Identification Of Haematopoietic Stem And Progenitor Cell Subpopulations
Funder
National Health and Medical Research Council
Funding Amount
$873,525.00
Summary
We want to dissect the machinery underlying how each and every individual stem and progenitor cell generates the different blood cell types. We have at our disposal the latest molecular and computational technologies to do this. Knowledge gained from this project could be used for tissue engineering to make blood cells on demand for patients with immune deficiency, or alternatively to treat leukaemia patients where blood cells are overproduced.
Making Human T- And B-lymphocytes For Immunotherapy And Antibody Production
Funder
National Health and Medical Research Council
Funding Amount
$795,880.00
Summary
Lymphocytes are white blood cells that are involved in producing antibodies, killing defective cells, or killing cells infected with viruses. In recent years, researchers have found ways to harness lymphocytes to develop medicines for treating a variety of different cancers. In this project, we will establish methods to make human lymphocytes in the laboratory from stem cells, paving the way for the broader application of this cell type to new therapies.
Characterization Of A Novel Regulator Of Angiogenesis
Funder
National Health and Medical Research Council
Funding Amount
$592,235.00
Summary
PI3K is an enzyme required for new blood vessel formation during embryo development as well as in response to tumour formation. We have identified a novel enzyme that opposes PI3K signals and we hypothesise that it regulates new blood vessel formation in various physiological settings. We propose to investigate the role of this enzyme in blood vessels using mouse models in which this protein is reduced or absent.
Blimp-1: A Master Regulator Of B-lymphocyte Terminal Differentiation?
Funder
National Health and Medical Research Council
Funding Amount
$154,250.00
Summary
B lymphocytes are the antibody-producing cells of the immune system. They are formed in the bone marrow, and are exported to the body to circulate, searching for signs of infection. These circulating cells are not fully mature, but when they encounter an invader, with the help of other immune cells, they change. Most become antibody-producing cells, the final, operational cells of the B cell lineage. A few cells are set aside as memory cells that can rapidly become antibody-producing cells shoul ....B lymphocytes are the antibody-producing cells of the immune system. They are formed in the bone marrow, and are exported to the body to circulate, searching for signs of infection. These circulating cells are not fully mature, but when they encounter an invader, with the help of other immune cells, they change. Most become antibody-producing cells, the final, operational cells of the B cell lineage. A few cells are set aside as memory cells that can rapidly become antibody-producing cells should the same infection occur again. This is the basis of vaccination. The secretion of antibodies into the serum (that can bind to and eliminate an invader anywhere in the body) is the main function of B lymphocytes. This project will study the genes that allow B cells to become antibody-secreting cells (called ASC). We will focus on the gene for Blimp-1, the B lymphocyte-induced maturation protein, which has been called the master regulator of ASC formation. This claim is based largely on circumstantial evidence, and has not been directly tested genetically. We have made a mouse in which the Blimp-1 gene has been altered so that we can disable it in carefully controlled way. Using this knockout mouse, we can directly test the requirement for Blimp-1 in ASC and in other cell types. We will study these animals, using many tests that can accurately measure the behaviour of isolated cells, or the immune responses of the animals. We will examine other genes that are thought to be required for ASC to form or to perform their work, to see if loss of Blimp-1 (a known gene silencer) has impacted on these other genes. In this way, we expect to identify the genetic program that drives a B cell to become a mature ASC. Using this knowledge, we hope eventually to be able to study diseases of ASC in humans (as occur in allergy, asthma, rheumatoid arthritis and leukaemia). This information may also be used to improve the outcome of vaccination.Read moreRead less
Investigating Tumour Development And Metastasis Using A Novel Drosophila Cancer Model.
Funder
National Health and Medical Research Council
Funding Amount
$505,500.00
Summary
The majority of cancers are derived from epithelial cells. The primary cause of cancer related deaths is due to the ability of these epithelial cancer cells to migrate and invade other tissues within the body away from their primary tissue of origin (metastasise). This proposal seeks to understand the pathways that are important in regulating the processes of epithelial cell migration and invasion that are instrumental in promoting the metastatic spread of tumour cells. As controls usually opera ....The majority of cancers are derived from epithelial cells. The primary cause of cancer related deaths is due to the ability of these epithelial cancer cells to migrate and invade other tissues within the body away from their primary tissue of origin (metastasise). This proposal seeks to understand the pathways that are important in regulating the processes of epithelial cell migration and invasion that are instrumental in promoting the metastatic spread of tumour cells. As controls usually operate to induce cell death in any cell that attempts to break away and invade other tissues, this proposal also seeks to understand some of the pathways that are responsible for causing these cells to die. To carry out these investigations we have developed a novel Drosophila model of epithelial cancer development. We use this model because of the ease with which it is possible to carry out complex genetic analyses and so dissect the roles of the many different signalling pathways involved in these processes. The strength of the model is that it is dependent upon genetic alterations that are also implicated in the development and metastatic spread of many mammalian cancers, namely activating mutations in two genes, Ras and Notch. It is expected, therefore, to offer considerable insight into why these activated genes also cause the spread of cancer cells in humans.Read moreRead less
Analysis Of Rho GTPase Signalling Pathways In An Epithelial To Mesenchymal Transition During Development Of The Mesoderm
Funder
National Health and Medical Research Council
Funding Amount
$409,500.00
Summary
A critical step in the progression of cancers that are derived from epithelial tissues is a transition from an epithelial cell type to a migratory mesenchymal cell type that can spread to other parts of the body. This change in cell behaviour also occurs, apparently by a similar mechanism, during the development of some normal tissue types. Here we propose to use an animal model of this process, coupled with advanced molecular genetic and cell biological techniques, to investigate a newly discov ....A critical step in the progression of cancers that are derived from epithelial tissues is a transition from an epithelial cell type to a migratory mesenchymal cell type that can spread to other parts of the body. This change in cell behaviour also occurs, apparently by a similar mechanism, during the development of some normal tissue types. Here we propose to use an animal model of this process, coupled with advanced molecular genetic and cell biological techniques, to investigate a newly discovered cell signalling mechanism required for the transition of cells from an epithelial form to a mesenchymal form. Understanding the molecular steps in this new pathway and discovering new genes involved will provide tools for understanding and preventing the metastasis of cancer cells.Read moreRead less