Characterization Of Novel Inhibitors Of G1-S Phase Progression In Drosophila
Funder
National Health and Medical Research Council
Funding Amount
$456,000.00
Summary
Cancer is a disease that affects 1-3 people and therefore, understanding the mechanisms by which cancer arises is of major importance to medical science. Cancers arise through the accumulation of mutations that alter normal cell proliferation control, differentiation, cell death or cell movement. Many genes involved in cancer have been identified, however, there are likely to be many more genes, that when disrupted or misexpressed can lead to cancer. We are interested in the regulation of cell p ....Cancer is a disease that affects 1-3 people and therefore, understanding the mechanisms by which cancer arises is of major importance to medical science. Cancers arise through the accumulation of mutations that alter normal cell proliferation control, differentiation, cell death or cell movement. Many genes involved in cancer have been identified, however, there are likely to be many more genes, that when disrupted or misexpressed can lead to cancer. We are interested in the regulation of cell proliferation, and have been studying this in the genetically amenable animal model system, the vinegar fly, Drosophila. A key regulator of cell proliferation in all multicellular organisms is Cyclin E, which is required to drive cells from the G1 (resting state) into S phase (where DNA replication occurs). Correct control of Cyclin E is important in limiting cell proliferation and many cancer-causing mutations result in up-regulation of this critical cell cycle regulator. We have used a genetic approach to identify novel negative regulators of Cyclin E. This proposal seeks to further clarify the mechanism by which the identified Cyclin E interactors regulate cell cycle progression. In addition, this proposal seeks to identify the genes encoding other cyclin E interactors, expected to be novel tumor suppressors. The expected outcome of this project is to elucidate novel genes and mechanisms that control cell proliferation in the context of a whole organism. Due to the conservation of cell proliferation and signalling proteins, this proposal is relevant to understanding human cancer.Read moreRead less
Differentiation Therapy Of Acute Myeloid Leukaemia: Combining RAR-agonists And G-CSF.
Funder
National Health and Medical Research Council
Funding Amount
$449,500.00
Summary
The application of cancer treatments that target specific molecules hold significant promise. However to apply these treatments detailed knowledge is required of the how the molecular targets function in cells. Our previous work using normal blood cells has identified two genes ( MAD1 and p27KIP1 ) that are required for the effects of one such targeted treatment that is aimed at the retinoic acid receptor alpha. We propose to test this treatment in mouse models of human leukaemia and in human le ....The application of cancer treatments that target specific molecules hold significant promise. However to apply these treatments detailed knowledge is required of the how the molecular targets function in cells. Our previous work using normal blood cells has identified two genes ( MAD1 and p27KIP1 ) that are required for the effects of one such targeted treatment that is aimed at the retinoic acid receptor alpha. We propose to test this treatment in mouse models of human leukaemia and in human leukemia cells grown in the laboratory. By deleting the genes for MAD1 and p27KIP1 we will determine if leukaemias lacking these genes fail to respond to treatments targeting the retinoic acid receptor alpha. We will also test if treatments that target retinoic acid receptors in combination with G-CSF, a protein that has previously been demonstrated to have anti-leukaemic activity, can work together to block growth of leukaemic and genetically modified cells. Together these studies will help define classes of leukamias that either will or will not respond to treatments aimed at retinoic acid receptor to better target future leukemia treatments.Read moreRead less
Regulators Of Cell Cycle As Therapeutic Drug-targets For Cortical Tubular Hyperplasia In Proteinuric Renal Disease
Funder
National Health and Medical Research Council
Funding Amount
$219,750.00
Summary
Currently in Australia, it has been estimated that approximately 60 000 people suffer from chronic kidney failure (CKF). In at least 80% of people with CKF, the kidney function will continue to worsen (due to disease progression) to the point where end-stage kidney failure (ESKF) has developed. When the latter occurs daily treatment by either dialysis or kidney transplantation is mandatory for a person to survive. At present, there are nearly 10 000 patients with ESKF who are being treated by di ....Currently in Australia, it has been estimated that approximately 60 000 people suffer from chronic kidney failure (CKF). In at least 80% of people with CKF, the kidney function will continue to worsen (due to disease progression) to the point where end-stage kidney failure (ESKF) has developed. When the latter occurs daily treatment by either dialysis or kidney transplantation is mandatory for a person to survive. At present, there are nearly 10 000 patients with ESKF who are being treated by dialysis or transplantation, in Australia. Although these treatments have allowed patients to survive, they are associated with significant and unacceptable patient morbidity and mortality. Current medical treatments to reduce the disease progression of CKF (and thereby extend the time taken to reach ESKF) are non-specific, partially effective and have a variable response. Also, these treatments are NOT known to arrest the progression of CKF. To compound the overall problem even further, the number of new patients starting chronic dialysis programmes is increasing (by 6% per year). Consequently, ESKF has been described by leading authorities as a medical catastrophe of world-wide dimensions, and research into ways to reduce-arrest the progression of CKF has been recommended as an urgent priority by the Australian Kidney Foundation. In CKF, the kidneys undergo compensatory growth which is harmful and paradoxically contributes to disease progression. The aim of this research program is to advance knowledge about the molecular mechanisms of kidney growth in CKF, with specific goals of: (i) identifying new molecular targets for drug-based manipulation of kidney growth; and (ii) to test the efficacy of experimental drugs which have an ability to alter kidney growth, and thereby reduce the progression of CKF.Read moreRead less
Regulation Of Cell Proliferation By The Actin Cytoskeleton
Funder
National Health and Medical Research Council
Funding Amount
$607,795.00
Summary
The architecture of cells defines both their shape and function. It has been known for a long time that cell architecture controls the growth of cells and in particular their capacity to proliferate. We have identified part of the architectural system which controls this process. In this project we will establish how this works and its role in the body. This research will test whether this part of the cell�s architecture is a suitable drug target for the treatment of disorders in cell growth.
Regulation And Function Of The Protein Tyrosine Phosphatase TCPTP In Mitosis
Funder
National Health and Medical Research Council
Funding Amount
$455,250.00
Summary
The cell cycle is a universal process by which cells reproduce and it underlies the growth and development of all living organisms. The most important events of the cell cycle concern the replication of chromosomal DNA during S phase and the separation of replicated DNA into progeny cells at mitosis. Mitosis is morphologically the most dynamic phase of the cell cycle and involves the precise coordination of many processes that are governed by reversible protein phosphorylation. Protein phosphata ....The cell cycle is a universal process by which cells reproduce and it underlies the growth and development of all living organisms. The most important events of the cell cycle concern the replication of chromosomal DNA during S phase and the separation of replicated DNA into progeny cells at mitosis. Mitosis is morphologically the most dynamic phase of the cell cycle and involves the precise coordination of many processes that are governed by reversible protein phosphorylation. Protein phosphatases play an important role in reversible protein phosphorylation and they are essential for mitosis. This grant proposal is focused on understanding the regulation and function of protein phosphatases in mitosis. Our studies will provide novel insight into processes mediating mitosis and may lead to the development of alternative strategies for treating cancer.Read moreRead less
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.
Tyrosine Kinases And Phosphatases In Cell Cycle Checkpoint Responses
Funder
National Health and Medical Research Council
Funding Amount
$513,946.00
Summary
In order for an organism to grow and develop, the cells that make up the tissues and organs need to undergo a process of cellular division, wherein individual cells grow and then divide into two cells. During this process of cellular growth and division the entire genome needs to be duplicated (this occurs during S-phase) and then divided equally into the two daughter cells. In S-phase several so-called 'checkpoint' mechanisms exist which ensure that this occurs in an orderly and precise manner. ....In order for an organism to grow and develop, the cells that make up the tissues and organs need to undergo a process of cellular division, wherein individual cells grow and then divide into two cells. During this process of cellular growth and division the entire genome needs to be duplicated (this occurs during S-phase) and then divided equally into the two daughter cells. In S-phase several so-called 'checkpoint' mechanisms exist which ensure that this occurs in an orderly and precise manner. The so-called 'DNA replication checkpoint' delays S-phase progression in response to 'replication stresses' that may otherwise cause DNA damage. Protein tyrosine kinases (PTKs) are hyperactivated in many human solid tumours and blood malignancies contributing to varied aspects of tumour progression. Our preliminary studies indicate that the inactivation of PTKs by protein tyrosine phosphatases may be essential for the suppression of S-phase progression in response to replication stress. Our goal is to understand the molecular mechanisms by which PTKs and tyrosine phosphatases contribute to S-phase checkpoints. Our studies will provide important insights into DNA replication stress-induced checkpoint responses in mammals and identify unprecedented mechanisms by which hyperactivated PTKs may contribute to tumour development.Read moreRead less
Centrosome Overduplication Contributes To Tumorigenesis
Funder
National Health and Medical Research Council
Funding Amount
$495,010.00
Summary
Cancer can be simplistically thought of as a disease of cell growth and division. In order to improve current treatment regimes and identify new ones, the underlying mechanisms controlling cell proliferation need to be fully understood. By defining these regulatory mechanisms, targets for current chemotherapeutic agents can be further characterised and new ones identified. This will lead to the targeted developments of new classes of drugs which can be used in the fight against cancer.
Escape From BRAF-induced Human Melanocyte Senescence In The Genesis Of Melanoma
Funder
National Health and Medical Research Council
Funding Amount
$601,776.00
Summary
Melanoma is the most lethal form of skin cancer and activation of the MAPK growth pathway is a crucial step in the initiation of this cancer, but alone is insufficient, as most melanocytes with active MAPK exist in a growth arrested state. The mechanisms responsible for arresting melanocytes in the presence of active MAPK will be investigated. This project will discover why some melanocytes develop into melanomas whereas most do not.
Negative Regulators Of Nuclear Import; Potential Links To Cancer
Funder
National Health and Medical Research Council
Funding Amount
$495,829.00
Summary
Trafficking of proteins into the nucleus is critical to mammalian cell function, relating strongly to developmental processes and cancer. We have identified a new class of molecule - negative regulators of nuclear import - that function to prevent entry into the nucleus of key regulators of the cell cycle-apoptosis, and have a potential link thereby to cancer. We propose to determine their mechanism of action, modulation by cellular signals, and how important this is to cell function-cancer.