A new approach to reversing and preventing immune-mediated diseases. Chronic inflammatory diseases affect up to 20 per cent of Australians. These diseases reduce wellbeing and life potential and shorten lifespan. This project addresses the urgent need for effective therapies and focuses on developing strategies for disease cure and prevention.
Rhinovirus impairs physiological and immunological lung development and causes exacerbation of allergic airways disease. Rhinovirus (RV) infections account for around 90 per cent of asthma exacerbations, yet the mechanisms behind this are unknown. This project will use mouse models to study the effects of early life RV infection and allergic sensitisation on respiratory and immunological development, with the expectation that early life RV infection disrupts anitgen presenting cell function.
Sterile inflammation as a determinant of adaptive immunity. When we injure ourselves, the site of injury becomes inflamed, which may help healing or cause trouble. This project aims to understand how the normal response to injury is controlled and why the process may sometimes go wrong.
Molecular and immunological approaches to managing Australia's seafood allergy epidemic. Seafood is an increasingly important cause of food allergy. Novel insight into the functions of why and how proteins from seafood develop to potent allergens will lead to the development of better diagnostics and therapeutics. This will assist patients to better manage their serious food allergy.
Convergence of biomaterials and immunology: a technology platform for delayed burst release of vaccines. A large challenge in vaccination, particularly in wildlife such as for the growing problem of Chlamydia in koalas, is to provide the necessary booster shots. This project will develop implants that will be inserted under the skin at the time of the first shot, and will spontaneously burst later to release the booster shot to provide protection.
Impaired innate antiviral immunity predisposes toward virus-associated airway remodelling in childhood asthma. Increased airway smooth muscle (ASM) mass is the major pathological feature of asthma that causes poor lung function. ASM remodelling occurs in early life, is refractory to current treatments and persists into later life. Severe respiratory virus infections in early life are a major risk factor for the development of asthma, yet it remains to be determined whether viruses promote ASM re ....Impaired innate antiviral immunity predisposes toward virus-associated airway remodelling in childhood asthma. Increased airway smooth muscle (ASM) mass is the major pathological feature of asthma that causes poor lung function. ASM remodelling occurs in early life, is refractory to current treatments and persists into later life. Severe respiratory virus infections in early life are a major risk factor for the development of asthma, yet it remains to be determined whether viruses promote ASM remodelling. Previous studies have developed a unique mouse model of childhood asthma and discovered the molecular mechanism by which this tissue tropism develops in response to virus infection. This project will identify new targets for immunomodulation and design new biologics to block ASM remodelling and the deleterious effects of respiratory virus infection in asthmatic subjects. Read moreRead less
SNARE-mediated perforin and cytokine release in natural killer cells. Cytotoxic cells release toxic granules and cytokine messengers to kill pathogen infected and cancerous cells and to mount immune responses. This project will investigate different SNARE molecules that regulate the secretion of perforin from granules and cytokines from other carriers, assisting in the understanding of complex but essential cellular pathways.
Discovery Early Career Researcher Award - Grant ID: DE180101075
Funder
Australian Research Council
Funding Amount
$365,058.00
Summary
Novel immune cell subsets in the centre nervous system and supporting tissues. This project aims to identify and characterise novel resident immune cell subsets within the brain and retina, and their close supporting tissues. The project expects to generate new knowledge in the areas of neuroimmunology and ocular immunology by using molecular and cellular techniques to examine the diversity of immune cells within the brain and retina. It is expected that the project will advance our understandin ....Novel immune cell subsets in the centre nervous system and supporting tissues. This project aims to identify and characterise novel resident immune cell subsets within the brain and retina, and their close supporting tissues. The project expects to generate new knowledge in the areas of neuroimmunology and ocular immunology by using molecular and cellular techniques to examine the diversity of immune cells within the brain and retina. It is expected that the project will advance our understanding of the biological mechanisms that protect the central nervous system from harmful inflammation and thus improve our knowledge of the immunobiology of the brain and eye.Read moreRead less
Membrane excitability and cellular calcium regulation in the peripheral nervous system under different (patho)-physiological conditions and in inflammatory disease. Studies of cytokine action on neurons and muscle give new insights into functional responses of the nervous system to systemic inflammation and sepsis. In some countries, sepsis is the third most frequent cause of death following heart attack. Elucidating the pathomechanisms allows to develop therapeutic strategies. Electrophysiology ....Membrane excitability and cellular calcium regulation in the peripheral nervous system under different (patho)-physiological conditions and in inflammatory disease. Studies of cytokine action on neurons and muscle give new insights into functional responses of the nervous system to systemic inflammation and sepsis. In some countries, sepsis is the third most frequent cause of death following heart attack. Elucidating the pathomechanisms allows to develop therapeutic strategies. Electrophysiology, Ca2+ regulation and optical membrane potentiometry allow us to monitor early changes in disease on a (sub)cellular level. Experiments on Ca2+ regulation and ion channel function in muscle with different cholesterol membrane contents will help to understand pathomechanisms in high cholesterol diseases, e.g. obesity, on the membrane level long before cardiovascular effects become prominent.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989436
Funder
Australian Research Council
Funding Amount
$400,000.00
Summary
Multiphoton microscopy of living animals as a tool for immunology and cell biology studies. The multiphoton microscope will enable us to watch the growth, migration and interactions of cells in a living animal in response to changes in the cells' environment will give us better understanding of how we work as living machines, and what can go wrong with that process to make us unwell.