Discovery of new metabolic functions in Plasmodium parasites. This research will provide new understanding about the metabolism of parasites, such as those that cause malaria. These parasites have evolved bespoke metabolic networks to survive in diverse host environments including mosquitos and humans. Previous studies have revealed many unique genes and metabolites in these organisms, but their biochemical function is not known. This project will use state-of-the-art metabolomics and proteomics ....Discovery of new metabolic functions in Plasmodium parasites. This research will provide new understanding about the metabolism of parasites, such as those that cause malaria. These parasites have evolved bespoke metabolic networks to survive in diverse host environments including mosquitos and humans. Previous studies have revealed many unique genes and metabolites in these organisms, but their biochemical function is not known. This project will use state-of-the-art metabolomics and proteomics technology to accurately identify novel metabolites produced by the parasites, and discover the enzymes that are responsible for their synthesis. This work will not only advance our understanding of cellular metabolism, but will provide new opportunities for future biotechnology applications.Read moreRead less
Multi-functional probes for global analysis of proteome stress in cells. This project aims to create a suite of multi-functional chemical probes to identify damaged proteins that undergo unfolding or specific modifications in cells under stress. These probes will not only generate fluorescence responses to reflect on protein quality control capacity but allow associated proteins and their networks to be identified in complex cellular environments, which is difficult to achieve by current methods ....Multi-functional probes for global analysis of proteome stress in cells. This project aims to create a suite of multi-functional chemical probes to identify damaged proteins that undergo unfolding or specific modifications in cells under stress. These probes will not only generate fluorescence responses to reflect on protein quality control capacity but allow associated proteins and their networks to be identified in complex cellular environments, which is difficult to achieve by current methods. The expected outcome is to deliver new methodology for a comprehensive understanding of the correlation between quality control machinery, stress responses and cell functions. This should provide significant benefits, including contributing to fundamental knowledge on the molecular causes of neurodegenerative diseases.Read moreRead less