Investigating The Role Of Mutant P53 And MCL-1 In The Sustained Growth Of MYC Lymphomas And Strategies For Targeted Therapy
Funder
National Health and Medical Research Council
Funding Amount
$616,940.00
Summary
A large number of human cancers have abnormal expression of a protein called MYC, leading to rapid growth. We found that when another protein called MCL-1 was inactivated, the lymphomas regressed. Importantly, mutations in the tumour suppressor gene called p53 are frequently found in cancer cells and we noticed that this could reduce the dependency on MCL-1. We aim to investigate this further in this grant proposal, in part using a novel drug that targets MCL-1.
Deciphering The Function Of Caspase-2 In DNA Damage Response And Tumour Suppression
Funder
National Health and Medical Research Council
Funding Amount
$808,007.00
Summary
Aberrant cell death and DNA damage response (DDR) are hallmarks of tumourigenesis. Recently we have discovered that an enzyme, caspase-2, previously implicated in cell death execution, also works in DDR and acts as a tumour suppressor. We now wish to validate these finding in preclinical models of cancer and understand precisely how caspase-2 safeguards against cancer development. These studies will help better understand tumourigenesis and may lead to the discovery of new drug targets.
Mechanisms Of Cytokine Independence During The Development Of Leukaemia
Funder
National Health and Medical Research Council
Funding Amount
$598,163.00
Summary
Signals from growth factors such as cytokines and hormones are required for cell survival. In their absence cells activate an in-built self-destruct process. Determining how cytokines regulate cell death will provide novel targets so that unwanted cells (like cancer cells) can be triggered to die and needed cells (such as brain cells) can survive.
PROTEIN TARGETS FOR THE STEROID RECEPTOR MODULATOR, CYCLOPHILIN 40
Funder
National Health and Medical Research Council
Funding Amount
$374,828.00
Summary
Steroids bind to specific receptor proteins in steroid responsive cells. These receptors are kept in a steroid-binding ready state by chaperone proteins which function to fold the receptors appropriately. The major chaperone protein is heat shock protein, hsp90. A second family of proteins called immunophilins, cooperate with hsp90 in receptor folding. These immunophilins can bind to immunosuppressant drugs, which may result in a change in receptor function. We have identified one of these immun ....Steroids bind to specific receptor proteins in steroid responsive cells. These receptors are kept in a steroid-binding ready state by chaperone proteins which function to fold the receptors appropriately. The major chaperone protein is heat shock protein, hsp90. A second family of proteins called immunophilins, cooperate with hsp90 in receptor folding. These immunophilins can bind to immunosuppressant drugs, which may result in a change in receptor function. We have identified one of these immunophilins as cyclophilin 40 ( CyP40), a protein that binds the immunosupressant drug, cyclosporin A. We have recently found that, in addition to binding to hsp90, CyP40 may bind to and regulate the function of other proteins which are important in how cells grow and die. The aims of this project are to study how CyP40 binds to hsp90 and to these other proteins and to determine the functional outcomes of these interactions.Read moreRead less
The Role Of Steatosis In Promoting Cellular Injury And Fibrogenesis In Human Liver Disease
Funder
National Health and Medical Research Council
Funding Amount
$414,375.00
Summary
Lay Description Fatty liver (steatosis) is important because it increases the vulnerability of the liver to factors that trigger inflammation and fibrosis. Patients with steatosis may develop steatohepatitis spontaneously and this increases the risk and rate of progression to cirrhosis, with consequent liver-related morbidity and mortality. In addition, steatosis significantly potentiates the severity of liver damage that is caused by other agents such as drugs or infections. To improve the prog ....Lay Description Fatty liver (steatosis) is important because it increases the vulnerability of the liver to factors that trigger inflammation and fibrosis. Patients with steatosis may develop steatohepatitis spontaneously and this increases the risk and rate of progression to cirrhosis, with consequent liver-related morbidity and mortality. In addition, steatosis significantly potentiates the severity of liver damage that is caused by other agents such as drugs or infections. To improve the prognosis of patients with fatty livers, it is important to understand why hepatic steatosis increases the risk for more serious liver disease. To date, much of our understanding of mechanisms of liver injury in fatty liver disease comes from animal models, and these findings have not been systematically evaluated in the human disease. Apart from optimizing body weight, there is no established treatment of fatty liver disease. Delineation of the mechanisms involved in liver injury will allow the development of specific protective strategies for steatotic livers.Read moreRead less
Cell Cycle Regulation By The Epidermal Growth Factor Receptor
Funder
National Health and Medical Research Council
Funding Amount
$227,036.00
Summary
The rate of growth and death of normal cells is regulated through signals transmitted from the cell surface to the nucleus. In many human cancers the normal regulatory mechanisms are subverted, leading to uncontrolled growth of the cells. We aim to characterize the signals that are initiated by binding of the Epidermal Growth Factor (EGF) to its receptor and to understand how these signals influence the ability of the cell to divide and to survive. We will identify the pathways that contribute t ....The rate of growth and death of normal cells is regulated through signals transmitted from the cell surface to the nucleus. In many human cancers the normal regulatory mechanisms are subverted, leading to uncontrolled growth of the cells. We aim to characterize the signals that are initiated by binding of the Epidermal Growth Factor (EGF) to its receptor and to understand how these signals influence the ability of the cell to divide and to survive. We will identify the pathways that contribute to uncontrolled growth in tumor cells. This knowledge is necessary for the design of new therapies targetted to the molecular lesions which stimulate solid tumors.Read moreRead less
CHARACTERISATION OF A NOVEL REGULATOR OF PHOSPHOINOSITIDE 3-KINASE-MEDIATED CELL PROLIFERATION AND PLATELET SIGNALLING
Funder
National Health and Medical Research Council
Funding Amount
$500,091.00
Summary
Critical functions such as cell growth, cell death and metabolism, are tightly controlled by key proteins which respond to specific stimuli. Perturbation of this process may lead to uncontrolled growth and cancer. This project proposes to examine the potential of a novel protein (an enzyme) as a physiological regulator of cell growth. It is proposed that this enzyme may function as a brake in preventing the evolution of a cancerous state. We will also study the ability of the novel enzyme to inf ....Critical functions such as cell growth, cell death and metabolism, are tightly controlled by key proteins which respond to specific stimuli. Perturbation of this process may lead to uncontrolled growth and cancer. This project proposes to examine the potential of a novel protein (an enzyme) as a physiological regulator of cell growth. It is proposed that this enzyme may function as a brake in preventing the evolution of a cancerous state. We will also study the ability of the novel enzyme to influence other diverse functions, such as uptake of glucose, and blood clot initiation.Read moreRead less