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.
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
Retromer directs membrane protein trafficking within the endosome. The exposure of proteins to the extracellular environment is dependent on how the travel through the various regions of the cell. The work will lead to a richer understanding of how this process is regulated by protein complexes. These complexes act within cells to drive the formation of membrane transport tubules containing cargo molecules.
Making muscle: molecular dissection of membrane domain formation. For a muscle to contract efficiently in response to an electrical signal it requires the formation of an extensive system of hollow membranous tubules through which the signal can be propagated. This proposal addresses the molecular mechanisms involved in the formation of this tubule system in skeletal muscle. This project will develop cell biology in a whole organism rather than a cell culture system and provide a new framework f ....Making muscle: molecular dissection of membrane domain formation. For a muscle to contract efficiently in response to an electrical signal it requires the formation of an extensive system of hollow membranous tubules through which the signal can be propagated. This proposal addresses the molecular mechanisms involved in the formation of this tubule system in skeletal muscle. This project will develop cell biology in a whole organism rather than a cell culture system and provide a new framework for Australian and international cell biologists. It will generate new knowledge, train young Australian scientists, help build international collaborative networks and engage the public outside the research community.Read moreRead less
The endosome at atomic resolution. The project seeks to improve understanding of intracellular transport. The transport of proteins is essential for controlling the interactions of a cell with its environment, and for regulating a huge number of cell signalling events. The retromer protein complex is a central mediator of intracellular trafficking in organelles called endosomes. It is vital for normal cell homeostasis in all eukaryotic organisms, and is an emerging target for treatment of human ....The endosome at atomic resolution. The project seeks to improve understanding of intracellular transport. The transport of proteins is essential for controlling the interactions of a cell with its environment, and for regulating a huge number of cell signalling events. The retromer protein complex is a central mediator of intracellular trafficking in organelles called endosomes. It is vital for normal cell homeostasis in all eukaryotic organisms, and is an emerging target for treatment of human neurodegenerative diseases. This project plans to use a combination of cutting-edge X-ray crystallographic and electron microscopy approaches to develop a multi-scale, pseudo-atomic structure of retromer and key regulatory proteins to understand how this multi-component protein machinery is assembled to control intracellular transport.Read moreRead less
Regulation of human immunodeficiency virus type 1 (HIV-1) replication by viral and cellular proteins. Using a mouse model, human cells will be treated with a very powerful antiviral protein using a gene therapy approach so as to block the human immunodeficiency virus (HIV) from growing. By learning how this antiviral protein works, this project will assist in the development of new strategies to treat HIV infection.
Structural analysis of a novel plasma membrane coat complex. The plasma membrane of mammalian cells forms a crucial barrier between the cell and the outside world. This project investigates how a newly-discovered family of proteins work together to generate specialised regions of the plasma membrane called caveolae.
Structural basis for the assembly of caveolae. Caveolae are small invaginations of the plasma membrane and are a characteristic feature of eukaryotic cells. Described morphologically in the early 1950s their many important functions are only just beginning to be revealed. Caveolae are multifunctional organelles that play a vital role in normal cellular processes such as signalling and membrane homeostasis, and are perturbed in cancer, lipid storage and muscle diseases. A new family of coat prote ....Structural basis for the assembly of caveolae. Caveolae are small invaginations of the plasma membrane and are a characteristic feature of eukaryotic cells. Described morphologically in the early 1950s their many important functions are only just beginning to be revealed. Caveolae are multifunctional organelles that play a vital role in normal cellular processes such as signalling and membrane homeostasis, and are perturbed in cancer, lipid storage and muscle diseases. A new family of coat proteins called cavins have recently been discovered. Cavins are essential for the formation of caveolae, and this project seeks to understand how these multiprotein complexes are assembled at the membrane interface and control caveola function at the molecular level.Read moreRead less