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
Identifying how bacterial cells find their middle: a new perspective. This project will reveal new information about how bacterial cells divide with high precision to ensure that each newborn cell contains the correct genetic material. The research uses frontier techniques, provides innovative training to young Australian researchers, and will identify new ways to treat infections caused by bacteria.
A link between antibiotic resistance and bacterial sporulation. This project aims to define the sporulation process in the bacterium Clostridium difficile, and advance our understanding of a link between antibiotic use and sporulation. To survive in hostile environments, some bacteria produce a dormant and resilient cell form called a spore which can survive for many years in unfavourable environments, but our understanding of how this process occurs is limited. This project will provide a deepe ....A link between antibiotic resistance and bacterial sporulation. This project aims to define the sporulation process in the bacterium Clostridium difficile, and advance our understanding of a link between antibiotic use and sporulation. To survive in hostile environments, some bacteria produce a dormant and resilient cell form called a spore which can survive for many years in unfavourable environments, but our understanding of how this process occurs is limited. This project will provide a deeper understanding of the sporulation process and the long-lasting detrimental impact of antibiotic use. The project expects to provide economic benefits, reduce environmental microbial contamination and contribute to better health of animals and humans.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200100111
Funder
Australian Research Council
Funding Amount
$373,097.00
Summary
Replication and transfer of novel plasmid classes in Acinetobacter. The project aims to reveal basic biology of plasmids found in Acinetobacter baumannii. A. baumannii is a bacterial pathogen that can rapidly acquire resistance to antibiotics, including last-resort antibiotics. In modern strains, acquisition is often mediated by plasmids. On the basis of DNA sequencing data, A. baumannii plasmids are likely to function differently to well-studied plasmids. However, surprisingly little experiment ....Replication and transfer of novel plasmid classes in Acinetobacter. The project aims to reveal basic biology of plasmids found in Acinetobacter baumannii. A. baumannii is a bacterial pathogen that can rapidly acquire resistance to antibiotics, including last-resort antibiotics. In modern strains, acquisition is often mediated by plasmids. On the basis of DNA sequencing data, A. baumannii plasmids are likely to function differently to well-studied plasmids. However, surprisingly little experimental work has been done to evidence this. By combining microbiological and bioinformatics approaches the project expects to generate new knowledge on the mechanisms of replication and transfer of A. baumannii plasmids. This may lead to new targets for strategies to slow and track the spread of antibiotic resistance.Read moreRead less
Molecular characterisation of hypervirulence and the infectious cycle in Clostridium difficile. Gut diseases caused by the bacterium Clostridium difficile are a significant animal and public health problem in Australia and many other countries. This project will allow us to understand how this bacterium causes disease, leading to the development of much needed preventative and treatment strategies for animals and human patients.
How does Clostridium perfringens carry multiple closely related plasmids? The project aims to determine how bacteria are able to replicate and maintain multiple copies of very closely related extrachromosomal elements or plasmids in the same cell. These plasmids are important as they encode toxin genes and antibiotic resistance genes. The project proposes to examine two fundamental hypotheses that are postulated to explain this novel phenomenon. The anticipated outcome of the project is the adva ....How does Clostridium perfringens carry multiple closely related plasmids? The project aims to determine how bacteria are able to replicate and maintain multiple copies of very closely related extrachromosomal elements or plasmids in the same cell. These plasmids are important as they encode toxin genes and antibiotic resistance genes. The project proposes to examine two fundamental hypotheses that are postulated to explain this novel phenomenon. The anticipated outcome of the project is the advancement of fundamental knowledge of how bacteria that cause disease in food-production animals can maintain the genetic elements that enable them to cause these diseases. This would contribute to our understanding of the epidemiology of these economically significant animal pathogens and may support the development of new methods of prevention or treatment.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180101563
Funder
Australian Research Council
Funding Amount
$365,058.00
Summary
The sweet road to synthesis of bacterial sugar structures. This project aims to characterise the synthesis pathways of nonulosonic acid sugars (NulOs) in bacteria using a combination of bioinformatics and experimental methodologies. Bacteria produce long chains of sugars or glycans on their cell surface known as capsules. These often contain important NulOs that can be uniquely harvested for use in the nutrition, cosmetic and bioremediation industries. By understanding the natural pathways of th ....The sweet road to synthesis of bacterial sugar structures. This project aims to characterise the synthesis pathways of nonulosonic acid sugars (NulOs) in bacteria using a combination of bioinformatics and experimental methodologies. Bacteria produce long chains of sugars or glycans on their cell surface known as capsules. These often contain important NulOs that can be uniquely harvested for use in the nutrition, cosmetic and bioremediation industries. By understanding the natural pathways of their synthesis, ‘glycans-by-design’ can be synthetically created with potent tailor-made properties. This project endeavours to examine how glycans with acidic sugars are produced to generate a fundamental understanding of sugar biology and create a database that will advance industrial applications in glycoengineering.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
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
Evolution of bacterial pathogenesis. Little is known regarding the specific evolutionary steps involved in the emergence of highly virulent microbial pathogens from benign or mildly virulent populations. The group A streptococcus is exemplary of this vexing problem - a large population reservoir of bacteria exists causing only mild infections and a highly virulent strain emerges causing significant disease and mortality. Utilising an extensive WHO reference collection of group A streptococcus is ....Evolution of bacterial pathogenesis. Little is known regarding the specific evolutionary steps involved in the emergence of highly virulent microbial pathogens from benign or mildly virulent populations. The group A streptococcus is exemplary of this vexing problem - a large population reservoir of bacteria exists causing only mild infections and a highly virulent strain emerges causing significant disease and mortality. Utilising an extensive WHO reference collection of group A streptococcus isolates. This project will define the evolutionary events that produced the most significant invasive strain designated M1T1. The M1T1 strain emerged in the mid-1980s, has since disseminated globally, yet the evolutionary sequence of events resulting in this emergence are largely unknown.Read moreRead less