The research described in this Project Grant application should help to us understand how our brains make memories. Our brains contain billions of interconnected nerve cells forming unimaginable numbers of possible networks. Previous research indicates that repetitive activation of individual networks can lead to changes in the strength of connections between nerve cells. These changes in connection strength are thought to underlie learning and memory. The experiments described in this proposal ....The research described in this Project Grant application should help to us understand how our brains make memories. Our brains contain billions of interconnected nerve cells forming unimaginable numbers of possible networks. Previous research indicates that repetitive activation of individual networks can lead to changes in the strength of connections between nerve cells. These changes in connection strength are thought to underlie learning and memory. The experiments described in this proposal will address the mechanisms underlying changes in the strength of connections between nerve cells. As most of the inputs nerve cells receive from other nerve cells are made onto their dendrites (small branching processes that extend from the cell body), the main objective is to investigate the interactions at the dendritic level responsible for changes in connection strength. The results of this work will raise our understanding of how memories are formed, which will be essential if we are to understand the cellular processes disrupted during memory dysfunction in neurological disorders such as dementia.Read moreRead less
Development And Refinement Of Neural Connections In The Adult Brain In Health And Disease
Funder
National Health and Medical Research Council
Funding Amount
$8,061,596.00
Summary
Our group will use innovative approaches such as advanced imaging and cell-sorting and development of animal models to determine how new neurons are generated, how they travel to different parts of the brain and how they integrate into the existing brain circuitry. These discoveries will point to new ways in which to treat brain damage both during ageing and during pathology. Since team members have previously been involved in progressing molecular discovery to clinical trials, we are also in a ....Our group will use innovative approaches such as advanced imaging and cell-sorting and development of animal models to determine how new neurons are generated, how they travel to different parts of the brain and how they integrate into the existing brain circuitry. These discoveries will point to new ways in which to treat brain damage both during ageing and during pathology. Since team members have previously been involved in progressing molecular discovery to clinical trials, we are also in a good position to exploit these discoveries in partnership with the biopharmaceutical industry.Read moreRead less
Molecular And Cellular Mechanisms Of Axon Guidance In The Vertebrate Nervous System
Funder
National Health and Medical Research Council
Funding Amount
$447,750.00
Summary
There are, at least, two major obstacles that have to be overcome in the design of therapies to assist the repair of injured brain tissue. First, the nerve cells that are damaged have to be encouraged to regrow - typically this regrowth is inhibited in the brain; and second, this regrowth has to be directed so that the correct connections are re-established. This project will begin to unravel some of the mechanisms that nerve cells use to wire up together during development. This information can ....There are, at least, two major obstacles that have to be overcome in the design of therapies to assist the repair of injured brain tissue. First, the nerve cells that are damaged have to be encouraged to regrow - typically this regrowth is inhibited in the brain; and second, this regrowth has to be directed so that the correct connections are re-established. This project will begin to unravel some of the mechanisms that nerve cells use to wire up together during development. This information can be used to assist in trying to modulate and facilitate directed regrowth following injury.Read moreRead less
Molecular And Cellular Mechanisms Of Axon Growth And Guidance In The Vertebrate Nervous System
Funder
National Health and Medical Research Council
Funding Amount
$467,545.00
Summary
There are millions of nerve cells in the vertebrate brain, each forming very precise and specific connections within neural circuits. During development of the embryo most of these cells are wired together. A Telstra technician will use the different colours of telephone cables to correctly connect them. Likewise, the growing processes of nerve cells in the brain use specific markers or labels as cues to establish the correct wiring. The aim of the present project is to characterize the specific ....There are millions of nerve cells in the vertebrate brain, each forming very precise and specific connections within neural circuits. During development of the embryo most of these cells are wired together. A Telstra technician will use the different colours of telephone cables to correctly connect them. Likewise, the growing processes of nerve cells in the brain use specific markers or labels as cues to establish the correct wiring. The aim of the present project is to characterize the specific role of some of these labels on nerve cells during development. This project will provide new fundamental knowledge about how brain cells are wired together during development of the embryo. This knowledge is essential for establishing strategies to enhance repair of brain cells following ischemic, excitotoxic or mechanical injury.Read moreRead less
Prof Paxinos ‘s work is involved in understanding brain organisation and function through the fusion of the fields of molecular genetics, comparative and developmental neuroanatomy and Neuro informatics
Role Of ABCA-G Transporters In Neuronal Cholesterol Regulation And Alzheimers Disease
Funder
National Health and Medical Research Council
Funding Amount
$557,582.00
Summary
Alzheimer's disease (AD) prevalence is rising and the contributing factors are poorly understood. Recent research shows that cholesterol regulates the production of neurotoxic amyloid-beta peptide (Abeta). We will study a class of proteins, ABC transporters, that we believe regulate neuronal cholesterol and Abeta metabolism. We will use isolated brain cells, human brain tissue and genetically engineered mice in order to define how cholesterol influences AD and identify new treatment options.
Investigating Action Potential Initiation And Propagation In Neurons Using Voltage-sensitive Dyes
Funder
National Health and Medical Research Council
Funding Amount
$317,076.00
Summary
Nerve impulses, or action potentials, are the fundamental electrical signals used by the nervous system for communication. Critical to an understanding of neuronal function is the knowledge of where these events are initiated and how they propagate. Furthermore, this knowledge is required for understanding what goes wrong under conditions where there is a disturbance in neuronal communication, as occurs in many neurological disorders such as multiple sclerosis and epilepsy.
Synaptic Inhibition And The Control Of Excitability In The Rodent Piriform Cortex
Funder
National Health and Medical Research Council
Funding Amount
$459,738.00
Summary
We are studying the properties of neurons (nerve cells) and brain circuits that enable mammals to recognise and remember odours. Our experiments will focus on neurons in the odour-processing region of the cerebral cortex of mice. This work will answer fundamental questions about how the brain interprets sensory inputs in order to build a coherent picture of the external world. Our findings will also provide a deeper understanding of the causes of epilepsy, leading to improved treatments.
Neuroprotection By Ndfip1 In Brain Injury - Identifying Targets And Understanding Mechanisms
Funder
National Health and Medical Research Council
Funding Amount
$836,225.00
Summary
Brain injury from trauma and motor vehicle accidents is a serious health issue, affecting approximately 30,000 Australians per year. About 10% of the victims suffer serious long term consequences, including mental, physical and behavioural impairment. We have discovered a new brain protein capable of preventing neurons from dying following injury. This grant will improve our understanding of how this protein works, and provide a scientific foundation for devising therapies.