Untangling the matrix of bacterial biofilms. This research aims to use forefront molecular microbiology and biophysical approaches to advance fundamental knowledge on bacterial biofilms. These bacterial clusters are held together by an extracellular matrix comprised of bacterial-derived fibrous protein and the polysaccharide cellulose, which imparts structural integrity and resistance to antimicrobials. The major goals of this project are to dissect how bacteria regulate production of the biofil ....Untangling the matrix of bacterial biofilms. This research aims to use forefront molecular microbiology and biophysical approaches to advance fundamental knowledge on bacterial biofilms. These bacterial clusters are held together by an extracellular matrix comprised of bacterial-derived fibrous protein and the polysaccharide cellulose, which imparts structural integrity and resistance to antimicrobials. The major goals of this project are to dissect how bacteria regulate production of the biofilm matrix, and examine how changes in the composition of the matrix alters its properties, including the penetration of antimicrobial peptides and antibiotics. The outcomes will help address the economic burden of difficult to treat industrial, environmental and biomedical biofilms.Read moreRead less
Creation of a super-resolution map of the bacterial cytokinesis machinery . Cell division is a fundamental process essential for life. Yet our understanding of this process on a molecular level is limited, mostly hampered by the inability to visualize the different components of the division machinery inside these tiny cells with adequate resolution. To overcome this barrier, capitalizing on recent advancements in imaging and molecular technologies combined with innovative engineering, this proj ....Creation of a super-resolution map of the bacterial cytokinesis machinery . Cell division is a fundamental process essential for life. Yet our understanding of this process on a molecular level is limited, mostly hampered by the inability to visualize the different components of the division machinery inside these tiny cells with adequate resolution. To overcome this barrier, capitalizing on recent advancements in imaging and molecular technologies combined with innovative engineering, this project aims to create a spatial and temporal map of the division machinery inside bacterial cells at unprecedented resolution. The expected outcomes are new knowledge on the mechanism of bacterial division and technological advances in biological imaging, informing applications in a wide variety of sectors.Read moreRead less
Structural Characterisation of the Type IX Secretion System. The Type IX Secretion System present in diverse bacteria of veterinary, agricultural, environmental and industrial importance enables effector proteins to be secreted and attached to the cell surface where they contribute to disease pathogenesis or degrade biopolymers of commercial interest. This project aims to determine the structure and assembly mechanism of this complex secretion nanomachine comprising 15 different proteins using s ....Structural Characterisation of the Type IX Secretion System. The Type IX Secretion System present in diverse bacteria of veterinary, agricultural, environmental and industrial importance enables effector proteins to be secreted and attached to the cell surface where they contribute to disease pathogenesis or degrade biopolymers of commercial interest. This project aims to determine the structure and assembly mechanism of this complex secretion nanomachine comprising 15 different proteins using state of the art microscopy. Knowledge of the structure will greatly enhance our understanding of secretion mechanisms and our ability to both inhibit the system to treat disease in animals or manipulate the system for industrial applications providing future economic and environmental benefits to our nation.Read moreRead less
Bacterial vesicles transport their bioactive cargo to the host nucleus. This project aims to investigate how bacterial membrane vesicles transport their cargo to the nucleus of cells and its impact on host cell functions. Bacteria use membrane vesicles as a means of communication with the host, but the full extent of their effects on host cells has yet to be fully elucidated. This project expects to generate new knowledge in the field using cutting-edge imaging and molecular biology approaches. ....Bacterial vesicles transport their bioactive cargo to the host nucleus. This project aims to investigate how bacterial membrane vesicles transport their cargo to the nucleus of cells and its impact on host cell functions. Bacteria use membrane vesicles as a means of communication with the host, but the full extent of their effects on host cells has yet to be fully elucidated. This project expects to generate new knowledge in the field using cutting-edge imaging and molecular biology approaches. The work should provide significant benefits, particularly towards the development of membrane vesicles in gene therapy, gene editing and other applications. Read moreRead less
Biogenesis and functions of bacterial membrane vesicles. This project aims to investigate the mechanisms that regulate the production of bacterial membrane vesicles and how this determines their bacterial cargo and subsequent biological functions. Bacterial membrane vesicles are naturally produced nanoparticles released by all bacteria as part of their normal growth. These vesicles contain a range of bacterial cargo and function to promote bacterial survival and growth. This project will advance ....Biogenesis and functions of bacterial membrane vesicles. This project aims to investigate the mechanisms that regulate the production of bacterial membrane vesicles and how this determines their bacterial cargo and subsequent biological functions. Bacterial membrane vesicles are naturally produced nanoparticles released by all bacteria as part of their normal growth. These vesicles contain a range of bacterial cargo and function to promote bacterial survival and growth. This project will advance our knowledge regarding the regulation of bacterial membrane vesicle biogenesis, their composition and biological functions. Collectively, these findings will facilitate the development and refinement of membrane vesicle-based biotechnologies with broad applications.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200101524
Funder
Australian Research Council
Funding Amount
$355,325.00
Summary
Taking Control: Understanding regulation of bacterial iron acquisition. This project aims to uncover the bacterial regulatory networks acting on a family of iron-stealing molecules called siderophores. Bacteria use siderophores to acquire iron from their hosts, the environment, and each other – as such, they have a central role in microbial life. Despite their importance, we have an incomplete knowledge of how these iron-stealing weapons are deployed. This project will develop a new genomics-bas ....Taking Control: Understanding regulation of bacterial iron acquisition. This project aims to uncover the bacterial regulatory networks acting on a family of iron-stealing molecules called siderophores. Bacteria use siderophores to acquire iron from their hosts, the environment, and each other – as such, they have a central role in microbial life. Despite their importance, we have an incomplete knowledge of how these iron-stealing weapons are deployed. This project will develop a new genomics-based, high-throughput technology for defining bacterial gene regulation networks, and use it to understand siderophore control. This will provide new knowledge of siderophore function, enhance understanding of bacterial community and host interactions, and establish leadership in a new genomics technology in Australia.Read moreRead less
Dissecting bacterial signal transduction. Bacteria have feelings. They sense and respond to changes using proteins called two-component signalling systems (TCSS). These comprise a sensor which activates a DNA binding protein in response to specific cues (signals). Using state-of-the-art genetic techniques and a synthetic biology approach, this research aims to reveal for the first time how these complex bacterial TCSS networks interact. The outcomes will be a fundamental, new understanding of ho ....Dissecting bacterial signal transduction. Bacteria have feelings. They sense and respond to changes using proteins called two-component signalling systems (TCSS). These comprise a sensor which activates a DNA binding protein in response to specific cues (signals). Using state-of-the-art genetic techniques and a synthetic biology approach, this research aims to reveal for the first time how these complex bacterial TCSS networks interact. The outcomes will be a fundamental, new understanding of how bacteria sense and respond to environmental signals; a deep dive into how bacteria feel. This knowledge will be the basis for innovative approaches to harness bacteria in biotech such as vaccine production, biofuels, or clever therapeutic interventions to stop bacterial infections.Read moreRead less
Novel link between bacterial sugar metabolism and cell-to-cell signalling. This project aims to understand the role and function of the bacterial communication system that enables bacteria to form complex communities and alter phenotypic traits, essential for survival in their environment. Bacteria survive in their environmental niches by developing complex multicellular communities. Cell to cell communication, termed quorum sensing (QS), is critical for this process and is linked to their capac ....Novel link between bacterial sugar metabolism and cell-to-cell signalling. This project aims to understand the role and function of the bacterial communication system that enables bacteria to form complex communities and alter phenotypic traits, essential for survival in their environment. Bacteria survive in their environmental niches by developing complex multicellular communities. Cell to cell communication, termed quorum sensing (QS), is critical for this process and is linked to their capacity to detect and secrete small signalling molecules, autoinducers. This project will provide a new paradigm in bacterial adaptation through comprehensive characterisation of the Autoinducer-2 QS system. This knowledge will provide future opportunities for intervention in microbial infestation with broad potential benefits.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL210100258
Funder
Australian Research Council
Funding Amount
$3,331,707.00
Summary
Understanding how bacteria adapt and function in the complex gut ecosystem. This project aims to investigate the role of the gut ecosystem in defining the structure and function of microbes. Given that one of the current challenges in microbiology is our inability to study individual microbes directly from complex, multi-microbial niches, this project aims to develop multidisciplinary methods to study microbes in their native state, to understand how they adapt to live in the gut. This understan ....Understanding how bacteria adapt and function in the complex gut ecosystem. This project aims to investigate the role of the gut ecosystem in defining the structure and function of microbes. Given that one of the current challenges in microbiology is our inability to study individual microbes directly from complex, multi-microbial niches, this project aims to develop multidisciplinary methods to study microbes in their native state, to understand how they adapt to live in the gut. This understanding should provide fundamental insights into adaptation mechanisms that lead to bacterial proliferation, disease and antibiotic resistance. As well as enhancing interdisciplinary collaborations, this work should provide economic benefits by contributing to improved gut health of animals, and more efficient food production.Read moreRead less
Discovery of Novel Bacteriophage with the Capacity to Modulate Gut Bacteria. This project aims to experimentally validate the largest ever collection of bacterial viruses (bacteriophages) within the gut microbiome. This project expects to generate new knowledge in the area of bacteriophage biology and genomics by using the innovative approaches of wet-lab and bioinformatic genome analyses. Expect outcomes of this project include the discovery of novel phages using bioinformatics, wet-lab validat ....Discovery of Novel Bacteriophage with the Capacity to Modulate Gut Bacteria. This project aims to experimentally validate the largest ever collection of bacterial viruses (bacteriophages) within the gut microbiome. This project expects to generate new knowledge in the area of bacteriophage biology and genomics by using the innovative approaches of wet-lab and bioinformatic genome analyses. Expect outcomes of this project include the discovery of novel phages using bioinformatics, wet-lab validation of their activity and characterisation of their potential to contribute new bacterial host metabolism. This should provide benefits, such as advancement to our understanding of bacteriophages, improved bioinformatic software, and a characterised collection of commercially valuable bacterial strains and phages.Read moreRead less