Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668093
Funder
Australian Research Council
Funding Amount
$115,000.00
Summary
Expansion and enhancement of the South Australian Regional Facility for Molecular Ecology and Evolution and the Australian Centre Ancient DNA. Provision of dedicated instruments for contemporary and ancient/fragmentary DNA analyses will provide numerous opportunities for innovative research solutions in basic biology, archaeological, agricultural, biomedical, forensic and environmental sciences. No similar combination of facilities currently exists in the Australian region severely curtailing an ....Expansion and enhancement of the South Australian Regional Facility for Molecular Ecology and Evolution and the Australian Centre Ancient DNA. Provision of dedicated instruments for contemporary and ancient/fragmentary DNA analyses will provide numerous opportunities for innovative research solutions in basic biology, archaeological, agricultural, biomedical, forensic and environmental sciences. No similar combination of facilities currently exists in the Australian region severely curtailing and jeopardising the quality of current and proposed research programs. The facilities will underlie innovative approaches to research in National Research Priorities 1 and 4 - An Environmentally Sustainable Australia and Safeguarding AustraliaRead moreRead less
Endosymbiotic DNA transfer. Interorganellar DNA movement is a major force in evolution. In higher organisms, the prokaryotic ancestors of mitochondria and chloroplasts donated many genes to the nucleus. Plants have unique potential in studies of the mechanisms that have driven genome evolution. We established experimentally that DNA moves from the chloroplast to the nucleus at high frequency and this provided us with a world lead in this scientifically new area. The relocated genes contribute to ....Endosymbiotic DNA transfer. Interorganellar DNA movement is a major force in evolution. In higher organisms, the prokaryotic ancestors of mitochondria and chloroplasts donated many genes to the nucleus. Plants have unique potential in studies of the mechanisms that have driven genome evolution. We established experimentally that DNA moves from the chloroplast to the nucleus at high frequency and this provided us with a world lead in this scientifically new area. The relocated genes contribute to the number and diversity of genes and gene function. Genetically manipulated (GM) crops use the chloroplast compartment to make high levels of protein, necessitating a full understanding of how transgenes behave within the cellular and the external environment.Read moreRead less
Genetic control of floral architecture. Different flowers have different designs, and so the design must ultimately be controlled by genes. We have identified a gene that keeps sepals separate, and promotes the initiation of petals. We think it does this by a novel growth suppression mechanism, and will now deduce its molecular and cellular basis. This will help maintain Australia's strength in fundamental plant biology. Also, by understanding how sepals and petals arise in a model laboratory sp ....Genetic control of floral architecture. Different flowers have different designs, and so the design must ultimately be controlled by genes. We have identified a gene that keeps sepals separate, and promotes the initiation of petals. We think it does this by a novel growth suppression mechanism, and will now deduce its molecular and cellular basis. This will help maintain Australia's strength in fundamental plant biology. Also, by understanding how sepals and petals arise in a model laboratory species, we can generalise for many species, including economic plants. Thus it may be possible to make designer crops through targeted genetic changes to their floral structure.Read moreRead less
Control of plant organ development by the PETAL LOSS gene of Arabidopsis. We have discovered a new gene in the model laboratory plant Arabidopsis thaliana that is involved in sepal and petal development. It encodes a transcription factor that apparently acts by repressing growth in the inter-sepal zone of flowers where petals arise. We now aim to determine how this growth suppression occurs, and whether it extends to leaves where the gene is also expressed. Control of the initiation and sculptur ....Control of plant organ development by the PETAL LOSS gene of Arabidopsis. We have discovered a new gene in the model laboratory plant Arabidopsis thaliana that is involved in sepal and petal development. It encodes a transcription factor that apparently acts by repressing growth in the inter-sepal zone of flowers where petals arise. We now aim to determine how this growth suppression occurs, and whether it extends to leaves where the gene is also expressed. Control of the initiation and sculpturing of plant organs by site-specific inhibition of growth is a newly discovered mechanism that may be useful in manipulating plant architecture.Read moreRead less
Understanding how auxin and dorsoventral patterning are coordinated in plants. This study will help reveal for the first time how the outgrowth of leaves, flowers and floral organs is coordinated by tissue patterning genes and the plant growth hormone auxin. All plants grow in this way, and our findings, made using a model laboratory plant, will be applicable to crop species as well. Thus we will both expand our core knowledge of how multicellular organisms are constructed, and also generate pos ....Understanding how auxin and dorsoventral patterning are coordinated in plants. This study will help reveal for the first time how the outgrowth of leaves, flowers and floral organs is coordinated by tissue patterning genes and the plant growth hormone auxin. All plants grow in this way, and our findings, made using a model laboratory plant, will be applicable to crop species as well. Thus we will both expand our core knowledge of how multicellular organisms are constructed, and also generate possibilities for modifying the patterns of leaf and flower development in agricultural and horticultural species. Crops with larger leaves, or flowers of different structure, may result.Read moreRead less
An integrated molecular approach to human evolution. This project aims to use the power of High Throughput Sequencing to investigate a range of genetic mechanisms that facilitate rapid human adaptation to diverse environments. This project expects to create the first ultra-high-quality Aboriginal Australian reference genome using Single Molecule, Real-Time Sequencing, which will expand the known range of human genomic and non-genomic variation. The results should offer the first detailed, long- ....An integrated molecular approach to human evolution. This project aims to use the power of High Throughput Sequencing to investigate a range of genetic mechanisms that facilitate rapid human adaptation to diverse environments. This project expects to create the first ultra-high-quality Aboriginal Australian reference genome using Single Molecule, Real-Time Sequencing, which will expand the known range of human genomic and non-genomic variation. The results should offer the first detailed, long-term reconstruction of the evolutionary history of human adaptability to specific environmental and cultural stressors. Importantly, the translation of the results to biomedical research will shed new light on the origins of modern diseases.Read moreRead less
Describing transition for people living with chronic illness. Our primary aim is to explore transition for people living with chronic illness. Understanding the nature of transition places health care professionals in an excellent position to assist the person living with chronic illness. This is important given that chronic illness has been acknowledged as the prime health concern of this era. We explore, how individuals living with chronic illness make sense of "becoming ordinary" rather than ....Describing transition for people living with chronic illness. Our primary aim is to explore transition for people living with chronic illness. Understanding the nature of transition places health care professionals in an excellent position to assist the person living with chronic illness. This is important given that chronic illness has been acknowledged as the prime health concern of this era. We explore, how individuals living with chronic illness make sense of "becoming ordinary" rather than "being ordinary", exploring how they give meaning to their sense of self and their sense of self capacity. As an interactive participatory action research program with 200 participants, we will validate the emerging transition thesis collaboratively. Resultant action has the potential to enhance participant's lives, foster collective community development, inform health care practice and advance theoretical debates.Read moreRead less
Understanding the molecular mechanisms of intellectual disability. Intellectual disability is frequent in the population, with one in every fifty people in the world directly affected. This project will improve our understanding of the correct development and function of the brain required for cognition by investigating specific roles and regulation of key molecules involved.
Trafficking of DNA between chloroplast and nucleus in higher plants. Reliably high levels of diverse proteins can be produced in plant chloroplasts. Environmental risks are considered low for chloroplast genes because they are not transmitted by pollen. However, we recently discovered that DNA escapes from the tobacco chloroplast to the nucleus with unexpectedly high frequency. The associated environmental risks require immediate investigation. This project will determine the fate of chloroplast ....Trafficking of DNA between chloroplast and nucleus in higher plants. Reliably high levels of diverse proteins can be produced in plant chloroplasts. Environmental risks are considered low for chloroplast genes because they are not transmitted by pollen. However, we recently discovered that DNA escapes from the tobacco chloroplast to the nucleus with unexpectedly high frequency. The associated environmental risks require immediate investigation. This project will determine the fate of chloroplast DNA that has moved to the nuclear genome and gain insight into the evolutionary and environmental consequences of chloroplast DNA escape. The ubiquity of DNA escape also will be studied in an edible crop with a small genome, tomato.Read moreRead less
Analysis of interorganellar transposition of DNA. The movement of DNA between organelles is a major driving force in the eukaryotic evolution. In yeast about 75% of all nuclear genes may derive from protomitochondria. Though DNA transfer per se continues in all higher cells, including mammals, in most species the functional transfer of genes has stopped. It continues at a high rate in plants, giving them unique potential in evolutionary studies of the genome. We established experimentally that D ....Analysis of interorganellar transposition of DNA. The movement of DNA between organelles is a major driving force in the eukaryotic evolution. In yeast about 75% of all nuclear genes may derive from protomitochondria. Though DNA transfer per se continues in all higher cells, including mammals, in most species the functional transfer of genes has stopped. It continues at a high rate in plants, giving them unique potential in evolutionary studies of the genome. We established experimentally that DNA moves frequently from the plastid (chloroplast) to the nucleus. We now aim to measure the frequency of DNA transposition from the plastid to the mitochondrion. If transposition is sufficiently frequent, the approach can be used to transformation the mitochondrial genome.Read moreRead less