The effect of age on regulatory T cell control of the innate and adaptive antiviral immune responses. Viral pathogens are a lead cause of infant mortality in the world. This project will define how T regulatory cells limit protective antiviral immune responses in the young. This information is critical for the development of potent antiviral vaccines that are effective from the newborn period without inducing autoimmunity. It will also provide novel insight into the way T regulatory cells can b ....The effect of age on regulatory T cell control of the innate and adaptive antiviral immune responses. Viral pathogens are a lead cause of infant mortality in the world. This project will define how T regulatory cells limit protective antiviral immune responses in the young. This information is critical for the development of potent antiviral vaccines that are effective from the newborn period without inducing autoimmunity. It will also provide novel insight into the way T regulatory cells can be manipulated both to dampen immunity, which can be used to develop strategies to reduce immune mediated disease and limit transplant rejection. Read moreRead less
A New Model for 3D Migration Involving Claw Structures and Metalloproteinases. This proposal will revolutionize ideas related to cell movement through three-dimensional (3D) matrix. Our method in mimicking the body's dense 3D matrix environment have led to the discovery of a new cell structure called Claws, and the formulation of a new model for 3D invasion in high density matrix. We will study the genes that control this type of migration including those involved in the formation of the cell fr ....A New Model for 3D Migration Involving Claw Structures and Metalloproteinases. This proposal will revolutionize ideas related to cell movement through three-dimensional (3D) matrix. Our method in mimicking the body's dense 3D matrix environment have led to the discovery of a new cell structure called Claws, and the formulation of a new model for 3D invasion in high density matrix. We will study the genes that control this type of migration including those involved in the formation of the cell front (Claw region), the back of the cells and matrix digestion. This work will have significant impact on normal and pathological human conditions from immune responses to tissue regeneration and cancer.Read moreRead less
Regulation of MHC-I and ICAM-1 by flavivirus, West Nile. This project investigates the intracellular signalling pathway responsible for the expression of genes which are critical to our immune response. We have demonstrated in a mouse model that high levels of expression of two of these genes in flavivirus encephalitis are associated with a survival advantage. We would expect this project to provide basic new information about the mechanisms of expression of these genes as well as information ab ....Regulation of MHC-I and ICAM-1 by flavivirus, West Nile. This project investigates the intracellular signalling pathway responsible for the expression of genes which are critical to our immune response. We have demonstrated in a mouse model that high levels of expression of two of these genes in flavivirus encephalitis are associated with a survival advantage. We would expect this project to provide basic new information about the mechanisms of expression of these genes as well as information about the interaction of this family of viruses, flavivirus with the host.Read moreRead less
An investigation into Infection, Immunity & Rational Drug Design. The human population is constantly under threat of microbial attack. The survival of our species reflects a delicate balance between infection and immunity. Whether an individual mounts an effective immune response or succumbs to microbial infection is critically dependent on host proteins interacting effectively with microbial antigens, versus microbes developing sophisticated strategies of invasion and immune evasion. This pr ....An investigation into Infection, Immunity & Rational Drug Design. The human population is constantly under threat of microbial attack. The survival of our species reflects a delicate balance between infection and immunity. Whether an individual mounts an effective immune response or succumbs to microbial infection is critically dependent on host proteins interacting effectively with microbial antigens, versus microbes developing sophisticated strategies of invasion and immune evasion. This proposal will provide fundamental advancement of knowledge in the areas of infection and immunity. The information gleaned from this research will lead to the rational development of therapeutics. Consequently, the research will potentially have an enormous global impact in the area of biomedical health.Read moreRead less
Body fluids: sweet protection against infection? Serious health problems caused by pathogenic microorganisms are in sharp increase due to aging population, escalating numbers of immunocompromised people and the increased resistance of microorganisms to currently available antibiotics. Our research will lead to development of new approaches to protect people and animals from pathogens before they invade the body. The commercial possibilities for new and natural antimicrobials are present from bot ....Body fluids: sweet protection against infection? Serious health problems caused by pathogenic microorganisms are in sharp increase due to aging population, escalating numbers of immunocompromised people and the increased resistance of microorganisms to currently available antibiotics. Our research will lead to development of new approaches to protect people and animals from pathogens before they invade the body. The commercial possibilities for new and natural antimicrobials are present from both the health and agricultural sectors in Australia and abroad. The technologies used and further developed will serve as a state-of-the-art training ground for the next generation of postgraduate students encompassing the integration of genomics, proteomics and glycomics technologies.Read moreRead less
Brain metabolic changes in experimental malaria: a paradigm for the molecular mechanisms of intravascular inflammation. Malaria is endemic in countries directly to the north of Australia, as close as Papua New Guinea and East Timor. This project's findings about malaria also will have relevance to other infectious diseases of national importance. The outcomes will contribute to Australia's research reputation. We will build international links that will increase the national knowledge base and r ....Brain metabolic changes in experimental malaria: a paradigm for the molecular mechanisms of intravascular inflammation. Malaria is endemic in countries directly to the north of Australia, as close as Papua New Guinea and East Timor. This project's findings about malaria also will have relevance to other infectious diseases of national importance. The outcomes will contribute to Australia's research reputation. We will build international links that will increase the national knowledge base and research skill base. Young scientists will be trained in state-of-the-art research techniques in a cross-disciplinary environment that is the way of future biological research. The project may identify potential drug targets for malaria or other infectious diseases. The Intellectual Property will be protected and commercialised.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100150
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
Beyond Proteomics: structure and function of protein modifications. The world's leading cancer therapeutics have come from the protein phosphorylation field, and glycomics has led to drugs that combat the flu and that stimulate red blood cell production in cancer patients. Thus there is a bright future for discovery of new medicines based on new knowledge in this area. Protein modifications are key to the understanding of disease mechanisms and for searching for new disease markers and new the ....Beyond Proteomics: structure and function of protein modifications. The world's leading cancer therapeutics have come from the protein phosphorylation field, and glycomics has led to drugs that combat the flu and that stimulate red blood cell production in cancer patients. Thus there is a bright future for discovery of new medicines based on new knowledge in this area. Protein modifications are key to the understanding of disease mechanisms and for searching for new disease markers and new therapeutics. In the hands of local experts the instruments will enable identification of these modifications and provide improved understanding of biology, increase the national competitiveness of Australia's scientists, and provide advanced technology training to the next generation of scientists.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0883081
Funder
Australian Research Council
Funding Amount
$350,000.00
Summary
High Content Cell Signaling Discovery and Screening Facility. The national benefits of this facility will be an increase in basic knowledge of how cells transmit signals to determine their behaviour in normal or stressed situations. There will be high impact publications in learned journals, new IP developed, enhanced education and training in cutting edge technologies. The discoveries from this work will provide candidates for development by the Biotechnology industry in Australia. All of this ....High Content Cell Signaling Discovery and Screening Facility. The national benefits of this facility will be an increase in basic knowledge of how cells transmit signals to determine their behaviour in normal or stressed situations. There will be high impact publications in learned journals, new IP developed, enhanced education and training in cutting edge technologies. The discoveries from this work will provide candidates for development by the Biotechnology industry in Australia. All of this will promote an innovation culture and economy. The work done in this facility addresses several National Research Priority areas including Promoting and maintaining good health, Frontier technologies for transforming industry and Safeguarding Australia.Read moreRead less
In vivo imaging of the immune system in self tolerance and infectious disease. This proposal will introduce sophisticated imaging technology into our cutting-edge research program. Our approach will permit high resolution imaging of the immune response within an intact animal; currently not possible in Australia at the present time. The unique combination of technology and biological resources will significantly advance knowledge in key areas of basic immunology research. It will provide local ....In vivo imaging of the immune system in self tolerance and infectious disease. This proposal will introduce sophisticated imaging technology into our cutting-edge research program. Our approach will permit high resolution imaging of the immune response within an intact animal; currently not possible in Australia at the present time. The unique combination of technology and biological resources will significantly advance knowledge in key areas of basic immunology research. It will provide local researchers insights into how the body responds to infectious disease and immune-related disorders and be directly applicable to vaccine design. The facility and related research program will undoubtedly attract a team of top-level national and international scientists and students keen to work with this advanced technology.Read moreRead less
Dissecting the Parameters for the Generation of Cytotoxic T Lymphocyte Immunity. This project aims to identify mechanisms by which antigen-presenting cells, such as dendritic cells, prime CD8+ T cells to generate effector and memory populations at the molecular level. The specific intention is to identify reagents capable of licensing dendritic cells, and examine the down-stream gene products/pathways generated by these signals using microarray analyses. Such knowledge will provide new insight i ....Dissecting the Parameters for the Generation of Cytotoxic T Lymphocyte Immunity. This project aims to identify mechanisms by which antigen-presenting cells, such as dendritic cells, prime CD8+ T cells to generate effector and memory populations at the molecular level. The specific intention is to identify reagents capable of licensing dendritic cells, and examine the down-stream gene products/pathways generated by these signals using microarray analyses. Such knowledge will provide new insight into CTL generation by providing greater understanding of how multicellular systems function both at the cellular and molecular level.Read moreRead less