Leaves in 3D: photosynthesis and water-use efficiency. This project aims to develop leaf anatomical ideotypes with improved photosynthesis and water-use efficiency for wheat, rice, chickpea and cotton using novel three dimensional imaging and modelling techniques. This project expects to generate new understanding of the role of leaf anatomy on leaf function. Expected outcomes of this project include the world's first 3D spatially-explicit, anatomically accurate model of leaves of crop plants to ....Leaves in 3D: photosynthesis and water-use efficiency. This project aims to develop leaf anatomical ideotypes with improved photosynthesis and water-use efficiency for wheat, rice, chickpea and cotton using novel three dimensional imaging and modelling techniques. This project expects to generate new understanding of the role of leaf anatomy on leaf function. Expected outcomes of this project include the world's first 3D spatially-explicit, anatomically accurate model of leaves of crop plants to allow virtual experiments identifying optimized anatomy for improved photosynthetic performance. Benefits to the agricultural industry include increased crop productivity and water-use efficiency to meet future global food demand and to make the most of Australia's limited water resourcesRead moreRead less
Long noncoding RNAs and their regulatory roles in epigenetic control of gene expression in plants. Epigenetic control of gene expression plays a critical role in development, environmental adaptation, stress response and disease resistance in plants, but its molecular basis remains largely unknown. The proposed study should contribute to the emerging field of epigenetics by discovering new regulatory noncoding RNAs involved in epigenetic mechanisms in plants. These new discoveries could potentia ....Long noncoding RNAs and their regulatory roles in epigenetic control of gene expression in plants. Epigenetic control of gene expression plays a critical role in development, environmental adaptation, stress response and disease resistance in plants, but its molecular basis remains largely unknown. The proposed study should contribute to the emerging field of epigenetics by discovering new regulatory noncoding RNAs involved in epigenetic mechanisms in plants. These new discoveries could potentially provide new opportunities and platforms for improving the performance, yield and quality of crop plants. The proposed study is therefore consistent with the national research priority goals such as breakthrough science, frontier technologies and promoting an innovation culture.Read moreRead less
Dissecting the Indigo Pathway in Natural Indigo Producing Plants: Intricate Pathway Engineering for the Generation of Blue-Fibre Cotton. Australian cotton growers must maintain a sustained competitive advantage in the future to compete within the global cotton market by commanding higher margins for specialty cotton lint over and above current revenues. Development, via biotechnology, of naturally-colored, 'blue' lint cottons is the technical goal, where novel environmentally-benign textile prod ....Dissecting the Indigo Pathway in Natural Indigo Producing Plants: Intricate Pathway Engineering for the Generation of Blue-Fibre Cotton. Australian cotton growers must maintain a sustained competitive advantage in the future to compete within the global cotton market by commanding higher margins for specialty cotton lint over and above current revenues. Development, via biotechnology, of naturally-colored, 'blue' lint cottons is the technical goal, where novel environmentally-benign textile products could be produced without the use of toxic synthetic dyes or caustic dyeing processes. Success will provide a unique opportunity to re-establish an Australian cotton/textile industry by allowing direct participation in the development, branding and marketing of novel Australian textile products, generating potential revenue upwards of $10B/year. Read moreRead less
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.