The biology of integrons and their role in bacterial adaptation. Bacteria evolve in ways that animals and plants do not. One of the tools available is the ability to share genes amongst individuals in a community. One example of this is the very rapid spread of antibiotic resistance genes in pathogens. Here we will be studying a genetic element that greatly contributes to this horizontal spread of genes. This will lead to a better understanding of how bacteria work, the direct benefits of whic ....The biology of integrons and their role in bacterial adaptation. Bacteria evolve in ways that animals and plants do not. One of the tools available is the ability to share genes amongst individuals in a community. One example of this is the very rapid spread of antibiotic resistance genes in pathogens. Here we will be studying a genetic element that greatly contributes to this horizontal spread of genes. This will lead to a better understanding of how bacteria work, the direct benefits of which includes the discovery of new pathways and genes for the biotechnology industry and greater understanding of how bacteria cause disease in us, other animals and in commercial crops.Read moreRead less
A functional genomic approach for understanding metal ion adaptation in marine cyanobacteria. Unicellular marine cyanobacteria constitute 20-40% of total marine chlorophyll biomass and carbon fixation, and hence significantly impact the global carbon cycle and are very relevant to combating global warming. This research will reveal some of the major mechanisms by which marine cyanobacteria have adapted to metal levels in coastal and oligotrophic environments. Thus these results will help us und ....A functional genomic approach for understanding metal ion adaptation in marine cyanobacteria. Unicellular marine cyanobacteria constitute 20-40% of total marine chlorophyll biomass and carbon fixation, and hence significantly impact the global carbon cycle and are very relevant to combating global warming. This research will reveal some of the major mechanisms by which marine cyanobacteria have adapted to metal levels in coastal and oligotrophic environments. Thus these results will help us understand the distribution and diversity of these organisms in relation to global primary productivity. They will also lead to the development of more robust biomarkers for metal stress and pollution in coastal environments.Read moreRead less
Bacterial Cell Division: Discovering how it begins and the network of protein interactions it requires. All cells must coordinate cell division with chromosome replication to ensure that the DNA is partitioned equally into newborn cells. We will establish the defect of a novel mutant blocked in the earliest stage of cell division in bacteria to obtain unique information about this vital regulatory step. We will use our newly discovered protein interaction network to establish what role protein i ....Bacterial Cell Division: Discovering how it begins and the network of protein interactions it requires. All cells must coordinate cell division with chromosome replication to ensure that the DNA is partitioned equally into newborn cells. We will establish the defect of a novel mutant blocked in the earliest stage of cell division in bacteria to obtain unique information about this vital regulatory step. We will use our newly discovered protein interaction network to establish what role protein interactions play in integrating cell division with other biological pathways in the cell to ensure its tight regulation. Our discoveries will facilitate the design of new antibiotics that target cell division to fight antibiotic-resistant bacteria and bioterrorism organisms.Read moreRead less
Investigating the Ability of Honey to Inhibit Bacterial Biofilms Found in Chronic Wounds. Chronic (non-healing) wounds are a serious health problem in Australia. One quarter of our institutionalized aged population have pressure ulcers. The difficulty in treating these wounds is that most contain communities of bacteria, called biofilms, that are not killed by conventional antibiotics. Special honeys from Australia and NZ that are effective in chronic wound treatment can eradicate these biofilms ....Investigating the Ability of Honey to Inhibit Bacterial Biofilms Found in Chronic Wounds. Chronic (non-healing) wounds are a serious health problem in Australia. One quarter of our institutionalized aged population have pressure ulcers. The difficulty in treating these wounds is that most contain communities of bacteria, called biofilms, that are not killed by conventional antibiotics. Special honeys from Australia and NZ that are effective in chronic wound treatment can eradicate these biofilms. This project will identify the components in honey that do this and determine how they do it, to provide a more effective chronic wound treatment. It will decrease the prevalence of these wounds in Australia and the associated personal trauma and health costs.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
Establishing how bacterial cells position the division site. Cell division is essential for life. It is required for bacterial infections and, if uncontrolled, causes diseases such as cancer. We will establish how bacterial cells position the division site precisely to ensure faithful production of newborn cells. We will use the latest technology in bacterial cell biology to provide novel, clear-cut information to maintain Australia at the leading edge of this important area of research. There i ....Establishing how bacterial cells position the division site. Cell division is essential for life. It is required for bacterial infections and, if uncontrolled, causes diseases such as cancer. We will establish how bacterial cells position the division site precisely to ensure faithful production of newborn cells. We will use the latest technology in bacterial cell biology to provide novel, clear-cut information to maintain Australia at the leading edge of this important area of research. There is an alarming increase in antibiotic resistant bacteria and an imminent threat of bioterrorism. This research allows the opportunity for the development of new antibiotics to protect Australia protected from these dangerous bacteria. Read moreRead less
A new molecular machine required for bacterial development into spores. This project aims to provide new knowledge on how bacteria produce dormant, stress-resistant cells called spores, and how bacteria transport molecules across their cellular layers to execute biological functions. Spores can act as a source of new and recurring infections in many bacterial pathogens. This project expects to reveal molecular details on a new class of nanomachines required for spore development. The new knowled ....A new molecular machine required for bacterial development into spores. This project aims to provide new knowledge on how bacteria produce dormant, stress-resistant cells called spores, and how bacteria transport molecules across their cellular layers to execute biological functions. Spores can act as a source of new and recurring infections in many bacterial pathogens. This project expects to reveal molecular details on a new class of nanomachines required for spore development. The new knowledge generated may expand the arsenal of molecular targets required to develop strategies interfering with spore formation. This provides a platform from which industry could attract investment for exploring innovative strategies for controlling bacteria.Read moreRead less
Regulating the earliest step in bacterial cell division: Z ring assembly. Cell division is essential for survival. What are the cues that signal cells to divide at the right place and at the right time? How do cells ensure that when division occurs to produce two newborn cells, each one receives the correct amount of DNA? The answers to these questions are essential to understand how organisms reproduce and grow. But they remain unknown. This research addresses these questions in bacteria. Our d ....Regulating the earliest step in bacterial cell division: Z ring assembly. Cell division is essential for survival. What are the cues that signal cells to divide at the right place and at the right time? How do cells ensure that when division occurs to produce two newborn cells, each one receives the correct amount of DNA? The answers to these questions are essential to understand how organisms reproduce and grow. But they remain unknown. This research addresses these questions in bacteria. Our discoveries will have a significant impact on our understanding of the regulation of this vital process and will facilitate the design of novel antibiotics that target it.Read moreRead less
Evolutionary and ecological complexity in an experimentally controlled environment. Understanding the capacity and mechanism of microbial evolution provides the framework for developing new strategies for preventing infectious disease. If we know how evolution works, it will be possible to hamper the capacity to evolve as a mechanism of preventing new diseases and controlling existing ones. This project will provide a mechanistic description of evolution in real time under controlled conditions. ....Evolutionary and ecological complexity in an experimentally controlled environment. Understanding the capacity and mechanism of microbial evolution provides the framework for developing new strategies for preventing infectious disease. If we know how evolution works, it will be possible to hamper the capacity to evolve as a mechanism of preventing new diseases and controlling existing ones. This project will provide a mechanistic description of evolution in real time under controlled conditions. This detailed information will be used in the education of the public and in debates about evolution. The project will also train at least five students in molecular and evolutionary microbiology, essential for facing future challenges.
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The role of central carbon metabolism in cell cycle control in bacteria. Bacteria are simple organisms, yet we still do not understand how they coordinate their growth with their reproduction so faithfully, generation after generation, to produce viable newborn cells. The new discovery of a link between the food bacteria eat and the first stage of their cell division now provides the opportunity to elucidate how bacteria 'measure' their energy production to control their proliferation. This proj ....The role of central carbon metabolism in cell cycle control in bacteria. Bacteria are simple organisms, yet we still do not understand how they coordinate their growth with their reproduction so faithfully, generation after generation, to produce viable newborn cells. The new discovery of a link between the food bacteria eat and the first stage of their cell division now provides the opportunity to elucidate how bacteria 'measure' their energy production to control their proliferation. This project combines the latest technology with complementary expertise in bacterial cell division and metabolism. This should identify the mechanism that integrates these fundamental pathways in bacteria, crucial to both their survival and ability to cause infection.Read moreRead less