Unlocking the secret chemistry of organosulfur biodegradation. The element sulfur is essential for life. Its transformation between organic-sulfur compounds to inorganic forms is a crucial part of the biogeochemical cycle. This project will elucidate the molecular details of the final leg of the biosulfur cycle: organosulfur breakdown into mineral form. An integrated chemical and biochemical approach will be used to illuminate how the carbon-sulfur bond is broken. This project will deliver a det ....Unlocking the secret chemistry of organosulfur biodegradation. The element sulfur is essential for life. Its transformation between organic-sulfur compounds to inorganic forms is a crucial part of the biogeochemical cycle. This project will elucidate the molecular details of the final leg of the biosulfur cycle: organosulfur breakdown into mineral form. An integrated chemical and biochemical approach will be used to illuminate how the carbon-sulfur bond is broken. This project will deliver a detailed molecular understanding of organosulfur breakdown to permit organosulfur recycling. Benefits of this research include potential biotechnology applications for breaking down xenobiotic organosulfonates and sustainable approaches to reduce dependence on agricultural fertilisers.Read moreRead less
How lipid binding proteins shape the activity of nuclear hormone receptors. This project aims to explore how a family of lipid binding proteins control organ specific activation of nuclear receptors – receptors that play a key role in generating energy and are critical for life. The project will employ chemical, molecular, cell biology approaches to generate new knowledge about lipid binding protein-receptor interactions and how these complexes dictate receptor activation. The outcomes could pro ....How lipid binding proteins shape the activity of nuclear hormone receptors. This project aims to explore how a family of lipid binding proteins control organ specific activation of nuclear receptors – receptors that play a key role in generating energy and are critical for life. The project will employ chemical, molecular, cell biology approaches to generate new knowledge about lipid binding protein-receptor interactions and how these complexes dictate receptor activation. The outcomes could provide a roadmap to design drugs that interact with the right protein in the right tissue and in doing so dramatically enhance drug specificity. This will benefit the success of drug treatments which require stimulation of a therapeutic response at a target site, and avoidance of potentially toxic activity at other locations.Read moreRead less