Discovery Of Novel T Cell Oncogenes By Using A Functional Retroviral CDNA Library Screen.
Funder
National Health and Medical Research Council
Funding Amount
$692,470.00
Summary
T cells mature in an organ called the thymus which is located on top of the heart. Blood borne T cell precursors enter the thymus after being resident in the bone marrow. T cell leukaemia is a disease where a blood cell that is committed to becoming a T cell is blocked from maturing into a functional cell. Instead, the leukaemic immature T cell uncontrollably divides to make endless non-functional copies of itself. As a result, normal functional T cells are outcompteted and the immune system is ....T cells mature in an organ called the thymus which is located on top of the heart. Blood borne T cell precursors enter the thymus after being resident in the bone marrow. T cell leukaemia is a disease where a blood cell that is committed to becoming a T cell is blocked from maturing into a functional cell. Instead, the leukaemic immature T cell uncontrollably divides to make endless non-functional copies of itself. As a result, normal functional T cells are outcompteted and the immune system is crippled. Patients generally die due to opportunistic infection. The molecular causes of T cell leukaemia are slowly being discovered. Up to 50% of all human T cell leukaemias overexpress SCL-TAL-1. Other T cell leukaemia-causing genes (oncogenes) include Ras and Notch. Current leukaemia treatments include chemotherapy and bone marrow transplants but even these fail ~30% of the time. Consequently, all T cell oncogenes need to be discovered so that disease-specific treatments can be generated. This proposal will utlise a functional retroviral cDNA library screen to uncover novel T cell lineage commitment genes and T cell oncogenes. This will be accomplished by constructing a coloured [GFP] cDNA library (a library of genes) that will be transfected (inserted) into immature T cells that cannot develop down the T cell pathway owing to the lack of a crucial gene (Rag-1). The T cell oncogene Ras and the T cell lineage commitment gene Notch can move cells past the Rag-1 block. If there is a gene in the cDNA library that can compensate for the lack of Rag-1 and allow the cells to mature we will detect it using high speed flow cytometryic cell sorting (like sieving weevils from flour very quickly). Once we find this cell we will isolate the gene using the colour tag. The potential oncogenes uncovered will provide the foundation for next generation drug development that targets each leukaemia based on its cause.Read moreRead less
Deciphering The Role Of Scribble In Development And Disease
Funder
National Health and Medical Research Council
Funding Amount
$628,789.00
Summary
Scribble is a protein that controls the orientation and organization of all cells within our body. Mutations in the Scribble gene are found in many cancers and also in some patients with spina bifida, however how these mutations cause these diseases is not understood. Here we propose experiments that can be used to link Scribble mutations to specific cellular functions. This information will help us design new therapies to treat diseases driven by tissue disorganization such as cancer.
The Role Of The Polarity Protein, Par3, In Haematopoiesis And Leukaemogenesis
Funder
National Health and Medical Research Council
Funding Amount
$589,777.00
Summary
Understanding the factors regulating blood production is critical to understanding how blood cancers occur and for the development of new therapies. Evidence is emerging of a vital role for the evolutionary conserved ‘polarity’ proteins in blood production and leukaemia This project will elucidate the role of the polarity protein, Par3, in normal and malignant blood cells, providing valuable insight into how Par3 regulates blood formation and the onset and severity of leukaemia.
DECIPHERING THE ROLE OF FOXP1 IN MAMMARY STEM CELLS AND DEVELOPMENT
Funder
National Health and Medical Research Council
Funding Amount
$569,109.00
Summary
Breast (mammary) epithelial cells undergo major changes across developmental stages, including puberty, pregnancy and lactation. This project will focus on the role of the molecular regulator, Foxp1, and how it influences normal mammary maturation. This work will inform whether Foxp1 is critical for controlling the activation of dormant stem cells and if this pathway can contribute to breast cancer formation when disrupted.
Determining recurrence risk in breast cancer is crucial, as more than half of all recurrences occur after 5 years. However, optimal management of breast cancer is hampered by the challenges in finding rational preventative and predictive targets. Our vision is to find targets responsible for progenitor cell expansion, as candidates for prevention, and to find markers of relapse, to predict early versus late responders to therapy.
Regulation Of The Drosophila C-Myc Homologue In Stem Cell Growth And Division.
Funder
National Health and Medical Research Council
Funding Amount
$613,397.00
Summary
The mechanisms controlling stem cell growth and division require elucidation if we are to use stem cells in regenerative medicine and find cancer treatments. Due to experimental limitations such mechanisms are largely unknown in humans. We aim to use the vinegar fly as a model system to understand the importance of microenvironment to cancer gene control in stem cells. We will identify the secreted signals, from the neighbouring cells, required to control cancer initiation in stem cells.
Preserving Ovarian Function During Chemotherapy And Old Age
Funder
National Health and Medical Research Council
Funding Amount
$425,048.00
Summary
Chemotherapy treatment and the natural ageing process leads to ovarian failure and infertility. For young cancer survivors, chemotherapy induced infertility is devastating, and like aged women, leads to hormonal changes that lead to osteoporosis, diabetes, obesity, and neurodegeneration. Here, a new class of molecules will be tested for their ability to prevent and reverse infertility folllowing chemotherapy treatment, and in old age. These findings will improve the healthy lifespan of women.
Cell death by a specialised process known apoptosis is a way of deleting unwanted and harmful cells from the body. As such, aberrant apoptosis is associated with a wide array of diseases including cancer. For example, abnormal levels of proteins that suppress apoptosis or enhance cell survival can result in cancer and often produce resistance to chemotherapy. To understand and treat cancers that result from aberrant apoptosis we need to know at a molecular level how apoptosis is regulated. Centr ....Cell death by a specialised process known apoptosis is a way of deleting unwanted and harmful cells from the body. As such, aberrant apoptosis is associated with a wide array of diseases including cancer. For example, abnormal levels of proteins that suppress apoptosis or enhance cell survival can result in cancer and often produce resistance to chemotherapy. To understand and treat cancers that result from aberrant apoptosis we need to know at a molecular level how apoptosis is regulated. Central to the apoptosis execution are a group of enzymes called caspases that target many cellular proteins for specific cleavage. In this proposal, we will investigate the function of one of the caspases (called caspase-2), in order to better understand its potential role in the apoptosis of cancer cells. A number of recent reports suggest that caspase-2 levels are reduced in many cancer cells. The human caspase-2 gene localizes to a chromosomal region frequently affected- deleted in leukaemia, and caspase-2 levels have been proposed to be predictors of remission and survival in patients with some types of leukaemia. We will study if loss of caspase-2 in cancer cells makes them resistant to killing by drugs and if mice lacking caspase-2 have an increased potential to develop cancer. Understanding caspase-2 function and its regulation is likely to provide new therapeutic opportunities and potential targets for cancer therapy.Read moreRead less
Characterising The Mechanisms That Control Blood Cell Development
Funder
National Health and Medical Research Council
Funding Amount
$335,616.00
Summary
Hematopoiesis is a tightly regulated process that provides the body with a constant supply of all the cells of the blood system. My studies aim to characterize the molecular mechanisms that regulate the expansion and differentiation of hematopoietic stem cells (HSCs) into each cell lineage. These studies will be key to the effective use of cellular transplantation therapeutic strategies and aim to provide a greater understanding of the mechanisms that underpin proliferative disorders such as can ....Hematopoiesis is a tightly regulated process that provides the body with a constant supply of all the cells of the blood system. My studies aim to characterize the molecular mechanisms that regulate the expansion and differentiation of hematopoietic stem cells (HSCs) into each cell lineage. These studies will be key to the effective use of cellular transplantation therapeutic strategies and aim to provide a greater understanding of the mechanisms that underpin proliferative disorders such as cancer.Read moreRead less
Cell death by a special process called apoptosis is a means of deleting unwanted and harmful cells from the body. Extensive apoptosis occurs during foetal development which is required to get rid of many excess cells produced during the growth of the embryo. Selective apoptosis is also essential for the formation of different tissues and organs in developing foetus. In the adult, apoptosis is required for proper functioning of the immune system, to remove virus infected and cancer cells and, in ....Cell death by a special process called apoptosis is a means of deleting unwanted and harmful cells from the body. Extensive apoptosis occurs during foetal development which is required to get rid of many excess cells produced during the growth of the embryo. Selective apoptosis is also essential for the formation of different tissues and organs in developing foetus. In the adult, apoptosis is required for proper functioning of the immune system, to remove virus infected and cancer cells and, in general, to maintain the correct number of cells in the body. As such, misregulation of apoptosis is associated with the pathogenesis of a wide array of diseases. To understand, manage and treat disorders that result from aberrant apoptosis, we need to know at molecular and cellular level, how apoptosis is brought about and how it is regulated. We have been studying these processes in detail for several years. Central to the apoptotic execution of cell death are a group of proteases called caspases, that target many cellular proteins for specific cleavage. The activation of caspases is the crucial step in the initiation of apoptosis and therefore each cell has developed complex ways to control this process. If we understand how these regulatory mechanisms operate, we can then formulate strategies that are targeted towards pathologies involving abnormal apoptosis. In this proposal we will use vinegar fly as a model to study the function of caspases in development. We believe that results from this proposal will have several major benefits. Firstly, they will provide important insight into the mechanisms of developmental apoptosis thereby filling many gaps in our current knowledge. Secondly, the study will endeavour to identify new molecules-pathways that lead to caspase activation. Finally, the proposed studies will shed light on the function of caspases in non-apoptotic pathways.Read moreRead less