Oxidative Damage and Cell Ageing. This research will benefit Australia by providing a fundamental understanding of how cells age. This will have immediate international impact at the scientific level and will inform strategies to reduce the rate of ageing and alleviation of age-related disorders. In the longer term the research may provide commercial and social outcomes by identifying antioxidant systems that will provide a genuine benefit in reducing ageing.
Cellular Responses to Oxidative Damage: Cell Aging. The aim of this project is to identify the mechanisms by which oxidative stress and free radical damage cause cell aging. This work will make a significant contribution to our understanding of the aging process in cells by identifying the major reactive oxygen species that contribute to cell aging, which defence systems and antioxidants provide the greatest degree of protection, what damage accumulates as cells age and which genetic systems ar ....Cellular Responses to Oxidative Damage: Cell Aging. The aim of this project is to identify the mechanisms by which oxidative stress and free radical damage cause cell aging. This work will make a significant contribution to our understanding of the aging process in cells by identifying the major reactive oxygen species that contribute to cell aging, which defence systems and antioxidants provide the greatest degree of protection, what damage accumulates as cells age and which genetic systems are activated as during the process.Read moreRead less
Dynamics and assembly of BRCA1-associated DNA repair complexes. This research project will study how cells respond to breakages in DNA by directing a team of repair proteins to the damaged DNA. BRCA1 is one of several repair proteins, and BRCA1 gene mutations impair its DNA repair function and predispose patients to breast/ovarian cancer. Improved insight into BRCA1 regulation could enhance our understanding of this disease. There are >13,000 new cases of breast/ovarian cancer each year with mor ....Dynamics and assembly of BRCA1-associated DNA repair complexes. This research project will study how cells respond to breakages in DNA by directing a team of repair proteins to the damaged DNA. BRCA1 is one of several repair proteins, and BRCA1 gene mutations impair its DNA repair function and predispose patients to breast/ovarian cancer. Improved insight into BRCA1 regulation could enhance our understanding of this disease. There are >13,000 new cases of breast/ovarian cancer each year with more than 3,300 deaths, making it a serious healthcare issue in Australia, and placing this project within Research Priority 2: Promoting and Maintaining Good Health. If successful this project will yield insights into the role of BRCA1 in fixing DNA aberrations which could help in anti-cancer agent development. Read moreRead less
Mitochondrial targeting of the DNA repair protein BARD1. This is a fundamental research project to address a novel localisation pattern of the nuclear DNA repair protein, BARD1. BARD1 gene mutations occur in a subset of breast/ovarian cancer patients, and improved insight into BARD1 regulation could enhance our understanding of this disease. There are over 13,000 new cases of breast/ovarian cancer each year with more than 3,300 deaths, making it a serious healthcare issue in Australia, and placi ....Mitochondrial targeting of the DNA repair protein BARD1. This is a fundamental research project to address a novel localisation pattern of the nuclear DNA repair protein, BARD1. BARD1 gene mutations occur in a subset of breast/ovarian cancer patients, and improved insight into BARD1 regulation could enhance our understanding of this disease. There are over 13,000 new cases of breast/ovarian cancer each year with more than 3,300 deaths, making it a serious healthcare issue in Australia, and placing this project within Research Priority 2: Promoting and Maintaining Good Health. If successful this project will characterise the cellular transport route of BARD1 which could help in anti-cancer agent development. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100032
Funder
Australian Research Council
Funding Amount
$379,264.00
Summary
Banking on spermatogonial stem cells to safeguard Australian native fauna. Spermatogonial stem cells in the testis are an untapped resource for species conservation. This project aims to characterise metabolic pathways that control spermatogonial stem cell function, and define the conserved nature of these pathways between model species (mouse) and vulnerable Australian native fauna. Expected outcomes of this project include an enhanced capacity to culture koala spermatogonia in vitro, which wil ....Banking on spermatogonial stem cells to safeguard Australian native fauna. Spermatogonial stem cells in the testis are an untapped resource for species conservation. This project aims to characterise metabolic pathways that control spermatogonial stem cell function, and define the conserved nature of these pathways between model species (mouse) and vulnerable Australian native fauna. Expected outcomes of this project include an enhanced capacity to culture koala spermatogonia in vitro, which will be a first step towards using spermatogonial biobanking as a tool to maintain genetic diversity in this species. Outcomes from this study should provide significant benefits in safeguarding our unique Australian native species, which is of particular importance following the catastrophic 2019/20 bushfire season.Read moreRead less
The effect of nitrogen monoxide on intracellular iron metabolism. We discovered that the crucial signalling molecule nitrogen monoxide (NO) mediates iron (Fe) and glutathione (GSH) release by the transporter MRP1 probably as an NO-Fe-GSH complex [DR(2006) PNAS USA 103:7670-5]. During our current ARC grant we have markedly extended these findings by showing that another molecule, GST Pi and MRP1 form part of a coordinated system that stores and transports NO as complexes of Fe and GSH, markedly e ....The effect of nitrogen monoxide on intracellular iron metabolism. We discovered that the crucial signalling molecule nitrogen monoxide (NO) mediates iron (Fe) and glutathione (GSH) release by the transporter MRP1 probably as an NO-Fe-GSH complex [DR(2006) PNAS USA 103:7670-5]. During our current ARC grant we have markedly extended these findings by showing that another molecule, GST Pi and MRP1 form part of a coordinated system that stores and transports NO as complexes of Fe and GSH, markedly extending NO half-life from milliseconds to hours. This has broad implications for understanding NO activity in many processes which have major vital health implications, including tumour cell killing by macrophages and blood pressure control.Read moreRead less
The Effect of Nitrogen Monoxide on Intracellular Iron Metabolism. For the first time, we discovered that nitric oxide (NO) is actively transported from cells by a protein that is known to also transport glutathione (GSH). This is important, as NO was thought to passively diffuse from cells. Active transport overcomes the problems of diffusion which is inefficient and non-targeted. Moreover, NO is released as a complex with iron and GSH which markedly increases its half-life. These findings have ....The Effect of Nitrogen Monoxide on Intracellular Iron Metabolism. For the first time, we discovered that nitric oxide (NO) is actively transported from cells by a protein that is known to also transport glutathione (GSH). This is important, as NO was thought to passively diffuse from cells. Active transport overcomes the problems of diffusion which is inefficient and non-targeted. Moreover, NO is released as a complex with iron and GSH which markedly increases its half-life. These findings have broad implications for understanding the activity of NO in many processes which have major health implications, including tumour cell killing by macrophages, blood pressure etc.Read moreRead less
The effect of nitrogen monoxide on intracellular iron metabolism. During our current ARC grant we discovered a novel relationship between energy metabolism and NO-mediated Fe efflux and showed that glutathione (GSH) is vital for this release mechanism (DR5,6). Intriguingly, this transport process is part of the cytotoxic effector machinery of activated macrophages against tumours, and requires further elucidation. We also showed that CO affects Fe metabolism by binding to Fe, and CO may modulate ....The effect of nitrogen monoxide on intracellular iron metabolism. During our current ARC grant we discovered a novel relationship between energy metabolism and NO-mediated Fe efflux and showed that glutathione (GSH) is vital for this release mechanism (DR5,6). Intriguingly, this transport process is part of the cytotoxic effector machinery of activated macrophages against tumours, and requires further elucidation. We also showed that CO affects Fe metabolism by binding to Fe, and CO may modulate NO's function. We will:-
(1) Examine if NO-mediated Fe release results in GSH efflux
(2) Identify the mechanism of NO-mediated Fe efflux.
(3) Assess the effect of inducing haem oxygenase 1 on Fe metabolism
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How do cells regulate redox environment at the subcellular level? Most organisms live in an aerobic environment that subjects their cells to reactive oxygen species. Reactive oxygen species have been proposed to lead to ageing, and in many diseases the balance between oxidising and reducing conditions (the redox environment) is perturbed. This research will identify how different cellular structures sense and maintain this redox homeostasis, not just in the whole cell, but within the different ....How do cells regulate redox environment at the subcellular level? Most organisms live in an aerobic environment that subjects their cells to reactive oxygen species. Reactive oxygen species have been proposed to lead to ageing, and in many diseases the balance between oxidising and reducing conditions (the redox environment) is perturbed. This research will identify how different cellular structures sense and maintain this redox homeostasis, not just in the whole cell, but within the different organelles in the cell. The work will help identify which cell compartments and processes are affected in different disease states and provide a fundamental understanding of how cells coordinate their different organelles to maintain the balance between oxidising and reducing conditions.Read moreRead less
Is transport of miRNAs essential for plant development? This project will provide knowledge of how a new class of biologically active molecule (micro RNA) regulates expression of genes at sites in the plant that are critical for growth and development. MicroRNAs are believed to influence the size and shape of plants, how rapidly they grow and how well they produce and fill seeds. These molecules are part of a group of bioactive signals that move throughout the plant, functioning like hormones bu ....Is transport of miRNAs essential for plant development? This project will provide knowledge of how a new class of biologically active molecule (micro RNA) regulates expression of genes at sites in the plant that are critical for growth and development. MicroRNAs are believed to influence the size and shape of plants, how rapidly they grow and how well they produce and fill seeds. These molecules are part of a group of bioactive signals that move throughout the plant, functioning like hormones but directly influencing how well critical genes work. Their exploitation holds great promise for manipulating plant performance and enhancing crop yields. Read moreRead less