Novel vitamin E analogues disrupt autocrine signalling and angiogenesis: Mechanistic studies and relevance to cancer management. Breast and mesothelioma cancers present a severe problem in Australia and many patients succumb due to lack of appropriate treatment. We believe that vitamin E analogues, selective drugs efficient against cancer cells, hold a promise as future drugs against these two pathologies. Vitamin E analogues act by several mechanisms, including toxic effect on the cancer cells ....Novel vitamin E analogues disrupt autocrine signalling and angiogenesis: Mechanistic studies and relevance to cancer management. Breast and mesothelioma cancers present a severe problem in Australia and many patients succumb due to lack of appropriate treatment. We believe that vitamin E analogues, selective drugs efficient against cancer cells, hold a promise as future drugs against these two pathologies. Vitamin E analogues act by several mechanisms, including toxic effect on the cancer cells and also on cells that are necessary for efficient progression of tumours, such as cells of the malignant blood vessels. Results of this project will be used to prepare clinical testing of these highly promising drugs.Read moreRead less
Developing efficient cancer therapies by targeting of vitamin E analogues to mitochondria. We propose a new strategy of developing efficient anti-cancer agents. Results of this project will lead to establishing highly proising anti-cancer drugs and will open new approaches for the design of novel agents that efficiently kill cancer cells.
Functional characterisation of CMAP, a novel centrosome- and midbody-associated protein. Cell division is a highly regulated process involving many components to produce two daughter cells which contain an equal amount of DNA. Thus incorrect localisation and modification of specific proteins that regulate this process cause cell division errors resulting in genomic instability. We have recently identified a novel protein called CMAP that is involved in the final stages of cell division, which in ....Functional characterisation of CMAP, a novel centrosome- and midbody-associated protein. Cell division is a highly regulated process involving many components to produce two daughter cells which contain an equal amount of DNA. Thus incorrect localisation and modification of specific proteins that regulate this process cause cell division errors resulting in genomic instability. We have recently identified a novel protein called CMAP that is involved in the final stages of cell division, which involves the cleavage of the cell membrane to produce two daughter cells. Here, we aim to characterise the mechanism(s) of CMAP function and to identify and characterise CMAP binding proteins to further understand the mechanisms involved in the final stages of cell division to maintain genomic stability.Read moreRead less
Understanding the role of the corepressor protein KAP1 in DNA damage response pathway. Defects in the DNA damage response pathway underpin many human genetic disorders and diseases, including cancer. A detailed understanding of this process has enormous implications for future medicine. Our characterization of a new player involved in DNA damage signalling will help in screening of inhibitors of this pathway that could be applied in chemo-and/or radiotherapy. The proposal will place Australia am ....Understanding the role of the corepressor protein KAP1 in DNA damage response pathway. Defects in the DNA damage response pathway underpin many human genetic disorders and diseases, including cancer. A detailed understanding of this process has enormous implications for future medicine. Our characterization of a new player involved in DNA damage signalling will help in screening of inhibitors of this pathway that could be applied in chemo-and/or radiotherapy. The proposal will place Australia among the leaders in this internationally significant and highly competitive area of research leading to the creation of new compounds. Capture of this technology will create the opportunity for IP income, novel exports and new enterprises for Australia.Read moreRead less
The function of truncated MEK1 protein in a G2 phase cell cycle delay and in mitosis. Understanding cell proliferation. Intracellular signaling pathways controlling cell growth are often mutated in cancers and other hyperproliferative diseases. Understanding precisely how these pathways operate and how mutations of these pathways can contribute to uncontrolled growth can readily provide new targets for preventative therapies or cures. We have identified a novel mechanism regulating one compone ....The function of truncated MEK1 protein in a G2 phase cell cycle delay and in mitosis. Understanding cell proliferation. Intracellular signaling pathways controlling cell growth are often mutated in cancers and other hyperproliferative diseases. Understanding precisely how these pathways operate and how mutations of these pathways can contribute to uncontrolled growth can readily provide new targets for preventative therapies or cures. We have identified a novel mechanism regulating one component of a well studied pathway, the MAPK pathway, and new functions for this component. The contribution of this novel component to mechanisms involved in regulating cell growth previously through to be controlled by the canonical MAPK pathway could change our understanding of the fundamental mechanisms controlling cell growth. Read moreRead less
Function of the unique mitotic form of MEK. Many of the mechanisms controlling normal cell growth and division are known, although there are an increasing number of examples of mechanism having more thn the originally defined functions. We have found that one well studied mechanism, the Ras-Raf-MEK-ERK pathway operates in a unique manner during the phase when cell division occurs, known as mitosis. Understanding this novel mechanism and identifying its function at this critical stage of cell d ....Function of the unique mitotic form of MEK. Many of the mechanisms controlling normal cell growth and division are known, although there are an increasing number of examples of mechanism having more thn the originally defined functions. We have found that one well studied mechanism, the Ras-Raf-MEK-ERK pathway operates in a unique manner during the phase when cell division occurs, known as mitosis. Understanding this novel mechanism and identifying its function at this critical stage of cell division will provide insights into how cell control the partitioning of replicated genome and produce two identical daugther cells.Read moreRead less
New Antioxidants Impacting on ROS and Free Radical Mediated Cellular Damage and Disease. Oxidative stress describes the condition where free radicals damage cells and biological systems and this stress underlies many diseases including neurological conditions and aging disorders such as Alzheimer's Disease. This project sets out to create new forms of powerful antioxidant drugs able to probe the mechanisms of such diseases with the view to developing new treatments and therapies.
Novel Vitamin E Analogues with Enhanced Specificity for Malignant Cells. The aim of this project is to synthesise and characterise novel compounds based on vitamin E succinate that are capable of efficiently and selectively killing cancer cells. The new compounds will be tested for their ability to induce programmed cell death in cancer cells and the most active of them will be also tested for anti-cancer effect in a pre-clinical model. We believe that novel analogues based on vitamin E succinat ....Novel Vitamin E Analogues with Enhanced Specificity for Malignant Cells. The aim of this project is to synthesise and characterise novel compounds based on vitamin E succinate that are capable of efficiently and selectively killing cancer cells. The new compounds will be tested for their ability to induce programmed cell death in cancer cells and the most active of them will be also tested for anti-cancer effect in a pre-clinical model. We believe that novel analogues based on vitamin E succinate can lead to the discovery of very effcient and selective anti-cancer drugs with no side-effects that may be used for patient treatment in the future. This makes our project of exceptional significance.Read moreRead less
Preventing genetic damage with BIX - a novel player in the DNA damage response pathway. Defects in the DNA damage-response pathway underpin many human genetic disorders and diseases, including cancer. A detailed understanding of this process has enormous implications for future medicine. Our characterization of a novel protein involved in DNA damage signalling will help in screening inhibitors of this pathway that could be applied in chemo-and/or radiotherapy. This proposal will place Australia ....Preventing genetic damage with BIX - a novel player in the DNA damage response pathway. Defects in the DNA damage-response pathway underpin many human genetic disorders and diseases, including cancer. A detailed understanding of this process has enormous implications for future medicine. Our characterization of a novel protein involved in DNA damage signalling will help in screening inhibitors of this pathway that could be applied in chemo-and/or radiotherapy. This proposal will place Australia among the leaders in this internationally significant and highly competitive area of research leading to the creation of new compounds. Capture of this technology will create the opportunity for IP income, novel exports and new enterprises for Australia.Read moreRead less
Identifying the pathways employed by growth hormone to regulate the proliferation of adult neural stem cells. As stem cells underpin the maintenance and regeneration of the brain and are known to decline in number and competence with age; understanding exactly how these cells are regulated is of broad national benefit. Furthermore, given the regulatory role of growth hormone throughout the body, insights gained from this project should lead to the discovery of novel therapeutic targets both with ....Identifying the pathways employed by growth hormone to regulate the proliferation of adult neural stem cells. As stem cells underpin the maintenance and regeneration of the brain and are known to decline in number and competence with age; understanding exactly how these cells are regulated is of broad national benefit. Furthermore, given the regulatory role of growth hormone throughout the body, insights gained from this project should lead to the discovery of novel therapeutic targets both within and outside the nervous system, ultimately leading to preventative and restorative strategies for maintaining good health. Finally, this Proposal is of significant national benefit as it will undoubtedly advance our knowledge base in stem cell biology, helping to maintain Australia as a global leader in stem cell research.Read moreRead less