Designing new generation adjuvants for allergy and parasite vaccines. Allergy vaccines have the potential to provide a permanent cure against many allergic diseases, currently affecting 20-30 per cent of people in developed countries. This project will study how allergy vaccines work and how we can improve their effectiveness and safety.
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.
Mechanism of action of an anti-inflammatory compound which targets alternatively activated macrophages. The project will study the mechanism by which a novel anti-inflammatory compound, developed by our commercial partner, suppresses the activity of a population of cells known as alternatively activated macrophages. These cells play a key role in driving allergic inflammation, including the inflammation associated with asthma.
Development of microbial bioproducts for the suppression of inflammation. Asthma and inflammatory diseases are serious health problems that result from excessive inflammation. Exposure to bacteria may reduce inflammation. This project will identify the bacterial components that reduce inflammation and develop them into new anti-inflammatory therapies for asthma.
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.
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.
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
Special Research Initiatives - Grant ID: SR140100001
Funder
Australian Research Council
Funding Amount
$35,000,000.00
Summary
The Juvenile Diabetes Research Foundation Australian Type 1 Diabetes Research Network and Program. This Proposal continues the development of the initial Type 1 Diabetes Clinical Research Network (CRN), launched by JDRF in June 2011 with a $5m grant from the Australian Government.
The principal goal of the CRN is to positively impact the life of people with T1D in Australia through the support and promotion of clinical research. A further electoral commitment of $35m over 5 years will enable f ....The Juvenile Diabetes Research Foundation Australian Type 1 Diabetes Research Network and Program. This Proposal continues the development of the initial Type 1 Diabetes Clinical Research Network (CRN), launched by JDRF in June 2011 with a $5m grant from the Australian Government.
The principal goal of the CRN is to positively impact the life of people with T1D in Australia through the support and promotion of clinical research. A further electoral commitment of $35m over 5 years will enable further progress towards finding a cure for T1D, including delivering better and faster access to new therapies and treatments that can help prevent and manage the disease.
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CD1C-LIPID-REACTIVE T CELLS. The immune system patrols our body examining molecules such as proteins and lipids that signal whether or not everything is ok. While protein recognition by the immune system is well understood, our knowledge of the fundamental features of lipid detection is poor. This project will investigate the detection of lipid molecules that are presented to the immune system in association with a molecule known as CD1c. The aims are to understand: 1. The cells that respond to ....CD1C-LIPID-REACTIVE T CELLS. The immune system patrols our body examining molecules such as proteins and lipids that signal whether or not everything is ok. While protein recognition by the immune system is well understood, our knowledge of the fundamental features of lipid detection is poor. This project will investigate the detection of lipid molecules that are presented to the immune system in association with a molecule known as CD1c. The aims are to understand: 1. The cells that respond to these lipids; 2. The cellular receptors that bind to these lipids; 3. The types of lipids involved in this process. This work is essential for us to understand lipid-based immunology which is critical if we ultimately wish to harness this to improve human health.Read moreRead less
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.