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Unrestricted antigen recognition by T lymphocytes. This project aims to investigate the unrestricted T cell repertoire; the molecular and structural basis of antigen recognition by unrestricted T cells; and the development of unrestricted T cells. T lymphocytes typically are restricted to detecting foreign molecules (antigens) on the cell membrane in association with specialised antigen-presenting molecules encoded within the highly polymorphic major histocompatibility (MHC) locus (MHC restricti ....Unrestricted antigen recognition by T lymphocytes. This project aims to investigate the unrestricted T cell repertoire; the molecular and structural basis of antigen recognition by unrestricted T cells; and the development of unrestricted T cells. T lymphocytes typically are restricted to detecting foreign molecules (antigens) on the cell membrane in association with specialised antigen-presenting molecules encoded within the highly polymorphic major histocompatibility (MHC) locus (MHC restriction). T lymphocytes that can recognise antigens in the absence of MHC or MHC like molecules challenges a major paradigm in the field of immunology. As T cell based therapy underpins treatments for cancer and infection, new mechanisms of T cell activation that are independent of patient genotype should ultimately create opportunities for therapeutic and commercial development, leading to both health and economic benefits.Read moreRead less
New genes and models for inflammatory bowel disease. Inflammatory bowel disease affecting millions of people world-wide and results in a significant economic burden ($100M in Australia per year). In collaboration with Australia’s largest biotechnology company, CSL, we will use a novel approach to discover the causes of inflammatory bowel disease. This work will lead to the development of new animal models of inflammatory bowel disease that are vital for analysing the disease and testing treatmen ....New genes and models for inflammatory bowel disease. Inflammatory bowel disease affecting millions of people world-wide and results in a significant economic burden ($100M in Australia per year). In collaboration with Australia’s largest biotechnology company, CSL, we will use a novel approach to discover the causes of inflammatory bowel disease. This work will lead to the development of new animal models of inflammatory bowel disease that are vital for analysing the disease and testing treatment options. In addition, this work may lead to new approaches to treating this disease. The project will result in a greater understanding of inflammatory bowel disease, the training of highly skilled scientists and potentially lead to economically valuable knowledge.Read moreRead less
Understanding T cell immunity induced by infection. We aim to understand how killer T cells are “programmed” upon activation and acquire their characteristic functions and how these are maintained into immunological memory. This proposal will provide insights important for the design and improvement of vaccine strategies to fight pathogens such as influenza, HIV and even tumors.
Development of purified antibodies that kill virus infected cells. This proposal will develop panels of purified and monoclonal antibodies that kill virus infected cells. These antibodies may show efficacy in preventing HIV infection. This is new technology that could subsequently be harnessed to protect or limit the devastating effects of chronic viruses such as HIV.
Cellular and molecular networks controlling protective immunity. This research aims to understand how a handful of master-regulator genes act to program immune cells required for immune responses to microbes, vaccination and to prevent cancer. It will provide a fundamental advance in our understanding of immune cell development and impact strategies aimed at the prevention and treatment of pathogen infections.
Development of novel vaccine delivery systems for induction of mucosal immunity in a large animal model. The induction of mucosal immune responses is a highly desirable goal in vaccine research and development, as it prevents entry of the large number of mucosal pathogens. This proposal aims to develop new mucosal vaccine delivery systems by combining intra-nasal, intra-lung and transcutaneous vaccine delivery with ISCOM-based adjuvants. The nature of the immune response will be analysed in real ....Development of novel vaccine delivery systems for induction of mucosal immunity in a large animal model. The induction of mucosal immune responses is a highly desirable goal in vaccine research and development, as it prevents entry of the large number of mucosal pathogens. This proposal aims to develop new mucosal vaccine delivery systems by combining intra-nasal, intra-lung and transcutaneous vaccine delivery with ISCOM-based adjuvants. The nature of the immune response will be analysed in real time using a sheep cannulation model. Subsequently, the efficacy of mucosal vaccination strategies will be tested in a chlamydia infection model.Read moreRead less
Characterisation and development of adjuvants for new generation veterinary and human vaccines. Vaccination is the most successful and cost-effective means of combating infectious diseases in both veterinary and human medicine. This project will increase our understanding of how vaccines work and will help the development of new vaccines against infections in both animals and man. The results of these studies will also increase the competitiveness of Australian scientists in the field of vaccine ....Characterisation and development of adjuvants for new generation veterinary and human vaccines. Vaccination is the most successful and cost-effective means of combating infectious diseases in both veterinary and human medicine. This project will increase our understanding of how vaccines work and will help the development of new vaccines against infections in both animals and man. The results of these studies will also increase the competitiveness of Australian scientists in the field of vaccine research and development.Read moreRead less
microRNAs and the control of T lymphocyte differentiation, function and malignant transformation. The molecular mechanism of the immune system is not completely understood. This project will investigate how transcription factors and microRNAs, two major types of regulatory molecules work together to control immune responses. The results from this research will assist in the design of better vaccination strategies and treat certain lymphomas.
Atypical T cell receptor recognition of monomorphic CD1 antigen-presenting molecule. T lymphocytes are white blood cells that respond to foreign molecules (antigens). Until recently, most known antigens were proteins. This project will study how T lymphocytes recognise a different class of antigen (glycolipids) that are likely to play an equally important role in the immune system.
Exploiting the lymphatic system for next generation vaccine development . Vaccination is the most successful and cost-effective means of combating infectious diseases. This project will look at how vaccine adjuvants work and will help the development of new vaccines against infections in both animals and man. It will also promote the training of Australian scientists in the field of vaccine research and development.