Understanding the diverse biology of CD4+ T cell resident memory. This project aims to examine the biology of CD4 T cell memory in tissues. The previously unappreciated complexity of the CD4 T cell resident memory compartment in the liver will be characterised, focusing on the generation, maintenance and diversity of functions of these cells. Expected outcomes include the generation of fundamental knowledge in the disciplines of cellular biology and immunology, and unique, highly specialised stu ....Understanding the diverse biology of CD4+ T cell resident memory. This project aims to examine the biology of CD4 T cell memory in tissues. The previously unappreciated complexity of the CD4 T cell resident memory compartment in the liver will be characterised, focusing on the generation, maintenance and diversity of functions of these cells. Expected outcomes include the generation of fundamental knowledge in the disciplines of cellular biology and immunology, and unique, highly specialised student and personnel training through the interdisciplinary approach utilised, which spans cellular biology, live-imaging and transcriptomic analyses. Expected benefits include influential publications and the import of a novel, specialised technique to Australia through an international collaboration (Germany)Read moreRead less
Mechanism and function of cell asymmetry during cell death. This project aims to investigate how dying cells rearrange their cellular contents to aid their removal.
More than 200 billions cells die daily in the human body. It is critical that dying cells are rapidly cleared as their buildup can interfere with normal tissue functions. This project will use a suite of contemporary molecular/cell biological approaches to study a newly identified process that occurs during cell death. Expected outc ....Mechanism and function of cell asymmetry during cell death. This project aims to investigate how dying cells rearrange their cellular contents to aid their removal.
More than 200 billions cells die daily in the human body. It is critical that dying cells are rapidly cleared as their buildup can interfere with normal tissue functions. This project will use a suite of contemporary molecular/cell biological approaches to study a newly identified process that occurs during cell death. Expected outcomes include a paradigm-shift in understanding the process of cell clearance.
This project is expected to generate fundamental new knowledge of the mechanisms by which dying cells are efficiently removed from tissues. This should provide significant benefits to the cell death and general cell biology fields.Read moreRead less
Mechanisms by which Beclin1 regulates intestinal homeostasis. This project aims to investigate if Beclin1, a protein which has an important and well-accepted role in promoting cell survival through the program of autophagy, has an alternate job mediating trafficking within a cell. Using novel mouse models and innovative techniques, the project aims to demonstrate the physiological importance of this alternate role for Beclin1. Expected outcomes include enhancing Australia's international researc ....Mechanisms by which Beclin1 regulates intestinal homeostasis. This project aims to investigate if Beclin1, a protein which has an important and well-accepted role in promoting cell survival through the program of autophagy, has an alternate job mediating trafficking within a cell. Using novel mouse models and innovative techniques, the project aims to demonstrate the physiological importance of this alternate role for Beclin1. Expected outcomes include enhancing Australia's international research standing, and providing research training for young scientists. Benefits include generation of new knowledge and a rethink of the basis for normal development and diseases where Beclin1 has been implicated.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100084
Funder
Australian Research Council
Funding Amount
$471,754.00
Summary
Deciphering the rules of T cell residency across intestinal compartments. Tissue-resident memory T cells (TRM) are key for immune protection against infection and cancer at barrier sites including the gut. Whilst much of our understanding of gut TRM comes from studies on the small intestine, how these cells develop and function in the large intestine is unknown. Using state-of-the-art techniques and novel animal models, this project aims to (i) identify molecular pathways by which the local inte ....Deciphering the rules of T cell residency across intestinal compartments. Tissue-resident memory T cells (TRM) are key for immune protection against infection and cancer at barrier sites including the gut. Whilst much of our understanding of gut TRM comes from studies on the small intestine, how these cells develop and function in the large intestine is unknown. Using state-of-the-art techniques and novel animal models, this project aims to (i) identify molecular pathways by which the local intestinal microenvironment influences TRM development and (ii) how these pathways could modulate TRM generation specifically in the small or large intestine. The expected outcomes are to generate fundamental new knowledge that will have significance for regulation of the immune response. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240101101
Funder
Australian Research Council
Funding Amount
$452,077.00
Summary
Dissecting the heterogeniety of human tissue-resident memory T cells. Tissue-resident memory T cells (TRM) are key to immune protection against infection and cancer, yet dysfunctional TRM cause autoimmune disease. Whilst much of our understanding of TRM comes from animal models, how these cells work in humans is largely unknown. This project aims to define the phenotypic, functional and regulatory heterogeneity of human TRM subsets in organs like the gut, liver, and skin using a unique human org ....Dissecting the heterogeniety of human tissue-resident memory T cells. Tissue-resident memory T cells (TRM) are key to immune protection against infection and cancer, yet dysfunctional TRM cause autoimmune disease. Whilst much of our understanding of TRM comes from animal models, how these cells work in humans is largely unknown. This project aims to define the phenotypic, functional and regulatory heterogeneity of human TRM subsets in organs like the gut, liver, and skin using a unique human organ donor tissue resource. The expected outcomes are to generate fundamental new knowledge that will have significance for the development of new therapies against infectious diseases, cancer and autoimmunity.Read moreRead less
Signaling in the crypt: a novel metabolic pathway in intestinal stem cells. The gut is the most rapidly renewing tissue in the body, driven by a highly active stem cell niche. Bile acids are emerging as critical regulators of this stem cell niche and disruption of bile acid homeostasis has profoundly adverse effects on intestinal renewal and hence gut health. We are addressing a critical gap in our understanding of how bile acids are controlled within stem cell niche. The aim of the project is ....Signaling in the crypt: a novel metabolic pathway in intestinal stem cells. The gut is the most rapidly renewing tissue in the body, driven by a highly active stem cell niche. Bile acids are emerging as critical regulators of this stem cell niche and disruption of bile acid homeostasis has profoundly adverse effects on intestinal renewal and hence gut health. We are addressing a critical gap in our understanding of how bile acids are controlled within stem cell niche. The aim of the project is to define the critical role of a novel enzyme called UGT8 in controlling intestinal stem cell response to bile acids; this is achieved by modulating UGT8 activity in intestinal stem cell models and determining the effects on stem cell function and the key signalling pathways that control intestinal homeostasis and renewal.Read moreRead less
How do stem cells get specified during embryonic muscle development? This project aims to investigate the mechanisms by which muscle stem cells first form in the embryo. This project expects to generate new knowledge on the mechanism that patterns cell types in the embryonic myotome. Expected outcomes of this project include uncovering the developmental mechanisms of cell type specification in the myotome with specific reference to the generation of stem cells. This should provide significant be ....How do stem cells get specified during embryonic muscle development? This project aims to investigate the mechanisms by which muscle stem cells first form in the embryo. This project expects to generate new knowledge on the mechanism that patterns cell types in the embryonic myotome. Expected outcomes of this project include uncovering the developmental mechanisms of cell type specification in the myotome with specific reference to the generation of stem cells. This should provide significant benefits as it will inform how long lived tissue resident stem cells can be made in the first instance, knowledge that is critical for making stem cells on demand outside the animal and manipulating stem cells in living tissue.Read moreRead less
How do unconventional T cells die? Mammalian cells die via several different mechanisms, each of which is tightly controlled at a molecular level. The choice of death pathway depends on the trigger and cell type. This project will investigate the mechanisms controlling death of T cells, including conventional T cells, and unconventional T cells, such as mucosal-associated invariant T (MAIT) cells, in normal conditions and during inflammation. It combines methods we developed to study MAIT cells ....How do unconventional T cells die? Mammalian cells die via several different mechanisms, each of which is tightly controlled at a molecular level. The choice of death pathway depends on the trigger and cell type. This project will investigate the mechanisms controlling death of T cells, including conventional T cells, and unconventional T cells, such as mucosal-associated invariant T (MAIT) cells, in normal conditions and during inflammation. It combines methods we developed to study MAIT cells in vivo with expertise in cell death analysis. This project is expected to elucidate the complex mechanisms controlling T cell survival/death and increase our fundamental understanding of cell death mechanisms of activated T cells.Read moreRead less
The impact of Hyaluronic Acid on growth factor signalling and angiogenesis. Blood vessel development is controlled by growth factor signalling. Vessels are attracted by and migrate along growth factor gradients, and this is controlled by the extracellular matrix (ECM). From the zebrafish model, we have identified a novel gene that modulates the ECM, impacting growth factor signalling and vessel development. The project will explore by what mechanism this gene impacts signalling. It will comprehe ....The impact of Hyaluronic Acid on growth factor signalling and angiogenesis. Blood vessel development is controlled by growth factor signalling. Vessels are attracted by and migrate along growth factor gradients, and this is controlled by the extracellular matrix (ECM). From the zebrafish model, we have identified a novel gene that modulates the ECM, impacting growth factor signalling and vessel development. The project will explore by what mechanism this gene impacts signalling. It will comprehensively define where in the embryo it is required and investigate what cofactors it interacts with to perform its function. Using genetic zebrafish and mouse models as well as cell culture models we will investigate the fundamental biology of this gene.Read moreRead less