Understanding the molecular mechanisms regulating neuronal fusion. Neurons are tightly connected individual cells that communicate through chemical and electrical signals, and this project aims to discover the key molecules that allow these cells to remain as individual units without fusing with each other. The nervous system, unlike other tissues, is made of discrete individual cells, connected by chemical and electrical synapses but not by cytoplasmic continuity. However, how this is achieved ....Understanding the molecular mechanisms regulating neuronal fusion. Neurons are tightly connected individual cells that communicate through chemical and electrical signals, and this project aims to discover the key molecules that allow these cells to remain as individual units without fusing with each other. The nervous system, unlike other tissues, is made of discrete individual cells, connected by chemical and electrical synapses but not by cytoplasmic continuity. However, how this is achieved and how neurons maintain their individuality during development, remodelling and ageing is unknown. The project aims to address this gap using a genetic approach and the nematode Caenorhabditis elegans as an experimental system. The results may provide insights into how the nervous system develops and functions.Read moreRead less
How membrane-sensing proteins regulate synaptic vesicle endocytosis. This project aims to elucidate the molecular basis of how membrane-sensing proteins regulate synaptic vesicle endocytosis in mammalian central neurons. Nerve cells’ ability to transmit cellular information to one another is important for normal brain function. Efficient communication between neurons through sustained neurotransmitter release relies on the continuous supply of synaptic vesicles in presynaptic nerve terminals. Ke ....How membrane-sensing proteins regulate synaptic vesicle endocytosis. This project aims to elucidate the molecular basis of how membrane-sensing proteins regulate synaptic vesicle endocytosis in mammalian central neurons. Nerve cells’ ability to transmit cellular information to one another is important for normal brain function. Efficient communication between neurons through sustained neurotransmitter release relies on the continuous supply of synaptic vesicles in presynaptic nerve terminals. Key to this process are membrane dynamics during synaptic vesicle retrieval, but the precise underlying mechanisms are not well understood. The intended outcome of this project is insights into the molecular mechanisms of synaptic transmission, the fundamental process of brain function, increasing understanding of physiological processes such as muscle movement, vision, hearing, touch, learning and memory.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100078
Funder
Australian Research Council
Funding Amount
$800,000.00
Summary
Live molecular imaging using super resolution microscopy, two photon and spinning disk confocal microscopy. With recent developments of super-resolution microscopy it is now feasible to image single molecules within the cellular environment in living cells. Such insight is key to understanding basic biological interactions that govern the wiring of our brain, communications between cells and neurons and cell-cell adhesion.
Nuclear functions of the microtubule-associated protein tau. The important neuronal protein, tau, has cellular functions that go far beyond its established role in stabilising microtubules. This project will determine which tau species are nuclearly localised, what the consequences are for nuclear functions, and how phosphorylation regulates this localisation.
A novel click chemistry approach to identify learning and memory molecules. This project seeks to contribute to a deeper understanding at a molecular level of how memory is stored in neurons. Long-term memories do not form immediately after learning. Initially fragile, they become resistant to disruption through a process known as memory consolidation. In a second process, termed reconsolidation, pre-established memories are updated and re-stored. Both processes depend on protein synthesis, but ....A novel click chemistry approach to identify learning and memory molecules. This project seeks to contribute to a deeper understanding at a molecular level of how memory is stored in neurons. Long-term memories do not form immediately after learning. Initially fragile, they become resistant to disruption through a process known as memory consolidation. In a second process, termed reconsolidation, pre-established memories are updated and re-stored. Both processes depend on protein synthesis, but little is known about the particular sets of proteins that are involved. The project plans to apply a novel biochemical protocol to a newly established transgenic mouse model that allows the visualisation and identification of newly synthesised proteins in the hippocampus, a brain area that is critical in memory formation.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
Identifying the pathways employed by growth hormone to regulate the proliferation of adult neural stem cells. As stem cells underpin the maintenance and regeneration of the brain and are known to decline in number and competence with age; understanding exactly how these cells are regulated is of broad national benefit. Furthermore, given the regulatory role of growth hormone throughout the body, insights gained from this project should lead to the discovery of novel therapeutic targets both with ....Identifying the pathways employed by growth hormone to regulate the proliferation of adult neural stem cells. As stem cells underpin the maintenance and regeneration of the brain and are known to decline in number and competence with age; understanding exactly how these cells are regulated is of broad national benefit. Furthermore, given the regulatory role of growth hormone throughout the body, insights gained from this project should lead to the discovery of novel therapeutic targets both within and outside the nervous system, ultimately leading to preventative and restorative strategies for maintaining good health. Finally, this Proposal is of significant national benefit as it will undoubtedly advance our knowledge base in stem cell biology, helping to maintain Australia as a global leader in stem cell research.Read moreRead less