Mechanisms Guiding Pathfinding And Positioning Of Cortical Interneurons
Funder
National Health and Medical Research Council
Funding Amount
$621,606.00
Summary
Brain disorders place an economic and social burden on Australia and the personal costs of these illnesses are immeasurable. Several brain abnormalities are caused from the failure of neurons to position themselves in the correct location when the brain develops. Our study aims to discover how neurons move and what factors influence this process. It provides an understanding of normal brain development, as well as providing insight into what may go wrong in the formation of brain diseases.
Characterisation Of Eurl, A Novel Gene Implicated In The Etiology Of Abnormal Brain Development And Intellectual Disability
Funder
National Health and Medical Research Council
Funding Amount
$597,541.00
Summary
Intellectual disability affects around one per cent of Australians, and can arise from genetic abnormalities during fetal life, such as through abnormal regulation of gene expression. We have identified a novel gene, known as eurl, which controls brain assembly as well as the ability of neurons to form functional connections within the brain. We will investigate how this novel gene controls brain development, and characterise eurl as a potential therapeutic target for learning and memory.
Understanding the contribution of neuroinflammation in acute and chronic neural injury. A major focus of this project will be investigating the involvement of neuroinflammation in neural cell damage. It will explore how neuroinflammation contributes to this damage in both acute and chronic neuropathologies.
The Role Of The Zinc Finger Transcriptional Repressor Znf238 During Nerve Cell Maturation
Funder
National Health and Medical Research Council
Funding Amount
$394,264.00
Summary
Proper foetal brain assembly is critical for brain function, but the underlying genetic mechanisms remain poorly defined. In this study, I will investigate a family of proteins that “turn on” neural gene expression in combination with another protein that “turns off” their expression during nerve cell development. Understanding this novel on/off mechanism for controlling gene expression in newborn nerve cells will further our understanding of how the brain is assembled.
Discovery Early Career Researcher Award - Grant ID: DE130100323
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
The regulation by transcription factor phosphorylation upon the myelinating process. The project will investigate the novel molecular events that control the myelinating process, which is essential for normal nervous system function. Outcomes of this project may aid the development of novel interventions to improve control of demyelinating diseases, which represent a substantial socio-economic burden.
Investigating the neuroprotective actions of metallo-complexes. Metal-based drugs offer an exciting new approach to treatment of neurodegeneration. However, little is known about how cells metabolise these drugs: information that is critical for further drug development. This project will determine how metal-based drugs are metabolized by neuronal cells and how this may result in therapeutic benefit.
Gene-environment interactions mediating experience-dependent plasticity in the healthy and diseased brain. The aim of this project is to understand how genes and environment combine to affect susceptibility to various brain disorders, using models of human diseases and manipulating environmental factors such as mental and physical activity. The project's focus is on neurological and psychiatric disorders, including Huntington's disease, depression, schizophrenia and autism.
Electrical activity in early enteric neuron development. Intestinal movements and secretion are critical to the good health and nutrition of both humans and animals. These functions are regulated by a large nervous system contained within the intestinal wall, the enteric nervous system. This project will identify how enteric nerve cells develop and how their behaviour influences the development of other enteric nerve cells. This is will provide an important base for more applied research aime ....Electrical activity in early enteric neuron development. Intestinal movements and secretion are critical to the good health and nutrition of both humans and animals. These functions are regulated by a large nervous system contained within the intestinal wall, the enteric nervous system. This project will identify how enteric nerve cells develop and how their behaviour influences the development of other enteric nerve cells. This is will provide an important base for more applied research aimed at developing treatments for diseases like chronic constipation and irritable bowel syndrome. It will also contribute to the growing knowledge about how epigenetic factors can modify genetically programmed development within the nervous system.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668266
Funder
Australian Research Council
Funding Amount
$264,000.00
Summary
High Resolution Cellular and Molecular Imaging System. Understanding where molecules are within cells, and how they interact with each other, is fundamental to significant advances being made in biology. Our research will use advanced imaging techniques to localize proteins within a variety of cells including neurons and germ cells. We will be able to determine how the different molecules within a single cell interact with each other. This information is relevant to many biological mechanisms ....High Resolution Cellular and Molecular Imaging System. Understanding where molecules are within cells, and how they interact with each other, is fundamental to significant advances being made in biology. Our research will use advanced imaging techniques to localize proteins within a variety of cells including neurons and germ cells. We will be able to determine how the different molecules within a single cell interact with each other. This information is relevant to many biological mechanisms and to many human diseases. Furthermore, our research will help maintain Australia's strong international reputation in the fields of neuroscience, protein trafficking and stem cells. Read moreRead less
Cell cycle and enteric neuron and glial differentiation. Enteric neurons arise from a very small starting population of precursor (neural crest) cells, most of which emigrate from the hindbrain, and colonise the developing gut. Over a protracted period of time the precursors proliferate and differentiate into glia and many different types of neurons. Cell cycle exit is a critical event in the development of many neuron types, largely because the time at which cells exit from the cell cycle lim ....Cell cycle and enteric neuron and glial differentiation. Enteric neurons arise from a very small starting population of precursor (neural crest) cells, most of which emigrate from the hindbrain, and colonise the developing gut. Over a protracted period of time the precursors proliferate and differentiate into glia and many different types of neurons. Cell cycle exit is a critical event in the development of many neuron types, largely because the time at which cells exit from the cell cycle limits the number of neurons that will be generated. We will determine whether exit from the cell cycle contributes to the differentiation and specification of enteric neurons and glia.Read moreRead less