Enhancing fertility for the Thoroughbred and Standardbred industries. Enhancing fertility for the Thoroughbred and Standardbred industries. Responding to industry calls for improved methods of detecting and managing infertility in both stallions and mares, this project aims to provide a platform for competitive collaborations between universities, biotechnology companies and horse breeders: the end-users of technological developments in equine reproduction. The Thoroughbred and Standardbred bree ....Enhancing fertility for the Thoroughbred and Standardbred industries. Enhancing fertility for the Thoroughbred and Standardbred industries. Responding to industry calls for improved methods of detecting and managing infertility in both stallions and mares, this project aims to provide a platform for competitive collaborations between universities, biotechnology companies and horse breeders: the end-users of technological developments in equine reproduction. The Thoroughbred and Standardbred breeding industries contribute over $6.5 billion per annum to the Australian economy and employ thousands of staff across their value chains. However, these industries suffer from breeding program inefficiencies that amount to over $800 million in annual losses. Expected outcomes are novel reproductive technologies and specialised research capabilities that will make the Australian equine industry a global leader.Read moreRead less
Targeted Development Of AMPK Β2-isoform Allosteric Activators
Funder
National Health and Medical Research Council
Funding Amount
$898,147.00
Summary
Sedentary lifestyles and consumption of high energy foods has led to dramatic increases in the incidence of diseases associated with metabolic dysregulation e.g. type 2 diabetes. An attractive drug target to treat these diseases is AMP-activated protein kinase (AMPK) which functions as a cellular fuel gauge. We have discovered a new drug that crucially activates the form of AMPK found in metabolically active organs. We aim to develop this drug to unlock new therapeutic opportunity.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100004
Funder
Australian Research Council
Funding Amount
$540,000.00
Summary
An automated 3D electron microscopy facility. An automated 3D electron microscopy facility: The aim of this project is to establish the next generation of electron microscopy facility, with a fully automated tool enabling 3D imaging. The automated serial section system incorporated in a scanning electron microscope circumvents the limitation of transmission electron microscopy, which provides unique insights into molecular structures and cell components at high resolution, however, the area and ....An automated 3D electron microscopy facility. An automated 3D electron microscopy facility: The aim of this project is to establish the next generation of electron microscopy facility, with a fully automated tool enabling 3D imaging. The automated serial section system incorporated in a scanning electron microscope circumvents the limitation of transmission electron microscopy, which provides unique insights into molecular structures and cell components at high resolution, however, the area and volume are limited in size to a few microns. This new type of microscope can image whole organisms and be used by non-electron microscopists. It will be housed in an open access facility and will meet a growing demand for 3D electron microscopy.Read moreRead less
Discovery of novel myokines by innovative proteomic analyses. This project will utilise sophisticated techniques to identify novel proteins that are released from contracting skeletal muscle termed myokines. It is expected the project will identify numerous novel proteins that may enhance our understanding of human biology.
Deciphering new regulators of lipid metabolism: a focus on lipid droplets . Lipid droplets store lipids in cells and the mitochondria break down this lipid to generate energy. Both organelles are critical for energy metabolism and cell survival. This project aims to determine the proteins that regulate the interaction between mitochondria and lipid droplets, and how these proteins regulate metabolism. It is anticipated that this project will identify the essential components of lipid droplet-mit ....Deciphering new regulators of lipid metabolism: a focus on lipid droplets . Lipid droplets store lipids in cells and the mitochondria break down this lipid to generate energy. Both organelles are critical for energy metabolism and cell survival. This project aims to determine the proteins that regulate the interaction between mitochondria and lipid droplets, and how these proteins regulate metabolism. It is anticipated that this project will identify the essential components of lipid droplet-mitochondria interactions and their impact on regulating cellular lipid metabolism. The intended outcome of this project is to provide fundamental new knowledge in understanding how organelles interact and how lipid metabolism is regulated. This knowledge has applications for the primary industries and biotechnology sector.Read moreRead less
Characterising the lipid droplet-mitochondria proteome. This project aims to determine the mechanisms by which the mitochondria and lipid droplets associate, and how this interaction influences lipid metabolism. Both critical for survival, lipid droplets are the bulk energy store in cells and the mitochondria break down this lipid to generate energy. It is anticipated that this project will identify the proteins that are critical for regulating contact between these organelles and the consequenc ....Characterising the lipid droplet-mitochondria proteome. This project aims to determine the mechanisms by which the mitochondria and lipid droplets associate, and how this interaction influences lipid metabolism. Both critical for survival, lipid droplets are the bulk energy store in cells and the mitochondria break down this lipid to generate energy. It is anticipated that this project will identify the proteins that are critical for regulating contact between these organelles and the consequences if this process becomes dysregulated. The project expects to provide fundamental new knowledge in understanding how organelles interact and how lipid metabolism is regulated. This knowledge has applications for the primary industries and biotechnology sector.Read moreRead less
Metabolic Stress Sensing By AMPK: Implications For Energy Balance And Isoform-targetting Therapeutics
Funder
National Health and Medical Research Council
Funding Amount
$632,188.00
Summary
Metabolic diseases such as obesity, type 2 diabetes and cardiovascular disease impose enormous medical and economic burdens on Western societies. Our research is focussed on the enzyme AMP-activated protein kinase (AMPK) which acts as the fuel gauge of the cell and is a promising drug target for combating metabolic diseases. Our discoveries provide critical insight on how AMPK is switched on by both energy demand and drugs, and will greatly assist development of AMPK-targetted therapeutics.
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
Machineries that maintain mitochondrial architecture. This project aims to define and characterise the protein machines that give mitochondria their characteristic shape in different cellular tissues. Innovative approaches involving gene editing and quantitative proteomics with molecular cell biology will be employed. This project expects to generate new knowledge in protein-mediated membrane shaping and mechanisms by which signaling occurs across multiple membranes. The project outcomes should ....Machineries that maintain mitochondrial architecture. This project aims to define and characterise the protein machines that give mitochondria their characteristic shape in different cellular tissues. Innovative approaches involving gene editing and quantitative proteomics with molecular cell biology will be employed. This project expects to generate new knowledge in protein-mediated membrane shaping and mechanisms by which signaling occurs across multiple membranes. The project outcomes should include enhanced capacity for fundamental cell biology research in Australia. The project anticipates the contribution of new tools for structural biology, benefiting therapeutic and biotechnology applications and the training of young researchers in frontier technologies.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.