Development Of Modified IGF-binding Proteins As Novel Anti-cancer Chemotherapeutics
Funder
National Health and Medical Research Council
Funding Amount
$77,375.00
Summary
We propose to enhance the effectiveness of current anti-cancer treatments by co-administering a protein to sequester growth factors that promote the resistance of cancer cells to chemotherapy. We aim to achieve improved destruction of breast and colorectal cancers but with reduced adverse side effects. Our in vitro data show the effectiveness of this novel co-therapeutic which is a modified form of a natural carrier protein for these growth factors. This application seeks funding to enable proof ....We propose to enhance the effectiveness of current anti-cancer treatments by co-administering a protein to sequester growth factors that promote the resistance of cancer cells to chemotherapy. We aim to achieve improved destruction of breast and colorectal cancers but with reduced adverse side effects. Our in vitro data show the effectiveness of this novel co-therapeutic which is a modified form of a natural carrier protein for these growth factors. This application seeks funding to enable proof of concept in vivo in order to attract commercial funding for clinical trials.Read moreRead less
A Novel One-step Approach In The Early Diagnosis Of Prostate Cancer
Funder
National Health and Medical Research Council
Funding Amount
$102,150.00
Summary
In order to avoid the invasiveness and imprecision of current prostate cancer detection, this programme is directed to developing a non-invasive and repeatable, accurate approach. This research project is designed to optimise retrieval of prostate cells from ejaculate and to compare two methods for profiling selected genetic changes to diagnose prostate cancer. The refinement of techniques, outlined in the application, is essential before proceeding to a clinical trial.
Development Of A Serum Based Test For Aggressive Prostate Cancer.
Funder
National Health and Medical Research Council
Funding Amount
$144,950.00
Summary
Prostate cancer is relatively slow growing, taking decades to reach clinical significance. A critical phase in the progression of prostate cancer is the transformation from latent (or dormant) to aggressive tumours; hence the saying that many men die with prostate cancer, rather than of prostate cancer. We aim to develop a test utilising inhibin-activin proteins as surrogate markers of aggressive disease based on our previous studies of a significant correlation between the expression of inhibin ....Prostate cancer is relatively slow growing, taking decades to reach clinical significance. A critical phase in the progression of prostate cancer is the transformation from latent (or dormant) to aggressive tumours; hence the saying that many men die with prostate cancer, rather than of prostate cancer. We aim to develop a test utilising inhibin-activin proteins as surrogate markers of aggressive disease based on our previous studies of a significant correlation between the expression of inhibins in tissues from men with high grade prostate cancer. This study aims to validate the correlation using serum rather than a tissue based assay.Read moreRead less
Evaluation Of The Therapeutic Potential Of SFTI-FCQR, A Novel Kallikrein 4-specific Protease Inhibitor
Funder
National Health and Medical Research Council
Funding Amount
$167,303.00
Summary
Prostate and ovarian cancers are on the rise in Australia's ageing population. In previous work, we have studied prostate and ovarian cancer cells that we have engineered to make the protease KLK4. These cells show signs associated with aggressive tumours and in particular may have some of the changes found in cancer cells that spread from their site of origin (metastasize). In this project, we will look at a drug-like molecule that we have designed with the aim of blocking the activity of KLK4.
Production Of Chimeric Monoclonal Antibodies To Pim1, A Novel Therapeutic Target For Cancer Treatment
Funder
National Health and Medical Research Council
Funding Amount
$188,850.00
Summary
Almost one in six men will develop prostate cancer during his lifetime. Every year, around 10,000 Australian men are diagnosed and more than 2,500 die of the disease, making prostate cancer the second largest cause of male cancer deaths after lung cancer. The research progress made on prostate cancer over the past 10 years has been encouraging. However the five-year survival rate remains low. There is a vital need to develop new methods to treat this disease. An exciting principle has emerged re ....Almost one in six men will develop prostate cancer during his lifetime. Every year, around 10,000 Australian men are diagnosed and more than 2,500 die of the disease, making prostate cancer the second largest cause of male cancer deaths after lung cancer. The research progress made on prostate cancer over the past 10 years has been encouraging. However the five-year survival rate remains low. There is a vital need to develop new methods to treat this disease. An exciting principle has emerged recently with the use of monoclonal antibodies (Mabs) such as Herceptin (a humanised anti-HER2 Mab), which is now being widely used to treat breast cancer. We produced 2 Mabs to Pim1, which significantly inhibited prostate cancer cell growth in mouse prostate cancer model. Pim1 is a novel oncoprotein, a biomarker for the treatment of prostate cancer as it overexpresses in more than 90% of prostate cancer, but not or less expressed in normal prostate, demonstrated by genearrays and immunohistochemical staining. Pim1 plays an important role in cell survival, proliferation and metastasis. Pim1 is a novel target, and the anti-Pim1 Mabs may be of value for the cancer therapy in humans. However, the murine Mab can not be repeatedly used in human because human would produce anti-mouse antibody response, and the murine Mab would be rapidly removed from circulation, which will greatly limit the therapeutic potential of the Mabs. Fortunately, the problem can be overcome by the use of hybrid chimeric antibodies. In this study, we are going to use chimeric technology to humanise the anti-Pim1 Mab and test them in vitro and in mouse model for the preclinical studies. We have had patent to protect our finding, and we are confident to produce mouse-human chimeric Mab for the future clinical trial as we have proper knowledge, techniques. We are also optimic for the future clinical trial as we have the experiences on commercialisation.Read moreRead less
Development Of Anti-CXCR2 Monoclonal Antibodies For Tumour Therapy
Funder
National Health and Medical Research Council
Funding Amount
$174,867.00
Summary
New therapies to treat cancers and inflammatory diseases are urgently required. Our aim is to develop a new treatment for cancer and inflammation, by blocking the chemokine receptor CXCR2 which is central to angiogenesis (blood vessel growth) and inflammation. We have produced a highly effective monoclonal antibody (mAb) inhibitor of CXCR2, that is suitable for preclinical and clinical development. The project aims to examine the efficacy of this mAb in mouse tumour models and inflammation.
The Development Of Store Operated Calcium Channel Monoclonal Antibody Inhibitors As A Therapeutic Option For Breast Cancer Treatment
Funder
National Health and Medical Research Council
Funding Amount
$230,753.00
Summary
Despite recent advances in the treatment of breast cancer, a significant proportion of women with this disease receive little benefit from currently available treatments and die from breast cancer. Hence, new therapies for the breast cancers with the poorest prognosis are needed. This grant exploits our earlier finding that a specific calcium channel is a likely therapeutic target for breast cancer. Funding from this grant will be used to develop an inhibitory monoclonal antibody to this target.
The majority of deaths from cancer are due to metastasis, which is the formation of secondary tumours at sites remote from the primary tumour. Metastasis involves conversion of some tumour cells to an invasive, migratory form in a process that is controlled by small genetic regulators known as microRNAs. In this project we will conduct experiments aimed to provide a proof of principle demonstration in mice that microRNAs can be used to block the formation of metastases.