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.
Cancer is now the number one killer of Australians and there is an unmet medical need to develop new therapies that are safe and maximize anti-cancer efficacy. Cancer immunotherapy now represents a new fourth pillar in cancer treatment to complement surgery, radiotherapy and chemo-/targeted therapies. This application aims to develop new therapeutic approaches to broaden the effectiveness of cancer immunotherapy and potentially allow the treatment of a broader range of cancers and patients.
Potential Anti-tumour Agents: Iron Chelators Of The Pyridoxal Isonicotinoyl Hydrazone Class
Funder
National Health and Medical Research Council
Funding Amount
$472,770.00
Summary
Iron (Fe) is essential for proliferation. Generally, cancer cells have a high Fe requirement due to their rapid rate of proliferation making them very susceptible to iron chelators which deplete cells of Fe. The potential of this therapy has been confirmed by the entrance of the chelator, Triapine (Vion Pharmaceuticals), into clinical trials. Further, a wide variety of studies including clinical trials have shown that the clinically used Fe chelator, desferrioxamine (DFO), can have potent anti-t ....Iron (Fe) is essential for proliferation. Generally, cancer cells have a high Fe requirement due to their rapid rate of proliferation making them very susceptible to iron chelators which deplete cells of Fe. The potential of this therapy has been confirmed by the entrance of the chelator, Triapine (Vion Pharmaceuticals), into clinical trials. Further, a wide variety of studies including clinical trials have shown that the clinically used Fe chelator, desferrioxamine (DFO), can have potent anti-tumour activity. Indeed, in an important clinical trial (Cancer Res 1990;50:4929), a marked decrease in tumour burden was observed while there was no significant side effects, demonstrating an appreciable therapeutic index. However, DFO suffers serious problems, including that it requires long infusions and does not readily permeate cells. Considering this, during the current NHMRC grant, we developed a novel group of chelators that show far greater activity than DFO and Triapine at inhibiting cancer growth in vitro and in vivo (Richardson BLOOD 2004;104:1450). These studies have been published in high quality journals such as BLOOD and Clin Cancer Res (Richardson 1995, 1997, 1999, 2001, 2002, 2004a,b,c) Recently, a potent metastasis suppressor gene, known as differentiation related gene-1 (Drg-1), has been identified. Up-regulation of this molecule plays an important role in inhibiting the growth of primary cancers and their metastatic spread. Importantly, we have recently shown that our new chelators markedly up-regulate the expression of Drg-1 in cancer cells and at the same time markedly and selectively inhibit the growth of these cells (Richardson BLOOD 2004;104:2967). Our hypothesis is the marked increase in Drg-1 expression after treatment with chelators could inhibit cancer cell growth and metastasis. Studies in this NHMRC grant renewal will lead to the development of new therapies and a greater understanding of cancer metastasis and biology.Read moreRead less
Iron is essential for the growth of all cells. Generally, cancer cells have a high iron requirement due to their rapid rate of proliferation. This makes them susceptible to the action of drugs called iron chelators that deplete cell iron. A wide variety of studies, including clinical trials in leukemia and neuroblastoma patients, have shown that the clinically used chelator, desferrioxamine (DFO), can have potent anti-tumour activity. Indeed, in an important clinical trial, a marked decrease in ....Iron is essential for the growth of all cells. Generally, cancer cells have a high iron requirement due to their rapid rate of proliferation. This makes them susceptible to the action of drugs called iron chelators that deplete cell iron. A wide variety of studies, including clinical trials in leukemia and neuroblastoma patients, have shown that the clinically used chelator, desferrioxamine (DFO), can have potent anti-tumour activity. Indeed, in an important clinical trial, a marked decrease in tumour burden was observed while there were no significant side effects, demonstrating an appreciable therapeutic index. However, DFO suffers from serious problems, including that it requires long infusions and does not readily penetrate cells. Further, in some cancer patients, DFO has shown little activity. Considering these results, we have developed a new group of chelators that show far greater activity than DFO at inhibiting cancer cell growth. These studies have been published in high quality journals such as BLOOD (Richardson et al. 1995, 1997, 1999) and form the basis for the current study. In this study we will examine how these iron-binding drugs work to inhibit the growth of cancer cells compared to their normal counterparts. These studies are important for the rational design of even more effective chelators. Recent studies in my lab have shown that our new chelators have far greater activity than a drug currently used to treat leukemia, known as hydroxyurea (HU). Our studies also show that the chelators act by a variety of mechanisms, explaining their greater activity than HU. Furthermore, we have shown that these chelators show significant anti-tumour activity in mice. The potential of this form of therapy has been confirmed by the entrance of the chelator, Triapine, into clinical trials (Vion Pharmaceuticals, USA). Our chelators are more effective than Triapine, thus, the present project is crucial for developing novel anti-tumour therapies.Read moreRead less
RNA interference is a newly discovered means by which we are able to turn off cancer-causing genes with high precision. However, it is difficult to get the drug to every cancer cell. Therefore we are designing and testing new RNA interference molecules that are able to alert the immune system to the presence of the cancer thus causing its elimination. This will prove to be a more effective cancer treatment than current therapies.
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.
Structural And Functional Studies Of The Human IL-3 Receptor
Funder
National Health and Medical Research Council
Funding Amount
$307,946.00
Summary
This proposal will study a protein hormone that is implicated in blood cell cancers and inflammatory diseases and for which current treatments are inadequate. We will determine how the hormone receptor becomes activated, identify and characterise new agents that block this activation. This information will help in the development of new and highly specific drugs for use in certain cancers in inflammatory diseases.
In cancer cells the normal process of cell death (called apoptosis) is defective, helping abnormal cells to grow and multiply unchecked. The Bak protein is a member of the Bcl-2 family of apoptosis regulators, and plays a pivotal role in mediating cell death. By defining each step in Bak-mediated apoptosis, we aim to better understand how cancer cells accumulate, and how targeting the Bcl-2 family may lead to effective anti-cancer therapeutics.
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.
I am a pharmacologist-cell biologist-molecular biologist and chemist examining the metabolism of iron in normal and neoplastic cells and the development of iron chelators for the treatment of a variety of diseases e.g., ?-thalassaemia and cancer.