Targeted development of dual action antitumour and antiangiogenic agents using differential and functional proteomics. There is an enormous need to develop more effective and less toxic therapeutic approaches to reduce the social and economic burden of cancer. The recent identification of small molecules that can act by both destroying cancer cells and the blood vessels that carry nutrients to them has provided a unique opportunity to define the pathways involved in the action of these agents in ....Targeted development of dual action antitumour and antiangiogenic agents using differential and functional proteomics. There is an enormous need to develop more effective and less toxic therapeutic approaches to reduce the social and economic burden of cancer. The recent identification of small molecules that can act by both destroying cancer cells and the blood vessels that carry nutrients to them has provided a unique opportunity to define the pathways involved in the action of these agents in order to develop more potent drug analogues. Development of these molecules will involve a collaborative and multidisciplinary link with our industry partner and the use of frontier technologies that may lead to improved health and economic outcomes for Australia. Read moreRead less
Rational Optimisation of the Uptake of Metal-Based Anti-Cancer Agents by Tumours. In this project will develop an understanding of how anticancer drugs are taken up, distributed and modified in tumours. The information gathered will be of value to all those developing new anticancer drugs and we will then use it to develop new drugs that more selectively target tumours and therefore have reduced side effects. Successful development of less toxic anticancer agents would lead to less debilitating ....Rational Optimisation of the Uptake of Metal-Based Anti-Cancer Agents by Tumours. In this project will develop an understanding of how anticancer drugs are taken up, distributed and modified in tumours. The information gathered will be of value to all those developing new anticancer drugs and we will then use it to develop new drugs that more selectively target tumours and therefore have reduced side effects. Successful development of less toxic anticancer agents would lead to less debilitating treatment, more effective treatment, and an increase in the number of patients effectively treated. Effective anticancer drugs can also be very large income earners for Australia.Read moreRead less
Improvement of anthracycline chemotherapy by enhancement of apoptotic responses and tumour targeted activation. Improved outcomes for anthracycline anticancer chemotherapy is of clear benefit to the nation. Tumour-localised treatment is expected to lead to improved responses, reduced side-effects and improved quality of life while rational selection of drug combinations is expected to enable treatment of tumours that were previously resistant to anthracyclines. With an aging population in Austra ....Improvement of anthracycline chemotherapy by enhancement of apoptotic responses and tumour targeted activation. Improved outcomes for anthracycline anticancer chemotherapy is of clear benefit to the nation. Tumour-localised treatment is expected to lead to improved responses, reduced side-effects and improved quality of life while rational selection of drug combinations is expected to enable treatment of tumours that were previously resistant to anthracyclines. With an aging population in Australia the incidence of cancer is predicted to rise dramatically - improved treatment outcomes and better use of chemotherapeutics will be of obvious national benefit. The development of new tumour-targeted agents is the subject of joint Intellectual Property between Australia and the USA, offering potential economic benefit. Read moreRead less
Tumour localisation and enhancement of anthracycline anticancer activity. The anthracyclines are one of the most widely used anticancer agents today. If the cytotoxicity of these agents can be localised to tumour cells, or their activity improved, then this will result in improved response rates, less side-effects and an improved quality of life for many patients for whom anthracycline treatment is an important part of their therapy. This will result in enormous national/community benefit to an ....Tumour localisation and enhancement of anthracycline anticancer activity. The anthracyclines are one of the most widely used anticancer agents today. If the cytotoxicity of these agents can be localised to tumour cells, or their activity improved, then this will result in improved response rates, less side-effects and an improved quality of life for many patients for whom anthracycline treatment is an important part of their therapy. This will result in enormous national/community benefit to an aging Australian population that is becoming increasingly more prone to cancer. Read moreRead less
Anticancer drug development: Enhancing the anticancer activity of mitoxantrone. Many cancer sufferers may benefit from this work if we are able to develop more active derivatives of mitoxantrone, or develop procedures to inhibit the repair of DNA lesions induced by mitoxantrone. This may result in therapies with improved response, reduced drug dosage and/or reduced side-effects. Because this work may result in one or more patents, and possibly commercialisation with Australian (and overseas) pha ....Anticancer drug development: Enhancing the anticancer activity of mitoxantrone. Many cancer sufferers may benefit from this work if we are able to develop more active derivatives of mitoxantrone, or develop procedures to inhibit the repair of DNA lesions induced by mitoxantrone. This may result in therapies with improved response, reduced drug dosage and/or reduced side-effects. Because this work may result in one or more patents, and possibly commercialisation with Australian (and overseas) pharmaceutical companies, there are potential commercial benefits to Australia. The "discovery" aspect of this work may also identify other cellular responses to mitoxantrone (ie specific genes which are re-expressed) and this may also reveal new targets to further enhance the activity of this drug.Read moreRead less
Molecular basis for the synergistic potentiation of anthracycline anticancer agents by formaldehyde-releasing prodrugs. AIMS: The overall aim is to develop a full understanding of the molecular basis for the synergistic activation of Adriamycin (and other anthracycline anticancer agents) by formaldehyde-releasing prodrugs such as AN-9.
SIGNIFICANCE: Because Adriamycin is currently one of the most widely used anticancer agents, and this activity has the potential to be dramatically enhanced by t ....Molecular basis for the synergistic potentiation of anthracycline anticancer agents by formaldehyde-releasing prodrugs. AIMS: The overall aim is to develop a full understanding of the molecular basis for the synergistic activation of Adriamycin (and other anthracycline anticancer agents) by formaldehyde-releasing prodrugs such as AN-9.
SIGNIFICANCE: Because Adriamycin is currently one of the most widely used anticancer agents, and this activity has the potential to be dramatically enhanced by the concurrent use of formaldehyde-releasing prodrugs, a biochemical understanding of these processes will provide the basis to exploit this synergy to provide improved treatment outcomes (eg, lower drug doses,reduced side-effects, improved activity against drug-resistanct tumours etc).
EXPECTED OUTCOMES: The long-term outcome of this project is commercialisation to develop products for clinical use based on this synergy (eg, drug/prodrug combinations) and ultimately the development of tumour-directed therapy to yield a tumour-localised anticancer response.Read moreRead less
Radiolabelled MMP binding agents for the identification, quantification, and targeting of MMPs in central nervous system (CNS) disorders and tumours. Cancer and diseases of the central nervous system (CNS) represent two of the major health challenges facing Australia because of the aging population. In order to address these challenges we need to develop methods for identifying tumours and CNS diseases using non-invasive technologies and at an early stage so that treatments can be applied when t ....Radiolabelled MMP binding agents for the identification, quantification, and targeting of MMPs in central nervous system (CNS) disorders and tumours. Cancer and diseases of the central nervous system (CNS) represent two of the major health challenges facing Australia because of the aging population. In order to address these challenges we need to develop methods for identifying tumours and CNS diseases using non-invasive technologies and at an early stage so that treatments can be applied when they are most likely to work. In this project, we are developing new radiolabelled compounds that will enable the imaging of tumours, tumour metastases and CNS diseases states.Read moreRead less
Biophysical identification of natural human antibody targets. A natural human antibody, PAT-SM6, isolated using technology developed by the partner organisation (Patrys), offers promise as a therapy to reduce mortalities due to cancer, the leading cause of death in Australia. The novelty of the approach pioneered by Patrys is the direct production of human antibodies which avoids undesirable side effects associated with the use of antibodies containing non-human components. This project is to ....Biophysical identification of natural human antibody targets. A natural human antibody, PAT-SM6, isolated using technology developed by the partner organisation (Patrys), offers promise as a therapy to reduce mortalities due to cancer, the leading cause of death in Australia. The novelty of the approach pioneered by Patrys is the direct production of human antibodies which avoids undesirable side effects associated with the use of antibodies containing non-human components. This project is to discover the specificity of PAT-SM6 for proteins and protein complexes and how these interactions lead to tumour cell death. This work will enhance the effectiveness of human antibody therapies and help in the development of this fast growing area within the biotechnology industry in Australia.Read moreRead less
Synthetic Endonucleases: Novel DNA Cleaving Agents for Cancer Chemotherapy. Cancer is a common disease in our society, with more than 1 in 4 of us dieing from it. The current survival rate is 50%, and has been so for the past 5 decades. Thus, there is clearly an urgent need for better forms of therapy. Chemotherapy is the mainstay of treatment once the disease has spread from its original site. The National Benefits from the development of a new class of effective cancer drug are two-fold. Firs ....Synthetic Endonucleases: Novel DNA Cleaving Agents for Cancer Chemotherapy. Cancer is a common disease in our society, with more than 1 in 4 of us dieing from it. The current survival rate is 50%, and has been so for the past 5 decades. Thus, there is clearly an urgent need for better forms of therapy. Chemotherapy is the mainstay of treatment once the disease has spread from its original site. The National Benefits from the development of a new class of effective cancer drug are two-fold. Firstly, much relief will come to people suffering from cancer, as some will live longer, and some will be cured. Secondly, the economic benefits are extensive, since the world market in cancer drugs is measured in billions $US, and significant monies will flow to those who hold the intellectual property rights. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0883032
Funder
Australian Research Council
Funding Amount
$1,300,000.00
Summary
800 MHz NMR spectrometer for biomolecular structure-function analysis. An understanding of how organisms function at the molecular level is central to developing the ability to fight many diseases in a rational way. This equipment will provide the capability for many different laboratories around NSW and the ACT to advance our knowledge at this fundamental level, primarily by examining the structures and functions of biomolecules such as proteins.