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
Molecular Mechanisms of NOD signalling. Alterations in NOD1 and NOD2 (nucleotide-binding oligomerization domain containing 1 and 2) signalling have been implicated in various human inflammatory diseases. Therefore, a clear understanding of the molecular signalling pathways is important to gain further insights into potential drug targets for the treatment of these diseases. Using novel experimental approaches, this project aims to identify new members of the NOD signalling pathway. It will test ....Molecular Mechanisms of NOD signalling. Alterations in NOD1 and NOD2 (nucleotide-binding oligomerization domain containing 1 and 2) signalling have been implicated in various human inflammatory diseases. Therefore, a clear understanding of the molecular signalling pathways is important to gain further insights into potential drug targets for the treatment of these diseases. Using novel experimental approaches, this project aims to identify new members of the NOD signalling pathway. It will test the effect of pharmacological inhibition of established molecules such as RIPK2 or IAPs in NOD dependent models for human diseases. Outcomes of this study will be of the utmost interest for the treatment of NOD driven diseases such as Crohn's disease, Blau syndrome or asthma.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130100537
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Neural regulation of immunity following brain injury. Following a brain injury, the brain tries to protect itself by blocking all inflammation. However, this renders the host with impaired immunity and increased risks to infections. The project aims to delineate the mechanisms behind this response, with the expected outcome of highlighting the important interplay between the nervous and immune system.
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
Imaging of immune responses to pathogens in vivo. This proposal represents an excellent opportunity for Australian science to participate in state-of-the-art research into the immune system and to be internationally competitive with the best researchers in the field. By combining advanced microscopy techniques with well developed biological models used by researchers at the University of Melbourne, this project will greatly improve our understanding of the dynamic interactions that occur betwee ....Imaging of immune responses to pathogens in vivo. This proposal represents an excellent opportunity for Australian science to participate in state-of-the-art research into the immune system and to be internationally competitive with the best researchers in the field. By combining advanced microscopy techniques with well developed biological models used by researchers at the University of Melbourne, this project will greatly improve our understanding of the dynamic interactions that occur between cells of the immune system during infectious diseases. The insight provided by this project will facilitate the design of better vaccines for protection against diseases, including influenza.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170100407
Funder
Australian Research Council
Funding Amount
$372,000.00
Summary
Biology of immune cells. This project aims to study immune cells that target harmful microbes by recognising by-products of their metabolism, and develop methods modulating their function. In particular, it aims to determine the immune recognition of the full range of microbial metabolites that activate these cells and unravel the mechanisms behind tolerance to nutrition-derived metabolites. This project is a potential opportunity for Australia to maximise its competitive edge in this field and ....Biology of immune cells. This project aims to study immune cells that target harmful microbes by recognising by-products of their metabolism, and develop methods modulating their function. In particular, it aims to determine the immune recognition of the full range of microbial metabolites that activate these cells and unravel the mechanisms behind tolerance to nutrition-derived metabolites. This project is a potential opportunity for Australia to maximise its competitive edge in this field and develop immune-modulatory agents ultimately leading to socioeconomic benefit.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.
Studies on peripheral T cell memory. Success in vaccination depends on the ability of the immune system to remember prior encounter with an infectious agent. This immune memory appears to work well for certain infections but not others, essentially meaning that for these diseases, effective vaccines remain unavailable. This application describes experiments based on a new leukocyte or white blood cell population that has been overlooked in studies of immune memory. The work involves identifyin ....Studies on peripheral T cell memory. Success in vaccination depends on the ability of the immune system to remember prior encounter with an infectious agent. This immune memory appears to work well for certain infections but not others, essentially meaning that for these diseases, effective vaccines remain unavailable. This application describes experiments based on a new leukocyte or white blood cell population that has been overlooked in studies of immune memory. The work involves identifying how they are formed and how they behave within the body. This work will therefore contribute to the development and production of new-generation vaccines to these so far uncontrollable infectious diseases.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989226
Funder
Australian Research Council
Funding Amount
$340,000.00
Summary
Multi-photon imaging for infection, immunity, and self recognition. This proposal will address a gap in our imaging capabilities, allowing us to visualise the movement of immune cells and infectious agents such as bacteria and viruses within living tissues. This will immensely improve our capacity to understand interactions between the immune system, invading organisms and the rest of our body. The intravital imaging system will provide novel insights into how the immune system works, which will ....Multi-photon imaging for infection, immunity, and self recognition. This proposal will address a gap in our imaging capabilities, allowing us to visualise the movement of immune cells and infectious agents such as bacteria and viruses within living tissues. This will immensely improve our capacity to understand interactions between the immune system, invading organisms and the rest of our body. The intravital imaging system will provide novel insights into how the immune system works, which will benefit the design of vaccines, the treatment of cancer, and our understanding of allergy. This state-of-the-art facility will also provide vital training in an emerging technology that will have application in many areas of biology.
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Defining the immunological roles of stromal cells within lymphoid tissues. The populations of endothelial and mesenchymal cells that construct the lymphoid tissues are being revealed as key players in the priming and orchestration of immune responses. Yet, fundamental knowledge of the molecular makeup and the functions of these stromal cells, particularly their roles in immune responses, is sorely lacking. This project will utilise a multidisciplinary approach including advanced imaging and bioi ....Defining the immunological roles of stromal cells within lymphoid tissues. The populations of endothelial and mesenchymal cells that construct the lymphoid tissues are being revealed as key players in the priming and orchestration of immune responses. Yet, fundamental knowledge of the molecular makeup and the functions of these stromal cells, particularly their roles in immune responses, is sorely lacking. This project will utilise a multidisciplinary approach including advanced imaging and bioinformatics to dissect the functions of the lymphoid stromal cells and their roles in the swelling of lymphoid tissues during immune responses. This will provide vital information about the biology of these understudied cells and reveal the ways in which they support the generation of immunity.Read moreRead less