Chemical and Biochemical Characterisation of Novel Iron Chelators with Therapeutic Potential. Iron is essential for life, but iron-overload is a potentially fatal condition. There is no natural mechanism to excrete iron in humans, so patients suffering from iron-overload disorders are treated with the chelator Desferal to enable iron excretion typically from an early age. Desferal is orally ineffective and must be given by subcutaneous infusion (12-24h, 5-6 days/week) resulting in poor patient c ....Chemical and Biochemical Characterisation of Novel Iron Chelators with Therapeutic Potential. Iron is essential for life, but iron-overload is a potentially fatal condition. There is no natural mechanism to excrete iron in humans, so patients suffering from iron-overload disorders are treated with the chelator Desferal to enable iron excretion typically from an early age. Desferal is orally ineffective and must be given by subcutaneous infusion (12-24h, 5-6 days/week) resulting in poor patient compliance. We will conduct critical chemical and biological experiments with a new series of potentially orally active iron chelators identified in our lab. The results from this project will be vital for the development of these compounds as pharmaceuticals.Read moreRead less
Cellular Responses to Adversity: Oxidative Stress and Protection Against Oxidative Damage. A deficiency in the protein haem oxygenase-1 causes severe biological consequences in animals and humans. These include decreased reproduction, retarded development, the inability of the body to handle iron, chronic inflammation and increased susceptibility to age-associated diseases. This study will determine how a deficiency of the protein alters cells at the level of genes, proteins and protein function ....Cellular Responses to Adversity: Oxidative Stress and Protection Against Oxidative Damage. A deficiency in the protein haem oxygenase-1 causes severe biological consequences in animals and humans. These include decreased reproduction, retarded development, the inability of the body to handle iron, chronic inflammation and increased susceptibility to age-associated diseases. This study will determine how a deficiency of the protein alters cells at the level of genes, proteins and protein functions. By doing so, the project will illuminate how haem oxygenase-1 alters cell functions in a beneficial way. This information will eventually assist in preventing the serious disorders associated with deficiency of haem oxygenase-1. It will also provide the basis for novel treatments to slow down age-associated diseases.Read moreRead less
Coordinating energy metabolism to enhance exercise capacity. Diet and exercise contribute to health and ageing productively whereas high caloric diets and sedentary life styles are deleterious. The enzyme AMPK regulates energy metabolism in response to diet and exercise and by studying it we expect to learn why diet and exercise are beneficial at the molecular level. This may allow the development of nutritional, exercise and drug strategies to enhance exercise capacity and well being during ....Coordinating energy metabolism to enhance exercise capacity. Diet and exercise contribute to health and ageing productively whereas high caloric diets and sedentary life styles are deleterious. The enzyme AMPK regulates energy metabolism in response to diet and exercise and by studying it we expect to learn why diet and exercise are beneficial at the molecular level. This may allow the development of nutritional, exercise and drug strategies to enhance exercise capacity and well being during ageing as well as suppress age onset diseases that include obesity diabetes cardiovascular disease hypertension and neurodegeneration.Read moreRead less
Systems therapeutics for metabolism: AMPK isoform specific drugs. Living cells have to maintain a steady balance between energy production and consumption in order to function properly. A key regulator of energy balance is an enzyme known as 5' AMP-activated protein kinase (AMPK), which regulates the burning and storage of fuels such as fat and sugars, in response to changes in energy demand. This project will provide a major advancement in our understanding of the regulation of AMPK at the mo ....Systems therapeutics for metabolism: AMPK isoform specific drugs. Living cells have to maintain a steady balance between energy production and consumption in order to function properly. A key regulator of energy balance is an enzyme known as 5' AMP-activated protein kinase (AMPK), which regulates the burning and storage of fuels such as fat and sugars, in response to changes in energy demand. This project will provide a major advancement in our understanding of the regulation of AMPK at the molecular level, and lay the foundations for the development of more effective drugs to treat energy balance disorders such as obesity and Type 2 diabetes. Furthermore, this proposal will contribute to enriching Australia's international profile and competitiveness in this important area of research.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.
Adaptive reprogramming of metabolism in regeneration. . Biologists have long been intrigued at the phenomenon of organ regeneration. Unlike most human organs, the liver exhibits the remarkable capacity to regenerate. Despite decades of research, the molecular underpinnings of liver regeneration are poorly understood. This research proposal aims to use zebrafish to elucidate the pathways involved in sensing injury and activating an adaptive transcriptional and metabolic response to orchestrate re ....Adaptive reprogramming of metabolism in regeneration. . Biologists have long been intrigued at the phenomenon of organ regeneration. Unlike most human organs, the liver exhibits the remarkable capacity to regenerate. Despite decades of research, the molecular underpinnings of liver regeneration are poorly understood. This research proposal aims to use zebrafish to elucidate the pathways involved in sensing injury and activating an adaptive transcriptional and metabolic response to orchestrate regeneration. Ultimately, this works aims to understand the metabolic requirements for regeneration. Expected outcomes include scholarly publications revealing fundamental principles of regeneration, new resources and pipelines for the research community as well as training for research students.Read moreRead less