How Bacteria Fold Virulence Factors to Cause Disease. Bacteria use folding enzymes to assemble proteins essential for cell integrity and pathogenicity. These foldases include the Disulphide bridge proteins, which catalyse the introduction of disulfide bonds. This project will study two important human pathogens, Salmonella Typhimurium and uropathogenic Escherichia coli, to address the fundamental and poorly understood questions of diversity of Dsb networks across bacterial pathogens and the role ....How Bacteria Fold Virulence Factors to Cause Disease. Bacteria use folding enzymes to assemble proteins essential for cell integrity and pathogenicity. These foldases include the Disulphide bridge proteins, which catalyse the introduction of disulfide bonds. This project will study two important human pathogens, Salmonella Typhimurium and uropathogenic Escherichia coli, to address the fundamental and poorly understood questions of diversity of Dsb networks across bacterial pathogens and the role of these foldases in virulence. The research will reveal how bacterial virulence factors are folded, identify novel targets for therapeutic intervention and provide the basis for structure-based design on new antimicrobials in the future. Read moreRead less
Molecular mechanisms of novel bacterial copper defense proteins. This project aims to reveal molecular and cellular mechanisms used by bacteria to neutralise the destructive effects of copper. Copper is an essential trace element in living systems. It is toxic to bacteria and so plays a vital role in nutritional immunity. To counteract copper toxicity, bacteria have evolved defense mechanisms. The project will investigate a novel but poorly understood class of bacterial proteins, the suppressor ....Molecular mechanisms of novel bacterial copper defense proteins. This project aims to reveal molecular and cellular mechanisms used by bacteria to neutralise the destructive effects of copper. Copper is an essential trace element in living systems. It is toxic to bacteria and so plays a vital role in nutritional immunity. To counteract copper toxicity, bacteria have evolved defense mechanisms. The project will investigate a novel but poorly understood class of bacterial proteins, the suppressor of copper sensitivity proteins, that contribute to this key virulence trait. The expected outcomes will be fundamental new knowledge of metallo-protein diversity, bacterial virulence mechanisms, and membrane protein function with potential impact on health, environment, and biotechnology.Read moreRead less
How does the chromatin remodeller CHD4 regulate gene expression? The mechanisms that determine how genes are switched on and off in different tissues and at different times are in many ways still mysterious. It is well established that gene expression patterns in complex organisms are determined in part by the manner in which DNA is physically packaged. Our aim is to define new aspects of these mechanisms that revolve around molecular motors that regulate DNA packaging. This foundational knowled ....How does the chromatin remodeller CHD4 regulate gene expression? The mechanisms that determine how genes are switched on and off in different tissues and at different times are in many ways still mysterious. It is well established that gene expression patterns in complex organisms are determined in part by the manner in which DNA is physically packaged. Our aim is to define new aspects of these mechanisms that revolve around molecular motors that regulate DNA packaging. This foundational knowledge will deepen our understanding of gene regulation in all complex organisms and will inform future efforts to rationally modulate gene expression patterns in agriculture, research and other important areas.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100149
Funder
Australian Research Council
Funding Amount
$590,000.00
Summary
Reaching new heights in high-resolution electron microscopy . High-resolution electron microscopy (EM): Direct electron detection cameras are a recent technological breakthrough delivering one of the greatest single advancements to the field of molecular cryo-EM. The aim of this project is to enable a 'first of a kind' cryo-EM platform in Australia enabling high-throughput atomic resolution protein structure determination. This will be achieved by integrating a state-of-the-art Gatan K2 Summit D ....Reaching new heights in high-resolution electron microscopy . High-resolution electron microscopy (EM): Direct electron detection cameras are a recent technological breakthrough delivering one of the greatest single advancements to the field of molecular cryo-EM. The aim of this project is to enable a 'first of a kind' cryo-EM platform in Australia enabling high-throughput atomic resolution protein structure determination. This will be achieved by integrating a state-of-the-art Gatan K2 Summit Direct Electron Detection camera system into the established cryo-EM facility managed by the University of Queensland node of the Australian Microscopy and Microanalysis Facility. This will offer unique and significantly improved capabilities for atomic resolution protein structure analysis, and will support a broad range of projects across the biological sciences.Read moreRead less
Structures to Solve Conflicts of DNA Replication and RNA Transcription. This project aims to understand how new DNA is made so quickly and without mistakes in cells that are about to divide, in spite of competition from other processes happening at the same time on the DNA that should stop or interfere with it, such as the synthesis of RNA. The project expects to use the latest available methods to uncover what the microscopic natural machines that make DNA and RNA look like, and how they compet ....Structures to Solve Conflicts of DNA Replication and RNA Transcription. This project aims to understand how new DNA is made so quickly and without mistakes in cells that are about to divide, in spite of competition from other processes happening at the same time on the DNA that should stop or interfere with it, such as the synthesis of RNA. The project expects to use the latest available methods to uncover what the microscopic natural machines that make DNA and RNA look like, and how they compete with each other for access to DNA. Potential outcomes include the identification of processes that can be compromised by small molecules that may be developed into new antibiotics. This would be of great benefit - new antibiotics are urgently needed as one approach to countering the threat of antimicrobial resistance.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100304
Funder
Australian Research Council
Funding Amount
$416,092.00
Summary
Understanding intramolecular regulation of ubiquitin enzymes. This project aims to combine structural, biophysical and functional studies to characterise how ubiquitin enzymes are regulated. Ubiquitination controls essential cellular pathways in all eukaryotes and this project expects to generate new knowledge regarding the vital regulation of this process. This project expects to develop broadly applicable techniques for investigating protein conformation and self-association as a means of cont ....Understanding intramolecular regulation of ubiquitin enzymes. This project aims to combine structural, biophysical and functional studies to characterise how ubiquitin enzymes are regulated. Ubiquitination controls essential cellular pathways in all eukaryotes and this project expects to generate new knowledge regarding the vital regulation of this process. This project expects to develop broadly applicable techniques for investigating protein conformation and self-association as a means of controlling catalytic activity. The project should significantly increase understanding of several modes of regulation of ubiquitin ligase catalytic activity, and how this controls a myriad of cellular processes. The project will lay the foundation for applied research anti-viral compounds, plant anti-fungals and cancer therapies.Read moreRead less
Three-dimensional structure determination of biomolecular assemblies from sparse data of different length scales. New computer algorithms will be combined with sparse experimental structure restraints, obtained with novel protein chemistry technologies, to generate accurate three-dimensional (3D) models of proteins and protein assemblies in solution and in the solid state. The new strategies will greatly increase the number of protein targets amenable to rational drug design.
Discovery Early Career Researcher Award - Grant ID: DE240100780
Funder
Australian Research Council
Funding Amount
$455,237.00
Summary
Functional and structural dissection of the human replisome. This project aims to develop technology to visualise the structure and enzymatic activities of the human replisome, the multiprotein assembly that copies DNA before cell division. A combination of novel single-molecule and state-of-the-art cryo-electron microscopy will be used to define how the human replisome coordinates DNA synthesis during times of replication stress. Key outcomes of this project include development of novel molecul ....Functional and structural dissection of the human replisome. This project aims to develop technology to visualise the structure and enzymatic activities of the human replisome, the multiprotein assembly that copies DNA before cell division. A combination of novel single-molecule and state-of-the-art cryo-electron microscopy will be used to define how the human replisome coordinates DNA synthesis during times of replication stress. Key outcomes of this project include development of novel molecular visualisation technologies, leading to the first molecular description of dynamic processes used by the human replisome. Benefits include improved understanding of a fundamental biological process that often malfunctions in cancers, development of novel methodology, and interdisciplinary training.Read moreRead less
Inhibiting pathological signalling in haematopoietic disease. Certain leukaemias and other blood diseases are caused by the mutation of one particular molecule, called Janus Kinase (JAK), inside our bodies. This project aims to understand the biochemical details of these diseases by studying this mutated molecule in detail. The project will aim to provide the information for developing effective therapeutics against these diseases.
The regulation of anti-viral immunity by host and viral proteins. Anti-viral immunity is initially triggered when specific immune sensors detect viral components within the cell. This project will use a combined functional/structural approach to investigate the specifics of immune activation by a pivotal immune sensor and use this information to understand how influenza A sabotages this specific immune response.