork and epidemiology to fully utilize the parasite lines we will construct. The formation of these consortia will greatly strengthen our ability to identify the most promising candidates for clinical development. This will also have great benefit to Australia by increasing the internationalization of our science and therefore access of our researchers to other expertise and also provides a means for networking outside of this country. To foster and increase our leadership in malaria I will develop a Functional Genomics facility that will provide the capacity to construct large panels of transgenic parasites and the ability to develop new genetic tools. Additionally, I will develop a specialized microscopy facility at WEHI to provide the advanced equipment required for visualizing molecular events in live cells. This facility will include a number of instruments including a Line scanner confocal that will be essential for following cellular events such as protein trafficking in live parasite lines.Read moreRead less
Tissue Specific Antigen Presenting Cell Functions During Infection.
Funder
National Health and Medical Research Council
Funding Amount
$555,325.00
Summary
T cell activation is often inefficient following infection or vaccination, resulting in poor control of pathogens. In this grant, we propose to investigate the cellular basis for sub-optimal CD4+ T cell activation following infection. Specifically, we will study the roles of antigen presenting cells in CD4+ T cell activation in an experimental model of visceral leishmaniasis caused by the human protozoan parasite Leishmania donovani.
Optimising Large-scale Public Health Interventions To Control Neglected Tropical Diseases
Funder
National Health and Medical Research Council
Funding Amount
$318,768.00
Summary
Neglected tropical diseases (NTD) are a group of health conditions that affect the poorest of the poor, particularly in remote and rural areas. They affect the most vulnerable communities and cause substantial, chronic health harms impairing personal and social development. Several debilitating NTD are common in remote indigenous communities and Pacific islands. I propose a series of studies to investigate new strategies to control NTD in large populations where these diseases are endemic.
Molecular Mechanism And Therapeutic Implications Of Prion Disease Strain Types In Sporadic Creutzfeldt Jakob Disease.
Funder
National Health and Medical Research Council
Funding Amount
$345,634.00
Summary
The prion diseases are a group of transmissible, neurodegenerative disorders affecting both humans and animals. The most common form in humans is sporadic Creutzfeldt-Jakob disease (CJD), although acquired (variant CJD) and inherited (familial CJD) forms also exist. Prion diseases are transmissible by inoculation with, or dietary exposure to, infected tissues. The infectious agent, referred to as a prion , has not been conclusively identified. However, a major component of purified prions is an ....The prion diseases are a group of transmissible, neurodegenerative disorders affecting both humans and animals. The most common form in humans is sporadic Creutzfeldt-Jakob disease (CJD), although acquired (variant CJD) and inherited (familial CJD) forms also exist. Prion diseases are transmissible by inoculation with, or dietary exposure to, infected tissues. The infectious agent, referred to as a prion , has not been conclusively identified. However, a major component of purified prions is an abnormal disease associated form of the host prion protein. Differences in the duration of illness and pathology of sporadic CJD suggests that the disease may be caused by different prion strains. The existence of different prion strains may explain the limited clinical success of anti-prion therapeutics modeled in rodent models of prion diseases. In this study a cell-free model of prion propagation will be used to investigate the basis of human prion strains. This assay will also be used to identify and determine whether the therapeutic efficacy of anti-prion compounds is influenced by human prion strain type. This study will represent the first host species and prion strain specific screen of anti-prion therapeutics aimed at developing the best possible model for the identification and development of therapeutics for human prion diseases.Read moreRead less
SBP1 And Altered Structure And Function Of Malaria-infected Red Blood Cells
Funder
National Health and Medical Research Council
Funding Amount
$439,550.00
Summary
Malaria is a serious disease affecting half the world's population. Every year, more than a million people (mostly children) die as a result of being infected with malaria parasites. Our work will help us to understand how the parasites alter normal human red blood cells and make them stick in organs such as the brain. Preventing the red blood cells from becoming sticky with new drugs will open up new lines of attack to combat this devastating disease.