Preclinical Development Of A Therapeutic Anticancer Antibody To C-Met
Funder
National Health and Medical Research Council
Funding Amount
$435,530.00
Summary
Many common cancers cannot be effectively treated. A range of these cancers (e.g. gastric and lung cancer) display the molecule c-Met on their cell surface. c-Met promotes tumour growth; therefore, blocking c-Met is a promising strategy for treating these cancers. However, no antibodies or drugs that target c-Met have been licensed. The therapeutics that are being developed to target c-Met all have considerable limitations. Thus, there is an opportunity to develop a 'best-in-class' therapeutic.
Osteosarcoma is the most common tumour of bone. Recent success in targeting immune checkpoint blockers such as Programmed death-1 (PD-1) in genomically complex tumours suggests that osteosarcomas may be amenable to such strategies. We will characterise the role of the PD-1 pathway in osteosarcoma development and growth. Using preclinical mouse models we will investigate the biology of the PD-1 pathway and study its potential as a therapeutic target in advanced and resectable osteosarcoma.
Toward Effective Targeted Therapies For Acute Myeloid Leukaemia (AML)
Funder
National Health and Medical Research Council
Funding Amount
$551,345.00
Summary
Standard chemotherapy for acute myeloid leukaemia (AML) is highly toxic, and has not changed in over 40 years. We will conduct a world-first clinical trial incorporating ABT-199 (Venetoclax) to target BCL2 into the standard-of-care treatment for AML. A second initiative will explore the potential for small molecule inhibitors to simultaneously target both BCL2 and its related partner MCL1, to create a “chemotherapy-free” regimen for AML. These studies promise to herald a new era in AML therapy.
Harnessing Anticalin Technology As A Multi-targeted Treament Approach For Vision Loss
Funder
National Health and Medical Research Council
Funding Amount
$627,273.00
Summary
Diabetes is a leading cause of vision loss and blindness worldwide and is caused by two factors called VEGF and Ang2, which damage blood vessels. Current treatments only block VEGF and many patients do not respond and suffer irreversible damage to sight. We have used ground-breaking anticalin technology to make a new drug (PRS-AUS1) that blocks both VEGF and Ang2. Studies will be performed in animal models and move to patients where we expect improved outcomes compared to current treatments.
Developing New Therapeutic Strategies For Brain Cancer
Funder
National Health and Medical Research Council
Funding Amount
$763,845.00
Summary
Each year, over 1,500 Australians will develop brain cancer. Unlike many cancers, it cannot be prevented by lifestyle changes. Adults with brain cancer usually die within 2 years. The overall aims of this funding are to extend patients' lives and build brain cancer research in Australia so that we have the best chance of curing this disease. The expected outcome is clinical trial of drug candidates for the most common and most deadly brain cancer, high-grade glioma.
Tailoring Targeted Therapy To DNA Repair-defective High-Grade Serous Ovarian Cancer
Funder
National Health and Medical Research Council
Funding Amount
$802,247.00
Summary
Ovarian cancer is a major cause of cancer death in women because current treatments are inadequate. Half of aggressive ovarian cancers have abnormalities in DNA repair and should be susceptible to new PARP inhibitor therapy, yet not all those respond. By developing a new model of studying human ovarian cancers in mice, we can discover markers to predict which ovarian cancers will respond best to these exciting new treatments.
An Integrated Systems Biology Approach For The Development Of New Therapeutic Strategies For The Treatment Of High Grade Glioma
Funder
National Health and Medical Research Council
Funding Amount
$696,404.00
Summary
Glioma, the most common adult brain cancer, is incurable. Recent advances now allow us to grow glioma cells directly from patients in the laboratory in a way that preserves the features of the original tumor. In this proposal we will systematically analyze such cells using state-of-the-art technologies to identify new processes important to glioma, which in turn should facilitate the identification of innovative therapeutic approaches.
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.
Utilization Of Gene-engineered T Cells For Enhancing Cancer Immunotherapy
Funder
National Health and Medical Research Council
Funding Amount
$761,656.00
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, whilst minimizing toxicity to normal tissue.
New Strategies For Enhancing Chimeric Antigen Receptor (CAR) T Cell Therapy For Cancer
Funder
National Health and Medical Research Council
Funding Amount
$849,540.00
Summary
The role of the immune system in cancer is now recognised as highly important, highlighted by the success of immunotherapy in patients. Yet many patients fail to respond to this form of treatment due to low frequency of lymphocytes present at the tumor site. A new form of immunotherapy involving transfer of gene-modified lymphocytes is a potential way to overcome this problem. This project will explore new strategies to enhance the utility of this approach against blood and solid cancers.