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.
Role Of MACROD2 Loss In DNA Repair, Chromosomal Instability And Development Of Colorectal Cancer: Clinical And Therapeutic Implications
Funder
National Health and Medical Research Council
Funding Amount
$772,871.00
Summary
The MACROD2 gene is deleted in one-third of human bowel cancers. We have discovered that MACROD2 deletion causes defective DNA repair and tumour chromosomal instability. Here, we will use novel laboratory models to show that MACROD2 loss actively promotes bowel cancer development. We will test the clinical implication of MACROD2 loss for predicting tumour therapy response and will investigate the potential of exploiting this deficiency for drug targeting.
Role Of Brm In Skin Tumour Progression From Benign To Malignant
Funder
National Health and Medical Research Council
Funding Amount
$457,267.00
Summary
Australia has the highest incidence of skin cancer in the world. Skin cancer is 3 times as common as all other cancers combined and continues to increase in incidence, particularly in the aging population. Skin cancer is caused by exposure to the ultraviolet radiation found in sunlight. Ultraviolet radiation causes the appearance of solar keratosis, or sunspots, benign lesions that are not particularly dangerous to human health. Some of these develop into malignant squamous cell carcinomas that ....Australia has the highest incidence of skin cancer in the world. Skin cancer is 3 times as common as all other cancers combined and continues to increase in incidence, particularly in the aging population. Skin cancer is caused by exposure to the ultraviolet radiation found in sunlight. Ultraviolet radiation causes the appearance of solar keratosis, or sunspots, benign lesions that are not particularly dangerous to human health. Some of these develop into malignant squamous cell carcinomas that can spread to other tissues and are potentially fatal. Little is known about the biological mechanisms involved in solar keratosis development into squamous cell carcinomas. We have identified the gene brm as being involved in this process. It has not previously been recognised that this gene is important for skin cancer development and therefore our preliminary studies have identified a potential new target. We will study the role of this gene in ultraviolet radiation induced skin carcinogenesis, determine whether it is mutated by ultraviolet radiation in human skin cancer, and what role in plays in some key biological processes in skin cancer development. This study will expand our understanding of malignant conversion during human skin carcinogenesis, the most prevalent human cancer in Australia.Read moreRead less
Adoptive Cell Transfer Incorporating Vaccination (ACTIV) Therapy For Cancer
Funder
National Health and Medical Research Council
Funding Amount
$601,950.00
Summary
We have made a breakthrough in a new treatment for cancer that can destroy large tumours in mice. The treatment involves a transfusion of white blood cells and an injection of a vaccine. In this project, we will seek to understand how the treatment works, and apply it to human white blood cells in preparation for a clinical trial in cancer patients.
Development Of Cancer Immunotherapy Using Gene-engineered T Cells In A Self-antigen Mouse Model
Funder
National Health and Medical Research Council
Funding Amount
$428,602.00
Summary
Killer T lymphocytes can penetrate tumours and their transfer into cancer patients has demonstrated some encouraging results, but this form of therapy and other approaches including vaccination remain ineffective in most cancer patients. In this project, we propose to improve the tumour trafficking and anti-tumour activities of killer cells by genetically engineering them with proteins that will enable them to recognise and destroy cancer cells.
Targeting Tumour-Stromal Interactions In Pancreatic Cancer
Funder
National Health and Medical Research Council
Funding Amount
$410,095.00
Summary
Pancreatic cancer claims five Australian lives every day and is one of the nations most lethal diseases. Despite aggressive treatment regimes, there has been no improvement in patient survival in the last decade. Evidence suggests that targeting cancer cells alone is not enough. The intense stromal reaction inhibits drug delivery and increases the aggressiveness of the tumours. Thus, depletion of the stroma or pancreatic stellate cells is a potential therapeutic target.
An Integrated Approach For The Efffective Adoptive Immunotherapy Of Cancer
Funder
National Health and Medical Research Council
Funding Amount
$468,119.00
Summary
Killer T lymphocytes can penetrate tumors and their transfer into cancer patients has demonstrated some encouraging results, but this form of immunotherapy remain ineffective in most cancer patients. We propose to improve the tumor trafficking and anti-tumor activities of killer cells by genetically engineering them with proteins that will enable them to recognise and destroy cancer cells. The outcomes of this project will validate this novel approach for treatment of cancer patients.
Redirecting T-cells For Immunotherapy Of Leukaemia And Lymphoma By The Expression Of A CD19-specific Chimeric Antigen Receptor Using The PiggyBac Transposon Gene Modification System
Funder
National Health and Medical Research Council
Funding Amount
$374,876.00
Summary
Most lymphomas respond to therapy but then relapse. Immune cells can attack and kill virus related lymphomas. However, most lymphomas are NOT virus related. We will create immune cells targeting these virus negative lymphomas by inserting artificial receptors into the immune cells. These receptors attach to the lymphoma and activate the immune cells. The immune cells will home to the lymphoma, kill lymphoma cells and persist in the body for many years, preventing lymphoma relapse.
My research is to learn more of the genetic and epigenetic mechanisms governing the development of the reproductive cell lineage, or the cells that make eggs and sperm. My research is required to better understand human reproduction and human embryonic, fetal and neonatal development, and will help in the treatment of diseases affecting these processes.
Compartmental Analysis Of T-cell Responses In Thoracic Malignancies
Funder
National Health and Medical Research Council
Funding Amount
$851,403.00
Summary
To improve immune therapy for cancer we have to be able to determine how cancer patients ‘see’ mutated cancer proteins. Blood is the easiest & most useful source of immune ‘killer’ cells for that task, but the lymph node that drains the tumour and the fluid that bathes a tumour probably contain a much higher number of these killer cells than blood. If so, studying them would help us better track responses to therapy and enable us to choose the best mutated proteins for a vaccine.