The regulation of signalling molecules in Saccharomyces Cerevisiae by inositol polyphosphate 5-phosphatases. Phosphoinositide signalling molecules regulate the actin cytoskeleton, secretion, vesicular trafficking and cell growth and death. We have identified, cloned and characterised a family of signal terminating enzymes called inositol polyphosphate 5-phosphatases (5-phosphatases) that regulate phosphoinositide signalling molecules. We have cloned and characterised four distinct 5-phosphatases ....The regulation of signalling molecules in Saccharomyces Cerevisiae by inositol polyphosphate 5-phosphatases. Phosphoinositide signalling molecules regulate the actin cytoskeleton, secretion, vesicular trafficking and cell growth and death. We have identified, cloned and characterised a family of signal terminating enzymes called inositol polyphosphate 5-phosphatases (5-phosphatases) that regulate phosphoinositide signalling molecules. We have cloned and characterised four distinct 5-phosphatases in the yeast Saccharomyces Cerevisiae and demonstrated by both deletion and overexpression studies that these enzymes regulate the actin cytoskeleton, endocytosis and secretion. This research proposal aims to investigate the signalling complexes the 5-phosphatases form with specific actin binding and or regulatory proteins, investigate the complex interactions of phosphoinositide lipid phosphatases and the roles they play in regulating secretion from the endoplasmic reticulum and finally characterize a novel 5-phosphatase that we have recently identified. Collectively the outcome of these studies will provide novel information about the functionallly significant signalling pathways regulated by this important enzyme family.Read moreRead less
The role of PtdIns(4,5)P2 in cellular responses in Saccharomyces cerevisiae. This grant application falls under the criteria of frontier technologies in genomics/phenomics and complex systems. We are characterizing a highly conserved network of signaling molecules regulated by complex large families of enzymes that regulate the bending of membranes, and cellular events including cell division in plants, yeast and mammalian cells. We have developed cutting edge novel technologies to localize sign ....The role of PtdIns(4,5)P2 in cellular responses in Saccharomyces cerevisiae. This grant application falls under the criteria of frontier technologies in genomics/phenomics and complex systems. We are characterizing a highly conserved network of signaling molecules regulated by complex large families of enzymes that regulate the bending of membranes, and cellular events including cell division in plants, yeast and mammalian cells. We have developed cutting edge novel technologies to localize signaling on specific intracellular membranes and visualise the role cellular lipids play in forming tubules in cells. This project will result in the presentation of Australian research at international forums and support the training of PhD students.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
A microscopical examination of curdlan production by an Agrobacterium sp. We will investigate the secretion of the insoluble polysaccharide curdlan, a (1,3)-beta-glucan, from the surfaces of Agrobacterium cells and the assembly of the individual polysaccharide chains into microfibrils. Using state-of-the-art techniques in time lapse and electron microscopy we will compare the images of wild type curdlan-producing cells with those of mutants impaired in the production of curdlan. The outputs will ....A microscopical examination of curdlan production by an Agrobacterium sp. We will investigate the secretion of the insoluble polysaccharide curdlan, a (1,3)-beta-glucan, from the surfaces of Agrobacterium cells and the assembly of the individual polysaccharide chains into microfibrils. Using state-of-the-art techniques in time lapse and electron microscopy we will compare the images of wild type curdlan-producing cells with those of mutants impaired in the production of curdlan. The outputs will be information on the mechanics of curdlan production that will complement that emerging from our molecular biological and biochemical studies. These will have implications for understanding bacterial polysaccharide production in general and may have a commercial outcome in enhanced curdlan production.Read moreRead less
Does a novel class of small RNA molecules control self-incompatibility in solanaceous plants? Self-incompatibility is a simple and genetically defined cell recognition system that prevents inbreeding in many plant species. Flowers of self-incompatible plants can distinguish self pollen from foreign pollen, and allow only foreign pollen to fertilise their egg cells. This proposal will investigate the possibility that the part of the genetic self-incompatibility locus controlling recognition of ....Does a novel class of small RNA molecules control self-incompatibility in solanaceous plants? Self-incompatibility is a simple and genetically defined cell recognition system that prevents inbreeding in many plant species. Flowers of self-incompatible plants can distinguish self pollen from foreign pollen, and allow only foreign pollen to fertilise their egg cells. This proposal will investigate the possibility that the part of the genetic self-incompatibility locus controlling recognition of pollen is a novel type of gene that encodes a small RNA molecule but no protein. Knowledge gained by studying the self-incompatibility genes will help us to understand how plant cells recognise each other, and may allow us to manipulate seed (and hence crop) production.Read moreRead less
Structural studies on the mitochondrial protein import machinery. Proteins transported across biological membranes are generally synthesized as precursors with signal sequences. These signal sequences are decoded by one of a number of membrane-specific protein transport machinery, but how this decoding occurs is largely unknown. This proposal aims to understand the structural basis of protein import into the mitochondrion, a poorly understood biological process. This study will enhance signif ....Structural studies on the mitochondrial protein import machinery. Proteins transported across biological membranes are generally synthesized as precursors with signal sequences. These signal sequences are decoded by one of a number of membrane-specific protein transport machinery, but how this decoding occurs is largely unknown. This proposal aims to understand the structural basis of protein import into the mitochondrion, a poorly understood biological process. This study will enhance significantly our understanding of mitochondrial biology, and will also have ramifications for other areas of protein transport.Read moreRead less
Guanylate cyclases - an expanding family critical in plant growth and development. The enzyme guanylate cyclase (GC) forms an important signalling molecule. We have identified unique GC molecules from higher plants. We shall use strategic basic research to determine the biological importance of these novel molecules in plant growth and development. We have formed an international team to achieve these goals and also to develop strong scientific links between Australia and other countries such as ....Guanylate cyclases - an expanding family critical in plant growth and development. The enzyme guanylate cyclase (GC) forms an important signalling molecule. We have identified unique GC molecules from higher plants. We shall use strategic basic research to determine the biological importance of these novel molecules in plant growth and development. We have formed an international team to achieve these goals and also to develop strong scientific links between Australia and other countries such as South Africa. The outcomes will provide new insight into the biological function of the novel GCs. Consequently, the new knowledge is critical to the development of novel biotechnological approaches to benefit sustainable agriculture in Australia.Read moreRead less
Regulation of the actin cytoskeleton by LIM kinase 2. Because the regulation of actin cytoskeleton is essential for many cellular processes including cell motility and the normal function of neurons, it is of great importance to understand its regulation. Elucidation of the molecular and biological mechanisms underlying the actin cytoskeleton including cell motility may enable the identification of novel therapeutic targets for the treatment of diseases such as cancer metastasis, Alzheimer disea ....Regulation of the actin cytoskeleton by LIM kinase 2. Because the regulation of actin cytoskeleton is essential for many cellular processes including cell motility and the normal function of neurons, it is of great importance to understand its regulation. Elucidation of the molecular and biological mechanisms underlying the actin cytoskeleton including cell motility may enable the identification of novel therapeutic targets for the treatment of diseases such as cancer metastasis, Alzheimer disease (AD) and/or Multiple Sclerosis (MS) in which the regulation of the actin cytoskeleton is affected.
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Analysis of the Role of Snapin in the Regulation of SNARE Complex Assembly. The aims of the proposed studies are to investigate the role played by a protein, snapin in the trafficking of membranes and cargo proteins between different compartments inside mammalian cells. Membrane trafficking is a fundamental cellular process that requires a family of related molecules termed SNARES. We have recently discovered that snapin interacts with certain members of the SNARE family, implying a critical rol ....Analysis of the Role of Snapin in the Regulation of SNARE Complex Assembly. The aims of the proposed studies are to investigate the role played by a protein, snapin in the trafficking of membranes and cargo proteins between different compartments inside mammalian cells. Membrane trafficking is a fundamental cellular process that requires a family of related molecules termed SNARES. We have recently discovered that snapin interacts with certain members of the SNARE family, implying a critical role in membrane trafficking. The proposed studies will provide important new insights into the molecular mechanisms underlying the function of both snapin and SNAREs, and membrane trafficking in general.Read moreRead less
Assembly and function of arabinogalactan-proteins: a class of proteoglycans involved in plant growth and development. We aim to define the mechanisms by which a family of cell surface proteoglycans, the arabinogalactan-proteins (AGPs), are assembled and contribute to the regulation of plant growth and development using Arabidopsis, a model system amenable to a functional genomics strategy. This will be achieved through the application of bioinformatics for gene discovery and molecular, biochemi ....Assembly and function of arabinogalactan-proteins: a class of proteoglycans involved in plant growth and development. We aim to define the mechanisms by which a family of cell surface proteoglycans, the arabinogalactan-proteins (AGPs), are assembled and contribute to the regulation of plant growth and development using Arabidopsis, a model system amenable to a functional genomics strategy. This will be achieved through the application of bioinformatics for gene discovery and molecular, biochemical and genetics approaches to define gene function. Understanding mechanisms that control plant growth and development will ultimately impact on industries (agriculture, horticulture and forestry) vital to Australia's prosperity.Read moreRead less