The role of copper in the early ubiquitination pathway. This project aims to explore the role of copper in ageing and protein turnover. The removal of damaged or excess proteins is achieved by ubiquitin-tagging in all kingdoms of life. It has recently been observed that one of the earliest steps of this process appears to be driven by copper. This project aims to elaborate the precise biochemical mechanisms by which copper regulates this important tagging and protein turnover system. It proposes ....The role of copper in the early ubiquitination pathway. This project aims to explore the role of copper in ageing and protein turnover. The removal of damaged or excess proteins is achieved by ubiquitin-tagging in all kingdoms of life. It has recently been observed that one of the earliest steps of this process appears to be driven by copper. This project aims to elaborate the precise biochemical mechanisms by which copper regulates this important tagging and protein turnover system. It proposes to characterise the structure and function of a newly identified copper-dependent form of cell enzyme which could be involved in amplifying ubiquitin-tagged protein breakdown. Copper is essential for life in all domains. Identifying copper as a major regulator in protein clearance is important in understanding this fundamental biological machinery.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130101168
Funder
Australian Research Council
Funding Amount
$364,900.00
Summary
Enhancement of light-driven electricity generation by cyanobacteria: en route to biosolar panels. Some species of naturally occurring cyanobacteria (blue-green algae) exhibit a special metabolic feature, which enables them to convert sunlight into electricity. This project will unveil the chemical and biological secrets behind this process and will lead to the creation of the first entirely biological solar panel.
Deciphering new regulators of lipid metabolism: a focus on lipid droplets . Lipid droplets store lipids in cells and the mitochondria break down this lipid to generate energy. Both organelles are critical for energy metabolism and cell survival. This project aims to determine the proteins that regulate the interaction between mitochondria and lipid droplets, and how these proteins regulate metabolism. It is anticipated that this project will identify the essential components of lipid droplet-mit ....Deciphering new regulators of lipid metabolism: a focus on lipid droplets . Lipid droplets store lipids in cells and the mitochondria break down this lipid to generate energy. Both organelles are critical for energy metabolism and cell survival. This project aims to determine the proteins that regulate the interaction between mitochondria and lipid droplets, and how these proteins regulate metabolism. It is anticipated that this project will identify the essential components of lipid droplet-mitochondria interactions and their impact on regulating cellular lipid metabolism. The intended outcome of this project is to provide fundamental new knowledge in understanding how organelles interact and how lipid metabolism is regulated. This knowledge has applications for the primary industries and biotechnology sector.Read moreRead less
Characterising the lipid droplet-mitochondria proteome. This project aims to determine the mechanisms by which the mitochondria and lipid droplets associate, and how this interaction influences lipid metabolism. Both critical for survival, lipid droplets are the bulk energy store in cells and the mitochondria break down this lipid to generate energy. It is anticipated that this project will identify the proteins that are critical for regulating contact between these organelles and the consequenc ....Characterising the lipid droplet-mitochondria proteome. This project aims to determine the mechanisms by which the mitochondria and lipid droplets associate, and how this interaction influences lipid metabolism. Both critical for survival, lipid droplets are the bulk energy store in cells and the mitochondria break down this lipid to generate energy. It is anticipated that this project will identify the proteins that are critical for regulating contact between these organelles and the consequences if this process becomes dysregulated. The project expects to provide fundamental new knowledge in understanding how organelles interact and how lipid metabolism is regulated. This knowledge has applications for the primary industries and biotechnology sector.Read moreRead less
The combined use of proteomics and small molecules for target identification and pathway analysis. This project intends to investigate how a series of new small molecules identified from our research to improve the metabolic effects of insulin. This project will integrate medicinal chemistry with proteomics and metabolic biology to identify the cellular targets and their mechanism of action.