Further Genetic and Molecular studies of an Important Prokaryotic Regulator Protein TyrR. Genomes encode many functions whose expression varies dramatically depending on particular cellular environments. Special proteins called Regulator Proteins act as sensors to detect subtle changes in the environment and, in response, to influence the expression of certain genes either dampening them down or stimulating their activity. We are working with the TyrR regulator protein of the simple bacterium E ....Further Genetic and Molecular studies of an Important Prokaryotic Regulator Protein TyrR. Genomes encode many functions whose expression varies dramatically depending on particular cellular environments. Special proteins called Regulator Proteins act as sensors to detect subtle changes in the environment and, in response, to influence the expression of certain genes either dampening them down or stimulating their activity. We are working with the TyrR regulator protein of the simple bacterium Escherichia coli to elucidate the molecular strategies used in these controls. Because this protein controls the expression of a number of genes with diverse functions, evolution has selected equally diverse mechanisms to achieve appropriate transcriptional responses. The detailed knowledge of the E.coli genome and of the various genes regulated by TyrR make it an excellent system for such fundamental studies.Read moreRead less
Cellular Gene Regulation Networks. The benefit to Australia will be scientific in terms of providing an understanding of how cells integrate transcriptional control systems and the networks that are involved. This will inform research on folate deficiency and aberrant human development and towards identifying genes that are important in improving efficiency of microbial fermentations. Additional and more practical major benefits will follow from the development of tools to analyse interaction ....Cellular Gene Regulation Networks. The benefit to Australia will be scientific in terms of providing an understanding of how cells integrate transcriptional control systems and the networks that are involved. This will inform research on folate deficiency and aberrant human development and towards identifying genes that are important in improving efficiency of microbial fermentations. Additional and more practical major benefits will follow from the development of tools to analyse interactions between control systems, including software of value to the research community. The work will provide postgraduate students with major training in up-to-date genomic technologies, and in the interface between application of bioinformatics and experimental science.
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Defining New Building Blocks for the Construction of Artificial Genetic Circuits. By characterising the components of a natural genetic switch, we will make available a set of well defined genetic building blocks for construction of rationally designed biological circuits. The ability to build such circuits would have significant economic benefit in areas such as metabolic engineering, to improve the efficiency of production of natural compounds from micro-organisms, and in biomedicine, for the ....Defining New Building Blocks for the Construction of Artificial Genetic Circuits. By characterising the components of a natural genetic switch, we will make available a set of well defined genetic building blocks for construction of rationally designed biological circuits. The ability to build such circuits would have significant economic benefit in areas such as metabolic engineering, to improve the efficiency of production of natural compounds from micro-organisms, and in biomedicine, for the controlled release of therapeutic compounds. The involvement of Honours and Ph.D students in this project will expose the next generation of Australian scientists to this emerging discipline. International collaboration leading to publications in high impact scientific journals will enhance Australia's scientific reputation.Read moreRead less
Phasevarions of Haemophilus influenzae: mechanisms and origins of a novel epigenetic system controlling coordinated random switching in expression of multiple genes. Central to the utilisation of biological information is our ability to identify and interpret DNA sequence information from genomes. In bacteria that cause disease, these investigations can identify key aspects of the infectious process or potential components of vaccines or new targets for antibiotics. Our recent work has identifie ....Phasevarions of Haemophilus influenzae: mechanisms and origins of a novel epigenetic system controlling coordinated random switching in expression of multiple genes. Central to the utilisation of biological information is our ability to identify and interpret DNA sequence information from genomes. In bacteria that cause disease, these investigations can identify key aspects of the infectious process or potential components of vaccines or new targets for antibiotics. Our recent work has identified a new genetic system, the 'phasevarion', that mediates random expression of multiple genes. The proposed research aims to advance our understanding of gene expression at the most basic level, revealing how bacteria generate diverse populations to evade environmental and immune stresses, and facilitating improved interpretation and use of DNA sequences for researchers and industry in this field.Read moreRead less
Decoding Bacterial Epigenetic Regulation. This project aims to characterise bacterial epigenetic regulation by determining the mechanism of action and impact of bacterial DNA methylation. This project expects to generate new knowledge about fundamental aspects of bacterial gene regulation, using a novel combination of cutting edge DNA and RNA sequencing, proteomic and bioinformatic approaches. The expected outcomes of this project will provide new tools to facilitate the integration of epigenomi ....Decoding Bacterial Epigenetic Regulation. This project aims to characterise bacterial epigenetic regulation by determining the mechanism of action and impact of bacterial DNA methylation. This project expects to generate new knowledge about fundamental aspects of bacterial gene regulation, using a novel combination of cutting edge DNA and RNA sequencing, proteomic and bioinformatic approaches. The expected outcomes of this project will provide new tools to facilitate the integration of epigenomic analysis into genomic studies, exponentially increasing the volume and value of data gathered. This would provide significant future benefits to all academic, biotechnology, agricultural, veterinary and pharmaceutical applications that involve bacterial genomic analysis.Read moreRead less
Evolution and ecology of integron gene cassettes: exploring the protein universe. Bacteria rapidly adapt to new conditions by sharing diverse genes via lateral genetic transfer, best illustrated by the spread of antibiotic resistance. This study will characterise mobile genes, discovering new gene families and proteins, and will expand existing knowledge of bacterial evolution.
How evolution is constrained by trade-offs between the multiplication and survival of organisms. The negative correlation between reproduction (production of large numbers of progeny) and survival (resistance to external challenges) is a crucial trade-off that limits the evolution of perfect organisms. Such trade-offs are extremely difficult to study in closely controlled experiments because of the complexities in biological organisation and life-cycles. This project will explore trade-offs usin ....How evolution is constrained by trade-offs between the multiplication and survival of organisms. The negative correlation between reproduction (production of large numbers of progeny) and survival (resistance to external challenges) is a crucial trade-off that limits the evolution of perfect organisms. Such trade-offs are extremely difficult to study in closely controlled experiments because of the complexities in biological organisation and life-cycles. This project will explore trade-offs using a novel synthetic biology strategy. Genes in bacteria will be engineered to produce strains with a range of fixed but different trade-off settings. The strain sets will allow unprecedented analysis of reproduction-survival trade-offs and testing of important models of how trade-offs control fitness and evolutionary outcomes.Read moreRead less
Unlocking the secrets of metabolic variation in a highly diverse bacterium. This project aims to explore metabolic diversity of Klebsiella pneumoniae, a bacterium relevant to the agricultural, veterinary, medical and biotechnology industries. It is expected to reveal significant insights into the biology of this diverse organism via an innovative combination of DNA sequence analyses and metabolic modelling. Expected outcomes include 4500 novel metabolic models and a novel population metabolic fr ....Unlocking the secrets of metabolic variation in a highly diverse bacterium. This project aims to explore metabolic diversity of Klebsiella pneumoniae, a bacterium relevant to the agricultural, veterinary, medical and biotechnology industries. It is expected to reveal significant insights into the biology of this diverse organism via an innovative combination of DNA sequence analyses and metabolic modelling. Expected outcomes include 4500 novel metabolic models and a novel population metabolic framework. This should provide major benefits for understanding bacterial ecology and evolution, and for future studies seeking to optimise industrial processes or prevent disease. It will also directly contribute to building Australia’s capacity in computational biology- a key driver of biotechnology innovation.Read moreRead less
Molecular genetic analysis of genes controlling morphogenesis: Dimorphic switching in the fungus Penicillium marneffei. Fungi exist in two predominant growth forms; unicellular yeast and multicellular mould (filamentous hyphae). Some fungi can alternate between these two forms in response to environmental stimuli, a process known as dimorphic switching. The cells of these two forms have distinctive shapes and physiological capacities established by genome-wide expression patterns that are trigge ....Molecular genetic analysis of genes controlling morphogenesis: Dimorphic switching in the fungus Penicillium marneffei. Fungi exist in two predominant growth forms; unicellular yeast and multicellular mould (filamentous hyphae). Some fungi can alternate between these two forms in response to environmental stimuli, a process known as dimorphic switching. The cells of these two forms have distinctive shapes and physiological capacities established by genome-wide expression patterns that are triggered by signalling pathways. This research aims to understand the fundamental mechanisms controlling dimorphic switching using Penicillium marneffei, a model system. P. marneffei switches between yeast and filamentous forms in response to temperature. Uncovering the molecular mechanisms that control dimorphic switching has important implications for biotechnology and medicine.Read moreRead less
Regulation of nuclear localisation of the AreA transcription factor in Aspergillus nidulans. An understanding of the means by which the expression of genes is regulated is of fundamental significance. Changes in gene expression are central to the development, growth and viability of all cells and their response to environmental changes/stresses. This study uses the fungus Aspergillus nidulans as an excellent molecular genetic tool to investigate how a key regulatory protein controls gene expres ....Regulation of nuclear localisation of the AreA transcription factor in Aspergillus nidulans. An understanding of the means by which the expression of genes is regulated is of fundamental significance. Changes in gene expression are central to the development, growth and viability of all cells and their response to environmental changes/stresses. This study uses the fungus Aspergillus nidulans as an excellent molecular genetic tool to investigate how a key regulatory protein controls gene expression in response to nitrogen starvation stress. Our understanding of these dynamic processes informs our approaches to the development of cancer therapies, to commercial biotechnology application and to control of human, plant and animal pathogens in which the infectious process is triggered by environmental stress. Read moreRead less