Deciphering the regulatory principles of metazoan development. This proposal aims to elucidate how regulatory elements in the genome, known as enhancers, determine the identity and function of animal tissues. Currently, it is believed that enhancers cannot be traced across evolutionarily distant animals. The project uses novel concepts, computational and molecular approaches to identify deeply conserved enhancers. It further dissects the mechanism of function by proteomics and high-throughput ge ....Deciphering the regulatory principles of metazoan development. This proposal aims to elucidate how regulatory elements in the genome, known as enhancers, determine the identity and function of animal tissues. Currently, it is believed that enhancers cannot be traced across evolutionarily distant animals. The project uses novel concepts, computational and molecular approaches to identify deeply conserved enhancers. It further dissects the mechanism of function by proteomics and high-throughput genomics. The expected outcomes will overturn our current view on enhancer evolution and reposition our understanding of how enhancers are functionally encoded in the genome. The work is an important contribution to understanding cellular complexity and species evolution with wide-ranging impact in genetics.Read moreRead less
Visualising genetic mosaicism during development. Genetic diversity is the variation in DNA sequence among individuals. We now know that there are also differences in the DNA sequences of cells within the same individual, known as genetic mosaicism. The aims of this proposal are 1) to develop a system to visualise genetic mosaicism 2) arising during embryonic development and 3) in the brain, driven by mobile DNA activity. The expected outcome of this proposal is an unprecedented understanding of ....Visualising genetic mosaicism during development. Genetic diversity is the variation in DNA sequence among individuals. We now know that there are also differences in the DNA sequences of cells within the same individual, known as genetic mosaicism. The aims of this proposal are 1) to develop a system to visualise genetic mosaicism 2) arising during embryonic development and 3) in the brain, driven by mobile DNA activity. The expected outcome of this proposal is an unprecedented understanding of the scope and consequences of mobile DNA-driven mosaicism. This work will have significant impacts in developmental genetics and neurogenetics, and has the benefit of introducing an innovative experimental system with the potential to spark international scientific collaboration and recognition.Read moreRead less
Organising Intracellular Compartments by Formation of Transport Carriers. This project aims to investigate the cellular components which generate carriers that transport material between compartments within the cell. The process of sorting proteins and sending them to the right place is a fundamental mechanism critical to understand how individual proteins function as the move around within cells. The generated knowledge about how cells organise themselves through the movement of proteins betwee ....Organising Intracellular Compartments by Formation of Transport Carriers. This project aims to investigate the cellular components which generate carriers that transport material between compartments within the cell. The process of sorting proteins and sending them to the right place is a fundamental mechanism critical to understand how individual proteins function as the move around within cells. The generated knowledge about how cells organise themselves through the movement of proteins between endosomal intracellular compartments will provide significant benefits by enhancing our capacity to understand this conserved cellular pathway which ensures the integrity of all cellular processes including signalling, communication, homeostasis and development.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
Molecular basis of glutamate receptor trafficking in neuronal plasticity . 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 how the trafficking of glutamate recep ....Molecular basis of glutamate receptor trafficking in neuronal plasticity . 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 how the trafficking of glutamate receptors is regulated in neurons during plasticity and learning. The outcomes will enhance our understanding of how neural plasticity is generated and maintained, knowledge that is critical for our understanding of the cellular correlates of information, sensory and motor processing, as well as learning, memory and cognition.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL210100107
Funder
Australian Research Council
Funding Amount
$2,960,000.00
Summary
Tracking nanoparticles: from cell culture to in vivo delivery. Understanding how cells function in the ‘real-time’ context of a living organism is a key challenge in the new era of cell biology. Using super-resolution light microscopy and state-of-the-art correlative electron microscopy together with model systems, this Fellowship aims to deliver new understandings of cells in their natural environment. Significantly, the project will elucidate how proteins or nanoparticles pass from the bloodst ....Tracking nanoparticles: from cell culture to in vivo delivery. Understanding how cells function in the ‘real-time’ context of a living organism is a key challenge in the new era of cell biology. Using super-resolution light microscopy and state-of-the-art correlative electron microscopy together with model systems, this Fellowship aims to deliver new understandings of cells in their natural environment. Significantly, the project will elucidate how proteins or nanoparticles pass from the bloodstream into tissues and then into cells, and in doing so deliver much-needed knowledge of protein and particle trafficking in situ. Outcomes and benefits include leading-edge fundamental science into the function of cells, education, outreach and building of Australian capacity in high-demand skill sets.Read moreRead less
Microbiome Regulation of the Host Mitochondrial Genome. This project aims to describe newly discovered processes by which bacteria that reside in the gut of an animal influences host mitochondria, the powerhouses of the cell. Using advanced genetic and molecular methodologies, this project aims to generate new knowledge on improving mitochondrial function as well as advance our understanding of the emerging field of microbiome research. Expected outcomes include a novel and universal technology ....Microbiome Regulation of the Host Mitochondrial Genome. This project aims to describe newly discovered processes by which bacteria that reside in the gut of an animal influences host mitochondria, the powerhouses of the cell. Using advanced genetic and molecular methodologies, this project aims to generate new knowledge on improving mitochondrial function as well as advance our understanding of the emerging field of microbiome research. Expected outcomes include a novel and universal technology platform in which to engineer small molecules and probiotics to improve mitochondrial health and enhance fitness in a range of animals. This should provide significant benefits, through both scientifically relevant outcomes and economic benefits through technological advancements.Read moreRead less
Dynamic DNA structure states and memory formation. Activity-induced gene expression is central to neural plasticity, learning, and memory; however, the underlying mechanisms of these processes in the brain have yet to be fully resolved. The aim of this proposal is to obtain a deeper understanding of the functional relationship between genes and brain function. By elucidating the full repertoire of epigenetic mechanisms in the brain during learning and the formation of memory, it is hoped that t .... Dynamic DNA structure states and memory formation. Activity-induced gene expression is central to neural plasticity, learning, and memory; however, the underlying mechanisms of these processes in the brain have yet to be fully resolved. The aim of this proposal is to obtain a deeper understanding of the functional relationship between genes and brain function. By elucidating the full repertoire of epigenetic mechanisms in the brain during learning and the formation of memory, it is hoped that the true nature of brain adaptation across the lifespan will be revealed. Findings which may then provide new opportunities to strengthen, maintain and optimise cognitive function.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
Unveiling the nanoscale organisation and dynamics of synaptic vesicle pools. This project aims to uncover the role of key molecules in allowing brain cells to actively communicate with each other. Communication between neurons relies on the fusion of synaptic vesicles containing neurotransmitters with the presynaptic plasma membrane. The addition of vesicular membrane is transient as the vesicles quickly reform from the plasma membrane and refill with neurotransmitter ready for subsequent rounds ....Unveiling the nanoscale organisation and dynamics of synaptic vesicle pools. This project aims to uncover the role of key molecules in allowing brain cells to actively communicate with each other. Communication between neurons relies on the fusion of synaptic vesicles containing neurotransmitters with the presynaptic plasma membrane. The addition of vesicular membrane is transient as the vesicles quickly reform from the plasma membrane and refill with neurotransmitter ready for subsequent rounds of fusion. This recycling process ensures that neurons communicate efficiently, however the underpinning mechanism is unknown. This project aims to use a recently developed single synaptic vesicle super-resolution tracking method to establish how Myosin-VI and Synapsin-IIa orchestrate this recycling in central and peripheral neurons. It will explain how neurons manage to preserve their ability to communicate.Read moreRead less