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Optimising Immunity Towards Cancers By Vaccination.
Funder
National Health and Medical Research Council
Funding Amount
$211,320.00
Summary
In this project we will be studying the mechanisms of how an efficient anti cancer vaccine could be generated. We will be using cervical cancer associated human papillomavirus type 16 E7 protein as the model protein in an experimental vaccine model in mice. The results obtained from this project not only able us to design better vaccines against cervical cancers in women but against many other cancers and viruses.
My research straddles biochemistry, cell biology and immunology. I am interested in the mechanisms of antigen presentation by dendritic cells, and the functions of the cystatin family of protease inhibitors.
Polynucleotide Vaccine Based On Targeted Delivery To Antigen Presenting Cells
Funder
National Health and Medical Research Council
Funding Amount
$540,075.00
Summary
We have previously generated a vaccine for breast and other adenocarcinomas by linking a breast cancer associated protein, MUC-1, to a sugar called mannan. This complex was capable of eradicating tumours in mice and its efficacy has been evaluated in human clinical trials (12 in total). As an extension to these studies we have now found that this sugar, mannan, can be used to deliver DNA to immune cells. The current project will evaluate a DNA vaccine for breast cancer.
The Role Of CD4+ T Cells In The Tumour Killing By CD8+ Memory T Cells.
Funder
National Health and Medical Research Council
Funding Amount
$303,000.00
Summary
It has been observed that human cancers grow in spite of the presence of tumour antigen specific memory CD8+ tumour killer T cells in the body. These memory killer cells are unable to kill the cancer. Our research work in a mouse model indicates that the CD8+ T cells can be activated to kill cancers if cancer antigen specific CD4+ T helper cells are activated. The mechanism how this happens is not clear. The role of regulatory or suppressor CD4+ T cells are also not known. In this proposal we wi ....It has been observed that human cancers grow in spite of the presence of tumour antigen specific memory CD8+ tumour killer T cells in the body. These memory killer cells are unable to kill the cancer. Our research work in a mouse model indicates that the CD8+ T cells can be activated to kill cancers if cancer antigen specific CD4+ T helper cells are activated. The mechanism how this happens is not clear. The role of regulatory or suppressor CD4+ T cells are also not known. In this proposal we wish to study the mechanism of how CD8+ memory T cells get activated to cancer killer cells by the CD4+ T helper cells. This information will help us to design better immunotherapies for cancer patients.Read moreRead less
The Role Of CD4+ T-helper Cells In The Generation, Maintenance And Activation Of A Long Lasting Anti-tumour CTL Effect.
Funder
National Health and Medical Research Council
Funding Amount
$247,383.00
Summary
In this research project we will be studying the mechanisms how a long-lasting anti-cancer response could be achieved by vaccination. This information not only will help to design better vaccines against cancers, but also will help to design better vaccines against viral diseases.
Mechanisms Of T Cell Migration And Interactions In Tumours
Funder
National Health and Medical Research Council
Funding Amount
$609,385.00
Summary
Cancer is still a leading cause of death. Thus, there is great need to develop improved anti-cancer therapies, which could be achieved by boosting the body's own resources, i.e. the immune system. Using a functional imaging approach, i.e. two-photon microscopy, we will directly visualise how tumour cells are attacked by the immune system. Mechanistic insight into this process will serve as a basis for the development of improved immuno-therapeutic strategies that aim to target cancer cells.
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.
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.
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