Imaging the generation and recall of protective antiviral immune responses in vivo. Our understanding of the in vivo dynamics of cellular immune responses to infectious diseases is poor. This project will utilise advanced intravital imaging combined with novel tools to dissect the cellular events involved in the generation and recall of T cell responses to localised virus infection, combined with a detailed functional analysis of the lymphoid organ stroma. Such fundamental information will contr ....Imaging the generation and recall of protective antiviral immune responses in vivo. Our understanding of the in vivo dynamics of cellular immune responses to infectious diseases is poor. This project will utilise advanced intravital imaging combined with novel tools to dissect the cellular events involved in the generation and recall of T cell responses to localised virus infection, combined with a detailed functional analysis of the lymphoid organ stroma. Such fundamental information will contribute to the development of new generation vaccines and therapies to protect against tissue-specific infectious diseases, cancers and autoimmune diseases.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100092
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Fluorescence microscopy with optical tweezers: imaging cellular responses. Life relies on the ability of our cells to receive and respond to signals with pinpoint accuracy, involving both chemical and mechanical signals. This equipment will allow scientists to expose cells to both types of signals and measure the response at an unprecedented level of accuracy for the first time.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100166
Funder
Australian Research Council
Funding Amount
$370,000.00
Summary
Imaging Cell and Tissue Architecture using Confocal and Super-Resolution Microscopy. Imaging cell and tissue architecture using confocal and super-resolution microscopy: This project aims to understand how the architecture of cells and tissues is controlled. This is because the organisation of biological space underpins the function of cells, tissues and organisms. This project will test the role of identified parts of cell architecture in regulating specific animal functions/pathologies. It wil ....Imaging Cell and Tissue Architecture using Confocal and Super-Resolution Microscopy. Imaging cell and tissue architecture using confocal and super-resolution microscopy: This project aims to understand how the architecture of cells and tissues is controlled. This is because the organisation of biological space underpins the function of cells, tissues and organisms. This project will test the role of identified parts of cell architecture in regulating specific animal functions/pathologies. It will do this by using new microscope technologies which are at the frontier of visualising cell structure in isolation and in the context of tissue including application to the living animal. The dynamic organisation of structures in cells will be imaged in living tissue. Novel insights into structure/function relationships in the body will impact the health industry and generate opportunities for new diagnostics and therapeutics. Read moreRead less
Cellular Organisation of Protective Immune Responses. Our immune system consists of a task force of white blood cells that coordinate to defeat invading pathogens. Research has revealed a cell receptor, CXCR3, controls immune cell interactions, which determine immune control and protection during initial cell activation and viral infection. This project will use a multi-disciplinary approach combining viral immunology, unique mouse models, advanced imaging, and bioinformatic analyses to dissect ....Cellular Organisation of Protective Immune Responses. Our immune system consists of a task force of white blood cells that coordinate to defeat invading pathogens. Research has revealed a cell receptor, CXCR3, controls immune cell interactions, which determine immune control and protection during initial cell activation and viral infection. This project will use a multi-disciplinary approach combining viral immunology, unique mouse models, advanced imaging, and bioinformatic analyses to dissect the cellular conversations that underpin immune protection. Revealing the mechanisms of cellular interactions during an immune response will have a major impact on development of targeted vaccines, and therapeutics (particularly for chronic infections and cancer), which are major health burdens.Read moreRead less
Multifunctional biodegradable nanoparticles for enhanced DNA vaccine delivery. DNA vaccine, which shows better immunological and economic merits than conventional vaccines, suffers clinical failure due to the difficulty of delivering intact DNA molecules to relevant cells. This project seeks to develop smart polymer nanospheres to protect the DNA molecules from premature degradation in order to improve its efficacy.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100125
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
Advanced fluorescence imaging facility: from super high resolution to whole animal imaging. The establishment of this advanced fluorescence imaging facility will provide cutting-edge infrastructure to examine cells, pathogens and interactions between engineered drug delivery systems in both cells and whole animals. The facility will foster the development of new nanomedicines.
I am a Clinical Immunologist, Immunopathologist, clinical researcher and laboratory scientist exploring the interactions between T cell and viral infections. My area of particular interest is the mechanisms by which HIV infection subverts effective T cel
A novel link between metabolism and host defence. This project aims to delineate how a protein modification that consists of the addition of a small sugar to cellular proteins, known as O-GlcNAcylation, provides a link between metabolism and complex cell functions. The model for these studies is a cell type of the immune system known as dendritic cells. Upon encountering pathogens these cells undergo metabolic changes that increase the rate of O-GlcNAcylation of proteins involved in immune respo ....A novel link between metabolism and host defence. This project aims to delineate how a protein modification that consists of the addition of a small sugar to cellular proteins, known as O-GlcNAcylation, provides a link between metabolism and complex cell functions. The model for these studies is a cell type of the immune system known as dendritic cells. Upon encountering pathogens these cells undergo metabolic changes that increase the rate of O-GlcNAcylation of proteins involved in immune responses, altering their function. This project will study how O-GlcNAcylation works and is regulated. The project expects to develop new technology and provide high-level training, increasing the competitiveness of the strategic biotechnology sector in AustraliaRead moreRead less
The Genetics Governing The Specificity Of T Cell Receptors For Peptide-MHC
Funder
National Health and Medical Research Council
Funding Amount
$303,828.00
Summary
T lymphocytes play a pivotal role in the immune system by recognising virus-infected tissue through the use of highly specific cell surface receptors. These T cell receptors (TCR) recognise viral peptides (p) presented by MHC molecules on the surface of virus-infected cells. For a TCR to be successfully triggered, it must lock onto an exact 3-dimentional pMHC match. In this way, any given TCR must simultaneously recognise both the viral peptide and the MHC presenting it. Such recognition must be ....T lymphocytes play a pivotal role in the immune system by recognising virus-infected tissue through the use of highly specific cell surface receptors. These T cell receptors (TCR) recognise viral peptides (p) presented by MHC molecules on the surface of virus-infected cells. For a TCR to be successfully triggered, it must lock onto an exact 3-dimentional pMHC match. In this way, any given TCR must simultaneously recognise both the viral peptide and the MHC presenting it. Such recognition must be sensitive and precise since a false positive could result in destruction of healthy tissue. There are a huge variety of TCRs and pMHCs, but there are only a few examples where the precise molecular interactions within the TCR-pMHC complex are known. Surprisingly, these studies have shown very limited consistency in the way the TCRs bind the pMHCs and therefore, the structural rules that underlie why TCRs consistently bind MHC remains a mystery of critical importance to this fundamental feature of the immune system. In this proposal, we will attempt to elucidate the rules of TCR-pMHC engagement. Another question to be addressed in this proposal is: During a viral infection, why are certain TCRs chosen above others that also have the capacity to recognise the same viral peptide? By investigating exactly which feature-s of these receptors predisposes their supremacy, we may be better able to predict the outcome of a pathogen attack and to even one day build our own super receptors. Finally, this proposal will also investigate how natural mutations in TCR genes across the human population affect our individual responses to viruses. Overall, advances in each of these core areas of medical research will aid in the development of new intelligent vaccines and individualised drugs for the treatment of cancer and infectious disease.Read moreRead less
Investigations Into The Biology And Functionality Of The Human T Cell Receptor
Funder
National Health and Medical Research Council
Funding Amount
$424,262.00
Summary
T lymphocytes play a pivotal role in the immune system by recognising virus-infected tissue and tumour cells through the use of specific cell surface receptors called T cell receptors (TCR). This project will study why partcular TCRs are used by the immune system, and will also examine the specificity of T cell recognition by determine the range of molecules an individual T cell can recognise. The work will aid in the development of new intelligent vaccines for cancer and infectious disease.