Understanding chaperone function, one molecule at a time. This project aims to determine how molecular chaperones, a class of proteins represented in all phyla of life, work together to keep proteins folded and functional, particularly following cellular stress. This is important as proteins are involved in virtually all biological processes. This project will exploit innovative microscopy techniques to watch these molecular chaperones as they work. Expected outcomes of this project are the firs ....Understanding chaperone function, one molecule at a time. This project aims to determine how molecular chaperones, a class of proteins represented in all phyla of life, work together to keep proteins folded and functional, particularly following cellular stress. This is important as proteins are involved in virtually all biological processes. This project will exploit innovative microscopy techniques to watch these molecular chaperones as they work. Expected outcomes of this project are the first definitive description of how molecular chaperones interact to refold proteins, and the development of novel methods to study dynamic biological processes. This should provide significant benefits including enhanced collaboration and scientific capacity in Australia.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100418
Funder
Australian Research Council
Funding Amount
$365,058.00
Summary
Novel chemical tools to study cathepsin X activation. This project aims to develop new chemical tools that can measure the specific activation of cathepsin X in cells, tissues, and live animals, as well as specific inhibitors for cathepsin X. The cysteine protease cathepsin X mediates basic biological functions that are essential for life, including cell communication, phagocytosis, immune maturation and neuritogenesis. The outcomes should benefit the wider research community. They could have lo ....Novel chemical tools to study cathepsin X activation. This project aims to develop new chemical tools that can measure the specific activation of cathepsin X in cells, tissues, and live animals, as well as specific inhibitors for cathepsin X. The cysteine protease cathepsin X mediates basic biological functions that are essential for life, including cell communication, phagocytosis, immune maturation and neuritogenesis. The outcomes should benefit the wider research community. They could have long-term implications for health and disease, and deliver economic benefits through commercialisation of the novel tools.Read moreRead less
Extracting energy from air: mechanism of a bacterial hydrogenase. The atmosphere has recently been shown to be a key source of energy for diverse soil bacteria. Bacteria use complex enzymes, namely Huc-type hydrogenases, to harvest atmospheric hydrogen directly from air to support growth and survival. However, little is known about how Huc functions within and outside cells. By synergising expertise in microbiology, biochemistry, and chemistry, we will resolve the mechanism, assembly, and integr ....Extracting energy from air: mechanism of a bacterial hydrogenase. The atmosphere has recently been shown to be a key source of energy for diverse soil bacteria. Bacteria use complex enzymes, namely Huc-type hydrogenases, to harvest atmospheric hydrogen directly from air to support growth and survival. However, little is known about how Huc functions within and outside cells. By synergising expertise in microbiology, biochemistry, and chemistry, we will resolve the mechanism, assembly, and integration of Huc, including the basis of its remarkably high affinity and oxygen insensitivity compared to previously studied hydrogenases. This project will enable biotechnological applications, as the first study of an enzyme that extracts energy from air, and has broad ecological and biogeochemical implications.Read moreRead less
Augmenting the activity of glyoxalase-1 to increase dicarbonyl clearance . Reactive intermediates generated during our metabolism contribute to ageing. Glyoxalase-1 is a key defence enzyme against these toxic intermediates and therefore ageing itself. This project aims to investigate novel pathways how the expression and activity of glyoxalase-1 are regulated. This interdisciplinary project expects to generate new understanding by combining relevant cell and animal models, protein chemistry, epi ....Augmenting the activity of glyoxalase-1 to increase dicarbonyl clearance . Reactive intermediates generated during our metabolism contribute to ageing. Glyoxalase-1 is a key defence enzyme against these toxic intermediates and therefore ageing itself. This project aims to investigate novel pathways how the expression and activity of glyoxalase-1 are regulated. This interdisciplinary project expects to generate new understanding by combining relevant cell and animal models, protein chemistry, epigenetics and structural biology. It is expected that this work will improve understanding of this fundamental biological defence. This will allow us to identify the potential means to enhance the capacity of glyoxalase-1 to the future benefit of biological ageing.Read moreRead less
Unravelling cell wall polysaccharide biosynthesis in pathogenic zygomycetes. This project aims to define mechanisms that control cell wall composition and stability in Rhizopus oryzae, a zygomycete fungus responsible for life-threatening human infections. The biochemical properties and function of vital enzymes involved in a newly discovered cell wall polysaccharide biosynthetic pathway will be determined using innovative approaches at the interface of biochemistry, microbiology, cell biology an ....Unravelling cell wall polysaccharide biosynthesis in pathogenic zygomycetes. This project aims to define mechanisms that control cell wall composition and stability in Rhizopus oryzae, a zygomycete fungus responsible for life-threatening human infections. The biochemical properties and function of vital enzymes involved in a newly discovered cell wall polysaccharide biosynthetic pathway will be determined using innovative approaches at the interface of biochemistry, microbiology, cell biology and structural biology. Expected outcomes include new knowledge on the enzymes that synthesise major fucose-based carbohydrates, to guide the future development of novel strategies for antifungal therapies. The data will also be applicable to animal protection from related zygomycete pathogens.
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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
Resurrecting Ancient Proteins to Unlock New Catalytic Activity. This project aims to study the proteins that nature uses to make penicillin and related antibiotics, and their prehistoric ancestors. By doing so, the project expects to deepen understanding of these important processes, open up ways to make new antibiotics, and generate new knowledge about protein evolution. Intended outcomes include new biocatalysts based on the ancient ones, new antibiotic compounds active against resistant bacte ....Resurrecting Ancient Proteins to Unlock New Catalytic Activity. This project aims to study the proteins that nature uses to make penicillin and related antibiotics, and their prehistoric ancestors. By doing so, the project expects to deepen understanding of these important processes, open up ways to make new antibiotics, and generate new knowledge about protein evolution. Intended outcomes include new biocatalysts based on the ancient ones, new antibiotic compounds active against resistant bacteria, and a richer understanding of how these proteins have evolved over the last 4 billion years. This promises significant benefits in the form of new ways to address the challenge posed by antimicrobial resistance to antibiotics, which is a serious threat to the continued effectiveness of current antibiotics.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230101173
Funder
Australian Research Council
Funding Amount
$374,318.00
Summary
Inhibiting adenylate-forming enzymes via a new reaction-hijacking mechanism. This project aims to identify and validate the adenylate-forming enzymes that are susceptible to reaction-hijacking inhibition in malaria parasites. This class of enzymes can be induced to synthesise their own nucleoside sulfamate inhibitor conjugates via a novel mechanism. This project expects to provide new knowledge about the molecular basis of this novel inhibition mechanism and susceptible target enzymes in the par ....Inhibiting adenylate-forming enzymes via a new reaction-hijacking mechanism. This project aims to identify and validate the adenylate-forming enzymes that are susceptible to reaction-hijacking inhibition in malaria parasites. This class of enzymes can be induced to synthesise their own nucleoside sulfamate inhibitor conjugates via a novel mechanism. This project expects to provide new knowledge about the molecular basis of this novel inhibition mechanism and susceptible target enzymes in the parasites. Adenylate-forming enzymes play critical roles in a diverse range of biochemical pathways, such as protein translation and fatty acid metabolism. The project seeks to deliver a new paradigm for the design of future antiparasitic agents.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