T cells play a central role in the immune response. The primary event in T cell activation is the triggering of a specific T cell receptor (TCR). Our studies will define new mechanisms for the regulation of TCR-mediated T cell responses. Our studies may yield novel insight into processes that contribute to the development of type 1 diabetes & inflammatory bowel disease.
Regulation Of The Signalling Efficiency Of The T Cell Antigen Receptor
Funder
National Health and Medical Research Council
Funding Amount
$456,557.00
Summary
An immune response starts with activation of the T cell antigen receptor (TCR). How T cell receptor signalling begins, however, is not well understood. We have developed a novel imaging approach that allows us to directly observe what happens after an antigen binds to the receptor. The research will provide mechanistic insights into how T cells sense and discriminate antigens. This knowledge will aid the development of cancer immunotherapies and vaccines.
How Lipids Affect Signalling Efficiencies In T Cells
Funder
National Health and Medical Research Council
Funding Amount
$472,882.00
Summary
A high fat diet can compromise the function our immune system. This project examines how lipids affect T cells. We propose that T cells from mice on a high fat diet can no longer respond to an immune challenge because the signalling processes that lead to activation are deregulated. We have established a new microscopy technique that allows us to measure the efficiency of signalling processes. We will use this method to identify which lipids contribute the most to T cell deregulation.
Spatial Organization Of Lck As A Regulatory Mechanism Of TCR Signalling
Funder
National Health and Medical Research Council
Funding Amount
$601,263.00
Summary
To function in an immune response, T cell become activated when the interactions between the T cell receptor and the kinase Lck on the cell surface results in intracellular signals. Here, we will investigate how the kinase is organized on the cell surface during receptor activation and what intrinsic and extrinsic parameters regulate its organization. The research is based on novel single molecule imaging tools and will provide new insights into the regulation of T cell activation.
Using viral inhibitors to understand the regualtion of apoptosis. Apoptosis is a form of cell death that is critical for the development and well-being of multicellular organisms. The activity of Bak or Bax, two members of the Bcl-2 family, are essential for apoptosis to proceed, but how the activity of these two proteins is regulated is unclear. Many viruses encode inhibitors of apoptosis and the project will make use of two novel viral inhibitors that specifically target Bak. The project aims ....Using viral inhibitors to understand the regualtion of apoptosis. Apoptosis is a form of cell death that is critical for the development and well-being of multicellular organisms. The activity of Bak or Bax, two members of the Bcl-2 family, are essential for apoptosis to proceed, but how the activity of these two proteins is regulated is unclear. Many viruses encode inhibitors of apoptosis and the project will make use of two novel viral inhibitors that specifically target Bak. The project aims to determine how the Bak inhibitors function and to provide valuable insights into the normal mechanisms regulating Bak activity.Read moreRead less
Molecular determinants of inflammatory caspase activity upon inflammasomes. Most processes fundamental to life rely on the timely, and regulated, execution of cellular functions. The innate immune system, in which both timing and regulation is paramount, rapidly detects invading microbes and induces a measured and timely antimicrobial response to clear infection. This project aims to address a key knowledge gap by characterising a mechanism for timely and controlled immune system activation and ....Molecular determinants of inflammatory caspase activity upon inflammasomes. Most processes fundamental to life rely on the timely, and regulated, execution of cellular functions. The innate immune system, in which both timing and regulation is paramount, rapidly detects invading microbes and induces a measured and timely antimicrobial response to clear infection. This project aims to address a key knowledge gap by characterising a mechanism for timely and controlled immune system activation and immune cell death via the non-canonical inflammasome. We do not currently understand how some immune pathways are turned on or off. This project will yield fundamental insight into mechanisms of mammalian inflammasome, inflammation and anti-microbial responses.Read moreRead less
How cell shape regulators control cell competition in tissue development. This project aims to determine how cell shape (polarity) regulators affect cell survival in an epithelial tissue. When mutation or wounding perturb cell shape regulators in a tissue cell, signalling pathways are altered that kill the aberrant cells. A surveillance mechanism termed "cell competition" is important to remove the damaged cells. This project will investigate a potential regulator of cell competition, the tyrosi ....How cell shape regulators control cell competition in tissue development. This project aims to determine how cell shape (polarity) regulators affect cell survival in an epithelial tissue. When mutation or wounding perturb cell shape regulators in a tissue cell, signalling pathways are altered that kill the aberrant cells. A surveillance mechanism termed "cell competition" is important to remove the damaged cells. This project will investigate a potential regulator of cell competition, the tyrosine phosphatase PTP61F, in response to perturbation of cell shape regulators, using the vinegar fly, Drosophila, and mammalian systems. This study is expected to reveal biomarkers that can be used to improve organismal fitness to increase productivity or to decrease it for pest control.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100011
Funder
Australian Research Council
Funding Amount
$900,000.00
Summary
Integrated Multimodal System for Multiplexed Imaging of Signal Transduction. This project will introduce a unique microscopy platform and associated technologies into the Australian research environment that will enable researchers to redefine our understanding of molecular signal transduction. The instrumentation will enable the multidimensional imaging of live cells with unprecendented speed and sensitivity. The featured imaging modalities will enable the integration of distinct biological, ....Integrated Multimodal System for Multiplexed Imaging of Signal Transduction. This project will introduce a unique microscopy platform and associated technologies into the Australian research environment that will enable researchers to redefine our understanding of molecular signal transduction. The instrumentation will enable the multidimensional imaging of live cells with unprecendented speed and sensitivity. The featured imaging modalities will enable the integration of distinct biological, biochemical and chemical probes with a focus on minimizing phototoxicity. Expected outcomes include new fundamental knowledge on molecular signal transduction and cell heterogeneity; development of novel probes and methodologies and the development of new and existing interdisciplinary research collaborations. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100066
Funder
Australian Research Council
Funding Amount
$440,000.00
Summary
Mass Cytometry: A breakthrough in multidimensional systems biology. Mass cytometry - a breakthrough in multidimensional systems biology: Mass Cytometry by Time of Flight marries the resolution, specificity and sensitivity of atomic stable isotope mass spectrometry to the high-throughput, single-cell analytical advantages of flow cytometry. Using molecular probes conjugated with stable isotope tags, a large increase is possible in the number of simultaneous quantitative measurements in complex sa ....Mass Cytometry: A breakthrough in multidimensional systems biology. Mass cytometry - a breakthrough in multidimensional systems biology: Mass Cytometry by Time of Flight marries the resolution, specificity and sensitivity of atomic stable isotope mass spectrometry to the high-throughput, single-cell analytical advantages of flow cytometry. Using molecular probes conjugated with stable isotope tags, a large increase is possible in the number of simultaneous quantitative measurements in complex samples. These parameters, denoting cell type, function and signalling status, will make possible future advances in the understanding of the diversity of cell phenotype and function with a systems biology approach. Read moreRead less
Control of cell fate decisions in neurogenesis: use of embryonic stem cells to investigate key signalling systems and gene expression programs. Human embryonic stem cells (hESC) have the potential to provide an unlimited source of specific subtypes of human neurons for basic studies in neuroscience and biomedical applications. The use of hESC is limited at present by a lack of control over lineage commitment during differentiation in vitro. This project will use engineered reporter hESC lines t ....Control of cell fate decisions in neurogenesis: use of embryonic stem cells to investigate key signalling systems and gene expression programs. Human embryonic stem cells (hESC) have the potential to provide an unlimited source of specific subtypes of human neurons for basic studies in neuroscience and biomedical applications. The use of hESC is limited at present by a lack of control over lineage commitment during differentiation in vitro. This project will use engineered reporter hESC lines to investigate which cell signalling pathways and gene expression programs are involved in controlling cell fate. The project will result in improved protocols for hESC differentiation allowing enrichment of cultures with specific neuronal subtypes, and significant advances in the understanding of neuronal lineage commitment and maturation during brain development. Read moreRead less