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.
The cell is the building block of life. This proposal focusses on the surface of the cell, the plasma membrane, and specialised structures called caveolae that are an abundant feature of animal cells. Altered caveolae are a feature of many human disease conditions. In this proposal we will address the function of caveolae. We will test the idea that proteins are released from caveolae into the cell when cells are stressed forming a novel signalling pathway disrupted in disease.
Epigenetic Regulation By PKC-theta In Human Breast Cancer Stem Cells.
Funder
National Health and Medical Research Council
Funding Amount
$818,132.00
Summary
Treating women with advanced breast cancer is difficult, and new drugs are needed to kill the cancer stem cells that cause recurrence. We think that a newly discovered protein, PKC-?, plays an important role in recurring breast cancer and can be targeted using novel ‘epigenetic’ drugs. Here, we will use cutting-edge DNA techniques to learn how this protein controls how cancer cells grow and produce the necessary data to show that targeting this protein is likely to be effective in real patients.
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.
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.
Molecular Regulation Of The Serine-Threonine Kinase ULK1 In Autophagy
Funder
National Health and Medical Research Council
Funding Amount
$299,431.00
Summary
Autophagy or self eating is a basic cellular process and can have either beneficial or adverse effects in cancer. It is essential to determine the status of autophagy in patients before considering drugs that block autophagy for therapy. A protein called ULK1 is needed for autophagy and may emerge as a pathological marker for autophagy in cancer as well as a potential drug target. This grant proposal will study ULK1 regulation and will lay the scientific foundation for its medical application.
Discovery Early Career Researcher Award - Grant ID: DE180100524
Funder
Australian Research Council
Funding Amount
$365,057.00
Summary
Manipulating selected inflammatory responses in macrophages. This project aims to define the structural and functional interactions of a new transmembrane adaptor SCIMP. SCIMP has recently been shown to effect the inflammatory pathway. The project outcomes will include the first structure of this unconventional complex. The project will have significant flow on benefits including new knowledge and new protein methodologies for end-users in research and industry, and ultimately economic impact.
Novel mechanisms of early growth response-1 activation through the epidermal growth factor receptor. This project will expand our knowledge of how cytokines and growth factors switch on signalling pathways from the cell surface to the nucleus. Unique antibodies will characterise regulatory routes, state-of-the-art microscopy will define dynamic patterns of receptor co-assembly, and in vivo studies will show receptor crosstalk in animal models.
Cardiac a1-adrenergic receptors in survival of the fittest. This project aims to determine the role of alpha1A-adrenergic receptor inactivation, a receptor/signalling pathway, in mediating cardiac contraction and survival in response to stressors fight-or-flight response triggers.Higher organisms’ ability to respond to environmental changes is central to the survival of the fittest, and is mediated by the release of catecholamines that stimulate adrenergic receptors. The precise receptor and sig ....Cardiac a1-adrenergic receptors in survival of the fittest. This project aims to determine the role of alpha1A-adrenergic receptor inactivation, a receptor/signalling pathway, in mediating cardiac contraction and survival in response to stressors fight-or-flight response triggers.Higher organisms’ ability to respond to environmental changes is central to the survival of the fittest, and is mediated by the release of catecholamines that stimulate adrenergic receptors. The precise receptor and signalling pathways underlying these adaptive responses remain unclear. This project’s research could improve contractility, reduce cardiomyocyte death and define organismal adaptation to extreme environmental changes.Read moreRead less
An active ion transport pathway exploited by coronaviruses. Cells have active transport “pumps” that are regulators of a variety of cellular processes. This project aims to understand how a specific ion pump is exploited by coronaviruses when they infect animal cells. These studies will provide new mechanistic insights into how coronaviruses alter calcium signalling in cells and how a specific ion pump regulates a variety of key processes during coronavirus infection. This work will greatly enha ....An active ion transport pathway exploited by coronaviruses. Cells have active transport “pumps” that are regulators of a variety of cellular processes. This project aims to understand how a specific ion pump is exploited by coronaviruses when they infect animal cells. These studies will provide new mechanistic insights into how coronaviruses alter calcium signalling in cells and how a specific ion pump regulates a variety of key processes during coronavirus infection. This work will greatly enhance our understanding of the intersection between ion pumps and viruses.Read moreRead less