Structural studies of host-pathogen interactions. The host-pathogen interface represents a major frontier for biomedical and biotechnological applications. This project aims to understand at the atomic level two such interfaces. In the first instance, the project will elucidate the molecular basis for inhibition of premature host cell death by poxviruses, in particular vaccinia and variola virus, the causative agent of smallpox. In the second instance, the aim is to understand how defensins, a ....Structural studies of host-pathogen interactions. The host-pathogen interface represents a major frontier for biomedical and biotechnological applications. This project aims to understand at the atomic level two such interfaces. In the first instance, the project will elucidate the molecular basis for inhibition of premature host cell death by poxviruses, in particular vaccinia and variola virus, the causative agent of smallpox. In the second instance, the aim is to understand how defensins, a major class of host defence molecules, recognise microbial targets such as fungi, and exert a potent antimicrobial effect. Understanding the precise molecular mechanisms operating at both these host-pathogen interfaces this will provide novel avenues for the design of antiviral and antimicrobial agents.Read moreRead less
Drug discovery and structural biology by NMR spectroscopy. This project aims to extend the use of nuclear magnetic resonance (NMR) spectroscopy in rational drug development and protein structure analysis. A new chemical labelling approach provides detailed three-dimensional structure information of large protein-ligand complexes, needed for structure-based lead-compound development. New chemical and paramagnetic lanthanide tags for site-specific dual labelling of proteins will enhance this techn ....Drug discovery and structural biology by NMR spectroscopy. This project aims to extend the use of nuclear magnetic resonance (NMR) spectroscopy in rational drug development and protein structure analysis. A new chemical labelling approach provides detailed three-dimensional structure information of large protein-ligand complexes, needed for structure-based lead-compound development. New chemical and paramagnetic lanthanide tags for site-specific dual labelling of proteins will enhance this technology, which will assess target-drug interactions by in-cell electron paramagnetic resonance (EPR) spectroscopy. The techniques offer scope for accelerated drug development in the pharmaceutical industries.Read moreRead less
New methods for structural biology and drug discovery by nuclear magnetic resonance spectroscopy. Paramagnetic lanthanide tags offer fresh opportunities in structural biology and for rational drug design. Novel nuclear magnetic resonance (NMR) spectroscopy techniques will selectively detect the NMR signals from protein regions marked by paramagnetic lanthanides, accelerating the structure analysis of protein-ligand complexes. New lanthanide tags will bind to phosphoserine and selenocysteine resi ....New methods for structural biology and drug discovery by nuclear magnetic resonance spectroscopy. Paramagnetic lanthanide tags offer fresh opportunities in structural biology and for rational drug design. Novel nuclear magnetic resonance (NMR) spectroscopy techniques will selectively detect the NMR signals from protein regions marked by paramagnetic lanthanides, accelerating the structure analysis of protein-ligand complexes. New lanthanide tags will bind to phosphoserine and selenocysteine residues site-specifically introduced into proteins. These tags will also enable accurate distance measurements by electron paramagnetic resonance (EPR) spectroscopy in large, biologically important protein systems hitherto not amenable to detailed structural studies and in proteins undergoing conformational changes. Read moreRead less
New methods for structure analysis of proteins and protein interactions. This project will advance nuclear magnetic resonance (NMR) technologies pioneered at the Australian National University which employ site-specific attachment of paramagnetic metal tags to proteins. A new and diverse set of strategies will dramatically extend the range of applications to targets of interest in the fight against cancer and bacterial infections.
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
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
The ins and outs of HIV biology. This project aims to delineate the fundamental mechanisms that regulate the production of HIV and the ability of HIV to cause AIDS in infected patients. It will utilise state-of-the-art technologies to unearth new clues that govern the biology of HIV, with the ultimate goal to develop novel vaccine and treatment strategies against HIV.
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
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100202
Funder
Australian Research Council
Funding Amount
$255,120.00
Summary
Three-dimensional cryo correlative light and electron microscopy facility. This project aims to establish a three-dimensional (3D) cryo-correlative light and electron microscopy facility. The facility will integrate light microscopy with high resolution cryo-electron tomography and 3D slice-and-view focused ion beam scanning electron microscopy. The open access facility should create new capabilities for Australian researchers to tag biological events and structures with fluorescence markers and ....Three-dimensional cryo correlative light and electron microscopy facility. This project aims to establish a three-dimensional (3D) cryo-correlative light and electron microscopy facility. The facility will integrate light microscopy with high resolution cryo-electron tomography and 3D slice-and-view focused ion beam scanning electron microscopy. The open access facility should create new capabilities for Australian researchers to tag biological events and structures with fluorescence markers and image them using the currently highest resolution 3D imaging techniques for biological matter. The facility expects to reveal fundamental insights into cell and structural biology, and help drive innovation in agriculture, pharmaceutics, and biomaterials.Read moreRead less
Structure function analysis of the NusA-RNA polymerase interaction. Genes must be turned on at the right time, at the correct level in the appropriate cell in all organisms. This project will determine the role of an essential component of the process in bacteria called NusA. The results will apply to bacteria as well as higher organisms, and also have the potential to identify a new antibiotic target.