Investigations Into The Role Of Neurotransmitter Release From Astrocytes In The Hippocampus
Funder
National Health and Medical Research Council
Funding Amount
$233,057.00
Summary
While ten per cent of the brain consists of neurons, responsible for movement and thinking, the rest is made up of cells called glial cells. Scientists have always believed that astrocytes, a type of glial cell known for its distinctive star like shape, provide only mechanical and metabolic support for neurons, by maintaining the environment in the brain. This project will investigate how astrocytes actively regulate neuronal activity and may have important roles to play in learning and memory.
Phosphatase Regulators Mediate Long-term Changes In Presynaptic Terminals
Funder
National Health and Medical Research Council
Funding Amount
$984,163.00
Summary
The strength of communication between each nerve cell in the brain depends on how active that nerve cell has been. This enables the brain to be adaptable and is a way for the brain to set up circuits that underlie how we learn and remember. More or less release of chemical messengers (neurotransmitters) into nerve cell junctions changes the strength of nerve cell communication. We have discovered a new chemical signalling pathway controlling neurotransmitter release.
Unravelling A New Fatty Acid Pathway Involved In Neuroexocytosis And Memory
Funder
National Health and Medical Research Council
Funding Amount
$539,631.00
Summary
This proposal build on the establishment by our laboratory of the assay capable of detecting free fatty acids, with great accuracy and sensitivity. Using this assay we have uncovered a completely new pathway highlighting the production of saturated free fatty acids linked to learning and memory. We will fully define how this pathway is regulated in the brain.
Creating A Phenotypic Catalogue Of Synaptic Vesicle Cycling Disorders
Funder
National Health and Medical Research Council
Funding Amount
$876,975.00
Summary
Developmental disorders affect 2-5% of children. In order to understand how these mutations will likely affect neurological function in these individuals, and to develop a tailored care and treatment program, we must first understand how these mutations affect neuronal communication. This research program will identify the underlying cause of neurological dysfunction in a subset of these disorders (synaptic vesicle cycle disorders), affecting 1200-3000 children in Australia alone.
Vesicular Trafficking Pathways Underpinning Neuronal Secretion And Survival
Funder
National Health and Medical Research Council
Funding Amount
$697,209.00
Summary
Plethora of diseases of the nervous system are caused by defects in vesicular trafficking including neurodegenerative diseases such as Alzheimer’s disease. I will explore the mechanisms underpinning synaptic vesicular trafficking using novel super resolution techniques and reveal the how secretory vesicles traffic to the plasma membrane, undergo exocytosis, and recycle. I will also explain how in the crowded environment of the presynaptic terminals, retrograde cargoes are transported back to the ....Plethora of diseases of the nervous system are caused by defects in vesicular trafficking including neurodegenerative diseases such as Alzheimer’s disease. I will explore the mechanisms underpinning synaptic vesicular trafficking using novel super resolution techniques and reveal the how secretory vesicles traffic to the plasma membrane, undergo exocytosis, and recycle. I will also explain how in the crowded environment of the presynaptic terminals, retrograde cargoes are transported back to the cell body thereby carrying survival signals.Read moreRead less
Neuronal communication relies on the process of exocytosis by which neurons release a neurotransmitter. Exocytosis is critical for the simplest muscle movement to complex tasks such as learning and memory, and is altered in several neurodegenerative pathologies. We will investigate how the protein Munc18 controls exocytosis. This research will be important for understanding how neurons communicate in health and disease and will be relevant to other processes such as insulin release in diabetes.