Translocated signals regulating stem cell (meristem) activity in legumes. Translocation channels of phloem and xylem allocate nutrients to growing plant organs. They also mediate communication between organs through transport of signals that elicit responses to developmental and environmental cues. The most important sites for signal transduction are the stem cells of root and shoot apical meristems. This project will discover and identify these signals using a metabolomic/proteomic approach an ....Translocated signals regulating stem cell (meristem) activity in legumes. Translocation channels of phloem and xylem allocate nutrients to growing plant organs. They also mediate communication between organs through transport of signals that elicit responses to developmental and environmental cues. The most important sites for signal transduction are the stem cells of root and shoot apical meristems. This project will discover and identify these signals using a metabolomic/proteomic approach and relying on a unique feature of lupin that permits collection of transport fluids. The project will identify ways to modify signal action to enhance performance of legumes.Read moreRead less
Investigations of signals involved in redox-regulation of carbon storage. This project seeks molecular understanding of signals optimising storage processes in plants in response to nutrient supply and environmental stress. Discovering regulatory signals that control carbon storage and yield will maintain Australia's international reputation in this field of research and may provide technical opportunities to improve crops in healthy or stressful environments. This is an issue of increasing impo ....Investigations of signals involved in redox-regulation of carbon storage. This project seeks molecular understanding of signals optimising storage processes in plants in response to nutrient supply and environmental stress. Discovering regulatory signals that control carbon storage and yield will maintain Australia's international reputation in this field of research and may provide technical opportunities to improve crops in healthy or stressful environments. This is an issue of increasing importance especially in the context of global warming. 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.
Read moreRead less
Transport systems that underpin nitrogen efficient maize. This project aims to define the nitrogen transport network involved in the uptake, storage and redistribution of inorganic nitrogen (nitrate and ammonium) over the developmental life cycle of maize. This information will provide novel insight into the genetic control of nitrogen use in maize and other cereal crops.
Cell wall invertase regulates fruit and seed development through sugar signals, sugar transporters and plasmodesmal gating. This project seeks to understand the molecular and cellular events controlling carbohydrate allocation in fruit and seed by focusing the coupling between sugar metabolism and transport using tomato as a model. The information generated may provide technological opportunities to improve fruit and seed development hence, crop yield.
Mechanisms regulating plant cell expansion: assessing the role of aquaporins and sugar signalling. This project seeks to understand the role of water channel genes in controlling water flow into expanding plant cells by using cotton fibre as a model cell. Water flow plays critical roles in plant growth, hence yield. The information generated may provide technological opportunities for improving water flow and utilization, hence, crop yield.
Physiological and molecular controls of plant transpiration efficiency: investigating the role of the ERECTA gene. Water is the single most limiting factor in agriculture and the world's supply of fresh water is diminishing, the greatest fraction of total water use being by agriculture. Progress in water-use efficiency will have social value, and this program should help us to achieve it. Our progress in this area is already one of the most successful of 'bottom-up' approaches - in the sense of ....Physiological and molecular controls of plant transpiration efficiency: investigating the role of the ERECTA gene. Water is the single most limiting factor in agriculture and the world's supply of fresh water is diminishing, the greatest fraction of total water use being by agriculture. Progress in water-use efficiency will have social value, and this program should help us to achieve it. Our progress in this area is already one of the most successful of 'bottom-up' approaches - in the sense of transferring knowledge from biochemistry and biophysics to breeding and agronomy, as CSIRO now has a successful wheat breeding program based on this earlier work of ours. Now that we have discovered a gene that controls water-use efficiency at the leaf level, we wish to see how the gene works, and how it affects mineral nutrition of leaves.Read moreRead less
The other half of the G-protein story: Functional analysis of the plant G-protein gamma subunits. It is now established that G-proteins are involved in the transduction of a number of important processes in plants (Cell division, stomata control, defence, light perception, etc). Nevertheless the data accumulated to date is based on the study of one of the two subunits (alpha) of the G-proteins. Almost nothing is known about the role of the second (and independent) subunit: beta-gamma. We will st ....The other half of the G-protein story: Functional analysis of the plant G-protein gamma subunits. It is now established that G-proteins are involved in the transduction of a number of important processes in plants (Cell division, stomata control, defence, light perception, etc). Nevertheless the data accumulated to date is based on the study of one of the two subunits (alpha) of the G-proteins. Almost nothing is known about the role of the second (and independent) subunit: beta-gamma. We will study for the first time the role of the beta-gamma subunit in plants. We will use a comprehensive approach combining biochemical, physiological, phenotypic, genomic and proteomic studies.Read moreRead less
Identifying novel salinity tolerance mechanisms by spatial and temporal analysis of lipids in barley. Agrifood production faces the dual challenges of an increasing world population and the threats of abiotic stresses arising from climate change and the erosion of arable land. Cereals, the major food crops, are poorly adapted to tolerate most abiotic stresses, including salinity. This project applies new technologies investigating spatial and temporal biochemical mechanisms a model cereal, Horde ....Identifying novel salinity tolerance mechanisms by spatial and temporal analysis of lipids in barley. Agrifood production faces the dual challenges of an increasing world population and the threats of abiotic stresses arising from climate change and the erosion of arable land. Cereals, the major food crops, are poorly adapted to tolerate most abiotic stresses, including salinity. This project applies new technologies investigating spatial and temporal biochemical mechanisms a model cereal, Hordeum vulgare (barley), utilises to adapt and tolerate salinity. The aims are to investigate the role of specifically plasma membrane lipids modulating either signalling pathways or membrane fluidity that impacts on adaptation during salinity. The results will provide new leads for the development of cereal germplasm with increased salt tolerance.Read moreRead less