Identifying T Cell Correlates Of Protective Immunity To Malaria In Childhood
Funder
National Health and Medical Research Council
Funding Amount
$396,026.00
Summary
Malaria claims nearly one million lives each year, mostly children. Although those living in endemic regions can acquire natural immunity, it develops slowly and isn`t completely protective. This project studies the impact of different levels of malaria exposure and age on the development of a protective immune response in children. By understanding the effect of high malaria exposure in the development of immunity it is hoped that new avenues for drug development may be identified.
The Role Of Fractalkine In Leukocyte Recruitment In The Periphery
Funder
National Health and Medical Research Council
Funding Amount
$215,196.00
Summary
This research will determine whether a new type of gene plays an important role in inflammation in tissues in the periphery. If it does, we will design strategies to inhibit its function, thereby controlling its effects in inflammation. Such treatment may be useful for diseases such as rheumatoid arthritis, diabetes as well as allergies.
Host Targeted Adjunctive Therapies To Boost Antimalarial Immunity
Funder
National Health and Medical Research Council
Funding Amount
$2,060,189.00
Summary
Malaria caused 200 million cases and 400000 deaths in 2018. One problem in developing new control strategies for malaria is that following a malaria infection, individuals develop disruptive immune responses that block vaccines. Our project investigates the ability of a repurposed drug to prevent the development of disruptive immune responses during malaria in humans. Results of our studies will inform the development of new malaria control tools.
Functional Assays Of Immunity To Malaria In Pregnant Women
Funder
National Health and Medical Research Council
Funding Amount
$578,905.00
Summary
Pregnant women are highly susceptible to malaria due to the adhesion of infected erythrocytes to the placenta. Antibodies to these infected erythrocytes can block their placental adhesion and/or facilitate their clearance by immune cells, improving pregnancy outcomes. We aim at informing vaccine design by better understanding the placental adhesion mechanisms and identifying targets of protective immunity as well as antibody correlates of protection from placental malaria and its consequences.
Protective memory T cell immune responses defend our body against pathogens by the rapid induction of killer T cells. This protects us from severe or perhaps even fatal disease. Our work will provide insights to how the body makes these potent ‘footsoldiers’. This work will have important implications for identifying how these immune cells can be manipulated to prevent and treat pathogenic and autoimmune disease and for optimising approaches to vaccination.
Characterisation Of Cell-mediated Immune Responses In Burkholderia Pseudomallei Infection
Funder
National Health and Medical Research Council
Funding Amount
$239,250.00
Summary
The bacterium Burkholderia pseudomallei, causes a life threatening condition known as melioidosis. Melioidosis is emerging as an important infectious disease in tropical regions of Australia and South East Asia. Death rates following acute disease are extremely high. Despite the importance of B. pseudomallei in tropical public health, very little is known regarding how the body's defence mechanisms prevent the spread of infection. The wide distribution of melioidosis in tropical Australia and ot ....The bacterium Burkholderia pseudomallei, causes a life threatening condition known as melioidosis. Melioidosis is emerging as an important infectious disease in tropical regions of Australia and South East Asia. Death rates following acute disease are extremely high. Despite the importance of B. pseudomallei in tropical public health, very little is known regarding how the body's defence mechanisms prevent the spread of infection. The wide distribution of melioidosis in tropical Australia and other parts of the world, and the lack of basic scientific information regarding this disease, has prompted this study. The bacterium lives within the body's cells and therefore does not respond well to standard antibiotic treatment. Although some of the basic immune mechanisms have been identified, how protection to the organism develops remains unclear. In this project we will investigate the effect of B. pseudomallei on immune cells or lymphocytes. This study will determine the patients' immune responses to the bacteria causing the disease. Our research team has already successfully carried out work on several different aspects of melioidosis. The characterisation of the basic immune function determined in the proposed study will provide the scientific basis for improvement in treatment and the development of possible preventive strategies against melioidosis.Read moreRead less