Investigating The Formation And Utility Of The Prenatal Platelet Forming System
Funder
National Health and Medical Research Council
Funding Amount
$793,442.00
Summary
A major challenge to regenerative medicine is discovering how to produce useful cell types in the laboratory. Particularly urgent is the need to generate large numbers of platelets, the building blocks of the clotting system, for clinical use. Current laboratory methods are woefully inefficient, thus cannot meet demand. This project aims to discover how platelets are made in nature. With this information we will be able to devise better platelet production strategies in the laboratory.
Understanding The Ancestry Of De Novo Blood Formation In The Early Embryo
Funder
National Health and Medical Research Council
Funding Amount
$484,666.00
Summary
Current laboratory methods rely on a hit-or-miss approach for the production of such cells, making the prospect of producing patient-specific cells an inefficient/financially prohibitive process. This project aims to generate new knowledge into when and how fate of early blood cells in selected in nature. With this information we will be able to devise effective blood progenitor cell production strategies in the laboratory.
Understanding how the brain grows and is organised is one of the great challenges of science. This project seeks to identify key regulators of neural progenitors as these are the building blocks from which all brains cells are derived. This knowledge may also identify new avenues through which to manipulate neural progenitor function. This has implications not only for normal brain development but also potential therapies for neural disorders and disease.
Enrichment, Differentiation And Functional Analysis Of Growth Hormone Progenitor Cells From The Adult Mouse Pituitary
Funder
National Health and Medical Research Council
Funding Amount
$469,500.00
Summary
Many important bodily functions including growth, metabolism, onset of puberty, fertility, lactation and the ability to cope with stress are controlled by hormones secreted by the pituitary gland. Consequently, insufficient hormone production by the pituitary gland (hypopituitarism) results in life-threatening conditions which are a significant clinical problem. Growth Hormone (GH) deficiency is the most common form of pituitary hormone deficiency, affecting 1:3,500 individuals. Currently, GH de ....Many important bodily functions including growth, metabolism, onset of puberty, fertility, lactation and the ability to cope with stress are controlled by hormones secreted by the pituitary gland. Consequently, insufficient hormone production by the pituitary gland (hypopituitarism) results in life-threatening conditions which are a significant clinical problem. Growth Hormone (GH) deficiency is the most common form of pituitary hormone deficiency, affecting 1:3,500 individuals. Currently, GH deficiency is treated by daily injections of growth hormone at a cost of $30,000 to $50,000 per patient per annum. However, even with daily injections and despite the cost, it is difficult to mimic the naturally fluctuating hormone levels in the body, resulting in incomplete growth rescue. Long term injections also have severe side effects that can lead to cardiovascular problems, abnormal bone density, diabetes and cancers of various types. To overcome the disadvantages of hormone therapy we are investigating a new cell replacement therapy to treat GH deficiency. This approach requires knowledge about the mechanism by which GH-secreting cells are generated and maintained in the adult pituitary. For the first time, we have isolated a type of progenitor (unspecialised) cell from adult mouse pituitary that is capable of dividing and generating GH-secreting cells. Our current research aims to further purify these cells and to show that they are capable of secreting GH in response to biologically relevant signals. In addition, we will test whether these cells can grow and develop into functional cells when introduced into mice. In particular, we will test whether the progenitor cells can rescue dwarfism using a mouse model of GH deficiency. This pioneering study will provide the first insight into the possibility of cell therapy for the pituitary, and may ultimately lead to the development of better therapies for patients with GH deficiency.Read moreRead less
Promoting Intestinal Stem-cell Mediated Regeneration Following Damage: A Critical Role For Neuregulin 1
Funder
National Health and Medical Research Council
Funding Amount
$648,447.00
Summary
Diseases, infections and pathologies are common clinical problems of the intestine in humans that can lead to loss of intestinal tissue. Individuals with these conditions can experience nutritional problems and severe cases result in death. Promoting regeneration of the damaged tissue is critical to re-establish intestinal function. In this study, we will examine the regenerative potential of a growth factor called Neuregulin1 in the intestine with the aim of facilitating tissue regeneration.
The Role Of Raptor And Rictor Signalling Pathways In Osteogenesis And Mesenchymal Stem Cell Fate Determination
Funder
National Health and Medical Research Council
Funding Amount
$562,742.00
Summary
Skeletal diseases associated with excessive bone loss and skeletal fragility, such as osteoporosis, affect 2.2 million Australians and cost our health system approximately $7.4 billion per annum. Studies from our laboratory suggest a critical role for the mTOR signalling pathway in bone development. Using transgenic animals and state-of-the-art techniques, we will investigate the role of mTOR in pre- and post-natal skeletal development. Results from these studies may provide novel approaches to ....Skeletal diseases associated with excessive bone loss and skeletal fragility, such as osteoporosis, affect 2.2 million Australians and cost our health system approximately $7.4 billion per annum. Studies from our laboratory suggest a critical role for the mTOR signalling pathway in bone development. Using transgenic animals and state-of-the-art techniques, we will investigate the role of mTOR in pre- and post-natal skeletal development. Results from these studies may provide novel approaches to treat age-related bone loss syndromes.Read moreRead less
De-differentiation Of Committed Cells Into Haematopoietic Stem Cells By The Instructive Role Of The Transcription Factor HOXB4
Funder
National Health and Medical Research Council
Funding Amount
$683,040.00
Summary
Blood stem cells are long-lived and can give rise to every cell type of the blood system and due to these properties they are currently used in the clinics. Despite their importance, our knowledge of the mechanisms the control the multiplication of these rare cells is very scarce. This proposal aims to identify key factors that have the potential to convert mature, easy available blood cells into stem cells. This knowledge has to potential to lead to novel system that allow the expansion of stem ....Blood stem cells are long-lived and can give rise to every cell type of the blood system and due to these properties they are currently used in the clinics. Despite their importance, our knowledge of the mechanisms the control the multiplication of these rare cells is very scarce. This proposal aims to identify key factors that have the potential to convert mature, easy available blood cells into stem cells. This knowledge has to potential to lead to novel system that allow the expansion of stem cells for transplantations in the future.Read moreRead less
A Stem Cell-specific MicroRNA-independent Function Of Drosha
Funder
National Health and Medical Research Council
Funding Amount
$637,702.00
Summary
Stem cells are responsible for producing and replenishing the ~200 specialised cell types in our body. Our goal is to understand the molecular switches that control the function of these cells. We recently discovered that the activity of certain genes within stem cells is controlled by degradation. This degradation is absolutely crucial for safeguarding the function of stem cells. This project will investigate how this novel mechanism is controlled within these cells.