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Biology of flowering plant male gametic cells in relation to fertilization. The world food supply is primarily dependent on plants. The continuation of an adequate food supply depends upon the success of fertilization that involves the fusion of the sperm cell with the egg cell. The entire process of fertilization can be manipulated once the specific molecules involved in its regulation have been identified. This project deals with the discovery of male gamete biomolecules involved in fertili ....Biology of flowering plant male gametic cells in relation to fertilization. The world food supply is primarily dependent on plants. The continuation of an adequate food supply depends upon the success of fertilization that involves the fusion of the sperm cell with the egg cell. The entire process of fertilization can be manipulated once the specific molecules involved in its regulation have been identified. This project deals with the discovery of male gamete biomolecules involved in fertilization. The knowledge obtained will have potential applications in developing novel breeding technologies for improved crop plants.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120101562
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Quantifying the contribution of leaf vein networks to the leaf economics spectrum in native and agricultural species. Using a combination of eco-physiological and geometric measures this project will evaluate the influence of leaf vein networks on leaf economics. It is expected that this work will identify vein investment and network design as major sources of variability underlying species adaptive strategies, and the global leaf economics spectrum as a whole.
ARC Centre of Excellence - In Plant Energy Biology (CPEB). Plant cell metabolism underlies the synthesis of important products in crops, and subtle changes in metabolism can enhance germination rates, early seedling vigour, biomass/yield, and tolerance to harsh environments. Research in CPEB will focus on control of this metabolism. Its expertise will enhance Australia's participation in major international research efforts directly relevant to sustainable agriculture in a country with fragile/ ....ARC Centre of Excellence - In Plant Energy Biology (CPEB). Plant cell metabolism underlies the synthesis of important products in crops, and subtle changes in metabolism can enhance germination rates, early seedling vigour, biomass/yield, and tolerance to harsh environments. Research in CPEB will focus on control of this metabolism. Its expertise will enhance Australia's participation in major international research efforts directly relevant to sustainable agriculture in a country with fragile/degrading ecosystems. The research will provide new approaches for enhancing quality metabolite traits important for human health. It will further strengthen our international leadership in plant energy science, and will strengthen Australia's research training in systems biology to influence plant function.Read moreRead less
How plants produce their biomass. This project aims to investigate mechanisms that underpin the formation of secondary walls, the bulk of biomass in plant cells. Plant cell walls are essential for plant growth and provide great raw materials for many industrial products. Understanding how cell walls are made would enable tailored plant biomass production, but understanding remains poor. The project will induce secondary walls at will and outline a framework for how secondary walls are made. The ....How plants produce their biomass. This project aims to investigate mechanisms that underpin the formation of secondary walls, the bulk of biomass in plant cells. Plant cell walls are essential for plant growth and provide great raw materials for many industrial products. Understanding how cell walls are made would enable tailored plant biomass production, but understanding remains poor. The project will induce secondary walls at will and outline a framework for how secondary walls are made. The outcomes are expected to be relevant for the fuel, feed, food and construction sectors, and thus to Australia's future.Read moreRead less
Improved models to understand the genomic architecture of complex traits. This project aims to improve modelling of the genetics underlying complex traits. The project will develop and test models for using genome-wide genetic data to investigate how much heritability (genetic effect) underlies traits of interest, where it lies in the genome, and how much of it is shared across traits. The new models will be implemented in statistical algorithms in a freely-available software package. This proj ....Improved models to understand the genomic architecture of complex traits. This project aims to improve modelling of the genetics underlying complex traits. The project will develop and test models for using genome-wide genetic data to investigate how much heritability (genetic effect) underlies traits of interest, where it lies in the genome, and how much of it is shared across traits. The new models will be implemented in statistical algorithms in a freely-available software package. This project expects to increase understanding of biological mechanisms, the efficiency of genetic association analyses and the accuracy of genomic prediction, including the effects of interventions. The project will adapt human models to a wider range of organisms, in particular bacteria.Read moreRead less
Spatio-temporal analysis of molecular changes during leaf senescence in arabidopsis and wheat and their response to the environment. Innovative agricultural solutions in Australia can be gained by changing the abundance of proteins and metabolites to influence plant performance and provide more robust plants and plant products. The aging and dying of leaves (leaf senescence) is a key factor in our understanding of plant development and the recovery of nutrients from dying tissues. Leaf senescenc ....Spatio-temporal analysis of molecular changes during leaf senescence in arabidopsis and wheat and their response to the environment. Innovative agricultural solutions in Australia can be gained by changing the abundance of proteins and metabolites to influence plant performance and provide more robust plants and plant products. The aging and dying of leaves (leaf senescence) is a key factor in our understanding of plant development and the recovery of nutrients from dying tissues. Leaf senescence is also important for pre-harvest impacts on seed and grain quality as leaves represent the major nitrogen store remobilised to feed these plant products. This work will support the generation of intellectual property to be applied within Australia's plant-based industries and at the same time provides a strong environment for the training of students and researchers.Read moreRead less
Improving plant productivity and human health using next generation biotechnology approaches. Both medical and plant sciences face similar technological problems in harnessing the power of modern DNA sequencing for accelerating the pace of beneficial gene function discovery. Plant and animal researchers will collaborate in this program to meet this common challenge. The research outcomes envisaged in this proposal will benefit human health by enabling more rapid discovery of genes related to obe ....Improving plant productivity and human health using next generation biotechnology approaches. Both medical and plant sciences face similar technological problems in harnessing the power of modern DNA sequencing for accelerating the pace of beneficial gene function discovery. Plant and animal researchers will collaborate in this program to meet this common challenge. The research outcomes envisaged in this proposal will benefit human health by enabling more rapid discovery of genes related to obesity, immunity, fertility, neurological function and cancer. In the plant sphere, the outcomes will shed new light on plant functions related to plant energy metabolism, vitamin biosynthesis drought tolerance and water use by crops. The research will benefit both human health and agricultural food production and quality.Read moreRead less
Expression of value added product in wheat. Wheat is an important food crop due to nutritional value of its seeds. Advances in development of reliable methods for plant genetic transformation now make it possible to apply genetic engineering to the improvement of this important crop. In this linkage application, we aim to introduce a gene for a value added nutraceutical product in elite cultivars of wheat. The successful outcome of the proposed project will lead to the development of value ad ....Expression of value added product in wheat. Wheat is an important food crop due to nutritional value of its seeds. Advances in development of reliable methods for plant genetic transformation now make it possible to apply genetic engineering to the improvement of this important crop. In this linkage application, we aim to introduce a gene for a value added nutraceutical product in elite cultivars of wheat. The successful outcome of the proposed project will lead to the development of value added wheat varieties that cannot be achieved through conventional breeding and will provide Australian industry competitive advantage in rapidly growing world wide market for new health promoting foods.Read moreRead less
Chemically re-engineering bioactive natural products using fragment based drug design. Current drug and agrichemical discovery technologies are under immense pressure to meet the future pharmaceutical and agriculture demand created by population growth. This project will develop a novel technology concept that re-engineers the chemical features of bioactive natural products optimising medicine and agrichemical discovery.
Characteristics of chlorophyll d-binding protein complexes: assembly of light-harvesting complexes. This project will investigate molecular mechanisms of photosynthesis in Chl d with the view to applying our findings in biotechnology and artificial photosynthesis. We will use a variety of molecular biology, proteomics and physical techniques to probe the bonding of Chl d to binding proteins. Synthetic peptide maquettes will provide a model to develop this understanding. Only two chlorophylls (a ....Characteristics of chlorophyll d-binding protein complexes: assembly of light-harvesting complexes. This project will investigate molecular mechanisms of photosynthesis in Chl d with the view to applying our findings in biotechnology and artificial photosynthesis. We will use a variety of molecular biology, proteomics and physical techniques to probe the bonding of Chl d to binding proteins. Synthetic peptide maquettes will provide a model to develop this understanding. Only two chlorophylls (a and d) have so far been found to take part in the primary reactions of photosynthesis. This research will grow our understanding of this pivotal process and underpin future developments in artificial photosynthesis and in the photonics industry.Read moreRead less