The Role Of Innate Inflammatory Responses In Viral Arthritis
Funder
National Health and Medical Research Council
Funding Amount
$782,514.00
Summary
Viruses are known to cause arthritis (HIV, hepatitis viruses, mosquito borne viruses). Symptoms of viral arthritis include joint pain, stiffness, and swelling. The mechanism of disease is poorly understood. We have developed a novel animal model of disease and human cell culture models by which to study disease caused by viral infections. This models provide an excellent opportunity to explore the mechanisms of rheumatic disease in a functioning animal and to explore new treatment regimes.
Macrophage Polarisation And Control Of Pulmonary Inflammation.
Funder
National Health and Medical Research Council
Funding Amount
$895,494.00
Summary
As key immune cells, macrophages are polarised to phenotypes that turn inflammation on or off. In cystic fibrosis, defective macrophage polarisation enhances inflammation and prevents lung repair. We are defining the molecules and cellular pathways that control this process and identifying targets for existing drugs that can be used to reprogram macrophages and restore lung repair to improve patient outcomes.
A New Master Adaptor Protein For Toll-like Receptor Signalling
Funder
National Health and Medical Research Council
Funding Amount
$869,288.00
Summary
Certain proteins on the surface of cells are able to sense danger and infection. These receptors use adaptor proteins to enable cells to respond appropriately. We have discovered a new adaptor that controls receptor signalling in inflammation. This new master adaptor likely has widespread roles in infection and inflammation. We aim to understand how this adaptor works, and to identify ways of blocking its actions. These studies may help us to control inflammation underpinning many diseases.
Innate Immune Signalling In Mycobacterium Tuberculosis Infection
Funder
National Health and Medical Research Council
Funding Amount
$562,857.00
Summary
Tuberculosis (TB) is a major global health threat that causes 1.5 million deaths every year. This study will characterise a new molecular control mechanism that optimises the immune response to the bacteria that cause TB and determine how it contributes to controlling the infection. Such knowledge is essential to help improve patient management and develop better treatments for this devastating disease.
Macrophages are important cells at the front-line of immunity where one of their main roles is to release anti-bacterial proteins. We will study the macrophage molecules, subcellular organelles and pathways that help to release these proteins to kill bacteria and fight infection. Our studies will identify new cellular targets for boosting immunity and treating inherited diseases with defective macrophage function.
Macrophages are white blood cells that provide front line defence against infection by initiating inflammatory responses by ingesting or phagocytosing microbes and by releasing soluble messengers (cytokines) to recruit other immune cells. These defensive functions require extensive trafficking of proteins within the macrophages. Protein trafficking is orchestrated in part by a family of membrane fusion proteins called SNAREs. By defining the relevant SNAREs, we have recently discovered a much ac ....Macrophages are white blood cells that provide front line defence against infection by initiating inflammatory responses by ingesting or phagocytosing microbes and by releasing soluble messengers (cytokines) to recruit other immune cells. These defensive functions require extensive trafficking of proteins within the macrophages. Protein trafficking is orchestrated in part by a family of membrane fusion proteins called SNAREs. By defining the relevant SNAREs, we have recently discovered a much acclaimed and novel pathway that allows efficient, combined cytokine secretion and phagocytosis in macrophages. Our studies proposed here will now expand on this discovery by comparing the phagocytic process, in terms of SNARE-mediated membrane and cytokine trafficking, for a wide range of microbes, highlighting differences that could provide new avenues for drug development. Moreover, since our strategy of using SNAREs to investigate and map trafficking pathways has proven so successful, we will now launch a major large-scale initiative to study ALL SNARE-mediated trafficking pathways in macrophages using a discovery pipeline of assays, including live cell imaging, we have developed. This will provide valuable information on many SNAREs including those associated with disease, and will elucidate trafficking pathways governing all macrophage actions in immunity, including cytokine secretion and antigen presentation. All of these pathways are highly relevant to current drug targets being used clinically or studied in inflammatory disease and for the development of vaccines.Read moreRead less