Apo2L/TRAIL Killing Of Tumour Cells And The Role Of Inhibitor Of Apoptosis Proteins
Funder
National Health and Medical Research Council
Funding Amount
$390,321.00
Summary
Melanomas and Gliomas are tumour types that respond poorly to current treatments. Current treatments are not only sometimes ineffective, but also unpleasant and may cause co-lateral damage. We will test 2 new targetted anti-cancer treatments, that so far appear to have minor side effects in small animal models, on these difficult to treat tumour types to see if and how they kill them. We also want to know whether these independent treatments can work together to kill tumours more effectively. Al ....Melanomas and Gliomas are tumour types that respond poorly to current treatments. Current treatments are not only sometimes ineffective, but also unpleasant and may cause co-lateral damage. We will test 2 new targetted anti-cancer treatments, that so far appear to have minor side effects in small animal models, on these difficult to treat tumour types to see if and how they kill them. We also want to know whether these independent treatments can work together to kill tumours more effectively. Although we will not personally test these drugs in clinical settings, these drugs or similar are currently in preclinical and clinical trials. This means that understanding how these drugs function is of paramount importance and may result in better clinical trials and possibly more rapid acceptance of the use of these drugs in patients.Read moreRead less
I am a cancer researcher trained in cell biology, immunology and molecular oncology. I made major contributions to the discoveries that defects in cell death can cause cancer, autoimmune disease and impair the response of cancers to chemotherapy. My current work aims to reach a detailed understanding of the molecular mechanisms of programmed cell death and to exploit this knowledge to develop novel therapeutics for cancer and autoimmune diseases that can directly activate this process.
How The Bcl-2 Protein Family Controls Apoptosis And Impacts On Cancer Development And Therapy
Funder
National Health and Medical Research Council
Funding Amount
$850,346.00
Summary
Impaired cell death (apoptosis) is now recognized as an important step towards cancer and a major barrier to effective therapy. The discoveries on apoptosis by Professor Jerry Adams and colleagues have galvanized the search for drugs that engage the cell’s apoptotic machinery as a new way to treat cancer. His proposed studies aim to clarify how apoptosis is controlled and how the control goes awry in cancer, and to determine how such drugs can be most effectively used to improve cancer treatment ....Impaired cell death (apoptosis) is now recognized as an important step towards cancer and a major barrier to effective therapy. The discoveries on apoptosis by Professor Jerry Adams and colleagues have galvanized the search for drugs that engage the cell’s apoptotic machinery as a new way to treat cancer. His proposed studies aim to clarify how apoptosis is controlled and how the control goes awry in cancer, and to determine how such drugs can be most effectively used to improve cancer treatment.Read moreRead less
Role Of Bak And Bax Membrane Anchors In Targeting And Apoptotic Pore Formation.
Funder
National Health and Medical Research Council
Funding Amount
$352,319.00
Summary
In cancer cells the normal process of cell death (called apoptosis) is defective, helping abnormal cells to grow and multiply unchecked. The Bak and Bax proteins are members of the Bcl-2 family of apoptosis regulators, and play a pivotal role in mediating cell death. By defining how these proteins form a pore in mitochondria, the point of no return in cell death, will help the development of novel anti-cancer agents that target the Bcl-2 family in general, and Bak and Bax in particular.
Developing Novel Anti-cancer Agens By High Throughput Chemical Screens For Small Molcules That Modulate The Pro-survival
Funder
National Health and Medical Research Council
Funding Amount
$125,000.00
Summary
Cancer is the second commonest cause of deaths in our community. Unfortunately, treatment often fails or causes unwanted side effects. This proposal seeks to discover and develop a novel class of anti-cancer drugs that act by directly activating programmed cell death (apoptosis). The Bcl-2 proteins are key regulators of cell death and by exploiting knowledge about these prime targets for cancer therapy, we aim to discover drugs that are potentially of considerable medical and commercial value.
Controlling The Pro-survival Protein Mcl-1: Discovering Novel Opportunities And Developing Innovative Approaches To Target Mcl-1 For Treating Cancers
Funder
National Health and Medical Research Council
Funding Amount
$749,415.00
Summary
Cancer cells are often sustained by evading cell death. Thus, a promising approach to develop new cancer treatments aims to restore their ability to commit cell suicide. Proteins related to Bcl-2 are, in this regard, attractive targets because they are prominent barriers to cell death. This project seeks to uncover how a Bcl-2 relative, Mcl-1, is regulated, and to explore how the mechanisms that underpin these processes can be targeted in cancers (melanomas, leukemias) that it sustains.
Elucidating The Cellular Processes That Are Critical For P53 Mediated Tumour Suppression
Funder
National Health and Medical Research Council
Funding Amount
$1,016,108.00
Summary
p53 is a tumour suppressor gene that is mutated in ~50% of human cancers. Mutations in p53 cause development of cancer and render malignant cells resistant to chemotherapy. We have identified genes regulated by p53 that appear critical for its tumour suppressive function. In this project, we will use innovative novel genetic tools to discover the cellular and biochemical functions of these genes. The ultimate goal of our studies is to identify novel targets for anti-cancer therapy.
Genetic Analysis Of Cell Death Pathways, Drug Resistance And Oncogenic Co-operativity In IL-3 Dependent Cell Lines
Funder
National Health and Medical Research Council
Funding Amount
$445,270.00
Summary
The ultimate fate of most of our cells is to die by committing suicide, because they are no longer required, are no longer functioning, or are potentially harmful. This normal physiological process is termed apoptosis . Inappropriate apoptosis can contribute to cell loss following heart attacks, stroke or neurodegenerative diseases, such as Alzheimer s or Parkinson s disease. Conversely, when cell death fails to occur, abnormal cells can accumulate and lead to cancer. In addition, because drugs ....The ultimate fate of most of our cells is to die by committing suicide, because they are no longer required, are no longer functioning, or are potentially harmful. This normal physiological process is termed apoptosis . Inappropriate apoptosis can contribute to cell loss following heart attacks, stroke or neurodegenerative diseases, such as Alzheimer s or Parkinson s disease. Conversely, when cell death fails to occur, abnormal cells can accumulate and lead to cancer. In addition, because drugs that are used to treat cancer may exert their effect by inducing apoptosis, a failure of this suicide response may cause resistance to chemotherapy. The genes of the apoptosis pathway function either to promote or inhibit cell death. We have found that some genes in the apoptosis pathway allow apoptosis to proceed rapidly, but do not decide the fate of the cell. Other genes are required for a cell to commit to die. If these genes are mutated then apoptosis does not occur and a functional cell may survive. The distinction between cells that decide fate and those that do not is crucial because it is only the genes that decide cell fate that can act as cancer genes, and are valid targets for therapy. We use a model in which apoptosis is caused by removal of a growth factor, using cell lines derived from mice that lack particular genes in the cell death pathway. These cells proliferate normally in the presence of growth factor, and allow us to determine the role of the genes when growth factor is withdrawn. Because these cells are sensitive to chemotherapeutic drugs, we can also determine the contribution these genes make to cancer drug sensitivity. Using this system, we have discovered that Puma, a gene known to be required for apoptosis in response to radiation, is also a critical activator of apoptosis following growth factor withdrawal. We will determine the manner in which Puma is regulated by growth factors, as well as identify and characterise other key components.Read moreRead less
Schistosomiasis is one of the world's most serious and prevalent diseases affecting nearly 200 million people world-wide. It is currently treated with a single drug, though there is growing concern about the development of resistance to it. In this proposal we will explore whether a new cellular pathway involving the cell death machinery we have identified in the disease-causing parasites could provide a possible target for the development of new treatments against schistosomiasis.