The regulation of skeletal muscle mass. This project aims to delineate a pathway involved in regulating skeletal muscle mass, and examine whether disrupting mitochondrial phospholipid synthesis affects mitochondrial structure and function, causing muscle wasting. Defining a new atrophy pathway will advance understanding of the mechanisms that control muscle mass. This project could have important economic and quality of life benefits, especially for agriculture, where achieving optimal muscle ma ....The regulation of skeletal muscle mass. This project aims to delineate a pathway involved in regulating skeletal muscle mass, and examine whether disrupting mitochondrial phospholipid synthesis affects mitochondrial structure and function, causing muscle wasting. Defining a new atrophy pathway will advance understanding of the mechanisms that control muscle mass. This project could have important economic and quality of life benefits, especially for agriculture, where achieving optimal muscle mass ensures international competitiveness, productivity and economic growth, and successful ageing, where maintaining muscle mass is essential.Read moreRead less
Investigation of the biochemical and physiological functions of the negative regulator of cytokine signalling SOCS-2. Cytokines exert their effects by binding and signalling through specific cell surface receptors to elicit their biological action, and if left unchecked, this signalling can cause significant tissue damage and toxicity. Our aim is to characterise a novel regulator of cytokine signalling, SOCS-2. SOCS-2 is strongly implicated in the regulation of post-natal growth as SOCS-2 defici ....Investigation of the biochemical and physiological functions of the negative regulator of cytokine signalling SOCS-2. Cytokines exert their effects by binding and signalling through specific cell surface receptors to elicit their biological action, and if left unchecked, this signalling can cause significant tissue damage and toxicity. Our aim is to characterise a novel regulator of cytokine signalling, SOCS-2. SOCS-2 is strongly implicated in the regulation of post-natal growth as SOCS-2 deficient animals are 40 percent larger than normal. Consequently, we wish to determine how SOCS-2 acts to limit the size of an animal and whether this involves regulation of growth hormone action.Read moreRead less
Molecular control of embryonic diapause. Many species can halt growth of the early embryo (diapause). This project will use novel animal models and new proteomics techniques to clarify what signals from the uterus control diapause of the embryo. This may uncover new mechanisms for cell regulation that will be relevant to the biology of stem cells, cancer and reproductive technologies.
Discovery Early Career Researcher Award - Grant ID: DE180100859
Funder
Australian Research Council
Funding Amount
$365,058.00
Summary
Phosphatidylserine: a regulator of muscle and mitochondrial biology? This project aims to characterise a novel pathway involved in regulating skeletal muscle mass through effects on mitochondrial function. This project will examine how degradation causes mitochondrial abnormalities leading to severe muscle wasting. This project is expected to advance understanding of how pathways interact, thus identifying novel mechanisms that impact on muscle structure and function. Understanding what makes mu ....Phosphatidylserine: a regulator of muscle and mitochondrial biology? This project aims to characterise a novel pathway involved in regulating skeletal muscle mass through effects on mitochondrial function. This project will examine how degradation causes mitochondrial abnormalities leading to severe muscle wasting. This project is expected to advance understanding of how pathways interact, thus identifying novel mechanisms that impact on muscle structure and function. Understanding what makes muscle vulnerable to atrophy is fundamental to developing strategies to counteract muscle wasting conditions. Methodologies developed will have broad application in the field of life sciences research.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
Role of suppressor of cytokine signalling proteins (SOCS3) in defective muscle repair and ageing. Old muscles are slower and weaker than young muscles, they are injured more easily and they repair less successfully. This proposal investigates the role of SOCS3-signalling in muscle repair, ultimately to improve healing and to promote healthy ageing that will enable older Australians to enjoy a better quality of life.
Neurons isolated from embryonic stem cells as functional models for drug discovery. By using gene expression-based selection criteria embryonic stem cells can be driven to differentiate into specific neuronal lineages which show many of the morphological characteristics and immunocytochemical features of neurons in culture. There is, however, comparatively little evidence indicating that these stem cell-derived neurons actually behave as neurons. Our aim is to characterise and contrast four ne ....Neurons isolated from embryonic stem cells as functional models for drug discovery. By using gene expression-based selection criteria embryonic stem cells can be driven to differentiate into specific neuronal lineages which show many of the morphological characteristics and immunocytochemical features of neurons in culture. There is, however, comparatively little evidence indicating that these stem cell-derived neurons actually behave as neurons. Our aim is to characterise and contrast four neuronal cell cultures established with gene-based selection criteria. These cultures will be characterised by gene expression, immunocytochemistry, radiolabelled neurotransmitter release, electrophysiology and Ca2+ imaging studies. This study will highlight the functional effects of gene selection procedures upon stem cell-derived neurons.Read moreRead less
Cytopathological roles of AMPK in mitochondrial dysfunction. This research project will benefit the Australian community by deepening our understanding of mitochondrial and neurodegenerative diseases. These diseases are incurable and treatment options are limited. The knowledge gained in this project should assist in the development of new or improved treatments. The project will also contribute to the training of young scientists in biomedical research and will enhance Australia's international ....Cytopathological roles of AMPK in mitochondrial dysfunction. This research project will benefit the Australian community by deepening our understanding of mitochondrial and neurodegenerative diseases. These diseases are incurable and treatment options are limited. The knowledge gained in this project should assist in the development of new or improved treatments. The project will also contribute to the training of young scientists in biomedical research and will enhance Australia's international scientific reputation because it involves a significant and novel biomedical discovery.
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Metabolic Profiling of Human Embryonic Stem Cells. Stem cell therapies are becoming a commercial reality. Stem cell products have an estimated value of US$ 87 million this year and are predicted to be worth US$ 8.5 billion within a decade. Development of stem cell products will be an international research effort with many contributing to the final products. Research described here will augment this effort, strengthening Australia's contribution by developing novel intellectual property and appl ....Metabolic Profiling of Human Embryonic Stem Cells. Stem cell therapies are becoming a commercial reality. Stem cell products have an estimated value of US$ 87 million this year and are predicted to be worth US$ 8.5 billion within a decade. Development of stem cell products will be an international research effort with many contributing to the final products. Research described here will augment this effort, strengthening Australia's contribution by developing novel intellectual property and applications. The training of individuals skilled in stem cell research will add to Australia's pool of stem cell researchers. Individuals trained in this area will be paramount to maintaining Australia's research effort and in the application of these technologies into the Australian health sector.Read moreRead less
Mapping and defining inter-organ cross talk during exercise. This project aims to examine precisely how organs communicate and interact. These interactions are particularly important during exercise, when continued movement demands intricate organ communication, and have major ramifications for the whole organism as it ages. Precisely how this communication takes place is unclear, but we now know that the movement of cargo with extracellular vesicles (EVs) plays an integral role in organ to orga ....Mapping and defining inter-organ cross talk during exercise. This project aims to examine precisely how organs communicate and interact. These interactions are particularly important during exercise, when continued movement demands intricate organ communication, and have major ramifications for the whole organism as it ages. Precisely how this communication takes place is unclear, but we now know that the movement of cargo with extracellular vesicles (EVs) plays an integral role in organ to organ communication. This project expects to build upon unprecedented recent developments we have made in the biology of inter-organ communication via EVs. The expected outcomes will have broad impact across life science and biotechnology.Read moreRead less