Investigation Of The Role Of Nfix In Adult Neurogenesis
Funder
National Health and Medical Research Council
Funding Amount
$349,590.00
Summary
This project will identify key components of the molecular roadmap that mediates adult neurogenesis. Elucidating the genes involved in this process will represent a major advance in our understanding of how neurogenesis within the adult brain is orchestrated, and will provide molecular targets for practical applications aimed at harnessing adult neurogenesis for replacement therapies.
Nfib Regulates Glial Differentiation During Development And Disease Via Repression Of The Key Epigenetic Protein, Ezh2
Funder
National Health and Medical Research Council
Funding Amount
$572,912.00
Summary
Glial development is critical during development, and unrestrained proliferation of glial stem cells in the adult can lead to deadly brain cancers such as glioma. At present there is no cure for glioma and current treatments do not significantly delay tumour progression. Nfib is a transcription factor that may prevent tumour growth through cellular differentiation. We will investigate the role of Nfib during development and in the pathogenesis of glioma and its potential as a therapeutic target.
The cell types of the blood, such as red and white blood cells, are produced in the bone marrow from a rare stem cell. The stem cell uses a handful of important master-regulatory genes that act in a hierarchy to promote the blood cell differentiation process. This research aims to understand how these master-regulators function in isolation and together in producing the white blood cells that are required for our immune response to microbes, vaccination and to prevent cancer.
Regulation Of Neural Progenitor Cell Self-renewal By The RNA-binding Protein ZFP36L1 During Development And Disease
Funder
National Health and Medical Research Council
Funding Amount
$345,401.00
Summary
The timely differentiation of neural stem cells is critical during development, and the unrestrained proliferation of neural stem cells in the adult can lead to deadly brain cancers such as glioma. At present our understanding of the key molecules that regulate neural stem cell behaviour during these processes remains limited. In this proposal we will investigate the molecular determinants underpinning neural stem cell biology, both within the developing brain, and within glioma.
Brain Repair Following Stroke: The Role Of Npas4, A Neural-specific Transcription Factor
Funder
National Health and Medical Research Council
Funding Amount
$611,053.00
Summary
Stroke is the #1 cause of adult disability in Australia and #2 cause of death. About 60,000 Australians suffer a stroke each year while about 250,000 live with the disabilities of stroke, costing over $2B/year. The Queen Elizabeth Hospital and University of Adelaide will study why the Npas4 gene switches on after stroke and the role it plays in brain repair. Future health benefits may be tests to help improve stroke outcome in patients and therapy to decrease loss of brain cells after stroke.
Dissecting The Embryonic Blood-endothelial Regulatory Code And Investigating Its Role In Leukaemia
Funder
National Health and Medical Research Council
Funding Amount
$646,389.00
Summary
Cancer initiating cells acquire stem cell characteristics and multiply within a supportive environment that helps maintain and propagate malignant cells. Identifying the normal hierarchy of gene control within blood stem cells and designing therapies that target cancer cells is the ultimate goal of this body of work.
C-Kit Signalling And Cellular Responses In Haemopoietic Cells
Funder
National Health and Medical Research Council
Funding Amount
$731,115.00
Summary
Growth factors acting on cell surface receptors activate multiple intracellular signalling pathways that regulate cellular growth and function. Mutations in the genes that code for these receptors or their downstream signalling pathways contribute to many human cancers. The contributions of different signalling pathways linked to these receptors to the various cellular responses (growth, maturation, functional activation) are not understood. In this project we aim to use cell and molecular biolo ....Growth factors acting on cell surface receptors activate multiple intracellular signalling pathways that regulate cellular growth and function. Mutations in the genes that code for these receptors or their downstream signalling pathways contribute to many human cancers. The contributions of different signalling pathways linked to these receptors to the various cellular responses (growth, maturation, functional activation) are not understood. In this project we aim to use cell and molecular biology approaches to determine the role of different signalling pathways in cellular responses mediated by the growth factor receptor c-Kit. The c-Kit receptor has essential functions in blood cell development, skin and hair pigmentation, gut function and the reproductive system. It is also essential for the development and function of mast cells which trigger allergic responses such as asthma and eczema. Mutant forms of the receptor have been identified in certain leukaemias and colon cancers. Many new drugs that target specific intracellular signalling pathways have recently been developed and are beginning to be evaluated in clinical trials. Better understanding of how individual pathways contribute to the function of c-Kit and other receptors is essential for optimal use of these new drugs. For example, it may enable the choice of drugs to block c-Kit dependent cancer cell growth or allergic reactions without affecting the growth of normal blood cells.Read moreRead less