Discovering the activity of novel CLE peptide hormones that regulate legume nodulation. This project aims to functionally characterise novel peptide hormones that regulate the number of nitrogen-fixing root nodules that legumes form. Findings will enhance the current nodulation model and could help to alleviate our reliance on expensive, often polluting, nitrogen-fertilisers by helping to optimise the nodulation process in agriculture.
Discovery of the systemic regulator of legume nodulation. This project aims to discover the novel, shoot-derived factor that legumes produce to regulate the number of nitrogen-fixing root nodules they form. Outcomes will enhance the current nodulation model and could help optimise the process in agriculture, which would help alleviate current reliance on nitrogen-fertilisers that are expensive and pollute.
Monolayer crystallization of membrane proteins. Membrane proteins comprise 25-40% of all proteins and conduct a myriad of finely tuned reactions in every cell. Despite their importance and diversity only ~40 membrane protein structures have been solved, due to the difficulty of producing high quality 2D and 3D crystals. We propose to develop and use the new monolayer crystallization technique, which employs a lipid monolayer as a crystallization template for 2D crystal production. A number of ....Monolayer crystallization of membrane proteins. Membrane proteins comprise 25-40% of all proteins and conduct a myriad of finely tuned reactions in every cell. Despite their importance and diversity only ~40 membrane protein structures have been solved, due to the difficulty of producing high quality 2D and 3D crystals. We propose to develop and use the new monolayer crystallization technique, which employs a lipid monolayer as a crystallization template for 2D crystal production. A number of important membrane proteins are available for these structural studies including ABC transporters, Caveolin-3 and the NS1 protein of Dengue virus, all of which are difficult to crystallize using conventional techniques.Read moreRead less
Control of selective microRNA release via exosomes and microvesicles. This project aims to improve our understanding of cell-to-cell communication. Cells release genetic material including microRNAs in lipid membrane-enclosed vesicles (called exosomes and microvesicles) to alter neighbouring and distant cells. Recent research shows that the contents of these vesicles are regulated by cell state, however, the molecular mechanisms are not yet known. This project will investigate the hypothesis tha ....Control of selective microRNA release via exosomes and microvesicles. This project aims to improve our understanding of cell-to-cell communication. Cells release genetic material including microRNAs in lipid membrane-enclosed vesicles (called exosomes and microvesicles) to alter neighbouring and distant cells. Recent research shows that the contents of these vesicles are regulated by cell state, however, the molecular mechanisms are not yet known. This project will investigate the hypothesis that changes in the RNA-binding protein composition of cholesterol-rich membranes mediate the selection of miRNA loaded in the vesicles. This knowledge may increase our understanding of mechanisms of disease because this mode of cell-to-cell communication is disrupted or hijacked in pathologies. Future translation in diverse applications may improve human, animal and plant health.Read moreRead less
Membrane proteins in innate immunity. The application of smarter and faster methods for understanding membrane proteins, targets of most drugs, is vital to a knowledge-based economy and a healthy society. The long-term benefits will include fundamental new knowledge on immunity, and implementation of new approaches that streamline costs and efforts of challenging, high-impact research.
Structure and function of human zinc transporter membrane proteins. The aim of this project is to create fundamental new knowledge on how important mammalian membrane proteins operate. Membrane proteins are key drug targets and are significantly under-represented in structural databases. The project plans to combine innovative membrane protein screening technology with gene expression, structural biology, biophysics and cell biology. The project outcomes may elucidate specific molecular mechanis ....Structure and function of human zinc transporter membrane proteins. The aim of this project is to create fundamental new knowledge on how important mammalian membrane proteins operate. Membrane proteins are key drug targets and are significantly under-represented in structural databases. The project plans to combine innovative membrane protein screening technology with gene expression, structural biology, biophysics and cell biology. The project outcomes may elucidate specific molecular mechanisms underpinning the essential biological process of zinc homeostasis.Read moreRead less
Towards high efficiency biofuel systems: a molecular resolution three-dimensional atlas of the photosynthetic machinery of a high-efficiency green algae cell. Solar-powered single-cell green-algae systems represent a powerful and environmentally friendly biotechnology used to produce clean fuels, food and high value products. This project is focused on solving the three-dimensional structure of key components of the photosynthetic machinery to improve the efficiency and profitability of advance ....Towards high efficiency biofuel systems: a molecular resolution three-dimensional atlas of the photosynthetic machinery of a high-efficiency green algae cell. Solar-powered single-cell green-algae systems represent a powerful and environmentally friendly biotechnology used to produce clean fuels, food and high value products. This project is focused on solving the three-dimensional structure of key components of the photosynthetic machinery to improve the efficiency and profitability of advance microalgae production systems.Read moreRead less
Bioengineering High Efficiency Solar Driven H2 Production. The project aims to bio-engineer high-efficiency microalgae cell-lines that can drive solar powered H2 production from water. It plans to do so by increasing proton and electron supply to the H2-producing hydrogenase. It builds on patented cell lines that have enhanced light capture efficiency and H2 production capabilities. The aim of this project is to increase the efficiency of the last stage of the process (three fold) in a major ste ....Bioengineering High Efficiency Solar Driven H2 Production. The project aims to bio-engineer high-efficiency microalgae cell-lines that can drive solar powered H2 production from water. It plans to do so by increasing proton and electron supply to the H2-producing hydrogenase. It builds on patented cell lines that have enhanced light capture efficiency and H2 production capabilities. The aim of this project is to increase the efficiency of the last stage of the process (three fold) in a major step in developing economic solar-fuel systems. National benefits include the development of advanced microalgae fuels systems to increase future fuel security, reduce CO2 emissions and assist with regional development.Read moreRead less
Novel approaches for structural and functional analysis of the protein complex COG, a tether that controls intra-Golgi trafficking. Production and engineering of proteins are key methodologies of the life sciences in general and biotechnology in particular. Our ability to produce and analyse protein-based components of the cell determines the expense and speed of discovery, as well as the creation of new vaccines, drugs, and diagnostic methods. The current project aims to develop new approaches ....Novel approaches for structural and functional analysis of the protein complex COG, a tether that controls intra-Golgi trafficking. Production and engineering of proteins are key methodologies of the life sciences in general and biotechnology in particular. Our ability to produce and analyse protein-based components of the cell determines the expense and speed of discovery, as well as the creation of new vaccines, drugs, and diagnostic methods. The current project aims to develop new approaches for protein production and to apply them to the analysis of the basic mechanisms of cell self-maintenance.Read moreRead less
NmlR-dependent thiol-based redox systems and their role in global stress responses in bacteria. All cells sense changes to their environment and respond by altering their metabolism. A major environmental change is oxidative stress which damages cells. Cells have the ability to sense oxidative stress and alter metabolic processes to defend against the damage that it elicits. This proposal will characterize a novel oxidative stress defense system that is found in a number of bacterial pathogens t ....NmlR-dependent thiol-based redox systems and their role in global stress responses in bacteria. All cells sense changes to their environment and respond by altering their metabolism. A major environmental change is oxidative stress which damages cells. Cells have the ability to sense oxidative stress and alter metabolic processes to defend against the damage that it elicits. This proposal will characterize a novel oxidative stress defense system that is found in a number of bacterial pathogens that need to defend themselves against attack by the host. The project may identify new ways to manage these bacterial pathogens. It may also provide an insight into oxidative stress defense processes that are linked to pathologies in humans.Read moreRead less