Spatial And Temporal Dimensions Of Mu-opioid Receptor Signalling: Implications For The Development Of Tolerance
Funder
National Health and Medical Research Council
Funding Amount
$799,316.00
Summary
The use of morphine as an analgesic is still limited by undesirable side effects such as tolerance. Despite decades of research, the mechanisms behind the development of tolerance are poorly understood. The ? opioid receptor is a protein expressed at the surface of the cells that is the target of morphine. This project will investigate the signalling events triggered by opioids with unprecedented resolution and will aim to elucidate why morphine elicits more tolerance than other opioid drugs.
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.
Ciliopathies are an emerging group of syndromes in society that have devastating health effects. Ciliopathy patients exhibit a specturm of disorders including polycystic kidneys, extra digits, retinal degeneration and neural tube defects. INPP5E is a gene that is mutated in patients with a ciliopathy syndrome. These studies will determine the role of INPP5E in ciliopathy disease and may identify INPP5E as a novel treatment target.
Dissecting The Role Of Insulin-regulated Phosphorylation Of Rab Guanine Nucleotide Exchange Factors In GLUT4 Trafficking
Funder
National Health and Medical Research Council
Funding Amount
$628,459.00
Summary
Diabetes and obesity are epidemic in the developed world. Impaired insulin action is a major cause. A key contributor is reduced glucose uptake into muscle and fat driving the pancreas to overproduce insulin. We have recently discovered three new molecules that we believe hold the secret to how insulin regulates the removal of the glucose from the blood stream after a meal. This proposal focuses on these three molecules and their regulation.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100157
Funder
Australian Research Council
Funding Amount
$600,000.00
Summary
Confocal and single molecule microscopes for systems microscopy. This project aims to establish Australia’s first system microscopy facility with dedicated live-cell confocal and single-molecule fluorescence microscopes. In systems microscopy, the imaging workflow is automated so that large and unbiased data sets of the spatiotemporal organisation of molecules and cells can be generated. Combined with statistical and bioinformatics analyses, image-derived data provides system-wide information th ....Confocal and single molecule microscopes for systems microscopy. This project aims to establish Australia’s first system microscopy facility with dedicated live-cell confocal and single-molecule fluorescence microscopes. In systems microscopy, the imaging workflow is automated so that large and unbiased data sets of the spatiotemporal organisation of molecules and cells can be generated. Combined with statistical and bioinformatics analyses, image-derived data provides system-wide information that is not easily obtainable with other approaches. The project will enable Australian researchers to image and analyse the full complexity of biological systems, potentially transforming cell biology, drug development and understanding the molecular basis of disease. It will also demonstrate how the capacity of microscopy facilities can be enhanced and bias in imaging data reduced by automating data acquisition and mining of image-based data.Read moreRead less
The role of phosphoinositides in endosomal maturation dynamics. This project aims to investigate the regulation of an intracellular compartment within a cell called endosomes, which plays critical roles in cellular homeostasis, signalling and pathogen entry. New knowledge is expected to be generated in understanding endosome maturation and the signalling events that drive this process using a unique, multidisciplinary approach combining state of the art imaging techniques and high throughput pro ....The role of phosphoinositides in endosomal maturation dynamics. This project aims to investigate the regulation of an intracellular compartment within a cell called endosomes, which plays critical roles in cellular homeostasis, signalling and pathogen entry. New knowledge is expected to be generated in understanding endosome maturation and the signalling events that drive this process using a unique, multidisciplinary approach combining state of the art imaging techniques and high throughput protein analysis. The anticipated outcomes will be to define the molecular steps that govern the membrane-bound machinery on endosomes that directs endosomal maturation. This should provide significant benefits in delineating a process that is linked to almost all aspects of cell life.Read moreRead less
New targets for antiviral therapies. The ability of dangerous viruses to cause lethal disease depends on their capacity to evade the immune system of infected hosts. This project will uncover at the molecular level the strategies used by viruses to disable immune responses; this will identify new ways to treat incurable diseases, by disabling the virus' defences against the immune system.
Phosphoinositide regulation of lysosome reformation during autophagy. This project aims to investigate a new critical step in the autophagy pathway, autophagic lysosome reformation, a fundamental, evolutionarily conserved mechanism for cellular homeostasis. By combining gene function studies with advanced cellular imaging techniques, this project will investigate the dynamic membrane changes that drive this lysosome recycling pathway and how it is regulated by a hierarchical succession of specif ....Phosphoinositide regulation of lysosome reformation during autophagy. This project aims to investigate a new critical step in the autophagy pathway, autophagic lysosome reformation, a fundamental, evolutionarily conserved mechanism for cellular homeostasis. By combining gene function studies with advanced cellular imaging techniques, this project will investigate the dynamic membrane changes that drive this lysosome recycling pathway and how it is regulated by a hierarchical succession of specific enzymes. The expected outcome will be to re-define the archetypical autophagy pathway and characterise novel mechanisms by which it is controlled. This project will reveal new fundamental biological processes, and act as a framework for developing new imaging modalities and tools for studying autophagy.Read moreRead less
Interrogating a novel protein scaffold that coordinates signal transduction and molecular motor function. The inside of a cell is an extremely crowded environment and the precise location of each component is carefully controlled. This project will unravel the protein machinery involved in transporting cargos in cells as they divide and identify new protein targets for the development of next generation anti-cancer drugs.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100046
Funder
Australian Research Council
Funding Amount
$289,381.00
Summary
A fast fluorescence lifetime imaging microscope to track protein dynamics. This project aims to establish a fast fluorescence lifetime imaging microscope that can track the intracellular journey of a protein throughout the entire structural framework of a living cell. By coupling single particle tracking technology with a cutting-edge fluorescence lifetime camera, this one-of-a-kind microscope will enable protein mobility and interaction to be spatially mapped with unprecedented temporal resolut ....A fast fluorescence lifetime imaging microscope to track protein dynamics. This project aims to establish a fast fluorescence lifetime imaging microscope that can track the intracellular journey of a protein throughout the entire structural framework of a living cell. By coupling single particle tracking technology with a cutting-edge fluorescence lifetime camera, this one-of-a-kind microscope will enable protein mobility and interaction to be spatially mapped with unprecedented temporal resolution. The benefit of this technology is that it will enable scientists in Australia to image, for the first time, the biophysical mechanism by which a protein navigates intracellular architecture to regulate a complex biological function at the single molecule level.Read moreRead less