How do protein quality control mechanisms maintain neuronal ageing? This project aims to interrogate how mechanisms of protein quality control act in the brain - an organ that is particularly vulnerable to a high load of misfolded protein - to maintain normal physiology during ageing. This project expects to make advances in cellular biochemistry and neuroscience, using an innovative proximity labelling approach to identify quality control regulators in neurons that specifically engage with misf ....How do protein quality control mechanisms maintain neuronal ageing? This project aims to interrogate how mechanisms of protein quality control act in the brain - an organ that is particularly vulnerable to a high load of misfolded protein - to maintain normal physiology during ageing. This project expects to make advances in cellular biochemistry and neuroscience, using an innovative proximity labelling approach to identify quality control regulators in neurons that specifically engage with misfolded proteins during ageing, within the nervous system of a living animal. Expected outcomes of this project will generate new knowledge of brain physiology and ageing relevant to all animals. This should provide significant benefits, such as a greater understanding of long-term brain functions including memory.Read moreRead less
Microtubule structure in nervous system repair. This Project aims to investigate the role of structural and functional cellular components known as microtubules in nervous system regeneration. This Project aims to use innovative approaches in confocal and electron microscopy, genetics, and cell biology, with the expectation of generating new knowledge into nervous system repair. Expected outcomes of this Project include a comprehensive description of how microtubules are rearranged following ner ....Microtubule structure in nervous system repair. This Project aims to investigate the role of structural and functional cellular components known as microtubules in nervous system regeneration. This Project aims to use innovative approaches in confocal and electron microscopy, genetics, and cell biology, with the expectation of generating new knowledge into nervous system repair. Expected outcomes of this Project include a comprehensive description of how microtubules are rearranged following nervous system injury and the importance of microtubule modifying proteins in promoting regeneration. This should provide significant benefits in our understanding of the cellular mechanisms behind nervous system repair, and offer new approaches for promoting regeneration after injury.Read moreRead less
Awaking quiescent neural stem cells. This project aims to generate new knowledge in the area of the evolutionary size of animals and plants, which is determined by intrinsic cell regulation and is constrained by nutrient availability. Brain size is perhaps the most profound example of this. Brain size regulation is underpinned by control of proliferation of neural stem cells (NSCs). Using Drosophila NSCs, the project will examine how nutrients impact on NSC quiescence versus activation, a key ch ....Awaking quiescent neural stem cells. This project aims to generate new knowledge in the area of the evolutionary size of animals and plants, which is determined by intrinsic cell regulation and is constrained by nutrient availability. Brain size is perhaps the most profound example of this. Brain size regulation is underpinned by control of proliferation of neural stem cells (NSCs). Using Drosophila NSCs, the project will examine how nutrients impact on NSC quiescence versus activation, a key characteristic of stem cell control throughout evolution. This will increase our understanding of how energy metabolism and nutrition influence organ size control in multicellular organisms, by determining how organs communicate with each other to convert nutrient signals to action stem cell proliferation.Read moreRead less
Revealing the mechanobiology of neural tube formation. This project aims to understand the formation of the neural tube; a fundamental tissue structure that generates the brain and the spinal cord. Using interdisciplinary approaches and exploiting recent advances in transgenic and imaging technologies, we expect to reveal the complex interplay between cells and their environment that generates mechanical forces to direct neural tissue formation. Outcomes include knowledge of previously intractab ....Revealing the mechanobiology of neural tube formation. This project aims to understand the formation of the neural tube; a fundamental tissue structure that generates the brain and the spinal cord. Using interdisciplinary approaches and exploiting recent advances in transgenic and imaging technologies, we expect to reveal the complex interplay between cells and their environment that generates mechanical forces to direct neural tissue formation. Outcomes include knowledge of previously intractable developmental processes, training of future scientists and development of international collaborations. This should provide enhanced imaging capacity, a higher quality scientific workforce and position Australia at the forefront of cell and developmental biology.Read moreRead less
Shaping the vertebrate brain: defining the cellular and genetic drivers . This project aims to uncover specific cellular and genetic mechanisms that control growth and shape of the brain. How brain shape and size changes during evolution of vertebrates is enigmatic but important to know for better understanding of behaviour and function of intact and diseased brain. The project aims to assemble team of national and international experts to build international capacity and unique genetics model t ....Shaping the vertebrate brain: defining the cellular and genetic drivers . This project aims to uncover specific cellular and genetic mechanisms that control growth and shape of the brain. How brain shape and size changes during evolution of vertebrates is enigmatic but important to know for better understanding of behaviour and function of intact and diseased brain. The project aims to assemble team of national and international experts to build international capacity and unique genetics model to generate new knowledge of the cellular and genetic components that drive evolution of different brain parts and shapes the vertebrate brain. In doing so the project aims to provide research training, excellence and knowledge that in future may benefit health and the society. Read moreRead less
Microfluidic models of the CNS: Understanding cells, circuits & synapses. Aims: We aim to develop new cell culture platforms to form defined networks of brain cells. These platforms will be used to determine the critical mechanisms underpinning central nervous system function.
Significance: The devices developed will enable an unprecedented capacity to monitor changes throughout a network, with analysis at the level of the synapse, cell and circuit.
Expected outcomes: We will advance knowledge ....Microfluidic models of the CNS: Understanding cells, circuits & synapses. Aims: We aim to develop new cell culture platforms to form defined networks of brain cells. These platforms will be used to determine the critical mechanisms underpinning central nervous system function.
Significance: The devices developed will enable an unprecedented capacity to monitor changes throughout a network, with analysis at the level of the synapse, cell and circuit.
Expected outcomes: We will advance knowledge regarding the function of the CNS and deliver complex human cellular systems, that have both discovery and commercial applications.
Benefit: These platforms will have subsequent application revealing the mechanisms underlying numerous neurological diseases, with capacity to upscale for rapid drug screening.
Read moreRead less
Engineering new tools to aid structure determination of membrane proteins. This project aims to address the inherent instability of G protein-coupled receptors (GPCRs), which are cell-surface proteins that are a major drug targets. The instability of GPCRs has resulted in a lack of atomic-level structural information that has hindered structure-based drug discovery efforts. This project expects to develop tools to improve GPCR stability and streamline the structure determination process. Project ....Engineering new tools to aid structure determination of membrane proteins. This project aims to address the inherent instability of G protein-coupled receptors (GPCRs), which are cell-surface proteins that are a major drug targets. The instability of GPCRs has resulted in a lack of atomic-level structural information that has hindered structure-based drug discovery efforts. This project expects to develop tools to improve GPCR stability and streamline the structure determination process. Project outcomes are intended to lead to significant advances in membrane protein structure determination and will have a substantial impact on future research in the pharmaceutical industry.Read moreRead less