Regulation Of Synaptic Vesicle Biogenesis For Synaptic Transmission
Funder
National Health and Medical Research Council
Funding Amount
$339,115.00
Summary
The overall aim is to better understand the molecular processes of nerve cell communication during learning, memory and abnormal brain activity that cause neurological diseases. The supply and generation (biogenesis) of synaptic vesicles (SVs) in nerve cells is critical to sustain neurotransmission. It requires complex protein interactions and signalling. Thus modulation of SV biogenesis at the molecular level will allows future development of new targeted treatments for neurological diseases.
Investigation Of The Molecular Mechanisms Underlying Alpha Synuclein Function At The Presynapse
Funder
National Health and Medical Research Council
Funding Amount
$419,180.00
Summary
Parkinson’s Disease (PD) is a common brain disease affecting 7 million people worldwide. It is caused by the death of brain cells. ?-synuclein is a protein in that brain that is likely to contribute to the cell death in PD, but the normal role of the protein remains unknown. This study will investigate the function of ?-synuclein in maintaining normal healthy brain activity. In addition, this work will help us understand how normal brain processes are affected in diseases such as PD.
Sulfonadyn-based Dynamin I-specific Inhibitors And Epilepsy
Funder
National Health and Medical Research Council
Funding Amount
$835,291.00
Summary
Epilepsy affects 1% of people, yet 30% do not respond to anti-epileptic drugs (AEDs). Traditional drug discovery fails to improve this situation. Our team discovered dynamin as a new target for better AED design and our lead sulphonadyns reduces seizures in animals. We will design better sulfonadyns that can ultimately be used for clinical trials by designing the drugs away from its actions outside of neurons. If successful, this will accelerate new AED development with less side-effects.
The Functional Interplay Between Alpha Synuclein And Synaptophysin In Synaptic Vesicle Recycling
Funder
National Health and Medical Research Council
Funding Amount
$405,461.00
Summary
Parkinson’s Disease (PD) is the second most common neurodegenerative disorder, affecting 7 million people worldwide. ?-synuclein is a protein in that brain that is likely to contribute to the death of brain cells in PD, but the normal role of the protein remains unknown. This study will investigate the function of ?-synuclein in maintaining normal healthy brain activity. In addition, this work will help us understand the processes that go awry in neurodegenerative disease states such as PD.
Differential Regulation Of Two Modes Of Exocytosis By Protein Phosphatases
Funder
National Health and Medical Research Council
Funding Amount
$399,750.00
Summary
The release of signals from nerve endings (exocytosis) is of fundamental importance to nervous system function. The recent recognition that nerve cells can release transmitter by at least two distinct modes of exocytosis has led to the need for a deeper understanding of the mechanisms that regulate exocytosis. Our identification of the key role played by two enzymes, PP2A and PP2B, represents a major insight into the molecular mechansisms regulating this process. The experiments will lead to the ....The release of signals from nerve endings (exocytosis) is of fundamental importance to nervous system function. The recent recognition that nerve cells can release transmitter by at least two distinct modes of exocytosis has led to the need for a deeper understanding of the mechanisms that regulate exocytosis. Our identification of the key role played by two enzymes, PP2A and PP2B, represents a major insight into the molecular mechansisms regulating this process. The experiments will lead to the identification of how PP2A and PP2B are regulated at the molecular level and the targets that are important in the control of exocytosis. The project will also develop new tools to specifically manipulate the two modes of exocytosis in order to understand their contribution to normal and pathological neurotransmission. Strong stimulation of exocytosis is associated with learning and memory in normal brain and neuronal damage under certain pathological conditions. Since switching from 1 mode of exocytosis to another is also induced by strong stimulation, an understanding of the molecular mechanisms that control the different modes of exocytosis may eventually lead to clinical applications.Read moreRead less
Defining A Role For The STONED Proteins In The Synaptic Vesicle Cycle
Funder
National Health and Medical Research Council
Funding Amount
$301,527.00
Summary
Nerve cells communicate with each other by means of chemical neurotransmitters. The level of communication is strictly controlled, and changes in the level, either up or down, is known as synaptic plasticity. This plasticity is thought to underly changes in the brain that account for both long and short term memory. Uncontrolled alterations in plasticity can also induce abnormal brain function, resulting in neurological disorders. Changes in the release of neurotransmitter are regulated at the m ....Nerve cells communicate with each other by means of chemical neurotransmitters. The level of communication is strictly controlled, and changes in the level, either up or down, is known as synaptic plasticity. This plasticity is thought to underly changes in the brain that account for both long and short term memory. Uncontrolled alterations in plasticity can also induce abnormal brain function, resulting in neurological disorders. Changes in the release of neurotransmitter are regulated at the molecular level by unknown mechanisms, however the chemical neurotransmitters are enclosed in small vesicles and it is believed that the control of the release of these vesicles, and their recycling, are important components of this mechanism. We have identified a gene that encodes two novel proteins of neurotransmission. Mutations that alter these genes can result in either increased or decreased synaptic activity. By using a combination of genetic and molecular techniques we propose to investigate how one of these two proteins operate to alter synaptic activity, as well as attempting to show how it interacts with other components of the synaptic machinery.Read moreRead less
The Role Of Intersectin-1 In Endocytic Anomalies: Implications For Down Syndrome And Alzheimer's Disease
Funder
National Health and Medical Research Council
Funding Amount
$510,500.00
Summary
Individuals with Down syndrome have three copies of human chromosome 21, rather than the normal two. We have discovered a gene called Intersectin-1, located on human chromosome 21, that is expressed at higher levels than normal in individuals with Down syndrome. Intersectin-1 has a role in endocytosis, a process whereby cells take up molecules from the outside. Endocytosis occurs in all cells but is highly specialised in the brain where chemical transmitters are released and then rapidly recover ....Individuals with Down syndrome have three copies of human chromosome 21, rather than the normal two. We have discovered a gene called Intersectin-1, located on human chromosome 21, that is expressed at higher levels than normal in individuals with Down syndrome. Intersectin-1 has a role in endocytosis, a process whereby cells take up molecules from the outside. Endocytosis occurs in all cells but is highly specialised in the brain where chemical transmitters are released and then rapidly recovered by endocytosis in a process enabling neurones to pass signals to one another. A disturbance in endocytosis has been reported as the earliest hallmark of Alzheimer's disease in both non-Down syndrome and Down syndrome individuals. This disturbance is characterised by the presence of enlarged endosomes (small packages in neuronal cells containing chemical neurotransmitters formed during endocytosis). These enlarged endosomes are present long before the characteristic plaques of Alzheimer's disease appear. Since all individuals with Down syndrome develop Alzheimer's-like neuropathology, there must be a common disease mechanism that can be traced to the extra gene dosage from chromosome 21. We propose that a malfunctioning of Intersectin-1 is this common mechanism and we aim to test our hypothesis by the generation and analysis of mouse models of disrupted endocytosis.Read moreRead less
Synaptic Integration And Plasticity In The Rat Piriform Cortex
Funder
National Health and Medical Research Council
Funding Amount
$250,500.00
Summary
The human cerebral cortex is the pinnacle of evolution. It is the most complex structure known, responsible for all of those skills - like language and reasoning - that make our species so remarkable. It is also a major site of many brain diseases, like schizophrenia and epilepsy. An understanding of how the cerebral cortex works would be a remarkable achievement, of immeasurable benefit to human health. How can one go about studying such a complex structure? The strategy taken in this project i ....The human cerebral cortex is the pinnacle of evolution. It is the most complex structure known, responsible for all of those skills - like language and reasoning - that make our species so remarkable. It is also a major site of many brain diseases, like schizophrenia and epilepsy. An understanding of how the cerebral cortex works would be a remarkable achievement, of immeasurable benefit to human health. How can one go about studying such a complex structure? The strategy taken in this project is to begin by studying one of the simplest regions of the cerebral cortex, the olfactory (or piriform) cortex. The olfactory cortex is an evolutionarily ancient region of cortex, with a simpler architecture than other cortical regions. Its task is to process the sense of smell, a primitive sense that is more elaborated in lower animals than in humans. The broad goal of our research is to understand, by studying the olfactory cortex of rats, how olfactory processing occurs at the level of nerve cells (neurons). We will use a number of powerful techniques - including microelectrode recording and laser microscopy - to measure the electrical properties of individual neurons. We will also study the synaptic connections between neurons, and how these connections change following memory-inducing stimuli. It is hoped that this work will shed light on how the healthy cortex is able to process and store information, and how brain diseases cause these functions to deteriorate.Read moreRead less
Neurexin And Neuroligin: A Code For Synaptic Development
Funder
National Health and Medical Research Council
Funding Amount
$349,590.00
Summary
As soon as we are born, we interpret our world through our senses, learn new information and lay down memory. These processes require molecules that connect neurons together. Mutations in genes encoding these molecules result in incorrect wiring of the brain and lead to mental disorders such as autism and schizophrenia. Using simple insect models, our project aims to unravel the fundamental mechanisms of how these molecules function in the brain and how their interaction controls behaviour.