Role of Tau and Synapsin in clustering distinct synaptic vesicle pools. Neurotransmitter-containing synaptic vesicles (SVs) are highly enriched in specific locations of brain cells, called nerve terminals via an unknown mechanism. The clustering of SVs depend on the phosphorylation of an unknown set of proteins. Two key proteins have been identified for their phosphorylation pattern and their potential to form membraneless compartments: tau and synapsin. Using highly innovative single-molecule s ....Role of Tau and Synapsin in clustering distinct synaptic vesicle pools. Neurotransmitter-containing synaptic vesicles (SVs) are highly enriched in specific locations of brain cells, called nerve terminals via an unknown mechanism. The clustering of SVs depend on the phosphorylation of an unknown set of proteins. Two key proteins have been identified for their phosphorylation pattern and their potential to form membraneless compartments: tau and synapsin. Using highly innovative single-molecule super-resolution microscopy, this grant will uncover how tau and synapsin phosphorylation controls the clustering of SVs thereby regulating neurotransmitter release. This project uses improved nanoscopic technologies and international
collaborations to unveil novel avenues in our understanding of brain communication.Read moreRead less
Super-resolving neurotransmitter release machinery during priming. Understanding how neurons communicate in the brain is one of the most challenging feats in neuroscience. The assembly of the molecular machinery involved in communication is unknown. This grant aims to understand how priming molecules Munc18 and Munc13, undergo a series of molecular steps leading to the release of neurotransmitter. Using innovative single-molecule super-resolution imaging we will uncover how Munc18 and Munc13 are ....Super-resolving neurotransmitter release machinery during priming. Understanding how neurons communicate in the brain is one of the most challenging feats in neuroscience. The assembly of the molecular machinery involved in communication is unknown. This grant aims to understand how priming molecules Munc18 and Munc13, undergo a series of molecular steps leading to the release of neurotransmitter. Using innovative single-molecule super-resolution imaging we will uncover how Munc18 and Munc13 are spatially and temporally organised to mediate communication. By elucidating how nanoclustering of these essential proteins enables key steps, this grant will reveal how brain cells communicate. This may then provide new opportunities to optimise underlying functions such as cognition, sensory and motor processing.Read moreRead less
Click chemistry to reveal how neurons and glia shape perineuronal nets . The extracellular matrix (ECM) and its perineuronal nets (which are net-like structures with holes wrapped around neurons) are largely underexplored, despite representing a remarkable 20% of the brain’s total volume and having been suggested to be involved in many brain functions. Interestingly, digestion of the ECM improves learning and memory, but deficits return once the ECM has reformed. However, how this ECM remodellin ....Click chemistry to reveal how neurons and glia shape perineuronal nets . The extracellular matrix (ECM) and its perineuronal nets (which are net-like structures with holes wrapped around neurons) are largely underexplored, despite representing a remarkable 20% of the brain’s total volume and having been suggested to be involved in many brain functions. Interestingly, digestion of the ECM improves learning and memory, but deficits return once the ECM has reformed. However, how this ECM remodelling is organised at a cell-type level is not understood. Here we aim to close this knowledge gap, using cutting-edge technology including bioconjugation and ultrasound-mediated cargo delivery. Together, this project aims to contribute to a deeper understanding of this major brain compartment in neuronal function. Read moreRead less
Migration-Dependent Signalling in Macrophages . The project aims to investigate a mechanism of communication used by immune cells to guide each other towards sites of damage. The project will characterise newly revealed cell signalling membrane trails left behind by migrating cells, utilising biochemistry, innovative imaging and microscopy and a transparent zebrafish model to view cell migration through living tissues. Expected outcomes include new fundamental knowledge in the area of immune cel ....Migration-Dependent Signalling in Macrophages . The project aims to investigate a mechanism of communication used by immune cells to guide each other towards sites of damage. The project will characterise newly revealed cell signalling membrane trails left behind by migrating cells, utilising biochemistry, innovative imaging and microscopy and a transparent zebrafish model to view cell migration through living tissues. Expected outcomes include new fundamental knowledge in the area of immune cell migration with relevance to the basic biology of inflammation, repair and regeneration and new innovations for cell imaging. Significant benefits are expected to arise from this new knowledge and from advanced skills training and improved national capabilities in bio-imaging and analysis.Read moreRead less
Heat regulation by the fibre types in muscle. Mammals maintain a constant core body temperature by generating heat in resting muscles in response to changes in the environmental temperatures. This project aims to show how the fibre types that make up skeletal muscles regulate heat generation against other muscle function, to maintain core body temperature and the normal movement and posture of the mammal. Project outcomes include defining, for the first time, how heat generation in the muscles o ....Heat regulation by the fibre types in muscle. Mammals maintain a constant core body temperature by generating heat in resting muscles in response to changes in the environmental temperatures. This project aims to show how the fibre types that make up skeletal muscles regulate heat generation against other muscle function, to maintain core body temperature and the normal movement and posture of the mammal. Project outcomes include defining, for the first time, how heat generation in the muscles of the body is regulated. This should provide critical knowledge of mammalian evolution and ways to manipulate metabolism, which may provide ways to assist with achieving a desired meat quality and yield in beef and other commercially important animals.Read moreRead less
Regulated muscle-based thermogenesis for body temperature regulation. Mammals maintain a constant core body temperature by generating heat in resting muscles in response to changes in the environmental temperatures. This project aims to show how the skeletal muscles that are closer to the body core contribute the majority of heat, how the muscles of the limbs have their heat generation curtailed as necessary, and how this is coordinated by the body in response to ambient temperature. Project out ....Regulated muscle-based thermogenesis for body temperature regulation. Mammals maintain a constant core body temperature by generating heat in resting muscles in response to changes in the environmental temperatures. This project aims to show how the skeletal muscles that are closer to the body core contribute the majority of heat, how the muscles of the limbs have their heat generation curtailed as necessary, and how this is coordinated by the body in response to ambient temperature. Project outcomes include defining, for the first time, how heat generation in the muscles of the body is regulated. This should provide critical knowledge of mammalian evolution and ways to manipulate metabolism, which may provide ways to assist the production of meat by managing hypothermia and hyperthermia risk in agriculture.Read moreRead less
Interrogating the extremes of skeletal muscle plasticity in vertebrates. This project aims to interrogate how muscles adapt to growth and endurance stimuli at different stages of life, relevant to addressing challenges facing the world’s ageing population. Using innovative gene technologies and molecular physiology in zebrafish and mice, this project will answer important, unresolved questions in muscle biology. The project will generate knowledge needed to develop interventions to improve quali ....Interrogating the extremes of skeletal muscle plasticity in vertebrates. This project aims to interrogate how muscles adapt to growth and endurance stimuli at different stages of life, relevant to addressing challenges facing the world’s ageing population. Using innovative gene technologies and molecular physiology in zebrafish and mice, this project will answer important, unresolved questions in muscle biology. The project will generate knowledge needed to develop interventions to improve quality of life for older Australians and address the physical realities of an ageing workforce. Benefits extend to enhancing workplace safety and productivity, improving farming efficiencies for livestock and aquaculture industries, and training emerging leaders in the biological sciences.Read moreRead less
Decoding the spatiotemporal control of DNA replication and repair. DNA replication is the fundamental mechanism of genetic inheritance and essential for all cellular life. This project aims to inform our understanding of how human cells coordinate the DNA replication machinery in time and space to accurately copy the human genome. By applying multiple innovative approaches and employing an interdisciplinary research team, this project is anticipated to generate new knowledge that explains how th ....Decoding the spatiotemporal control of DNA replication and repair. DNA replication is the fundamental mechanism of genetic inheritance and essential for all cellular life. This project aims to inform our understanding of how human cells coordinate the DNA replication machinery in time and space to accurately copy the human genome. By applying multiple innovative approaches and employing an interdisciplinary research team, this project is anticipated to generate new knowledge that explains how the human genome is replicated. This knowledge is expected to generate research publications of high quality and provide economic benefits, such as unlocking new potentially patentable DNA technologies. 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
Regulation of activity-induced glutamate receptor trafficking in neurons. Neurons communicate via synapses, where chemicals (such as glutamate) are released to transmit neuronal signals. This proposal is aimed at understanding the molecular mechanisms of neuronal communication and adaptive plasticity, which are essential for normal brain function. The proposed research will combine biophysical, biochemical, molecular and cell biological assays to elucidate the role of a calcium binding protein i ....Regulation of activity-induced glutamate receptor trafficking in neurons. Neurons communicate via synapses, where chemicals (such as glutamate) are released to transmit neuronal signals. This proposal is aimed at understanding the molecular mechanisms of neuronal communication and adaptive plasticity, which are essential for normal brain function. The proposed research will combine biophysical, biochemical, molecular and cell biological assays to elucidate the role of a calcium binding protein in controlling glutamate receptor trafficking in neurons. The outcomes will enhance our understanding of how neural plasticity is generated and maintained, knowledge that is critical for our understanding of cellular correlates of information, sensory and motor processing, as well as learning, memory and cognition. Read moreRead less