Navigating flux control through a branched metabolic pathway. This project aims to uncover control points and programmes in the mevalonate pathway, an important cellular metabolic pathway that produces cholesterol and isoprenoids. Knowledge of its regulation is largely restricted to just one enzyme (HMGCR). This project will determine how regulation of the later sterol-producing segment affects the early isoprenoid-segment of the mevalonate pathway; investigate how the two alternate routes to ch ....Navigating flux control through a branched metabolic pathway. This project aims to uncover control points and programmes in the mevalonate pathway, an important cellular metabolic pathway that produces cholesterol and isoprenoids. Knowledge of its regulation is largely restricted to just one enzyme (HMGCR). This project will determine how regulation of the later sterol-producing segment affects the early isoprenoid-segment of the mevalonate pathway; investigate how the two alternate routes to cholesterol synthesis operate and are regulated; and explore a co-ordinated and possibly co-operative transcriptional program. This project is expected to provide valuable knowledge of how cells control these critical lipids, which will ultimately inform better ways to treat diseases of cholesterol excess and defects in this pathway.Read moreRead less
Augmenting the activity of glyoxalase-1 to increase dicarbonyl clearance . Reactive intermediates generated during our metabolism contribute to ageing. Glyoxalase-1 is a key defence enzyme against these toxic intermediates and therefore ageing itself. This project aims to investigate novel pathways how the expression and activity of glyoxalase-1 are regulated. This interdisciplinary project expects to generate new understanding by combining relevant cell and animal models, protein chemistry, epi ....Augmenting the activity of glyoxalase-1 to increase dicarbonyl clearance . Reactive intermediates generated during our metabolism contribute to ageing. Glyoxalase-1 is a key defence enzyme against these toxic intermediates and therefore ageing itself. This project aims to investigate novel pathways how the expression and activity of glyoxalase-1 are regulated. This interdisciplinary project expects to generate new understanding by combining relevant cell and animal models, protein chemistry, epigenetics and structural biology. It is expected that this work will improve understanding of this fundamental biological defence. This will allow us to identify the potential means to enhance the capacity of glyoxalase-1 to the future benefit of biological ageing.Read moreRead less
Signaling in the crypt: a novel metabolic pathway in intestinal stem cells. The gut is the most rapidly renewing tissue in the body, driven by a highly active stem cell niche. Bile acids are emerging as critical regulators of this stem cell niche and disruption of bile acid homeostasis has profoundly adverse effects on intestinal renewal and hence gut health. We are addressing a critical gap in our understanding of how bile acids are controlled within stem cell niche. The aim of the project is ....Signaling in the crypt: a novel metabolic pathway in intestinal stem cells. The gut is the most rapidly renewing tissue in the body, driven by a highly active stem cell niche. Bile acids are emerging as critical regulators of this stem cell niche and disruption of bile acid homeostasis has profoundly adverse effects on intestinal renewal and hence gut health. We are addressing a critical gap in our understanding of how bile acids are controlled within stem cell niche. The aim of the project is to define the critical role of a novel enzyme called UGT8 in controlling intestinal stem cell response to bile acids; this is achieved by modulating UGT8 activity in intestinal stem cell models and determining the effects on stem cell function and the key signalling pathways that control intestinal homeostasis and renewal.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100259
Funder
Australian Research Council
Funding Amount
$467,964.00
Summary
Interrogating the adaptive potential of skeletal muscle. Disruptions to muscle oxidative capacity and growth signalling underpin atrophy and dysfunction with ageing, which impacts on an individual’s quality of life. These biological processes are thought to be mutually exclusive and compete during muscle adaptation. This project aims to define how these processes regulate the extent of muscle adaptation, and how modifying these attributes influence functional capacity in the context of ageing. T ....Interrogating the adaptive potential of skeletal muscle. Disruptions to muscle oxidative capacity and growth signalling underpin atrophy and dysfunction with ageing, which impacts on an individual’s quality of life. These biological processes are thought to be mutually exclusive and compete during muscle adaptation. This project aims to define how these processes regulate the extent of muscle adaptation, and how modifying these attributes influence functional capacity in the context of ageing. This project will provide fundamental new knowledge in understanding how modifying muscle attributes influence successful ageing. This knowledge will improve resilience, productivity, and wellbeing of all Australians, with implications for reducing societal and economic burden.Read moreRead less
How do cells survive nutrient stress? Insight into mechanisms. This project studies cell survival under nutrient stress in eukaryotes. Building on extensive preliminary data that identifies novel TOR (Target of Rapamycin) Complex 2 (TORC2) control points it expects to generate new knowledge of critical and conserved features of stress control of macroautophagy that ensures cell survival. It uses interdisciplinary and innovative approaches to validate and characterize nutrient-stress dependent si ....How do cells survive nutrient stress? Insight into mechanisms. This project studies cell survival under nutrient stress in eukaryotes. Building on extensive preliminary data that identifies novel TOR (Target of Rapamycin) Complex 2 (TORC2) control points it expects to generate new knowledge of critical and conserved features of stress control of macroautophagy that ensures cell survival. It uses interdisciplinary and innovative approaches to validate and characterize nutrient-stress dependent signaling. Expected outcomes include novel insights into environmental control of cell proliferation and forging cross institutional collaborations. This knowledge benefits basic and applied biology and is relevant to industries/projects utilizing living cells as nutrient supports cell survival and proliferation.Read moreRead less
Metabolite regulation of mitochondrial fission. This project aims to understand how the function and health of mitochondria – the energy producing structures in cells - are controlled by fat molecules. The project expects to integrate cutting edge techniques and instrumentation to generate new knowledge of how fat molecules interact with, and influence, enzymes that control how cells maintain their mitochondria in response to nutrient state. An anticipated goal is to define a fingerprint for enz ....Metabolite regulation of mitochondrial fission. This project aims to understand how the function and health of mitochondria – the energy producing structures in cells - are controlled by fat molecules. The project expects to integrate cutting edge techniques and instrumentation to generate new knowledge of how fat molecules interact with, and influence, enzymes that control how cells maintain their mitochondria in response to nutrient state. An anticipated goal is to define a fingerprint for enzymes regulated by fat molecules that will be of great interest to researchers across many branches of life sciences. Expected outcomes and benefits will be deeper understanding of fat molecules as nutrient signalling metabolites, and how they influence cell metabolism, growth and development.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
Unravelling a canonical mitochondrial stress response pathway. Stress has a major impact on all life forms and is considered one of the key determinants of healthy ageing. This project aims to unravel a highly novel pathway through which many different forms of stress converge to induce a conserved stress response in mammalian cells. Major outcomes include rewriting the textbook on how stress is sensed by cells and how cells respond to this stress and will provide novel approaches and technologi ....Unravelling a canonical mitochondrial stress response pathway. Stress has a major impact on all life forms and is considered one of the key determinants of healthy ageing. This project aims to unravel a highly novel pathway through which many different forms of stress converge to induce a conserved stress response in mammalian cells. Major outcomes include rewriting the textbook on how stress is sensed by cells and how cells respond to this stress and will provide novel approaches and technologies for studying stress in a broad range of organisms and systems. This project will benefit all efforts to understand stress and aid efforts by others to ameliorate stress-mediated health defects across the animal kingdomRead moreRead less
Uncovering New Mechanisms of Metabolite-Sensing and Signaling. This project aims to understand how cells sense changes in metabolic activity, to ensure energy demands are matched with nutrient supply. Our proposal will fill critical gaps in our understanding of the molecular mechanisms underlying metabolic sensing. This will generate new knowledge with far reaching potential for Australian industries that rely on the propagation and utilization of living organisms, including agriculture, biotech ....Uncovering New Mechanisms of Metabolite-Sensing and Signaling. This project aims to understand how cells sense changes in metabolic activity, to ensure energy demands are matched with nutrient supply. Our proposal will fill critical gaps in our understanding of the molecular mechanisms underlying metabolic sensing. This will generate new knowledge with far reaching potential for Australian industries that rely on the propagation and utilization of living organisms, including agriculture, biotechnology and brewing, as well as knowledge relevant to sporting performance and the metabolic dimensions of ageing. This project will support advanced training of early career researchers and PhD students, which will expand Australian research capabilities and contribute to a producing a highly skilled workforce.Read moreRead less
Characterization of the dark metabolome of eukaryotic cells. The project aims to investigate the full metabolic potential of a group of eukaryotic organisms using advanced analytical and computational techniques. It will identify novel metabolites and enzyme activities that are currently not predicted from genome annotations. Expected outcomes of the project include the delineation of new metabolic processes that are common to all eukaryotes, the characterization of new enzymes families, and the ....Characterization of the dark metabolome of eukaryotic cells. The project aims to investigate the full metabolic potential of a group of eukaryotic organisms using advanced analytical and computational techniques. It will identify novel metabolites and enzyme activities that are currently not predicted from genome annotations. Expected outcomes of the project include the delineation of new metabolic processes that are common to all eukaryotes, the characterization of new enzymes families, and the generation of comprehensive metabolic databases. An improved understanding of cellular metabolism will provide direct benefits in biotechnology, food production, environmental monitoring and the diagnosis and treatment of human metabolic and infectious diseases. Read moreRead less