The Role Of Ryk/AF6/Eph Complexes In Neuronal Pathfinding/fasciculation
Funder
National Health and Medical Research Council
Funding Amount
$422,036.00
Summary
During embryonic development nerve cells in the central nervous system have to find the right connections to make with other nerve cells. The process by which nerve cells find the right partners to make connections with is called neuronal pathfinding. Once some nerve cells have made the right connections, other nerve cells attach to these cells and form bundles of nerve fibres. This process is called fasciculation or bundling. This whole process is vital to the normal development and function of ....During embryonic development nerve cells in the central nervous system have to find the right connections to make with other nerve cells. The process by which nerve cells find the right partners to make connections with is called neuronal pathfinding. Once some nerve cells have made the right connections, other nerve cells attach to these cells and form bundles of nerve fibres. This process is called fasciculation or bundling. This whole process is vital to the normal development and function of the central nervous system and the brain. Without the right connections between nerves, information could not be received, processed or sent to organs in the body. We are now starting to discover some of the molecules which control the process of nerve cell pathfinding during development. It has been known for some time that proteins called Eph receptors play an important role in neuronal pathfinding and development of the head region in mice. We have now discovered that two other proteins called Ryk and AF-6 are able to bind to Eph receptors. We have very recently created mice which lack the Ryk protein and these mice have defects in their head deveopment strikingly similarto the head defects seen in mice that lack Eph receptors. We now wish to see whether Ryk mice have defects in neuronal pathfinding and fasciculation as do mice lacking Eph receptors. We also think that Ryk, Af-6 and Eph receptors form a protein complex which can modify cell function. We now wish to explore how this protein complex can do this.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
Understanding the biological mechanisms of nerve degeneration is an essential step toward the development of novel therapies for human neurodegenerative conditions such as Parkinson's, Alzheimer's and Huntington's diseases, and for spinal cord injuries. The studies presented in this proposal, using the powerful molecular and genetic tools available for the small nematode worm C. elegans, will provide new insights into the cellular and molecular mechanisms responsible for nerve degeneration.
Neogenin Regulates Progenitor Division And Interneuron Migration In The Developing Forebrain
Funder
National Health and Medical Research Council
Funding Amount
$526,878.00
Summary
In humans, mutations in genes controlling the production of new neurons in the embryonic brain result in severe disruption of the adult cortex. This project tests the hypothesis that one cell surface molecule, Neogenin, regulates the birth of new neurons and their subsequent travels through the developing brain to form the neocortex. The outcome of these studies will provide fundamental insights into the aberrant processes that underlie human mental retardation, epilepsy, dyslexia and autism.
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
Post Synaptic Density Scaffold Proteins In The Growth Cone: Homer And Shank, Crucial For Calcium Signaling.
Funder
National Health and Medical Research Council
Funding Amount
$237,909.00
Summary
Our brain is a complex, yet precise electrical circuit. Understanding how the embryonic brain is wired has direct implications for all aspects of life, from the growing foetus in mother's womb, to learning algebra and for maintaining the active memories of our ageing population. This project aims to provide new insight into understanding how the embryonic brain is wired, crucial information for future pharmacological or gene therapy approaches to mental illness, ageing, and neuronal injury.