Race status, sources of resistance and mechanisms of resistance to Peronospora parasitica, a major threat to oilseed Brassica production in Australia. Through successful identification of mechanisms and molecular characterisation of resistance to Peronospora parasitica races and the identification of sources of host resistance against these races, breeders, for the first time, will be able to develop cultivars with resistance against the full spectrum of P. parasitica races occurring across sout ....Race status, sources of resistance and mechanisms of resistance to Peronospora parasitica, a major threat to oilseed Brassica production in Australia. Through successful identification of mechanisms and molecular characterisation of resistance to Peronospora parasitica races and the identification of sources of host resistance against these races, breeders, for the first time, will be able to develop cultivars with resistance against the full spectrum of P. parasitica races occurring across southern Australia. Benefits include prevention of severe losses in canola from downy mildew, and more viable and sustainable production with less reliance upon fungicides. This research addresses the National Research Priority 'An Environmentally Sustainable Australia' and the Priority Goal of 'Transforming existing industries', and will particularly benefit southern Australian rural communities.Read moreRead less
Race status, resistance mechanisms, and new sources of resistance to Phytophthora clandestina, a major threat to subterranean clover production. Devastating outbreaks of disease caused by Phytophthora clandestina (Phytophthora root rot) since the late 1970s demonstrated the capacity of this disease to impact severely on clover pasture production across southern Australia, particularly as new races of Phytophthora have rapidly emerged to overcome the resistance of all commercial cultivars. The p ....Race status, resistance mechanisms, and new sources of resistance to Phytophthora clandestina, a major threat to subterranean clover production. Devastating outbreaks of disease caused by Phytophthora clandestina (Phytophthora root rot) since the late 1970s demonstrated the capacity of this disease to impact severely on clover pasture production across southern Australia, particularly as new races of Phytophthora have rapidly emerged to overcome the resistance of all commercial cultivars. The proposed research seeks to delineate new races of the pathogen, to identify the histological and biochemical mechanisms by which resistance to Phytophthora root rot is expressed, and to identify new sources of host resistance. This proposed research will enable breeders, for the first time, to incorporate multiple types of resistance and against different races into new host varieties.Read moreRead less
Novel photoprotective mechanisms and functional biodiversity of high light tolerance in the model alga Chlamydomonas. Most plants have limited capacity to avoid high light (HL) stress which commonly accompanies drought and high temperature stress. We will identify novel genes and proteins that underlie diverse mechanisms of photoprotection in unique very high light resistant (VHLR) mutants in the alga Chlamydomonas and develop new tools to screen other plants for these attributes. Depending on p ....Novel photoprotective mechanisms and functional biodiversity of high light tolerance in the model alga Chlamydomonas. Most plants have limited capacity to avoid high light (HL) stress which commonly accompanies drought and high temperature stress. We will identify novel genes and proteins that underlie diverse mechanisms of photoprotection in unique very high light resistant (VHLR) mutants in the alga Chlamydomonas and develop new tools to screen other plants for these attributes. Depending on progress, we expect to express them in the higher plant Arabidopsis as a first step towards utilization of VHLR genes for crop improvement. Understanding the mechanisms conferring HL photoprotection is a research priority in plant sciences and will further strengthen Australia's innovative contributions to the internationally networked Chlamydomonas Genome Project.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100086
Funder
Australian Research Council
Funding Amount
$850,000.00
Summary
A Single-Molecule Super-Resolution Microscopy Facility in Western Australia. A single-molecule super-resolution microscopy facility in Western Australia:
The project aims to establish a facility combining single-molecule imaging with super-resolution microscopy to enable biologists in Western Australia to resolve and directly observe interacting macromolecules in plants, animals and organisms, Interacting macromolecules form the basis of cell biology. Imaging and characterising such interaction ....A Single-Molecule Super-Resolution Microscopy Facility in Western Australia. A single-molecule super-resolution microscopy facility in Western Australia:
The project aims to establish a facility combining single-molecule imaging with super-resolution microscopy to enable biologists in Western Australia to resolve and directly observe interacting macromolecules in plants, animals and organisms, Interacting macromolecules form the basis of cell biology. Imaging and characterising such interactions in living cells and tissues has become possible with the latest molecular imaging techniques and super-resolution optical microscopy (with spatial resolutions of 20 nanometres or better). The facility seeks to advance science across diverse regional priorities in agriculture, environment, marine ecology, medicine and health.Read moreRead less
When to Flower - analysis of a novel genetic locus (FLH) that accelerates flowering. The development of plants is largely determined by the environment. The flowering time of some plants, including many crop species, is accelerated by vernalization, a long period of low temperature. Using a combination of genetic and molecular techniques in the model plant Arabidopsis, this project will characterise a novel locus, FLH that enhances the response to vernalization. The identification of FLH will si ....When to Flower - analysis of a novel genetic locus (FLH) that accelerates flowering. The development of plants is largely determined by the environment. The flowering time of some plants, including many crop species, is accelerated by vernalization, a long period of low temperature. Using a combination of genetic and molecular techniques in the model plant Arabidopsis, this project will characterise a novel locus, FLH that enhances the response to vernalization. The identification of FLH will significantly enhance our understanding of flowering time pathways, and may lead to the generation of plant varieties designed to flower faster or slower than usual.Read moreRead less
Plant Transfer Cells - Discovering the Mechanisms of Wall Ingrowth Formation. This project seeks fundamental molecular understanding of how specialized plant cells that are designed for optimum transport of nutrients develop. So-called "transfer cells" are important for efficient nutrient transport and distribution in many crop species of significance to agriculture. Discovering the mechanisms that coordinate development of these specialized cells will maintain Australia's international reputat ....Plant Transfer Cells - Discovering the Mechanisms of Wall Ingrowth Formation. This project seeks fundamental molecular understanding of how specialized plant cells that are designed for optimum transport of nutrients develop. So-called "transfer cells" are important for efficient nutrient transport and distribution in many crop species of significance to agriculture. Discovering the mechanisms that coordinate development of these specialized cells will maintain Australia's international reputation in this field of research, as well as provide technological opportunities to enhance crop yields by manipulating the efficiency of nutrient distribution in crop species. Read moreRead less
Induction of Plant Transfer Cells - Discovering Regulatory Networks. This project seeks molecular understanding of regulatory mechanisms responsible for inducing formation of specialized plant cells that are of central importance in controlling nutrient transport. These so-called "transfer cells" play pivotal roles in determining crop nutrition and hence yield under normal and stressful environments such as soil nutrient deficiencies and salinity. Discovering regulatory mechanisms that control f ....Induction of Plant Transfer Cells - Discovering Regulatory Networks. This project seeks molecular understanding of regulatory mechanisms responsible for inducing formation of specialized plant cells that are of central importance in controlling nutrient transport. These so-called "transfer cells" play pivotal roles in determining crop nutrition and hence yield under normal and stressful environments such as soil nutrient deficiencies and salinity. Discovering regulatory mechanisms that control formation of these specialized cells will maintain Australia's international reputation in this field of research. In addition, the information platform generated may provide technological opportunities to optimise nutrient flows in healthy plants, combat certain environmental stresses and control pathogen attack.
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Genetic control of flowering and photoperiodism in pea. The timing of flowering in many plant species is strongly influenced by photoperiod. The mechanisms by which photoperiod controls flowering will be investigated using the garden pea as a model system. New pea mutants impairing photoperiod responses will be identified and characterized, and photoperiod response genes from Arabidopsis will be mapped and used for expression studies in pea. This work will provide important new information about ....Genetic control of flowering and photoperiodism in pea. The timing of flowering in many plant species is strongly influenced by photoperiod. The mechanisms by which photoperiod controls flowering will be investigated using the garden pea as a model system. New pea mutants impairing photoperiod responses will be identified and characterized, and photoperiod response genes from Arabidopsis will be mapped and used for expression studies in pea. This work will provide important new information about the physiological roles of the Arabidopsis genes and the molecular identity of the pea genes. It will add to our knowledge of how flowering is regulated, and this will have important agronomic applications.Read moreRead less
Comparative genetics of flowering and photoperiod responsiveness in legumes. The results from this project will add to our basic knowledge of the way in which environmental factors influence flowering in plants. The timing and duration of flowering is a critical determinant of yield for many crop species, and of market value for many ornamental species. A better understanding of the basic genetics and physiology of flowering will thus be relevant for plant breeders and horticulturalists seeking ....Comparative genetics of flowering and photoperiod responsiveness in legumes. The results from this project will add to our basic knowledge of the way in which environmental factors influence flowering in plants. The timing and duration of flowering is a critical determinant of yield for many crop species, and of market value for many ornamental species. A better understanding of the basic genetics and physiology of flowering will thus be relevant for plant breeders and horticulturalists seeking to modify flowering responses to suit particular production strategies, and will help to maintain the strong position of Australia as a world leader in applied aspects of plant/environment interactions. It will also strengthen the international reputation of Australia for high-quality basic research in plant development.Read moreRead less
A systems approach to dissect the pathogenicity and host specificity of the Fusarium wilt pathogen, Fusarium oxysporum. The pathogenic fungus Fusarium oxysporum causes wilt disease in many plant species, including many that are important for Australian agriculture. Developing environmentally friendly disease protection strategies against this pathogen requires a clear understanding of infection strategies used by the fungus to invade its host. This project, along with a parallel project in host ....A systems approach to dissect the pathogenicity and host specificity of the Fusarium wilt pathogen, Fusarium oxysporum. The pathogenic fungus Fusarium oxysporum causes wilt disease in many plant species, including many that are important for Australian agriculture. Developing environmentally friendly disease protection strategies against this pathogen requires a clear understanding of infection strategies used by the fungus to invade its host. This project, along with a parallel project in host resistance mechanisms, will provide the basis for development of a world leading platform in mechanisms of fungal pathogenicity and virulence and plant disease resistance/susceptibility. Application of the knowledge gained in this project to other host-pathogen interactions will thereby provide opportunities for improved crop protection and biosecurity.Read moreRead less