A proteomic approach to the identification of novel targets for allergy treatment. Eosinophils are involved in parasite immunity and in the pathology of allergic diseases including asthma. Eosinophil recruitment and activation is critical to their functional activity, but the relevant molecular mechanisms have not been fully elucidated. In the present proposal, a unique resource of eosinophils, at different stages of recruitment and activation, will be used for detailed proteomic analysis to ide ....A proteomic approach to the identification of novel targets for allergy treatment. Eosinophils are involved in parasite immunity and in the pathology of allergic diseases including asthma. Eosinophil recruitment and activation is critical to their functional activity, but the relevant molecular mechanisms have not been fully elucidated. In the present proposal, a unique resource of eosinophils, at different stages of recruitment and activation, will be used for detailed proteomic analysis to identify molecules and molecular pathways involved in eosinophil migration and activation. These studies may lead to novel anti-inflammatory strategies and more targeted drug treatments that will generate significant intellectual property and be of enormous benefit to allergy patients worldwide.Read moreRead less
Rational structure-based drug design of protein tyrosine kinase inhibitors. Protein tyrosine kinases (PTK) are a large, pivotal family of signalling molecules implicated in diseases such as cancer and immune-related disorders, that cause significant morbidity and mortality within the population. This research proposal aims to develop PTK-specific small molecule inhibitors to combat such diseases. Cytopia's drug discovery capability, coupled with the X-ray crystallographic expertise within Monas ....Rational structure-based drug design of protein tyrosine kinase inhibitors. Protein tyrosine kinases (PTK) are a large, pivotal family of signalling molecules implicated in diseases such as cancer and immune-related disorders, that cause significant morbidity and mortality within the population. This research proposal aims to develop PTK-specific small molecule inhibitors to combat such diseases. Cytopia's drug discovery capability, coupled with the X-ray crystallographic expertise within Monash University, will permit a rational, structure-based drug discovery platform to be established. The ultimate goal of this innovative and mutlidisciplinary approach, namely a portfolio of phase I therapeutics, will be of substantial benefit in the medical health area.Read moreRead less
Rational structure-based drug design of protein tyrosine kinase inhibitors. This research project is focussed on understanding the physiological roles of a group of enzymes within the cell, as well as developing therapeutics to combat significant diseases. It will achieve this by developing compounds to enzymes that are implicated in the disease process. The research project represents a continuation of a collaboration between academic researchers at Monash University, and an Australian biotec ....Rational structure-based drug design of protein tyrosine kinase inhibitors. This research project is focussed on understanding the physiological roles of a group of enzymes within the cell, as well as developing therapeutics to combat significant diseases. It will achieve this by developing compounds to enzymes that are implicated in the disease process. The research project represents a continuation of a collaboration between academic researchers at Monash University, and an Australian biotechnology company, Cytopia Ltd.Read moreRead less
Investigating the atomic structure of an immune cell inhibitory receptor. T cells play a key role in the adaptive immune system, whose reactivity must be controlled to prevent aberrant reactivity. Central to the function of T cells is the T cell antigen receptor, and a host of co-stimulatory molecules, co-receptors and inhibitory receptors. This proposal, in partnership with Immutep Ltd, aims to gain a basic understanding of the structure and function of a key inhibitory receptor found on T cel ....Investigating the atomic structure of an immune cell inhibitory receptor. T cells play a key role in the adaptive immune system, whose reactivity must be controlled to prevent aberrant reactivity. Central to the function of T cells is the T cell antigen receptor, and a host of co-stimulatory molecules, co-receptors and inhibitory receptors. This proposal, in partnership with Immutep Ltd, aims to gain a basic understanding of the structure and function of a key inhibitory receptor found on T cells, termed the Lymphocyte activation gene-3 (LAG-3). The proposal utilises a combination of cellular immunology and structural biology to gain insight into the form and function of the LAG-3 molecule. Ultimately this fundamental knowledge can be used by the biotechnology industry.Read moreRead less
Investigating the structure of a T cell immune checkpoint molecule. This project aims to investigate the basic structure and function of a key co-receptor expressed on T cells, known as lymphocyte activation gene-3. T cells play a role in the immune system but must be managed to prevent autoimmunity. Insight into the function of the lymphocyte activation gene-3 function can be used to tailor immunotherapeutics to treat a variety of diseases, including cancer. Functionality of the T cell recept ....Investigating the structure of a T cell immune checkpoint molecule. This project aims to investigate the basic structure and function of a key co-receptor expressed on T cells, known as lymphocyte activation gene-3. T cells play a role in the immune system but must be managed to prevent autoimmunity. Insight into the function of the lymphocyte activation gene-3 function can be used to tailor immunotherapeutics to treat a variety of diseases, including cancer. Functionality of the T cell receptor is determined by utilising structural biology and cellular immunology techniques. The impact of this project effects the development of innovative T cell immunomodulatory agents, improving the health and quality of life of the Australian population.Read moreRead less
Dissecting the physiology of multipotent mesenchymal stromal cells to develop vaccine candidates for respiratory disease. The project aims to gain an understanding of how a type of adult stem cell inhibits immune responses that cause asthma. The project will produce new stem cell products and facilitate the design of a vaccine for asthma and other respiratory diseases, which would greatly reduce the burden of such conditions.
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.
Ecology, morphology and the diversification of Australian lizards. This project aims to determine the factors driving the spectacular radiation of lizards in Australia. To date, most investigations of lizard anatomy have focused exclusively on external characteristics. This project will examine the underlying internal anatomy to investigate whether morphological innovation is associated with enhanced rates of ecological, life-history and species diversification. The project expects to shed light ....Ecology, morphology and the diversification of Australian lizards. This project aims to determine the factors driving the spectacular radiation of lizards in Australia. To date, most investigations of lizard anatomy have focused exclusively on external characteristics. This project will examine the underlying internal anatomy to investigate whether morphological innovation is associated with enhanced rates of ecological, life-history and species diversification. The project expects to shed light on the evolution of Australia’s most diverse vertebrate lineage, and provide comparative data with which to interpret the lizard fossil record in Australia, and the range declines and relative extinction risks of native lizard species.Read moreRead less
Enhancing immunogenicity of DNA vaccines by targeted delivery to antigen presenting cells. Vaccines have proven to be one of the most effective means of preventing infection and also provide promise as a treatment for cancer. However, the range of effective technologies that make possible the delivery of vaccines that can protect against a broad range of infections is limited. DNA based vaccines are attractive because they are relatively easy to produce against a wide range of infections. Howeve ....Enhancing immunogenicity of DNA vaccines by targeted delivery to antigen presenting cells. Vaccines have proven to be one of the most effective means of preventing infection and also provide promise as a treatment for cancer. However, the range of effective technologies that make possible the delivery of vaccines that can protect against a broad range of infections is limited. DNA based vaccines are attractive because they are relatively easy to produce against a wide range of infections. However, DNA vaccines often provide poor protection against infections. This project will explore a unique technology developed in Australia and that will greatly improve the effectiveness of DNA vaccines against a broad range of diseases. Read moreRead less
Functional characterisation of neurons derived from embryonic stem cells and NS cells. The ability to obtain specific neurons from NS cells will revolutionise the study of nerve function, will allow the establishment of much-improved models for discovery of new drugs, and will define how enriched populations of neural cells can be obtained for applications in treatment of neurodegenerative diseases. The project will provide vital data for the emerging biotechnology industry associated will appl ....Functional characterisation of neurons derived from embryonic stem cells and NS cells. The ability to obtain specific neurons from NS cells will revolutionise the study of nerve function, will allow the establishment of much-improved models for discovery of new drugs, and will define how enriched populations of neural cells can be obtained for applications in treatment of neurodegenerative diseases. The project will provide vital data for the emerging biotechnology industry associated will applications of stem cell biology, and will stimulate clinical researchers to investigate the therapeutic potential of cell derived from NS cells.Read moreRead less