Factors involved in release of cytochrome c from mitochondria during apoptosis. Mitochondria are energy-producing organelles that activate cell death by selective release of constituents, notably cytochrome c, which participate in death-signalling cascades. I aim to probe such mitochondrial release mechanisms in intact cells, by focussing on features of translocated proteins relevant to release. Cultured mouse cells lacking cytochrome c are uniquely suited to these studies. A series of cytochrom ....Factors involved in release of cytochrome c from mitochondria during apoptosis. Mitochondria are energy-producing organelles that activate cell death by selective release of constituents, notably cytochrome c, which participate in death-signalling cascades. I aim to probe such mitochondrial release mechanisms in intact cells, by focussing on features of translocated proteins relevant to release. Cultured mouse cells lacking cytochrome c are uniquely suited to these studies. A series of cytochrome c derivatives will be engineered in elongated or aggregated forms and their release studied (including interactions with putative release machinery components) following death-signal activation. The project will elucidate a central mechanism in the cell death process, highly significant in many biological contexts.Read moreRead less
Identification of Proteins that Regulate Apoptosis Through Interaction With IAPS. Apoptosis is the process by which multicellular organisms eliminate unwanted cells. Identifying proteins involved in cell death regulation is central to our understanding of disease states arising from aberrations in this process. The mammalian protein DIABLO, promotes cell death by interacting with and antagonising inhibitor of apoptosis proteins (IAPS). Given the existence of several IAP regulatory proteins (IRPs ....Identification of Proteins that Regulate Apoptosis Through Interaction With IAPS. Apoptosis is the process by which multicellular organisms eliminate unwanted cells. Identifying proteins involved in cell death regulation is central to our understanding of disease states arising from aberrations in this process. The mammalian protein DIABLO, promotes cell death by interacting with and antagonising inhibitor of apoptosis proteins (IAPS). Given the existence of several IAP regulatory proteins (IRPs) in insects, other mammalian IRPs probably also exist. These may be of equal importance in regulating apoptosis, especially in tissues where DIABLO is not expressed. The main aim of the proposed study is to idenitify and characterise other IRPs in mammalian cells.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0226463
Funder
Australian Research Council
Funding Amount
$160,000.00
Summary
Fluorescence Lifetime Imaging Facility. The aim of this proposal is to establish the first fluorescence lifetime imaging facility (FLIM) in Australia. The imaging technique provided by the new facility when combined with the use of novel fluorescent protein technology will enable many different events, represented by protein-protein interactions, to be non-invasively, visualised spatially and temporally inside the living cell. The new facility will provide timely state-of -the-art infrastructu ....Fluorescence Lifetime Imaging Facility. The aim of this proposal is to establish the first fluorescence lifetime imaging facility (FLIM) in Australia. The imaging technique provided by the new facility when combined with the use of novel fluorescent protein technology will enable many different events, represented by protein-protein interactions, to be non-invasively, visualised spatially and temporally inside the living cell. The new facility will provide timely state-of -the-art infrastructure necessary for research groups to further develop and maintain their international reputations, will build stronger research collaborations between partner institutions and will attract researchers from overseas.Read moreRead less
Developmental Switches: Nuclear Transport and Spermatogenesis. We propose to test the novel hypothesis that changes in the nuclear import machinery are a key facet of cellular differentiation. We will investigate a new paradigm in developmental biology regarding whether differentiation is achieved, or can be directed, by altering transport of macromolecules, such as specific transcription factors, into the nucleus. This project will define changes in the nuclear import machinery that accomp ....Developmental Switches: Nuclear Transport and Spermatogenesis. We propose to test the novel hypothesis that changes in the nuclear import machinery are a key facet of cellular differentiation. We will investigate a new paradigm in developmental biology regarding whether differentiation is achieved, or can be directed, by altering transport of macromolecules, such as specific transcription factors, into the nucleus. This project will define changes in the nuclear import machinery that accompany germ and somatic cell differentiation in the developing and adult mammalian testis. This will be linked to changes in the function of key proteins acting within the nucleus using both in vitro and in vivo approaches.
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Insertion and assembly of proteins and lipids into biological membranes. We propose a multi-disciplinary approach to this fundamental biological problem and have established collaborations with experts in the USA, UK and Austria. Benefits from this research program fall into two discrete types. Firstly, detailed knowledge of the mechanism what is now a poorly understood biological process of cellular membrane assembly, with the prospects for using the knowledge for intervention into diseases suc ....Insertion and assembly of proteins and lipids into biological membranes. We propose a multi-disciplinary approach to this fundamental biological problem and have established collaborations with experts in the USA, UK and Austria. Benefits from this research program fall into two discrete types. Firstly, detailed knowledge of the mechanism what is now a poorly understood biological process of cellular membrane assembly, with the prospects for using the knowledge for intervention into diseases such as cancer. Secondly, excellent outcomes are provided for the training of postgraduate students and research staff. This project entails cutting edge technology, and the development of skills not common in Australia.Read moreRead less
Characterisation of molecular regulation of telomerase and telomeres by p53 in cell ageing. Telomeres, the ends of chromosomes shorten as a function of cell division, and thereby limit cell lifespan. Telomerase synthesizes telomeres and thus renders cells immortal. Recently, we found that p53, a protein with an important role in cell aging and in the uncontrolled growth of cancer, interacts with telomeres and telomerase by binding to the telomere proteins TRF1 and TRF2. This project will deciphe ....Characterisation of molecular regulation of telomerase and telomeres by p53 in cell ageing. Telomeres, the ends of chromosomes shorten as a function of cell division, and thereby limit cell lifespan. Telomerase synthesizes telomeres and thus renders cells immortal. Recently, we found that p53, a protein with an important role in cell aging and in the uncontrolled growth of cancer, interacts with telomeres and telomerase by binding to the telomere proteins TRF1 and TRF2. This project will decipher the mechanisms by which p53 regulates telomerase and telomeres, and establish the interrelationship of these proteins in regulating cell lifespan, death and immortalisation. It will provide important information for molecular intervention in cell ageing and immortalisation.Read moreRead less
Molecular control of apoptosis and protein homeostasis. A million cells are produced every second by cell division. At the same time a million cells commit suicide by a process called apoptosis. When cells fail to die when they should they can develop into cancers. In heart attacks, stroke and neurodegenerative diseases, many cells appear to activate their self destruct mechanism to die unnecessarily. Drugs that can cause cancer cells to kill themselves, or drugs that prevent cells dying when th ....Molecular control of apoptosis and protein homeostasis. A million cells are produced every second by cell division. At the same time a million cells commit suicide by a process called apoptosis. When cells fail to die when they should they can develop into cancers. In heart attacks, stroke and neurodegenerative diseases, many cells appear to activate their self destruct mechanism to die unnecessarily. Drugs that can cause cancer cells to kill themselves, or drugs that prevent cells dying when they shouldn't, would make a major impact on many important diseases. Understanding the molecular mechanisms of cell death is the first step towards developing these drugs.Read moreRead less
Autophagic vacuole formation in mammalian skeletal muscle; role of FOXO proteins. Loss of muscle tissue is a hallmark of many common health problems including cancer, HIV-Aids and renal failure. Recently, we identified that a family of transcription factors termed the forkhead box class-O (FOXO) winged helix transcription factors are key regulators of both anabolic (building) and catabolic (wasting) signalling pathways. This project will investigate the molecular regulation of cell integrity by ....Autophagic vacuole formation in mammalian skeletal muscle; role of FOXO proteins. Loss of muscle tissue is a hallmark of many common health problems including cancer, HIV-Aids and renal failure. Recently, we identified that a family of transcription factors termed the forkhead box class-O (FOXO) winged helix transcription factors are key regulators of both anabolic (building) and catabolic (wasting) signalling pathways. This project will investigate the molecular regulation of cell integrity by FOXO proteins. Although very basic in nature, these projects will identify how FOXO proteins regulate muscle cell building and wasting and, therefore, present a potential therapeutic target for muscle wasting diseases, making this project highly significant.Read moreRead less
Isolation and analysis of novel caspases. Apoptosis is an evolutionarily conserved cellular process which must be tightly controlled for normal development and to avoid disease. Rapid progress has been made recently in the elucidation of apoptotic pathways, but many important components are likely still unknown. The caspases constitute the effector arm of apoptotic signalling pathways and some members play important roles in cytokine maturation. We aim to identify novel caspases using an innovat ....Isolation and analysis of novel caspases. Apoptosis is an evolutionarily conserved cellular process which must be tightly controlled for normal development and to avoid disease. Rapid progress has been made recently in the elucidation of apoptotic pathways, but many important components are likely still unknown. The caspases constitute the effector arm of apoptotic signalling pathways and some members play important roles in cytokine maturation. We aim to identify novel caspases using an innovative technique, and to characterise their function and regulation. Molecules identified in this project may be candidate targets for therapies which modulate apoptosis for treatment or prevention of disease, or diagnostic reagent development.Read moreRead less
The role of palmitoylation in hair follicle and epidermal stem cell biology. A proteins activity can be shaped by sugar, phosphate and lipid modifications. This proposal will investigate the effects of the lipid modification called palmitoylation, about which we know very little. Our preliminary experiments suggest that palmitoylation is crucial for normal skin biology. We will explore its effects on the biology of the proteins which are modified, the cells in which they are found and the tis ....The role of palmitoylation in hair follicle and epidermal stem cell biology. A proteins activity can be shaped by sugar, phosphate and lipid modifications. This proposal will investigate the effects of the lipid modification called palmitoylation, about which we know very little. Our preliminary experiments suggest that palmitoylation is crucial for normal skin biology. We will explore its effects on the biology of the proteins which are modified, the cells in which they are found and the tissues in which they reside. Understanding more about these modifications will help us to learn more about the biology of our skin and will help us to understand diseases which affect our largest organ.Read moreRead less