Photosynthesis under extreme conditions. The aim of this project is to characterise modifications to the light dependent reactions of photosynthesis of simple, single cell organisms that live under harsh environmental conditions including: i) elevated temperature; ii) low, variable and low energy (red) light; iii) arid and variable hydration; and iv) chemical stress e.g. low pH. In a changing biosphere brought about by anthropological climate change, a better understanding of existing adaptions ....Photosynthesis under extreme conditions. The aim of this project is to characterise modifications to the light dependent reactions of photosynthesis of simple, single cell organisms that live under harsh environmental conditions including: i) elevated temperature; ii) low, variable and low energy (red) light; iii) arid and variable hydration; and iv) chemical stress e.g. low pH. In a changing biosphere brought about by anthropological climate change, a better understanding of existing adaptions of bacterial photosynthetic organisms may allow more resilient crops and other essential plants to be developed in the future. The project brings together an international consortium of world renowned experts across key aspects of photosynthesis. Read moreRead less
Methods for Protein Structure Analysis by Electron Paramagnetic Resonance. This highly interdisciplinary project aims to establish new tools to analyse the structure and motions of proteins that are otherwise difficult to study. A combination of advanced biochemistry, modern magnetic spectroscopy methods, and high-performance computing techniques will be applied to study proteins at physiological concentrations and in complex environments. New techniques will be developed and tested on proteins ....Methods for Protein Structure Analysis by Electron Paramagnetic Resonance. This highly interdisciplinary project aims to establish new tools to analyse the structure and motions of proteins that are otherwise difficult to study. A combination of advanced biochemistry, modern magnetic spectroscopy methods, and high-performance computing techniques will be applied to study proteins at physiological concentrations and in complex environments. New techniques will be developed and tested on proteins of high biochemical or biomedical importance, and the approach will be applied to established drug targets.Read moreRead less
Molecular mechanisms of mechanosensation and shape regulation in cells. This project aims to explore how cells physically sense and respond to the surrounding environment on a molecular level. Physical distortion of erythrocytes doubles their glucose consumption and increases cation membrane flux five-fold. This mechanism involves opening of the mechanosenstive ion channel Piezo1. This project will include a kinetic description of these phenomena, with a goal to establish a predictive mathematic ....Molecular mechanisms of mechanosensation and shape regulation in cells. This project aims to explore how cells physically sense and respond to the surrounding environment on a molecular level. Physical distortion of erythrocytes doubles their glucose consumption and increases cation membrane flux five-fold. This mechanism involves opening of the mechanosenstive ion channel Piezo1. This project will include a kinetic description of these phenomena, with a goal to establish a predictive mathematical model of the regulation of cell-shape and volume. The project will provide an understanding of mechanisms operating when cells and tissues are succumbing to trauma and invasion, and how to control these processes on a molecular level.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100065
Funder
Australian Research Council
Funding Amount
$423,808.00
Summary
Designing Organocatalysts to Achieve Hyperpolarised Magnetic Resonance. Magnetic resonance techniques (such as MRI scans) suffer from an inherent insensitivity problem. In medical imaging, this can hamper diagnosis and mean long scan times for patients. This project aims to chemically develop catalysts which dramatically increase sensitivity, producing a signal that is thousands of times more visible. This project is significant as these catalysts can turn common, harmless molecules in the body ....Designing Organocatalysts to Achieve Hyperpolarised Magnetic Resonance. Magnetic resonance techniques (such as MRI scans) suffer from an inherent insensitivity problem. In medical imaging, this can hamper diagnosis and mean long scan times for patients. This project aims to chemically develop catalysts which dramatically increase sensitivity, producing a signal that is thousands of times more visible. This project is significant as these catalysts can turn common, harmless molecules in the body - even water - into visible tracers. The expected outcomes of this project include the synthesis and understanding of these catalysts which will be chemically fine-tuned to maximise their effectiveness. Potential benefits include translation to MRI applications to improve diagnosis and treatment, or chemical monitoring.Read moreRead less