Targeted Alpha Therapy For Metastatic Breast Cancer Using Alpha-Herceptin
Funder
National Health and Medical Research Council
Funding Amount
$332,420.00
Summary
The specific aim of this proposal is to demonstrate, in non-human primates, proof–of-concept of a patented new platform vaccine technology (scrambled antigen vaccine or SAVINE) designed to encode all the protein sequences of an infectious agent, in this case HIV-1. These are arranged as equal-sized, overlapping fragments such that all potential T cell epitopes that are needed to induce broad T-cell-mediated immunity are maintained. The synthetically designed vaccine uses consensus sequences of H ....The specific aim of this proposal is to demonstrate, in non-human primates, proof–of-concept of a patented new platform vaccine technology (scrambled antigen vaccine or SAVINE) designed to encode all the protein sequences of an infectious agent, in this case HIV-1. These are arranged as equal-sized, overlapping fragments such that all potential T cell epitopes that are needed to induce broad T-cell-mediated immunity are maintained. The synthetically designed vaccine uses consensus sequences of HIV-1 to provide universal coverage of the major HIV-1 strains for a global population. The synthetic systematically designed HIV-1 vaccine will be delivered using our newly developed prime-boost immunisation regime that induces particularly high levels of cell-mediated immunity.Read moreRead less
Synthetic Approaches For Dissection Of The Signalling Response Heterogeneity And Targeted Therapeutic Use Of Type-1 Interferons
Funder
National Health and Medical Research Council
Funding Amount
$375,974.00
Summary
Type-1 interferons have been used to treat at least 14 diseases, including cancer, hepatitis and multiple sclerosis. Differing success of treatment and serious side effects felt by patients, however, have limited use of these otherwise powerful therapies. I aim to better understand the responses different cells have to interferons to improve their utility in the clinic. Also, I will develop approaches to target interferons to the site of disease, reducing the side effects felt by patients.
Targeted Alpha Therapy: Development Of A New Treatment For Metastatic Cancer
Funder
National Health and Medical Research Council
Funding Amount
$394,400.00
Summary
Breast cancer is the most commonly diagnosed, malignant cancer in women and prostate cancer is the most common non-life style related cancer in men. In spite of the most aggressive therapy, a significant percentage of men and women die of secondary disease (metastases) which usually spreads in the early stages. Currently, therapy is limited to chemotherapy and hormone therapy, both of which show clinical improvement but long term survival is uncertain. Targeted alpha therapy (TAT) is a new cance ....Breast cancer is the most commonly diagnosed, malignant cancer in women and prostate cancer is the most common non-life style related cancer in men. In spite of the most aggressive therapy, a significant percentage of men and women die of secondary disease (metastases) which usually spreads in the early stages. Currently, therapy is limited to chemotherapy and hormone therapy, both of which show clinical improvement but long term survival is uncertain. Targeted alpha therapy (TAT) is a new cancer treatment that we are developing in mouse models of human breast and prostate cancer. With TAT we are exploiting the fact that aggressive breast and prostate cancer cells, but not normal cells, express a particular tissue-barrier degrading protein system (uPA) which is specifically recognised by a natural inhibitor protein (PAI2). This protein inhibitor is labeled with a highly effective cell killing agent, a radioisotope that emits high energy alpha particles with a short range of only a few cell diameters . The alpha-labeled PAI2 selectively kills cancer cells at their most malignant stage by targeting the uPA system on these cells. Another benefit of TAT is that little radiation damage occurs to nearby or distant normal cells. Thus side-effects would be minimised. The outcome of our research to date has been to show the potential of our unique TAT approach as a possible new therapy for breast and prostate cancer. This therapy may well prove beneficial for other cancers. Further safety evaluations studies in mice will be followed by a dose tolerance clinical trial in humans. We expect to be able to show that our TAT will regress breast and prostate cancer tumours without complications in mice. The human trials will show the tolerance limits to TAT. If successful, TAT could provide the basis for a major change in prognosis and quality of life of breast and prostate cancer patients.Read moreRead less
Therapeutic Targeting Of MYCN Oncoprotein Stability In Neuroblastoma
Funder
National Health and Medical Research Council
Funding Amount
$590,206.00
Summary
A high level of MYCN protein is a major indicator of aggressive neuroblastoma (NB) but unfortunately there have been many barriers to the design of targeted therapies. We have identified a protein called PA2G4 which is a cofactor for MYCN in promoting cancer cell growth. We have developed a compound which inhibits PA2G4 and MYCN protein levels and reduces tumour growth. We will examine how PA2G4 cause aggressive tumour characteristics and test new methods to block PA2G4.
Treatments that target cancer causing genes called oncogenes have resulted in new treatment paradigms for cancer. We suggest that outcomes of patients with cancer will be further substantially improved by understanding how cancers can overcome resistance to these treatments that develops in many patients. To accelerate the adoption of these and other new treatments for cancer we will also develop new frameworks for clinical trials.
Melanoma Genetics: Clinical Translation Of The Germline-somatic Continuum
Funder
National Health and Medical Research Council
Funding Amount
$2,231,372.00
Summary
While new targeted and immune therapies can improve prognosis from metastatic melanoma, long-term survival for most patients remains elusive due to drug resistance or failure of the immune system to kill the tumour. There thus remains a significant need to improve early detection, monitoring of relapse, and treatment strategies, to increase survival and provide cures. My research vision addresses these three pillars of cancer research using innovative and cutting edge genetic approaches.
Next-generation Glioblastoma Multiforme Therapies Based On Multistage Delivery Nanovectors
Funder
National Health and Medical Research Council
Funding Amount
$314,644.00
Summary
Nanomedicine provides novel therapies with enhanced treatment success and reduced side effects, which improve the patient’s quality of life. Drug delivery systems that are able to treat highly drug-resistant tumours such as glioblastoma multiforme (GBM) are a key target for nanomedicine-based therapies. We will investigate a new GBM treatment by developing a multistage delivery nanovector to selectively carry and release a combination of chemical and physical therapeutics.
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.
Design And Application Of New Nanomaterials Theranostic Platforms For Targeted Treatment Of Cancer
Funder
National Health and Medical Research Council
Funding Amount
$530,626.00
Summary
The project aims to develop intelligent drugs that attract to malignant tumors like magnets. These powerful, next-generation chemotherapy drugs seek out cancerous cells, allowing physicians to see exactly where tumours lie. Nanoparticles inside the drugs then switch on upon contact with X-ray radiation beams. This new method, which can diagnose, deliver targeted therapy and monitor the response to therapy all at the same time, would reduce the amount of radiation needed to kill cancer cells.
Strategies For Enhancing The Treatment Of Colon Cancer.
Funder
National Health and Medical Research Council
Funding Amount
$590,785.00
Summary
Colorectal cancer is the third leading cause of cancer related death in Australia. Strategies to improve outcomes for these patients are urgently needed. This NHMRC SRF Fellowship will seek to identify new molecules in cancer cells which can be targeted to treat this disease, and to discover genes which can be used to improve patient response to treatment.