Genome wide screening for gene products that regulate the celluar dynamics of lipid droplets. Obesity is a pandemic that if not stopped, will lead to huge social and economic problems in Australia. In essence, the hallmark of human obesity is the accumulation of cellular lipid droplets. This research will benefit Australia by providing a fundamental understanding of how lipid droplets are formed. This will have immediate international impact at the scientific level and will also provide novel ta ....Genome wide screening for gene products that regulate the celluar dynamics of lipid droplets. Obesity is a pandemic that if not stopped, will lead to huge social and economic problems in Australia. In essence, the hallmark of human obesity is the accumulation of cellular lipid droplets. This research will benefit Australia by providing a fundamental understanding of how lipid droplets are formed. This will have immediate international impact at the scientific level and will also provide novel targets and strategies for treating obesity. The proposed study will also benefit Australian agriculture by providing strategies to improve oil production from plant seeds. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989078
Funder
Australian Research Council
Funding Amount
$400,000.00
Summary
Unique, state-of-the-art lipidomics infrastructure. The new technologies provided through this grant will significantly enhance our understanding of lipids and their role in normal cell biology and disease. These new insights will be vital in improving our understanding of lipid-related disorders such obesity, type 2 diabetes and cardiovascular disease and helping to improve their treatment and prevention.
New methods to complete the lipidomics puzzle: revealing the structural diversity of lipids by mass spectrometry. Lipid-related disorders such as obesity, diabetes and heart disease are reaching epidemic proportions in the western world. The integration of innovative techniques will provide Australia with unique capabilities to investigate these diseases and place Australia at the forefront of lipid research internationally.
Future Industries Research - Biotechnology and Nanotechnology: Small talk: Communication networks in microbes. We will use the Australian Proteome Analysis Facility to address the multifaceted mechanisms of microbial interactions and produce new knowledge about the pathogen Pseudomonas aeruginosa, a common cause of death in cystic fibrosis patients. We will characterise the interactions between P. aeruginosa and the emerging fungal pathogen Scedosporium aurantiacum as a proactive step towards be ....Future Industries Research - Biotechnology and Nanotechnology: Small talk: Communication networks in microbes. We will use the Australian Proteome Analysis Facility to address the multifaceted mechanisms of microbial interactions and produce new knowledge about the pathogen Pseudomonas aeruginosa, a common cause of death in cystic fibrosis patients. We will characterise the interactions between P. aeruginosa and the emerging fungal pathogen Scedosporium aurantiacum as a proactive step towards better understanding of pathogen communication. Improved understanding of pathogen interactions should facilitate the development of novel anti-adhesives as therapeutics. Our project will train young scientists in a new integrated approach to biology.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170100226
Funder
Australian Research Council
Funding Amount
$372,000.00
Summary
How innate lymphoid cells regulate mammalian lung development. This project aims to determine the ability of a subset of lung resident immune cells to promote normal lung development through the regulation of stem cells. The lung is constantly exposed to countless environmental challenges including microbes. Mammals’ local immune systems protect the lung from these challenges. This is particularly important in early-life when the lung is still developing. However, impaired lung development affec ....How innate lymphoid cells regulate mammalian lung development. This project aims to determine the ability of a subset of lung resident immune cells to promote normal lung development through the regulation of stem cells. The lung is constantly exposed to countless environmental challenges including microbes. Mammals’ local immune systems protect the lung from these challenges. This is particularly important in early-life when the lung is still developing. However, impaired lung development affects humans and livestock, costing >$3 billion p.a. The intended outcome is to identify basic biological processes involved in normal mammalian lung development, which may lead to strategies to prevent chronic lung diseases in humans and animals.Read moreRead less
The fate of single virus particles during infection. This project applies innovative imaging techniques to elucidate the logistics of cellular function. Establishing a cutting-edge technology platform will spawn discovery and research creativity in fundamental science, as well as applications in biomedical and biotechnology research disciplines. We will foster a highly skilled workforce, an essential asset for maintaining and enhancing Australia's reputation and capability as a leader in researc ....The fate of single virus particles during infection. This project applies innovative imaging techniques to elucidate the logistics of cellular function. Establishing a cutting-edge technology platform will spawn discovery and research creativity in fundamental science, as well as applications in biomedical and biotechnology research disciplines. We will foster a highly skilled workforce, an essential asset for maintaining and enhancing Australia's reputation and capability as a leader in research excellence.Read moreRead less
Biophysical characterization of protein interactions within a transcription factor network. Gene expression is regulated in part by interactions between pairs and groups of proteins known as transcription factors and co-regulators. These proteins assemble into complexes at gene promoters and enhancers and thereby control the expression of that gene. Little is known at the molecular level of how these complexes form and how different interactions cooperate or compete with each other. In this prop ....Biophysical characterization of protein interactions within a transcription factor network. Gene expression is regulated in part by interactions between pairs and groups of proteins known as transcription factors and co-regulators. These proteins assemble into complexes at gene promoters and enhancers and thereby control the expression of that gene. Little is known at the molecular level of how these complexes form and how different interactions cooperate or compete with each other. In this proposal we aim to define a complex between two transcriptional regulators (HOP and SRF) involved in cardiac development and to begin to define other interactions that make up a transcriptional network essential for development of a normal heart.Read moreRead less
Hydrophobin proteins on the fungal frontline. This project aims to use advanced biophysical techniques to study the role of hydrophobin proteins in three diseases caused by fungi. The specific focus will be on hydrophobins from fungal species that cause severe loss of rice plants, cause invasive growths in humans, and infect the eggs of endangered turtles and result in death of the turtle embryos. Hydrophobins are small fungal proteins that assemble into large biological layers at the boundary ....Hydrophobin proteins on the fungal frontline. This project aims to use advanced biophysical techniques to study the role of hydrophobin proteins in three diseases caused by fungi. The specific focus will be on hydrophobins from fungal species that cause severe loss of rice plants, cause invasive growths in humans, and infect the eggs of endangered turtles and result in death of the turtle embryos. Hydrophobins are small fungal proteins that assemble into large biological layers at the boundary between the fungus and the host. This research aims to focus on characterising the structure of the layers, understanding how they form and how they attach to the host tissue. This work may lead to new antifungal strategies aimed at reducing the impact of these devastating fungal infections.Read moreRead less
Molecular mechanisms of stem cell self-renewal. Muscle growth and regeneration is critically dependent on its stem cell compartment. We have discovered that the p38 MAPK pathway is essential for stem cell self-renewal in the C2C12 myogenic cell line. This proposal seeks to understand the molecular basis of stem cell self-renewal in skeletal muscles, data that may be applicable to many stem cell systems, and to the enormous promise of stem cell therapies for injury and diseases of the aged. We wi ....Molecular mechanisms of stem cell self-renewal. Muscle growth and regeneration is critically dependent on its stem cell compartment. We have discovered that the p38 MAPK pathway is essential for stem cell self-renewal in the C2C12 myogenic cell line. This proposal seeks to understand the molecular basis of stem cell self-renewal in skeletal muscles, data that may be applicable to many stem cell systems, and to the enormous promise of stem cell therapies for injury and diseases of the aged. We will attempt to alter the balance of stem cell production by enforced p38 expression, and take microarray and proteomics approaches to define stem cell pathways.Read moreRead less
Regulation of mammalian heart development by transcription factors FHL2, GATA-4 & FOG-2. FHL2 is involved in many biological processes including intracellular signaling and gene transcription. GATA and FOG proteins are critical for the development of diverse tissues, including the heart. Knowledge gained in this project will advance our understanding of many cellular processes, including heart development, and will contribute to our knowledge in Biology, Zoology and Veterinary Science. More spe ....Regulation of mammalian heart development by transcription factors FHL2, GATA-4 & FOG-2. FHL2 is involved in many biological processes including intracellular signaling and gene transcription. GATA and FOG proteins are critical for the development of diverse tissues, including the heart. Knowledge gained in this project will advance our understanding of many cellular processes, including heart development, and will contribute to our knowledge in Biology, Zoology and Veterinary Science. More specifically, it will contribute to Stem Cell research, a 'hot' area in the biotechnology industry, particularly towards building a strong base of expertise, skills and technological capability in this new field, and may even lead to the development of a commercial product e.g. a heart muscle cell-coated biomaterial to aid failing heart.Read moreRead less