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
Fyn-STEP-Tau axis: the nanoscale mechanisms of synaptic plasticity. This project investigates how brain cells use their molecular machinery to communicate with one another. At the heart of this process lies the synapses, the contact points that connect brain cells. This project will employ an innovative combination of quantitative microscopy techniques, gene knockout mouse models, and advanced computational and mathematical analyses to generate new knowledge on how a crucial set of proteins orga ....Fyn-STEP-Tau axis: the nanoscale mechanisms of synaptic plasticity. This project investigates how brain cells use their molecular machinery to communicate with one another. At the heart of this process lies the synapses, the contact points that connect brain cells. This project will employ an innovative combination of quantitative microscopy techniques, gene knockout mouse models, and advanced computational and mathematical analyses to generate new knowledge on how a crucial set of proteins organises in space and time to regulate synaptic connectivity. This will provide significant benefits, including molecular-level insight into the inner workings of the brain and interdisciplinary training for students. The expected outcomes include a deeper understanding of brain functions, such as learning and memory.Read moreRead less
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
Discovery Early Career Researcher Award - Grant ID: DE200100778
Funder
Australian Research Council
Funding Amount
$390,000.00
Summary
Mapping the neural circuits that underlie emotional learning. This project aims to understand the precise neural circuits that mediate the formation of emotional memories. Recent findings have identified a novel complexity in these circuits and the goal of this proposal is to resolve the underlying mechanism that drives emotional memories. In detail, this project will combine state of the art dual- optical stimulation techniques combined with behaviour-dependent tagging of neurons to investigate ....Mapping the neural circuits that underlie emotional learning. This project aims to understand the precise neural circuits that mediate the formation of emotional memories. Recent findings have identified a novel complexity in these circuits and the goal of this proposal is to resolve the underlying mechanism that drives emotional memories. In detail, this project will combine state of the art dual- optical stimulation techniques combined with behaviour-dependent tagging of neurons to investigate the precise brain circuits linked to emotional learning, an approach that also allows knowledge transfer to other research fields. Expected outcomes and benefits of the project is a significant shift in our understanding of the neural mechanisms that underlie emotional learning.Read moreRead less
Tuning the activating stimulus of voltage-gated sodium channels. This proposal aims to advance fundamental knowledge about how proteins (ion channels) found on the surface of neurons (brain cells and nerves) function as molecular conduits of cell-to-cell electrical communication. We aim to study how molecular probes and structural parts of these proteins affect the local chemical environment of ion channels, and how this leads to fine tuning of the ion channel's sensitivity to the stimulus that ....Tuning the activating stimulus of voltage-gated sodium channels. This proposal aims to advance fundamental knowledge about how proteins (ion channels) found on the surface of neurons (brain cells and nerves) function as molecular conduits of cell-to-cell electrical communication. We aim to study how molecular probes and structural parts of these proteins affect the local chemical environment of ion channels, and how this leads to fine tuning of the ion channel's sensitivity to the stimulus that activates them (cell membrane voltage).
The conceptual knowledge gained from this project would advance our understanding of a fundamental physiological process and facilitate the development of drugs that regulate ion channel function, such as anti-epileptics, analgesics and insecticides.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
Deciphering novel cross-talk between innate cytokine receptors. Understanding the basic functions of interferons, how they signal to cells, is central to understanding fundamental immunity. Interferons are crucial molecules of the immune system that are important for normal cell development and they protect the body from viral infection and cancer but can be deleterious in different autoimmune diseases and trauma settings. Preliminary Data shows there is a pathway of interferon signalling that h ....Deciphering novel cross-talk between innate cytokine receptors. Understanding the basic functions of interferons, how they signal to cells, is central to understanding fundamental immunity. Interferons are crucial molecules of the immune system that are important for normal cell development and they protect the body from viral infection and cancer but can be deleterious in different autoimmune diseases and trauma settings. Preliminary Data shows there is a pathway of interferon signalling that has previously been overlooked. This project aims to understand how this pathway works and how it contributes to the normal workings of cells. This fundamental science has future consequences for the design of vaccines and for the design of therapeutics to treat diseases that show defective interferon signalling.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200101300
Funder
Australian Research Council
Funding Amount
$423,711.00
Summary
Lipopolysaccharide-induced macrophage extracellular traps in host defence. The innate immune system is the first line of defence against invading microbes. Macrophages are key innate immune cells that deploy antimicrobial responses to clear infection and restore health. There are many critical unanswered questions on the molecular mechanisms that drive macrophage inflammatory and antimicrobial pathways. This project aims to elucidate a novel inflammatory mechanism that immobilises and kills inva ....Lipopolysaccharide-induced macrophage extracellular traps in host defence. The innate immune system is the first line of defence against invading microbes. Macrophages are key innate immune cells that deploy antimicrobial responses to clear infection and restore health. There are many critical unanswered questions on the molecular mechanisms that drive macrophage inflammatory and antimicrobial pathways. This project aims to elucidate a novel inflammatory mechanism that immobilises and kills invading bacteria via newly discovered structures made by dying macrophages called extracellular traps. Insight we gain by interrogating this immune cell signalling pathway, called the non-canonical inflammasome, will add valuable knowledge to our fundamental understanding of mammalian inflammation and anti-microbial responses
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Discovery Early Career Researcher Award - Grant ID: DE240101055
Funder
Australian Research Council
Funding Amount
$448,737.00
Summary
How blood vessel stiffness regulates their growth and maintenance. This project aims to reveal an unidentified molecular mechanism of how endothelial cells in the walls of blood vessels detect stiffness of the surrounding environment in order to regulate blood vessel growth and maintenance. The results are expected to advance the emerging field of mechanobiology by combining cutting-edge cell biology and microscopy techniques carried out in novel 3D cell culture and unique quail models. The bene ....How blood vessel stiffness regulates their growth and maintenance. This project aims to reveal an unidentified molecular mechanism of how endothelial cells in the walls of blood vessels detect stiffness of the surrounding environment in order to regulate blood vessel growth and maintenance. The results are expected to advance the emerging field of mechanobiology by combining cutting-edge cell biology and microscopy techniques carried out in novel 3D cell culture and unique quail models. The benefits of these outcomes include generation of knowledge on the impact of tissue stiffness on the signalling mechanisms that drive formation and maintenance of blood vessels. In the long term, this fundamental understanding could give rise to major developments in emerging industries such as organ bioengineering.Read moreRead less
Pyroptotic macrophages posthumously sculpt immune responses. The life of an organism relies on the timely birth and death of its cells. Importantly, it is crucial for cells to die not only at the right time, but also in an appropriate manner. This proposal investigates a cell death pathway that triggers potent immune responses. This proposal seeks to reveal precisely how cell death sculpts immune responses. Expected outcomes include new insights into how immune cells die, and how they instruct i ....Pyroptotic macrophages posthumously sculpt immune responses. The life of an organism relies on the timely birth and death of its cells. Importantly, it is crucial for cells to die not only at the right time, but also in an appropriate manner. This proposal investigates a cell death pathway that triggers potent immune responses. This proposal seeks to reveal precisely how cell death sculpts immune responses. Expected outcomes include new insights into how immune cells die, and how they instruct immune responses from beyond the grave. Project benefits include a fundamental understanding of how cell death signalling sculpts tissue immune responses, and knowledge of how to manipulate cell death responses for future basic research and commercial applications beyond this project.Read moreRead less