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Mastering pyrimidine editing in RNA. Many plants and animals can alter their genetic information via RNA (ribonucleic acid) editing, a process that is often essential for the growth and development of the organism. This ability provides accurate control over gene expression and has great potential as a biotechnological tool in agriculture and medicine. RNA editing could be used to switch genes on or off in biotechnological production systems with an unprecedented degree of precision, or to corre ....Mastering pyrimidine editing in RNA. Many plants and animals can alter their genetic information via RNA (ribonucleic acid) editing, a process that is often essential for the growth and development of the organism. This ability provides accurate control over gene expression and has great potential as a biotechnological tool in agriculture and medicine. RNA editing could be used to switch genes on or off in biotechnological production systems with an unprecedented degree of precision, or to correct genetic diseases. This project aims to understand two RNA editing pathways in plants, one of which is found nowhere else and likely to involve a novel enzymatic mechanism. We will use the understanding gained to develop novel RNA processing tools usable in any living organism.Read moreRead less
IDENTIFYING CONTROL ELEMENTS IN CHLOROPLAST GENE EXPRESSION. Energy from sunlight is captured by photosynthesis in plants, providing the basis for the terrestrial food chain. This process takes place in chloroplasts, subcellular structures that derived from photosynthetic bacteria a billion years ago. Chloroplasts have their own DNA, containing genes encoding the most important photosynthetic proteins. This project aims to provide the world’s best resources for the study of chloroplast genes. In ....IDENTIFYING CONTROL ELEMENTS IN CHLOROPLAST GENE EXPRESSION. Energy from sunlight is captured by photosynthesis in plants, providing the basis for the terrestrial food chain. This process takes place in chloroplasts, subcellular structures that derived from photosynthetic bacteria a billion years ago. Chloroplasts have their own DNA, containing genes encoding the most important photosynthetic proteins. This project aims to provide the world’s best resources for the study of chloroplast genes. In the process, we will discover how these important genes are regulated to provide photosynthetic proteins in the right amounts, in the right cells, at the right time. The knowledge and resources gained will facilitate improvement of photosynthetic function in future agricultural crops.Read moreRead less
A portable RNA-editing machine. Many plants maintain an elaborate RNA-editing machine that allows them to correct accumulated errors in their organellar genomes by specifically editing the RNA transcripts of the affected genes. A portable and adaptable version of this molecular machine would have significant biotechnological value, providing the ability to correct genetic errors, and to intervene in gene regulation without permanently altering a genome. The project aims to combine molecular and ....A portable RNA-editing machine. Many plants maintain an elaborate RNA-editing machine that allows them to correct accumulated errors in their organellar genomes by specifically editing the RNA transcripts of the affected genes. A portable and adaptable version of this molecular machine would have significant biotechnological value, providing the ability to correct genetic errors, and to intervene in gene regulation without permanently altering a genome. The project aims to combine molecular and structural biology approaches to fully characterise the components of the machine, thus allowing us to reconstitute it in cell-free systems and ultimately in other organisms.Read moreRead less
Deciphering a protein code for recognising Ribonucleic acid (RNA) targets. This project will decipher the protein code employed by a large family of plant proteins for the specific recognition of RNA sequences. This knowledge will be immediately helpful for designing a new generation of biotechnological tools for the agricultural and biomedical sciences.
Australian Laureate Fellowships - Grant ID: FL140100179
Funder
Australian Research Council
Funding Amount
$2,800,000.00
Summary
Controlling gene expression with synthetic RNA-binding proteins. Controlling gene expression with synthetic RNA-binding proteins. The growth and development of living organisms is largely determined by the genes they contain, but converting the genetic information into biological activity requires intermediary processes involving RNA and proteins that bind to and process RNA. This project aims to understand how the largest class of RNA-binding protein in plants recognise their target RNAs and ai ....Controlling gene expression with synthetic RNA-binding proteins. Controlling gene expression with synthetic RNA-binding proteins. The growth and development of living organisms is largely determined by the genes they contain, but converting the genetic information into biological activity requires intermediary processes involving RNA and proteins that bind to and process RNA. This project aims to understand how the largest class of RNA-binding protein in plants recognise their target RNAs and aims to develop custom-designed proteins for switching genes on or off. This technology will be used to create new hybrid cereal varieties and will also be valuable for applications in human health, such as the correction of genetic mutations.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140101096
Funder
Australian Research Council
Funding Amount
$395,220.00
Summary
Evolutionary Adaptation of the Chemical Language of Nutrient Acquisition Strategies in Higher Plants. The autotrophic and sessile nature of plants means that they need to respond to nutrient limitations in a finely tuned manner to grow and survive. Metabolites play an important role during these adaptations, either as direct modulators or as biochemical indicators of the pathways activated. Plants have evolved from relatively simple unicellular organisms that have a remarkable adaptability to re ....Evolutionary Adaptation of the Chemical Language of Nutrient Acquisition Strategies in Higher Plants. The autotrophic and sessile nature of plants means that they need to respond to nutrient limitations in a finely tuned manner to grow and survive. Metabolites play an important role during these adaptations, either as direct modulators or as biochemical indicators of the pathways activated. Plants have evolved from relatively simple unicellular organisms that have a remarkable adaptability to respond to their environment through metabolite-modulated quorum-sensing mechanisms. Preliminary evidence suggests that plants have either retained some of this ability or have evolved novel nutrient recognition strategies. This project will elucidate these pathways to gain new insights into nutrient acquisition in plants.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120101117
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Understanding the molecular machines making proteins essential for life: investigating specialisation of plastid ribosome composition and function. Plastid ribosomes are complex molecular machines responsible for the production of proteins required for photosynthesis, a process which underlies global food and oxygen production. By determining if distinct plastid types have ribosomes that differ in both composition and function, the project could benefit biotechnological applications.
Regulation and role of metabolic networks for respiration in plants. This project aims to understand the regulation of respiration in plants which underpins the energy provision that cells need to operate. Understanding respiration and how it responds to the changing environment is a building block needed for rational engineering of our future food from plants.
A new and rapidly evolving class of plant peptides. The project will study a diverse class of drug-like mini-proteins that are thought to have emerged genetically over 12 million years ago. This project will explore why plants have kept making these mini-proteins for so long and whether it is the same reason the founding member of this mini-protein class is such a good drug.
A novel DNA motif involved in plant mitochondrial stress responses. The future of Australia's agriculture is threatened by limited water resources, temperature extremes and soil salinity. This project aims to unravel how plants are able to adapt to this continuously changing environment, by focusing on the role of mitochondria - cellular compartments essential for energy metabolism and plant stress responses.