A Genome Wide Screen For Human Genes That Support The Replication Of Intracellular Bacterial Pathogens
Funder
National Health and Medical Research Council
Funding Amount
$321,090.00
Summary
Coxiella burnetii is a bacterium that causes a life threatening infection of humans, termed Q fever.Coxiella survives and replicates inside human cells within a unique protected niche and little is known about how the bacterium does this. This study will identify and investigate the individual human proteins that are used by the bacterium to manipulate the human cells it inhabits and the mechanisms through which the bacterium achieves this.
Host-pathogen Interactions In Burkholderia Infection
Funder
National Health and Medical Research Council
Funding Amount
$490,322.00
Summary
Melioidosis is a fatal tropical disease caused by a bacterium Burkholderia pseudomallei. We found that when the bacterium infects macrophage-like cells in culture (that normally kills bacteria), the cells turn into a cell like an osteoclast, a cell that normally degrades bone. Since an osteoclast is unable to kill bacteria, we speculate that the bacterium subverts the macrophage differentiation pathway and directs the cells into a state where it is unable to attack the invading bacteria.
Role Of P2X7 In Innate And Adaptive Immunity To Mycobacterial Infections
Funder
National Health and Medical Research Council
Funding Amount
$472,500.00
Summary
Tuberculosis remains an enormous global health problem. Some 32% of the world s population are infected, with over 2 million persons dying each year. It is not well understood why some infected individuals develop clinical disease yet others remain healthy, but many cases are due to reactivation of dormant organisms lying within a specialized white cell, the macrophage. We know that declining socio-economic conditions, HIV co-infection, and some genetic risk factors such as HLA type contribute t ....Tuberculosis remains an enormous global health problem. Some 32% of the world s population are infected, with over 2 million persons dying each year. It is not well understood why some infected individuals develop clinical disease yet others remain healthy, but many cases are due to reactivation of dormant organisms lying within a specialized white cell, the macrophage. We know that declining socio-economic conditions, HIV co-infection, and some genetic risk factors such as HLA type contribute to the likelihood of an individual developing disease, but current known factors are insufficient to fully account for the risk of an infected individual developing disease. We have recently shown that the tuberculosis bacteria can be killed by the addition of a natural compound, ATP, to infected macrophages. This process occurs when ATP activates the P2X7 receptor leading to mycobacterial killing. We have identified several polymorphisms (mutations) in the P2X7 receptor. In individuals with one particular polymorphism, designated A1513C, these people do not respond to ATP and do not kill tuberculosis using this pathway. TB patients who are heterozygous for the A1513C polymorphism show approximately a 50% reduction in mycobacterial killing. We have preliminary evidence that this A1513C polymorphism is expressed at an over represented frequency in TB patients we have tested, suggesting that having this polymorphism may increase your risk of developing tuberculosis. The aim of this project is two fold. One, we will investigate the functioning of this receptor, determining how the P2X7 receptor is activated and how it interacts with other molecules in the immune system to kill tuberculosis. Secondly we shall determine if polymorphisms in the P2X7 receptor are a risk factor for the development of tuberculosis and leprosy disease.Read moreRead less