Novel mechanisms of bacterial arsenic metabolism - arsenate reduction and arsenite oxidation. Novel arsenic metabolising bacteria (i.e., arsenate respiring and arsenite oxidising), which are both phylogenetically and physiologically unique, have been isolated from arsenic-contaminated areas in Australia. The arsenate respiring bacterium, Chrysiogenes arsenatis, is of particular interest as it is the only organism reported able to respire with arsenate using the respiratory substrate acetate as t ....Novel mechanisms of bacterial arsenic metabolism - arsenate reduction and arsenite oxidation. Novel arsenic metabolising bacteria (i.e., arsenate respiring and arsenite oxidising), which are both phylogenetically and physiologically unique, have been isolated from arsenic-contaminated areas in Australia. The arsenate respiring bacterium, Chrysiogenes arsenatis, is of particular interest as it is the only organism reported able to respire with arsenate using the respiratory substrate acetate as the electron donor. It is proposed that physiological, biochemical and molecular biological studies be carried out to better understand the mechanisms by which these organisms metabolise arsenic. The knowledge gained from these studies will have worldwide application in the development of an arsenic bioremediation system.Read moreRead less
Ribonucleic acid (RNA)-binding proteins regulate protein targeting and organelle biosynthesis. We will investigate a new paradigm in biology: the coordination of protein expression in space and time. Detailed knowledge will be gained about proteins that perform important roles in ensuring the proliferative potential of cells an essential aspect of stem cell biology, regenerative medicine and development of cancer. The study combines skills in several aspects of genetics, biochemistry and molecul ....Ribonucleic acid (RNA)-binding proteins regulate protein targeting and organelle biosynthesis. We will investigate a new paradigm in biology: the coordination of protein expression in space and time. Detailed knowledge will be gained about proteins that perform important roles in ensuring the proliferative potential of cells an essential aspect of stem cell biology, regenerative medicine and development of cancer. The study combines skills in several aspects of genetics, biochemistry and molecular cell biology and will therefore provide excellent training opportunities for PhD students and postdoctoral fellows in an internationally highly competitive field of research.Read moreRead less
Regulation of Stress Hormone Receptors in the Brain. Our research will provide information on how the brain controls our response to stress and will allow the development of targeted strategies to reduce the possibility during chronic stress of the development of conditions such as anxiety and depression. This will improve mental health outcomes in Australia and add to Australia's economic and social stability.
Genetic analysis of cohesin function and regulation in Drosophila. In yeast, a multiprotein complex, called cohesin, holds newly replicated chromatids together until the cell is ready to partition each chromatid into its daughter cells. We and others have shown that cohesins are regulated differently in animal cells. We propose to combine classical genetic analyses with two new and innovative techniques, time-lapse confocal microscopy of fluorescent proteins in living cells and gene-specific kno ....Genetic analysis of cohesin function and regulation in Drosophila. In yeast, a multiprotein complex, called cohesin, holds newly replicated chromatids together until the cell is ready to partition each chromatid into its daughter cells. We and others have shown that cohesins are regulated differently in animal cells. We propose to combine classical genetic analyses with two new and innovative techniques, time-lapse confocal microscopy of fluorescent proteins in living cells and gene-specific knockout techniques to study key cohesin regulators in Drosophila. These studies will provide us with novel insights into how multicellular organisms regulate the structure and stability of their chromosomes.Read moreRead less
Biochemical, Genomic and Phenomic Analysis of Gastric Parietal Cells from Wildtype and Mutant Mice. The interface between the cell and its environment is the cell membrane. Signals, nutrients, and ions all have to cross this barrier. In addition, the cells contain many specialized intracellular membranous compartments. We know little about the signals that direct the synthesis of these structures and determine their final composition and shape. This grant will utilize acid secretory cells in the ....Biochemical, Genomic and Phenomic Analysis of Gastric Parietal Cells from Wildtype and Mutant Mice. The interface between the cell and its environment is the cell membrane. Signals, nutrients, and ions all have to cross this barrier. In addition, the cells contain many specialized intracellular membranous compartments. We know little about the signals that direct the synthesis of these structures and determine their final composition and shape. This grant will utilize acid secretory cells in the stomach to examine these questions because they contain a very extensive membrane system. We will use a state-of-the-art genetic and cell biological technologies to manipulate and analyse these cells in a whole animal setting.Read moreRead less
Protein Kinase Regulatory Switches: Decision-Making in the Nucleus. This project plans to examine new regulatory mechanisms for an important signalling enzyme in the cell nucleus. It aims to define how this enzyme enters the nucleus, to characterise new modifications that affect its actions, and to establish how a conserved nuclear protein may provide an unexpected regulatory platform to send nucleus-initiated signals back to the cell cytoplasm. This reverse signalling is a novel mechanism for i ....Protein Kinase Regulatory Switches: Decision-Making in the Nucleus. This project plans to examine new regulatory mechanisms for an important signalling enzyme in the cell nucleus. It aims to define how this enzyme enters the nucleus, to characterise new modifications that affect its actions, and to establish how a conserved nuclear protein may provide an unexpected regulatory platform to send nucleus-initiated signals back to the cell cytoplasm. This reverse signalling is a novel mechanism for integrating nuclear actions that has the potential to create a signal transduction circuit triggered by environmental or genetic factors. This information is crucial in defining the molecular logic of signalling events that may be ultimately targeted to control cell growth, differentiation and survival.Read moreRead less
Plant Genes Conferring Resistance to Ultraviolet Radiation. Ultraviolet (UV) radiation induces DNA damage that can decrease plant growth and productivity. Our aim is to begin deciphering the mechanisms responsible for the UV resistance phenotype in plants by: 1) isolating genes that control processing of UV-induced DNA damage; 2) determining the influence of UV on gene activity; and 3) elucidating the functions and essential interactions of the gene products. The results of this study will help ....Plant Genes Conferring Resistance to Ultraviolet Radiation. Ultraviolet (UV) radiation induces DNA damage that can decrease plant growth and productivity. Our aim is to begin deciphering the mechanisms responsible for the UV resistance phenotype in plants by: 1) isolating genes that control processing of UV-induced DNA damage; 2) determining the influence of UV on gene activity; and 3) elucidating the functions and essential interactions of the gene products. The results of this study will help us understand how these genes operate to produce the UV resistance phenotype. This new knowledge will facilitate eventual engineering of plants to increase agricultural productivity by enhancing resistance to solar UV radiation.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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How neurons maintain their fate. This project aims to investigate how neurons maintain their identity, without reverting back to less specialised cells. Stable fate maintenance is essential because when it fails, cells lose their ability to perform their ascribed function, which impedes organism fitness. This project aims to define how two proteins work in partnership to maintain the identity of brain neurons. We intend our discoveries to stimulate new research, for example to test whether the h ....How neurons maintain their fate. This project aims to investigate how neurons maintain their identity, without reverting back to less specialised cells. Stable fate maintenance is essential because when it fails, cells lose their ability to perform their ascribed function, which impedes organism fitness. This project aims to define how two proteins work in partnership to maintain the identity of brain neurons. We intend our discoveries to stimulate new research, for example to test whether the human counterparts of the Drosophila proteins studied here, function similarly. Benefits will be provided in the form of job creation, and new knowledge in fundamental aspects of life, including brain development and cell fate maintenance.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0883081
Funder
Australian Research Council
Funding Amount
$350,000.00
Summary
High Content Cell Signaling Discovery and Screening Facility. The national benefits of this facility will be an increase in basic knowledge of how cells transmit signals to determine their behaviour in normal or stressed situations. There will be high impact publications in learned journals, new IP developed, enhanced education and training in cutting edge technologies. The discoveries from this work will provide candidates for development by the Biotechnology industry in Australia. All of this ....High Content Cell Signaling Discovery and Screening Facility. The national benefits of this facility will be an increase in basic knowledge of how cells transmit signals to determine their behaviour in normal or stressed situations. There will be high impact publications in learned journals, new IP developed, enhanced education and training in cutting edge technologies. The discoveries from this work will provide candidates for development by the Biotechnology industry in Australia. All of this will promote an innovation culture and economy. The work done in this facility addresses several National Research Priority areas including Promoting and maintaining good health, Frontier technologies for transforming industry and Safeguarding Australia.Read moreRead less