Peril and promise: Origins and spread of integron gene cassettes. Integrons have a major role in spreading antibiotic resistance genes among pathogens. They do so by capturing gene cassettes encoding resistance, yet how these cassettes are generated, the taxa in which they originate, and the range of traits that cassettes can encode have been outstanding questions for 30 years. This project addresses these long standing questions. The project will analyze single bacterial cells to detect newly ....Peril and promise: Origins and spread of integron gene cassettes. Integrons have a major role in spreading antibiotic resistance genes among pathogens. They do so by capturing gene cassettes encoding resistance, yet how these cassettes are generated, the taxa in which they originate, and the range of traits that cassettes can encode have been outstanding questions for 30 years. This project addresses these long standing questions. The project will analyze single bacterial cells to detect newly generated cassettes and assign them to specific taxa, using an innovative method that links cassette DNA to bacterial 16S rDNA. Understanding cassette origins is the key to controlling their activity, both to harness integrons for biotechnology, and to prevent pathogens from acquiring new, dangerous traits. Read moreRead less
Biology and evolution of intracellular parasitism. This project will investigate the development of intracellular parasitism in environmental amoebae. The outcomes of this work will help to understand the mechanisms by which bacteria have evolved to survive inside cells and in some cases cause disease.
Epigenetic regulation in bacteria. This project aims to understand the effect of DNA modification on gene regulation in the bacterial organism Escherichia coli, which causes urinary tract infection worldwide. High-throughput DNA sequencing technologies mean one can determine the entire genetic blueprint of a bacterium – its genome – accurately, quickly and cheaply. Single-molecule real-time sequencing provides a complete read-out of a bacterial genome (genetic data) and chemical modifications of ....Epigenetic regulation in bacteria. This project aims to understand the effect of DNA modification on gene regulation in the bacterial organism Escherichia coli, which causes urinary tract infection worldwide. High-throughput DNA sequencing technologies mean one can determine the entire genetic blueprint of a bacterium – its genome – accurately, quickly and cheaply. Single-molecule real-time sequencing provides a complete read-out of a bacterial genome (genetic data) and chemical modifications of the DNA (epigenetic data). Epigenetic data can affect regulation: how genes are switched off and on. This project seeks to harness the power of single-molecule DNA sequencing, together with state-of-the-art genomic and molecular approaches, to better understand the impact of DNA modification on gene regulation in the model bacterial organism, Escherichia coli. This work will support advanced training in bioinformatics and microbiology and improve our understanding of regulation in all bacteria.Read moreRead less
The protein O-glycosylation pathway in Neisseria meningitidis. Neisseria meningitidis causes bacterial meningitis, a sudden and severe disease of particular concern to children in both the developed and developing worlds. This project will contribute to an understanding of how these bacteria evade the immune system by modifying the proteins displayed on their surface, which will help in the development of a vaccine.
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.
Breaking through the Gram-negative cell barrier. This project aims to develop fundamental knowledge of the cell envelope in Gram-negative bacteria, which functions as a permeability barrier to small molecules. Combining innovative functional genomics with biochemistry, this project will determine how small molecules can pass across the cell envelope, and the chemical properties that they need to do so. Some Gram-negative bacteria are human pathogens and cause serious infections, whereas others a ....Breaking through the Gram-negative cell barrier. This project aims to develop fundamental knowledge of the cell envelope in Gram-negative bacteria, which functions as a permeability barrier to small molecules. Combining innovative functional genomics with biochemistry, this project will determine how small molecules can pass across the cell envelope, and the chemical properties that they need to do so. Some Gram-negative bacteria are human pathogens and cause serious infections, whereas others are used in biotechnology for biosynthetic chemical production or bioremediation. This project expects to help the future development of new antibiotics and assist in the design of strains to be used in biotechnological applications.Read moreRead less
Effect of predation on virulence traits of opportunistic pathogens. The project aims to determine if increased fitness of bacteria in animal or human hosts (increased virulence) can occur due to indirect rather than direct selective pressure, particularly pressure on bacteria arising from predation by protozoa. Protozoa feed on many pathogenic bacteria (e.g. those that cause cholera and chronic infections) in the ocean, and warming oceans are predicted to increase predation. Knowing the effect o ....Effect of predation on virulence traits of opportunistic pathogens. The project aims to determine if increased fitness of bacteria in animal or human hosts (increased virulence) can occur due to indirect rather than direct selective pressure, particularly pressure on bacteria arising from predation by protozoa. Protozoa feed on many pathogenic bacteria (e.g. those that cause cholera and chronic infections) in the ocean, and warming oceans are predicted to increase predation. Knowing the effect of warming oceans on marine bacteria and the emergence of virulence in bacteria that are subject to predation in the environment can inform design of tools for monitoring the risk of infection outbreaks. Benefits would be realised by academic researchers, clinicians and policy-makers interested in optimising the tracking of infection threats.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL210100071
Funder
Australian Research Council
Funding Amount
$3,246,000.00
Summary
“L-form” bacteria: basic science, antibiotics, evolution and biotechnology. This Fellowship addresses key gaps in knowledge about cell wall deficient bacteria called L-forms: an altered state of bacteria with intriguing properties both structurally and functionally. The main aims of the research program are to improve our understanding of the basic biology of L-forms and employ them as tools in several important ways: for understanding the mechanisms of cell wall synthesis and how antibiotics wo ....“L-form” bacteria: basic science, antibiotics, evolution and biotechnology. This Fellowship addresses key gaps in knowledge about cell wall deficient bacteria called L-forms: an altered state of bacteria with intriguing properties both structurally and functionally. The main aims of the research program are to improve our understanding of the basic biology of L-forms and employ them as tools in several important ways: for understanding the mechanisms of cell wall synthesis and how antibiotics work, as models for early steps in the evolution of cellular life, and as a significant new platform for the production of proteins and fine chemicals. Outcomes and benefits include improved understanding of how to generate new antibiotics, and the development of new platforms for Australian biotechnology and biocommerce.Read moreRead less
Tracking the molecular dynamics of adaptation with horizontal gene transfer. This project aims to track the dynamics of adaptation with gene exchange by building the first experimental evolution model that can directly observe this process. The acquisition of genes from other strains and species (horizontal gene transfer) frequently underlies bacterial adaptation, but it is unknown how this occurs. This project aims to shift understanding of how microbial populations respond to environmental cha ....Tracking the molecular dynamics of adaptation with horizontal gene transfer. This project aims to track the dynamics of adaptation with gene exchange by building the first experimental evolution model that can directly observe this process. The acquisition of genes from other strains and species (horizontal gene transfer) frequently underlies bacterial adaptation, but it is unknown how this occurs. This project aims to shift understanding of how microbial populations respond to environmental challenges. There are significant benefits to be gained from understanding how microbes adapt in response to climate change and the widespread application of antibiotics, given that microbial populations form intimate associations with humans and sustain all of the world’s ecosystems.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140101728
Funder
Australian Research Council
Funding Amount
$395,220.00
Summary
The regulation and evolution of posttranscriptional gene networks. The ability of cells to regulate gene expression is key for organism development, adaptation to new environments and evolutionary changes that shape the diversity of life on Earth. This project studies the RNA binding proteins called PUFs which are central for gene expression in diverse organisms. Using cutting-edge new generation systems biology approaches, this project will study how PUF proteins regulate genes to enable metabo ....The regulation and evolution of posttranscriptional gene networks. The ability of cells to regulate gene expression is key for organism development, adaptation to new environments and evolutionary changes that shape the diversity of life on Earth. This project studies the RNA binding proteins called PUFs which are central for gene expression in diverse organisms. Using cutting-edge new generation systems biology approaches, this project will study how PUF proteins regulate genes to enable metabolic adaptation, differentiation of cell types and the evolution of new gene expression outputs in distinct biological species. The outcomes will include new insights into the regulation and evolution of posttranscriptional gene networks. Read moreRead less