LATERAL GENE TRANSFER, GENOME EVOLUTION AND THE EMERGENCE OF NEW DISEASES CAUSED BY FUNGAL PATHOGENS IN THE PLEOSPORALES. Normal evolution involves the transfer of genes within species. The modest variation between progeny powers natural selection. Lateral gene transfer is the movement of genetic material between species. It allows for large evolutionary steps. Although common in bacteria, it has rarely been described convincingly in higher organisms such as fungi, plants or animals. We have evi ....LATERAL GENE TRANSFER, GENOME EVOLUTION AND THE EMERGENCE OF NEW DISEASES CAUSED BY FUNGAL PATHOGENS IN THE PLEOSPORALES. Normal evolution involves the transfer of genes within species. The modest variation between progeny powers natural selection. Lateral gene transfer is the movement of genetic material between species. It allows for large evolutionary steps. Although common in bacteria, it has rarely been described convincingly in higher organisms such as fungi, plants or animals. We have evidence that one group of fungal pathogens is particularly adept at acquiring new genes that enable them to cause new diseases. We will determine the mechanism and frequency of gene transfer in this group. The work had fundamental significance in evolutionary biology, in the emergence of new diseases and in the use of genetically-modified organisms.Read moreRead less
Understanding fungal diversity and functioning in forest soils using molecular and stable isotope approaches. The project aims to investigate fungal community structure and functioning in forest soils using novel molecular, stable isotope and physiological approaches. This will provide new insights into the linkage between diversity and functioning in forest soil fungal communities and the importance of these organisms in ecosystem processes. In addition, this pioneering research will facilitate ....Understanding fungal diversity and functioning in forest soils using molecular and stable isotope approaches. The project aims to investigate fungal community structure and functioning in forest soils using novel molecular, stable isotope and physiological approaches. This will provide new insights into the linkage between diversity and functioning in forest soil fungal communities and the importance of these organisms in ecosystem processes. In addition, this pioneering research will facilitate development and refinement of methodologies that will pave the way for future investigations of fungal ecology. The on-going collaboration will produce high quality joint publications and provide significant opportunities for early career researchers to gain international experience in a dynamic research environment.Read moreRead less
Future climate change: consequences for decomposition and pathways of carbon flow through rhizosphere fungal communities. The proposed collaboration will provide novel insights into likely consequences of global climate change on decomposition and pathways of carbon flow through forest soils. This will refine predictive models of future climate change and its impacts on the sustainability of Australia's forests. It will also enhance the protection of our valued habitats and their important soil ....Future climate change: consequences for decomposition and pathways of carbon flow through rhizosphere fungal communities. The proposed collaboration will provide novel insights into likely consequences of global climate change on decomposition and pathways of carbon flow through forest soils. This will refine predictive models of future climate change and its impacts on the sustainability of Australia's forests. It will also enhance the protection of our valued habitats and their important soil biodiversity. The knowledge gained will help land managers to adapt current practices to meet the demands of future climate change. This will maximize the opportunities for sequestering carbon in Australia's forests and so contribute to meeting Australia's global responsibility for mitigation of climate change.Read moreRead less
Global genetic regulation of carbon metabolism in filamentous fungi. Fungi are of great importance in medicine, agriculture and industry. They are used extensively for food, antibiotic and chemical production and, increasingly, for generating cheap substrates for bioethanol. However many are serious pathogens of plants and humans. Understanding how fungi control their metabolism is of fundamental importance for their more effective use or control. This project takes advantage of a fungus that is ....Global genetic regulation of carbon metabolism in filamentous fungi. Fungi are of great importance in medicine, agriculture and industry. They are used extensively for food, antibiotic and chemical production and, increasingly, for generating cheap substrates for bioethanol. However many are serious pathogens of plants and humans. Understanding how fungi control their metabolism is of fundamental importance for their more effective use or control. This project takes advantage of a fungus that is easily studied in the laboratory by advanced genetic techniques to identify the ways in which genes are turned on and off in response to changes in the nutrients available. By comparing DNA sequences the results are readily applied to fungi of economic importance.Read moreRead less
Understanding an exotic disease: Initiation of sex and infection by the sugarcane smut Ustilago scitaminea. Australian sugar exports generate almost $2 billion in annual sales, making the sugar industry a critical facet of the Australian economy. In 2006, Australia's primary sugar producing region came under threat when an outbreak of sugarcane smut caused by the fungus Ustilago scitaminea first appeared in Queensland. Management of this potentially devastating disease has focused on breeding pr ....Understanding an exotic disease: Initiation of sex and infection by the sugarcane smut Ustilago scitaminea. Australian sugar exports generate almost $2 billion in annual sales, making the sugar industry a critical facet of the Australian economy. In 2006, Australia's primary sugar producing region came under threat when an outbreak of sugarcane smut caused by the fungus Ustilago scitaminea first appeared in Queensland. Management of this potentially devastating disease has focused on breeding programmes aimed at developing resistant sugarcane cultivars, a complex process hampered by a lack of information about the mechanisms of smut resistance. Our research will provide key insight into the mechanisms by which U. scitaminea infects sugarcane, directing future breeding efforts and protecting this valuable industry against further outbreaks.Read moreRead less
A novel approach to fighting fungal infections: targeted disruption of hydrophobin monolayers. Fungal infestations of important crops such as cotton cause large economic losses to Australian agriculture while in the medical sector, fungal infections are responsible for high levels of mortality in immunocompromised patients. Our research will provide a new approach to fighting fungal infections by targeting the hydrophobin proteins, which form a robust coating on fungal aerial structures, such as ....A novel approach to fighting fungal infections: targeted disruption of hydrophobin monolayers. Fungal infestations of important crops such as cotton cause large economic losses to Australian agriculture while in the medical sector, fungal infections are responsible for high levels of mortality in immunocompromised patients. Our research will provide a new approach to fighting fungal infections by targeting the hydrophobin proteins, which form a robust coating on fungal aerial structures, such as spores. This layer is critical for fungal growth and reproduction and confers water resistance and tolerance to harsh conditions. Our work seeks to develop reagents that can specifically block regions on the protein that are responsible for forming this coating.
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Exploring the genetic and functional diversity nexus in ericoid mycorrhizal and related symbioses. Epacrids are important components of the Australian flora and several are considered threatened, yet we know relatively little regarding the importance of ericoid mycorrhizal fungal diversity to their survival. The proposed work will provide essential information on the functional significance of ericoid mycorrhizal endophyte diversity in the growth and survival of epacrids. It will further lead to ....Exploring the genetic and functional diversity nexus in ericoid mycorrhizal and related symbioses. Epacrids are important components of the Australian flora and several are considered threatened, yet we know relatively little regarding the importance of ericoid mycorrhizal fungal diversity to their survival. The proposed work will provide essential information on the functional significance of ericoid mycorrhizal endophyte diversity in the growth and survival of epacrids. It will further lead to improved propagation of epacrids and better informed decisions for sustainable management of Australian native vegetation.Read moreRead less
Discovery Indigenous Researchers Development - Grant ID: DI0668388
Funder
Australian Research Council
Funding Amount
$87,458.00
Summary
The genetic basis for bioactivity in the traditional medicine plants of Australia. A plant species that produces a bioactive compound usually produce the compound in very small amounts. To allow for marketable levels of production of the bioactive compound, numerous amounts of plants would need to be removed from the environment. This not only removes the limited supply of possibly rare types of plants from the environment but also denies the use of this plant by traditional people. Locating and ....The genetic basis for bioactivity in the traditional medicine plants of Australia. A plant species that produces a bioactive compound usually produce the compound in very small amounts. To allow for marketable levels of production of the bioactive compound, numerous amounts of plants would need to be removed from the environment. This not only removes the limited supply of possibly rare types of plants from the environment but also denies the use of this plant by traditional people. Locating and using the genes responsible for producing these bioactive compounds will allow their sustainable biosynthesis.Read moreRead less
Dynamics and correlations of many-body systems. The proposed program will greatly enhance Australian science through linking innovative
theoretical techniques with the successful ongoing Australian experimental program in atom
lasers, atom chip interferometry and ultra-cold fermions. Pioneering theoretical methods in
quantum phase-space are internationally recognized, and will be extended into new areas relevant
to Australia. These have fundamental significance to fields ranging from nanotec ....Dynamics and correlations of many-body systems. The proposed program will greatly enhance Australian science through linking innovative
theoretical techniques with the successful ongoing Australian experimental program in atom
lasers, atom chip interferometry and ultra-cold fermions. Pioneering theoretical methods in
quantum phase-space are internationally recognized, and will be extended into new areas relevant
to Australia. These have fundamental significance to fields ranging from nanotechnology to
astrophysics, as well as providing a route to improved atomic clocks and other instruments.
Combining these theoretical and computational methods from the physical sciences with biology
and genetics will provide future cross-disciplinary benefits to Australian biomedical science.Read moreRead less
Recombination of mitochondrial genomes: what can we learn from chigger mites? This project will bring three benefits to Australia. First, it will enhance Australia's research capacity in the fields of organelle genomics and evolutionary biology. Second, it will yield highly skilled young researchers: a postdoctoral fellow (Shao), a PhD student and two BSc Honours students. Third, it will generate new knowledge about genome recombination in animal mitochondria. Recombination is a fundamental, yet ....Recombination of mitochondrial genomes: what can we learn from chigger mites? This project will bring three benefits to Australia. First, it will enhance Australia's research capacity in the fields of organelle genomics and evolutionary biology. Second, it will yield highly skilled young researchers: a postdoctoral fellow (Shao), a PhD student and two BSc Honours students. Third, it will generate new knowledge about genome recombination in animal mitochondria. Recombination is a fundamental, yet poorly understood issue in mitochondrial genomics and evolutionary biology. Knowledge from this project will also improve our understanding of other important issues that are associated with animal mitochondria; like the mechanisms of mitochondrial disease and ageing, and the evolution of modern humans and other animals.Read moreRead less