Dissection Of The Mechanisms Of Action Of Evolutionarily Conserved Apoptotic Pathway Components
Funder
National Health and Medical Research Council
Funding Amount
$253,500.00
Summary
Animals eliminate unwanted cells through a highly controlled process termed apoptosis. Defects in apoptosis can contribute to cancer or autoimmune disease. Conversely, diseases such as stroke and Alzheimer's disease have been linked to excessive cell death. To develop drugs that promote apoptosis when it fails to occur, or prevent inappropriate cell death, it is necessary to elucidate the molecular mechanisms controlling apoptosis. The first recognised component of the mammalian cell death machi ....Animals eliminate unwanted cells through a highly controlled process termed apoptosis. Defects in apoptosis can contribute to cancer or autoimmune disease. Conversely, diseases such as stroke and Alzheimer's disease have been linked to excessive cell death. To develop drugs that promote apoptosis when it fails to occur, or prevent inappropriate cell death, it is necessary to elucidate the molecular mechanisms controlling apoptosis. The first recognised component of the mammalian cell death machinery was Bcl-2; a protein associated with development of cancer. Despite much research since then, the way in which Bcl-2 and related proteins function is still unknown. This project capitalises on previous genetic and biochemical studies in a model genetic organism (the roundworm) to address this important issue. Animal cell death pathway components can be introduced into yeast such that activation of the introduced pathways leads to yeast death and its inhibition promotes yeast survival. We have used this approach to reconstitute the worm cell death pathway and a major mammalian apoptosis pathway in yeast. Yeast strains bearing these reconstituted pathways will be used to test functional equivalence of candidate mammalian proteins and their putative roundworm counterparts. The system will also be exploited to identify and characterise novel proteins that regulate cell death in mammals and worms. Understanding the way in which key molecules regulate apoptosis will assist in the development of diagnostic and therapeutic reagents for many diseases in which cell death regulation is perturbed. This project capitalises on the evolutionary conservation of apoptosis to characterise the mechanisms of action of important mammalian apoptotic regulators and to seek novel mammalian apoptotic pathway components. Proteins identified in this way are likely to be important apoptotic regulators, as our approach ensures that their functions are evolutionarily conserved.Read moreRead less
Discovery Of Novel Oncogenes And Tumour Suppressor Genes Via Genetic Interactions With Drosophila Cbl.
Funder
National Health and Medical Research Council
Funding Amount
$396,760.00
Summary
Cancer is a complex genetic disease resulting from an accumulation of mutations that allow a cell to escape its normal growth controls. The cell can then multiply indefinitely to produce a tumour. We still only know the nature of some of these mutations, and the genes that they affect. Recently the fruitfly, Drosophila, has gained increasing importance in the discovery of new cancer genes and understanding how they function. The long history of genetic studies with this organism, and the recent ....Cancer is a complex genetic disease resulting from an accumulation of mutations that allow a cell to escape its normal growth controls. The cell can then multiply indefinitely to produce a tumour. We still only know the nature of some of these mutations, and the genes that they affect. Recently the fruitfly, Drosophila, has gained increasing importance in the discovery of new cancer genes and understanding how they function. The long history of genetic studies with this organism, and the recent completion of the DNA sequence of the entire genetic code of the fruitfly allows a wealth of experiments to be conducted on how mutations affect growth and development. We have used the fruitfly to investigate how a particular cancer gene, v-cbl, causes cells to lose growth control and are now using this organism in a systematic way to discover new cancer genes. We will then map these genes onto the human genome to determine if these genes are also responsible for human cancers.Read moreRead less
Control Of Salvador-Warts-Hippo Pathway Activity In Drosophila And Mammals
Funder
National Health and Medical Research Council
Funding Amount
$514,048.00
Summary
The primary function of the Salvador-Warts-Hippo (SWH) pathway is to dictate the appropriate size of organs in developing animals. Deregulation of this pathway results in vastly overgrown organs and can lead to the formation of cancer in humans. Our study will provide important insights into how the size of organs are controlled during development by identifying new SWH pathway components. We will also increase understanding of diseases that arise due to aberrant tissue growth, such as cancer.
The Role Of Scube Genes In Hedgehog Signal Transduction
Funder
National Health and Medical Research Council
Funding Amount
$496,446.00
Summary
Cancer often results form the miss-regulation and-or mutation of genes that control tissue formation in the developing embryo. Particular sets of genes combine to form a signal transduction pathway that coordinates the cell's response to its environment during the course of normal fetal growth. One such pathway is called the Hedgehog signal transduction pathway which has been shown to coordinated cell division and patterning within malignant and normal tissues. Genes encoding components of this ....Cancer often results form the miss-regulation and-or mutation of genes that control tissue formation in the developing embryo. Particular sets of genes combine to form a signal transduction pathway that coordinates the cell's response to its environment during the course of normal fetal growth. One such pathway is called the Hedgehog signal transduction pathway which has been shown to coordinated cell division and patterning within malignant and normal tissues. Genes encoding components of this pathway are mutated in the most common forms of human cancers. Understanding how this pathway is regulated is critical to designing strategies to treat the onset and progression of these cancers. The studies outlined in this grant plan to study a new component of this pathway that we have identified in our laboratory, in an easy to study vertebrate model, the zebrafish embryo. We plan to study how this class of proteins, termed scube proteins, acts to control activation of the pathway. We hope this will lead to a fuller understanding of this process, and at the same time help understand the nature of the end result of the patterning process within the muscle cells that we are studyingRead 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
Cellular signals controlling oocyte activation. This research will significantly advance our understanding of the basic biological processes that underpin the fertility rate of all mammals and are key to the immediate and future health and well-being of Australian landscape and society. Understanding the processes that maintain healthy quiescent oocytes over many years before activation and subsequent growth will enable development of methods of increasing productivity in domestic animals and en ....Cellular signals controlling oocyte activation. This research will significantly advance our understanding of the basic biological processes that underpin the fertility rate of all mammals and are key to the immediate and future health and well-being of Australian landscape and society. Understanding the processes that maintain healthy quiescent oocytes over many years before activation and subsequent growth will enable development of methods of increasing productivity in domestic animals and enhancing fertility in endangered species. Knowledge of these cellular mechanisms will underpin biotechnology platforms necessary for novel methods of feral animal population control thus contributing at multiple levels to an economically sustainable 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
The role of heparan sulfate proteoglycans in the control of osteoblast phenotype. Very little is known about how bone cells progress from a naive precursor state, through differentiation and then maturation into adult cells. We wish to purify sugars from the bone cell membrane, extracellular matrix and culture medium, and examine the cellular response following the addition of these various sugar fractions to osteoblast cell cultures in combination with known growth factors. If we can control ....The role of heparan sulfate proteoglycans in the control of osteoblast phenotype. Very little is known about how bone cells progress from a naive precursor state, through differentiation and then maturation into adult cells. We wish to purify sugars from the bone cell membrane, extracellular matrix and culture medium, and examine the cellular response following the addition of these various sugar fractions to osteoblast cell cultures in combination with known growth factors. If we can control the progression of osteoblastic cells through the phases of recruitment, proliferation, differentiation and maturation by the addition of specific sugar fractions then we can potentially control bone formation.Read moreRead less