Australian Laureate Fellowships - Grant ID: FL180100109
Funder
Australian Research Council
Funding Amount
$2,762,247.00
Summary
Unifying mechanisms of innate immunity signaling in animals and plants. This project aims to improve our understanding of innate immunity, the first line of defense against pathogens in diverse organisms. Innate immune pathways are key to a range of pathological states in animals, and provide plants with resistance to the diseases that account for 15% of crop losses. This project will generate knowledge, through characterising mechanisms of cell signalling for mammalian and plant innate immunity ....Unifying mechanisms of innate immunity signaling in animals and plants. This project aims to improve our understanding of innate immunity, the first line of defense against pathogens in diverse organisms. Innate immune pathways are key to a range of pathological states in animals, and provide plants with resistance to the diseases that account for 15% of crop losses. This project will generate knowledge, through characterising mechanisms of cell signalling for mammalian and plant innate immunity. The outcomes will include a unified signalling model, and form the foundation for a range of applications in human biology and agriculture, such as the development of durable and effective resistance in crops.Read moreRead less
Crosstalk between breast cancer cells and the microenvironment to promote metastasis. Breast cancer spread (metastasis) to distant tissues is usually fatal. It is now clear that cross-talk between cancer cells and other normal cells is essential for metastasis and previous studies have discovered two key mechanisms: tumour cell suppression of immune defence pathways to escape immune recognition, and activation of proteases to promote invasion and blood vessel growth. Using unique models and cell ....Crosstalk between breast cancer cells and the microenvironment to promote metastasis. Breast cancer spread (metastasis) to distant tissues is usually fatal. It is now clear that cross-talk between cancer cells and other normal cells is essential for metastasis and previous studies have discovered two key mechanisms: tumour cell suppression of immune defence pathways to escape immune recognition, and activation of proteases to promote invasion and blood vessel growth. Using unique models and cellular imaging, this project aims to investigate the cell specific functions of these pathways and the therapeutic potential of altering their expression and function. This project may lead to the development of novel predictors of metastasis in patients and new targeted therapeutics to prevent breast cancer spread.Read moreRead less
Membrane proteins in innate immunity. The application of smarter and faster methods for understanding membrane proteins, targets of most drugs, is vital to a knowledge-based economy and a healthy society. The long-term benefits will include fundamental new knowledge on immunity, and implementation of new approaches that streamline costs and efforts of challenging, high-impact research.
Structure and function of human zinc transporter membrane proteins. The aim of this project is to create fundamental new knowledge on how important mammalian membrane proteins operate. Membrane proteins are key drug targets and are significantly under-represented in structural databases. The project plans to combine innovative membrane protein screening technology with gene expression, structural biology, biophysics and cell biology. The project outcomes may elucidate specific molecular mechanis ....Structure and function of human zinc transporter membrane proteins. The aim of this project is to create fundamental new knowledge on how important mammalian membrane proteins operate. Membrane proteins are key drug targets and are significantly under-represented in structural databases. The project plans to combine innovative membrane protein screening technology with gene expression, structural biology, biophysics and cell biology. The project outcomes may elucidate specific molecular mechanisms underpinning the essential biological process of zinc homeostasis.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
Exceptions Prove the Rule: How Antigen Recognition Drives T cell Activation. CD8+ T cells are immune cells that are critical for the adaptive immune response, which is central to immune function in vertebrates. CD8+ T cells mediate their effector functions only after activation, which occurs via T cell receptor (TCR) recognition of foreign antigens. Here, unique reagents and sophisticated technologies will be used to define precisely how the nature of TCR-antigen recognition impacts on T cell ac ....Exceptions Prove the Rule: How Antigen Recognition Drives T cell Activation. CD8+ T cells are immune cells that are critical for the adaptive immune response, which is central to immune function in vertebrates. CD8+ T cells mediate their effector functions only after activation, which occurs via T cell receptor (TCR) recognition of foreign antigens. Here, unique reagents and sophisticated technologies will be used to define precisely how the nature of TCR-antigen recognition impacts on T cell activation and effector function. This work builds on an earlier identification of an entirely novel mode of TCR-antigen recognition, and its success will establish novel paradigms in T cell biology and represent a key advance in knowledge in the life sciences.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL160100049
Funder
Australian Research Council
Funding Amount
$2,915,738.00
Summary
A molecular investigation into immune function. A molecular investigation into immune function. The project aims to understand how key immune recognition events enable immunity. This project would use a multidisciplinary approach empowered by technological innovations, including the latest advances in atomic and molecular imaging. This research is expected to identify new approaches for the biotechnology industry.
Metabolite- and lipid-based immunity. This project aims to investigate T-cell immunity to lipids and metabolites. The immune system protects hosts from pathogens, and uses T-cells to recognise infected host cells. However, many facets of T-cell function are not understood. This project will unearth the evolutionary and molecular correlates of lipid- and metabolite-based immunity across diverse species. This will provide basic fundamental insights and conceptual advances into a poorly understood, ....Metabolite- and lipid-based immunity. This project aims to investigate T-cell immunity to lipids and metabolites. The immune system protects hosts from pathogens, and uses T-cells to recognise infected host cells. However, many facets of T-cell function are not understood. This project will unearth the evolutionary and molecular correlates of lipid- and metabolite-based immunity across diverse species. This will provide basic fundamental insights and conceptual advances into a poorly understood, but crucial, component of the immune system.Read moreRead less
Lifespan-dependent molecular shaping of the T cell receptor repertoire. Mammals have an intricate and highly complex immune system, whose function alters throughout life. Why and how this occurs is very unclear however, yet remains a crucial question. This project aims to provide fundamental knowledge on how the human lifespan shapes specific T cell receptors and determine molecular mechanisms underlying gain-of-function and loss-of-function during immunologically distinct phases of life. This p ....Lifespan-dependent molecular shaping of the T cell receptor repertoire. Mammals have an intricate and highly complex immune system, whose function alters throughout life. Why and how this occurs is very unclear however, yet remains a crucial question. This project aims to provide fundamental knowledge on how the human lifespan shapes specific T cell receptors and determine molecular mechanisms underlying gain-of-function and loss-of-function during immunologically distinct phases of life. This project will provide analysis of multi-dimensional, high throughput datasets to identify fundamental links between the transcriptional landscape and TCR signatures across human lifespan, thus will significantly answer key immunological questions in the field.Read moreRead less
A molecular investigation into the naïve T cell repertoire. This project aims to interrogate the relationship between T cell receptor (TCR) recognition modes and T cell recruitment and activation. CD8+ T cells are important for adaptive immunity. Their recognition, via TCR, of peptides bound to MHC class I antigen-presenting molecules (pMHCI), initiates a signalling cascade which activates T cells effector functions. All structural information on TCR recognition of pMHCI is based on TCRs prevale ....A molecular investigation into the naïve T cell repertoire. This project aims to interrogate the relationship between T cell receptor (TCR) recognition modes and T cell recruitment and activation. CD8+ T cells are important for adaptive immunity. Their recognition, via TCR, of peptides bound to MHC class I antigen-presenting molecules (pMHCI), initiates a signalling cascade which activates T cells effector functions. All structural information on TCR recognition of pMHCI is based on TCRs prevalent in immune responses, and all recognise pMHCI using a conserved orientation. This project aims to use this observation to study the relationship between TCR recognition modes and T cell recruitment and activation.Read moreRead less