Heat regulation by the fibre types in muscle. Mammals maintain a constant core body temperature by generating heat in resting muscles in response to changes in the environmental temperatures. This project aims to show how the fibre types that make up skeletal muscles regulate heat generation against other muscle function, to maintain core body temperature and the normal movement and posture of the mammal. Project outcomes include defining, for the first time, how heat generation in the muscles o ....Heat regulation by the fibre types in muscle. Mammals maintain a constant core body temperature by generating heat in resting muscles in response to changes in the environmental temperatures. This project aims to show how the fibre types that make up skeletal muscles regulate heat generation against other muscle function, to maintain core body temperature and the normal movement and posture of the mammal. Project outcomes include defining, for the first time, how heat generation in the muscles of the body is regulated. This should provide critical knowledge of mammalian evolution and ways to manipulate metabolism, which may provide ways to assist with achieving a desired meat quality and yield in beef and other commercially important animals.Read moreRead less
Regulated muscle-based thermogenesis for body temperature regulation. Mammals maintain a constant core body temperature by generating heat in resting muscles in response to changes in the environmental temperatures. This project aims to show how the skeletal muscles that are closer to the body core contribute the majority of heat, how the muscles of the limbs have their heat generation curtailed as necessary, and how this is coordinated by the body in response to ambient temperature. Project out ....Regulated muscle-based thermogenesis for body temperature regulation. Mammals maintain a constant core body temperature by generating heat in resting muscles in response to changes in the environmental temperatures. This project aims to show how the skeletal muscles that are closer to the body core contribute the majority of heat, how the muscles of the limbs have their heat generation curtailed as necessary, and how this is coordinated by the body in response to ambient temperature. Project outcomes include defining, for the first time, how heat generation in the muscles of the body is regulated. This should provide critical knowledge of mammalian evolution and ways to manipulate metabolism, which may provide ways to assist the production of meat by managing hypothermia and hyperthermia risk in agriculture.Read moreRead less
Interrogating the extremes of skeletal muscle plasticity in vertebrates. This project aims to interrogate how muscles adapt to growth and endurance stimuli at different stages of life, relevant to addressing challenges facing the world’s ageing population. Using innovative gene technologies and molecular physiology in zebrafish and mice, this project will answer important, unresolved questions in muscle biology. The project will generate knowledge needed to develop interventions to improve quali ....Interrogating the extremes of skeletal muscle plasticity in vertebrates. This project aims to interrogate how muscles adapt to growth and endurance stimuli at different stages of life, relevant to addressing challenges facing the world’s ageing population. Using innovative gene technologies and molecular physiology in zebrafish and mice, this project will answer important, unresolved questions in muscle biology. The project will generate knowledge needed to develop interventions to improve quality of life for older Australians and address the physical realities of an ageing workforce. Benefits extend to enhancing workplace safety and productivity, improving farming efficiencies for livestock and aquaculture industries, and training emerging leaders in the biological sciences.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
Australian Laureate Fellowships - Grant ID: FL170100086
Funder
Australian Research Council
Funding Amount
$2,924,858.00
Summary
Methane bioconversion to liquid chemicals. This project aims to develop a suite of leading-edge biotechnology solutions to enable the cost-effective production of liquid chemicals from biogas. This will create a much stronger economic driver for biogas production from organic wastes, by significantly increasing the value of biogas compared to its current use for power generation. With a multi-disciplinary approach, the project will substantially advance the fundamental science in the exciting an ....Methane bioconversion to liquid chemicals. This project aims to develop a suite of leading-edge biotechnology solutions to enable the cost-effective production of liquid chemicals from biogas. This will create a much stronger economic driver for biogas production from organic wastes, by significantly increasing the value of biogas compared to its current use for power generation. With a multi-disciplinary approach, the project will substantially advance the fundamental science in the exciting and highly valuable area of anaerobic microbial conversion of methane, the least understood process in the global carbon cycle. This transformational research has a strong potential to create a new biotechnology sector producing high-value chemicals from methane, and will propel Australia to the forefront of sustainable resources research.Read 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
Uncovering a novel energy-sensing mechanism in the brain. This project aims to investigate a novel regulator of energy homeostasis in the brain, a protein kinase called SIK3. Energy homeostasis is essential for life as it ensures an adequate supply of fuel to cells of the body. This project intends to generate new knowledge about molecular switches to regulate energy homeostasis by using innovative gene technologies and transgenic animal models. The expected outcomes include generating fundament ....Uncovering a novel energy-sensing mechanism in the brain. This project aims to investigate a novel regulator of energy homeostasis in the brain, a protein kinase called SIK3. Energy homeostasis is essential for life as it ensures an adequate supply of fuel to cells of the body. This project intends to generate new knowledge about molecular switches to regulate energy homeostasis by using innovative gene technologies and transgenic animal models. The expected outcomes include generating fundamental insights into how SIK3 in the hypothalamic neurons regulates energy homeostasis. Benefits include improving population health and wellbeing, informing the development of new bio-medical technologies, and expanding the capabilities of Australia’s next generation of researchers.
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Molecular networks underlying mitochondrial biogenesis in humans. Mitochondria are essential for life, and we propose a highly-innovative approach (employing multiple, cutting-edge ‘omic’ technologies and bioinformatics) to advance the fundamental understanding of how mitochondria respond and adapt to exercise in humans. The project outcomes should include significant new knowledge and advanced expertise that can be used by others to facilitate additional research outcomes. The project anticipa ....Molecular networks underlying mitochondrial biogenesis in humans. Mitochondria are essential for life, and we propose a highly-innovative approach (employing multiple, cutting-edge ‘omic’ technologies and bioinformatics) to advance the fundamental understanding of how mitochondria respond and adapt to exercise in humans. The project outcomes should include significant new knowledge and advanced expertise that can be used by others to facilitate additional research outcomes. The project anticipates the contribution of innovative tools for molecular biology research, benefiting therapeutic and biotechnology applications. This project will support advanced training of young researchers in frontier technologies, which will expand Australian research capabilities and help produce a higher quality workforce.Read moreRead less