Regulation of autophagy dependent cell and tissue deletion. This project aims to elucidate novel mechanisms that regulate autophagy-depdendent cell death during animal development. It will combine the power of Drosophila genetics with multidisciplinary approaches, such as proteomics, bioinformatics and cell biology. Given the conserved nature of autophagy the oucomes will provide highly topical and exciting new knowledge of broad biological significance. The project will help establishing inter ....Regulation of autophagy dependent cell and tissue deletion. This project aims to elucidate novel mechanisms that regulate autophagy-depdendent cell death during animal development. It will combine the power of Drosophila genetics with multidisciplinary approaches, such as proteomics, bioinformatics and cell biology. Given the conserved nature of autophagy the oucomes will provide highly topical and exciting new knowledge of broad biological significance. The project will help establishing international collaborations, enhancing Australia’s competitiveness and reputation in an important area of research, and provide training of HDR students in skills across a range of areas. In the long-term the research findings may translate into improved agriculture, food production and human health outcomes.Read moreRead less
Genetic selection of artificial polyketides. This project aims to harness the potential of synthetic biology to build cells that can make valuable new derivatives of polyketides. Polyketides are natural products that have proven to be highly effective for use in industry, medicine and agriculture. The technologies developed in this project will provide resources to discover new chemicals, accessible to almost any scientific laboratory. Expected outcomes include the opportunity to put the future ....Genetic selection of artificial polyketides. This project aims to harness the potential of synthetic biology to build cells that can make valuable new derivatives of polyketides. Polyketides are natural products that have proven to be highly effective for use in industry, medicine and agriculture. The technologies developed in this project will provide resources to discover new chemicals, accessible to almost any scientific laboratory. Expected outcomes include the opportunity to put the future of natural product discovery and optimisation in the hands of the wider scientific community, which will provide significant benefits, such as providing new tools for Australian industries.Read moreRead less
The LINK to Regulating Lysine Levels in Wheat. This project aims to characterise a recently discovered allosteric mechanism called 'Ligand-Induced association by Lysine (K)' (LINK) model. LINK model regulates the function of a key biosynthetic enzyme in bacteria and plants, including agriculturally-important species such as wheat. Also, it represents a highly significant discovery to the field of biochemistry. The expected outcomes of this project include an in-depth understanding of the molecul ....The LINK to Regulating Lysine Levels in Wheat. This project aims to characterise a recently discovered allosteric mechanism called 'Ligand-Induced association by Lysine (K)' (LINK) model. LINK model regulates the function of a key biosynthetic enzyme in bacteria and plants, including agriculturally-important species such as wheat. Also, it represents a highly significant discovery to the field of biochemistry. The expected outcomes of this project include an in-depth understanding of the molecular basis of a new allosteric mechanism for regulating intracellular lysine levels, which in the longer term offers excellent potential to be manipulated for agricultural benefits.Read moreRead less
Developing macrophage-based technologies for tissue regeneration. Different tissues show distinct regenerative capacities with an organism and across the phylogeny. What underlies this diversity in regenerative ability at cellular and molecular level is far from clear. Building on foundational discoveries in zebrafish, this study seeks to determine if this capacity could, in part, be explained through the properties of a component of the innate immune system, the macrophage, which preliminary da ....Developing macrophage-based technologies for tissue regeneration. Different tissues show distinct regenerative capacities with an organism and across the phylogeny. What underlies this diversity in regenerative ability at cellular and molecular level is far from clear. Building on foundational discoveries in zebrafish, this study seeks to determine if this capacity could, in part, be explained through the properties of a component of the innate immune system, the macrophage, which preliminary data shows generates a transient pro-regenerative muscle stem cell niche in zebrafish. This study will determine if macrophage subtypes acts to coordinate regeneration in other tissues and systems and if a programable pro-regenerative cell can be made in vitro that stimulate regeneration in different settings.Read moreRead less
A genomic and phenomic investigation of a mitochondrial glutathione transferase. The aim of this study is to understand of the genomics, structure and function of glutathione transferase Kappa (GSTK), a novel GST found in mitochondria. The investigations will achieve several outcomes. (1)an understanding of the organisation of GSTK gene(s) in humans and mice; (2) determination of the role of GSTK in mitochondria, by investigating the phenotype of knockout mice; (3) determination of the crysta ....A genomic and phenomic investigation of a mitochondrial glutathione transferase. The aim of this study is to understand of the genomics, structure and function of glutathione transferase Kappa (GSTK), a novel GST found in mitochondria. The investigations will achieve several outcomes. (1)an understanding of the organisation of GSTK gene(s) in humans and mice; (2) determination of the role of GSTK in mitochondria, by investigating the phenotype of knockout mice; (3) determination of the crystal structure of human GSTK; (4) An understanding of GSTK's substrate specificity, reaction kinetics and structure/function relationships. Since GSTK is confined to mitochondria, and may not be related to other GSTs, we may also identify novel functionsRead moreRead less
Cell death by self-eating: Autophagy-dependent tissue removal. This project aims to study the mechanisms and regulation of autophagy-dependent cell death. Cell death maintains cell and tissue homeostasis. Although most cell death is mediated by apoptosis, other modes of cell deletion have emerged recently. One form of cell death involves autophagy, the catabolic process of cellular self-digestion through lysosomal enzymes. As autophagy is a default mechanism of cell survival under stress, the id ....Cell death by self-eating: Autophagy-dependent tissue removal. This project aims to study the mechanisms and regulation of autophagy-dependent cell death. Cell death maintains cell and tissue homeostasis. Although most cell death is mediated by apoptosis, other modes of cell deletion have emerged recently. One form of cell death involves autophagy, the catabolic process of cellular self-digestion through lysosomal enzymes. As autophagy is a default mechanism of cell survival under stress, the idea of autophagy-dependent cell death has been controversial. This proposal aims to resolve this question and provide highly topical knowledge of broad biological significance.Read moreRead less
Universal transcriptome editing technologies. Ribonucleic acid (RNA) is life’s most essential molecule – as no living cell or virus can function without it. Although RNA plays many critical roles in cells, from information transfer and regulation of gene expression to scaffolding macromolecular structures and catalysis, the current approaches to manipulate RNA for technological purposes are limited in many respects. This project brings together the scientists who were the first to discover a uni ....Universal transcriptome editing technologies. Ribonucleic acid (RNA) is life’s most essential molecule – as no living cell or virus can function without it. Although RNA plays many critical roles in cells, from information transfer and regulation of gene expression to scaffolding macromolecular structures and catalysis, the current approaches to manipulate RNA for technological purposes are limited in many respects. This project brings together the scientists who were the first to discover a universal code for recognition of RNA by proteins and one of the world’s leading RNA-focused biotechnology companies, Locana Biosciences, with the goal of providing robust and versatile tools to target RNA in diverse organisms.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE200100117
Funder
Australian Research Council
Funding Amount
$1,275,000.00
Summary
A platform consortium for integrated 'systems-omics' research. The proposal aims to establish a multi-institutional integrated ‘systems-omics’ platform across two of Victoria’s leading research universities, and associated research institutes. The platform will consist of two cutting edge ultra-high resolution mass spectrometers (i) a Thermo Scientific Orbitrap Fusion LUMOS for rapid and comprehensive metabolomic profiling and detailed structural characterization, located at La Trobe University ....A platform consortium for integrated 'systems-omics' research. The proposal aims to establish a multi-institutional integrated ‘systems-omics’ platform across two of Victoria’s leading research universities, and associated research institutes. The platform will consist of two cutting edge ultra-high resolution mass spectrometers (i) a Thermo Scientific Orbitrap Fusion LUMOS for rapid and comprehensive metabolomic profiling and detailed structural characterization, located at La Trobe University, and (ii) a Thermo Scientific Orbitrap Q Exactive HFX for high-throughput, deep and reproducible quantitative proteome analysis, located at the University of Melbourne.This platform will address applications across the agri-biosciences, medicinal agriculture and fundamental biomedical sciences sectors.Read moreRead less
Regulation of AMPK enzyme by xenobiotics and a-subunit phosphorylation. Living cells balance energy production and consumption in order to survive. An enzyme AMPK regulates burning and storage of fuels such as fat and sugars and mediates control of appetite and energy expenditure. This project will advance understandings of the regulation of AMPK and explain how some natural products modulate metabolism.
Improving clostridial toxoid production through molecular fermentation maps. This project aims to improve vaccine production by generating detailed molecular maps of fermentation which will be used to design superior fermentation processes with reduced cost. Toxoid vaccines, used routinely in the livestock industry to prevent animal-disease caused by pathogenic Clostridia, are produced using batch fermentation processes. These processes have undergone limited optimisation over the past five deca ....Improving clostridial toxoid production through molecular fermentation maps. This project aims to improve vaccine production by generating detailed molecular maps of fermentation which will be used to design superior fermentation processes with reduced cost. Toxoid vaccines, used routinely in the livestock industry to prevent animal-disease caused by pathogenic Clostridia, are produced using batch fermentation processes. These processes have undergone limited optimisation over the past five decades. Low titres and frequent batch failures greatly affect capital use and represent a significant cost. In addition, current optimisation approaches are limited by the use of expensive and noisy endpoint assays. This project aims to use high-throughput chemistry (multi-omics) that overcome these limitations.Read moreRead less