Molecular Targeting To Telomerase And Cancer Cell Immortality By A Novel Inhibitor
Funder
National Health and Medical Research Council
Funding Amount
$430,812.00
Summary
Infinite growth of cancer cells is a hallmark of cancer. Telomerase is required for cancer cell immortality. Inhibition of telomerase may thus offer an opportunity to stop cancer cells. We have identified an inhibitor of telomerase. This project will study the mechanisms of action of the novel inhibitor, investigating how to control cancer cell immortality as a baseline for more applied anti-cancer therapeutic studies.
Identification And Characterisation Of Amplified Oncogenes In Liposarcoma
Funder
National Health and Medical Research Council
Funding Amount
$354,293.00
Summary
Liposarcoma is the commonest single subtype of sarcomas, a group of cancers that disproportionately affects the young. The overall mortality for liposarcomas is approximately 50%. Chemotherapy may temporarily controlling disease in under a third of patients, but is toxic and cannot achieve cure. We have identified new potential therapeutic targets, and aim to develop these in the clinic.
Functional Genomics Approaches To Define New Drug-targets For Cancer Therapy
Funder
National Health and Medical Research Council
Funding Amount
$374,797.00
Summary
Cancer is a deadly disease that results from the accumulation of genetic mistakes (mutations) that encourage cells to divide and spread. There are some key mutations that occur in many different types of cancer. My project aims to exploit this common blueprint to design drugs that will selectively kill cancer cells, while leaving normal cells unharmed. We will identify new drug targets for the treatment of breast, colon and lung cancer and assess these targets in a variety of model systems.
One of the hallmarks of cancer cells is their ability to divide and multiply in an uncontrolled manner. Specific proteins that make up the skeleton of cells (cytoskeleton) play an important part in the cell division process and as such make extremely important targets for anticancer therapy. Our research is developing ways to best target cell division proteins so that we can make drug resistant cancer cells sensitive to chemotherapy.
I am a cancer molecular and cell biologist determining the mechanisms of anticancer drug action and resistance in both childhood and adult malignancies. My research involves the development and investigation of both in vivo and in vitro models of resistan
Synthetic Analogues Of The Actinomycin, Quinamycin And Nogalamycin Groups Of Antitumour Antibiotics
Funder
National Health and Medical Research Council
Funding Amount
$376,433.00
Summary
The principal difficulty in the treatment of the common solid tumours that cause the majority of cancer deaths is the problem of drug resistance. For example, many patients with cancer of the lung, breast or colon respond well to drug treatment with their tumours initially regressing, only to return later in an aggressive drug-resistant form. In this event, the inevitable outcome is that the tumour grows through drug treatment and the patient eventually succumbs and dies. This is also a familiar ....The principal difficulty in the treatment of the common solid tumours that cause the majority of cancer deaths is the problem of drug resistance. For example, many patients with cancer of the lung, breast or colon respond well to drug treatment with their tumours initially regressing, only to return later in an aggressive drug-resistant form. In this event, the inevitable outcome is that the tumour grows through drug treatment and the patient eventually succumbs and dies. This is also a familiar scenario in the treatment of adults with leakaemias and non-Hodgkins lymphomas. The underlying cause of drug resistance is the genetic instability of cancer cells which results in tumours that are heterogeneous, making it almost inevitable that a cancer cell will arise that is resistant to treatment. There are many mechanisms of resistance, some of which are peculiar to particular drug types, some are permeability barriers and some involve genetic deregulation of the biochemistry of cell death. One way of subverting resistance is by the use of drugs whose mechanism of action is novel so that the tumour is challenged to devise a new defense. Here, we are attempting to develop synthetic analogues of a class of naturally- occurring antitumour antibiotic whose mechanism of action is unusual but which has not been exploited by medicinal chemists because of the difficulty of the chemistry involved. These antibiotics work by binding to DNA and inhibiting the first step in the process whereby genes are turned into proteins. We have designed compounds that are chemically accessible that our preliminary work suggests mimic the DNA-binding and biological properties of the natural antibiotics. The proposed work will enable us to evaluate whether this new class of agent has experimental antitumour activity, particularly amongst drug-resistant tumours.Read moreRead less
High Resolution Genome-wide Genomic Analysis Of DCIS To Identify Genes Involved In Disease Initiation And Progression
Funder
National Health and Medical Research Council
Funding Amount
$543,370.00
Summary
DCIS is the most common type of noninvasive breast cancer and in some women may progress to malignant disease but little in know about how it develops. We will bring to bear our experience with cutting edge technology and access to extensive clinical resources to the analysis of a large series of pure DCIS with the aim of identifying previously unknown cancer causing genes. This data will lead to the identification of novel breast cancer genes that will assist clinical management.
A Preclinical Model Of Relapse In Acute Lymphoblastic Leukaemia
Funder
National Health and Medical Research Council
Funding Amount
$573,515.00
Summary
Leukaemia is the most common type of cancer in children but resistance to therapy continues to be a significant problem. This project will investigate the biology of drug-resistance and relapse using a mouse model that replicates the human disease. We hope to identify novel therapeutic targets that can be used in combination with existing therapies to improve outcomes in this disease. We also hope to identify markers that can be used to screen for patients at increased risk of relapse.
Roles Of Impaired Apoptosis And Differentiation In Tumourigenesis And Therapy
Funder
National Health and Medical Research Council
Funding Amount
$21,656,910.00
Summary
The ten scientific laboratories in this program have joined forces to investigate two ways in which tumours develop. Both are of particular interest, because they suggest new ways in which cancer might be overcome. Most of our tissues are continually renewed throughout life by production of new cells. Therefore many of the old cells in each tissue must die off to maintain the proper cell numbers. To eliminate cells that are no longer needed or have become damaged, the body has developed a remark ....The ten scientific laboratories in this program have joined forces to investigate two ways in which tumours develop. Both are of particular interest, because they suggest new ways in which cancer might be overcome. Most of our tissues are continually renewed throughout life by production of new cells. Therefore many of the old cells in each tissue must die off to maintain the proper cell numbers. To eliminate cells that are no longer needed or have become damaged, the body has developed a remarkable cell suicide process termed apoptosis. Unfortunately, however, occasionally a random accident to the genes in one of our cells prevents the machinery for apoptosis from being turned on. In that case, the cell will not die when it should and, by continually dividing, it may eventually give rise to a cancer. Since most cancer cells still retain most of the machinery for apoptosis, however, a drug that could switch on this natural cell death machinery would provide a promising new approach to cancer therapy. Identifying and developing such drugs is one major long-term goal of this program. The other focus of our program concerns stem cells. These are rare cells with the remarkable ability to generate an entire tissue. For example, one of our laboratories has identified stem cells that can generate all the cells in the breast. The almost unlimited regenerative capacity of stem cells has a built-in danger. If a stem cell acquires the ability to proliferate excessively, it can go on to form a tumour. Indeed, many cancer researchers now suspect that rare stem cells within a tumour cause its inexorable growth. If tumour growth is maintained by stem cells, it will be essential to develop new forms of therapy that target these rare cancer stem cells rather than merely the bulk of the tumour cells. This is another key long-term goal of our program.Read moreRead less