Living on air: how do bacteria scavenge atmospheric trace gases? This project aims to determine the molecular and cellular basis of atmospheric trace gas oxidation by bacteria. Bacteria have a remarkable ability to adapt to resource limitation and environmental change by entering dormant states. Our research has shown they survive in this state by using atmospheric hydrogen and carbon monoxide as energy sources. This interdisciplinary project will determine how bacteria achieve this by elucidati ....Living on air: how do bacteria scavenge atmospheric trace gases? This project aims to determine the molecular and cellular basis of atmospheric trace gas oxidation by bacteria. Bacteria have a remarkable ability to adapt to resource limitation and environmental change by entering dormant states. Our research has shown they survive in this state by using atmospheric hydrogen and carbon monoxide as energy sources. This interdisciplinary project will determine how bacteria achieve this by elucidating the regulation, mechanism, and integration of the three uncharacterised enzymes that mediate this process. Outcomes and benefits include understanding of the processes that facilitate bacterial persistence, regulate atmospheric composition, and in turn support resilience of natural ecosystems.Read moreRead less
Cell-Sort MultiTool: a Novel Platform for Bacterial Single-Cell Analysis . This project aims to advance molecular understanding of antibiotic resistance in bacterial populations at the single-cell level, using an innovative approach integrating microfluidics, microscopy and genomics. The study of individual bacterial cell genetics is essential to provide fundamental insights into heterogeneous resistance, an important component of resistance development. Expected outcomes include a new platform ....Cell-Sort MultiTool: a Novel Platform for Bacterial Single-Cell Analysis . This project aims to advance molecular understanding of antibiotic resistance in bacterial populations at the single-cell level, using an innovative approach integrating microfluidics, microscopy and genomics. The study of individual bacterial cell genetics is essential to provide fundamental insights into heterogeneous resistance, an important component of resistance development. Expected outcomes include a new platform technology for high-throughput multiplexed screening and improved knowledge of bacterial heterogeneity, informing antibiotic usage. This interdisciplinary project should yield significant benefits in society and economy by reducing healthcare costs, boosting health for Australians and commercialising advanced technologies. Read moreRead less
Australian Laureate Fellowships - Grant ID: FL170100008
Funder
Australian Research Council
Funding Amount
$3,248,822.00
Summary
Genes, reproduction and inheritance in a microbe. The project aims to particularly explore sexual gene inheritance in Plasmodium, a representative of a large group of human and animal parasites. Plasmodium must have a sexual exchange of genes in the mosquito for the transfer of disease to a new host. This project will investigate the fate and behaviour of Plasmodium genes during reproduction; the differing chromosome states resulting from sexual genetic processes and the asymmetrical inheritance ....Genes, reproduction and inheritance in a microbe. The project aims to particularly explore sexual gene inheritance in Plasmodium, a representative of a large group of human and animal parasites. Plasmodium must have a sexual exchange of genes in the mosquito for the transfer of disease to a new host. This project will investigate the fate and behaviour of Plasmodium genes during reproduction; the differing chromosome states resulting from sexual genetic processes and the asymmetrical inheritance of some Plasmodium genes. The project is expected to advance Australia’s ability to understand the reproduction and survival of these parasites in their mosquito vector and develop cutting-edge genetic tools that will advance the microbial genetics discipline globally. This may ultimately lead to biotechnology and biomedical outcomes.Read moreRead less
Metabolic control of gene expression networks and microbiome interactions. The proposal aims to advance our understanding of how metabolism (and resulting metabolites) regulate the expression of genes, and investigate how these processes dictate the interaction of microbiota with the immune system. The project is expected to generate transformative knowledge of gene regulation, a fundamental process for cellular function, and decipher how the microbiome yeast Candida albicans interacts with immu ....Metabolic control of gene expression networks and microbiome interactions. The proposal aims to advance our understanding of how metabolism (and resulting metabolites) regulate the expression of genes, and investigate how these processes dictate the interaction of microbiota with the immune system. The project is expected to generate transformative knowledge of gene regulation, a fundamental process for cellular function, and decipher how the microbiome yeast Candida albicans interacts with immune cells and bacteria. By utilising a powerful combination of molecular and systems biology with molecular genetics and imaging, the project outcomes should foster interdisciplinary collaborations and build capacity for fundamental and applied research to benefit academia and industry, locally and globally.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
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
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
Exploiting microbial metabolites to understand fungal biology. The project aims to investigate the principles of hyphal growth in fungi, by studying the mechanisms of action of a bacteria-derived compound that inhibits hyphae. Changing cell shape between yeast and hyphae is a prototype developmental switch enabling fungi to escape stressful environments, while hyphal invasion promotes fungal infections of animals and plants that endanger food security and biodiversity. By using interdisciplinary ....Exploiting microbial metabolites to understand fungal biology. The project aims to investigate the principles of hyphal growth in fungi, by studying the mechanisms of action of a bacteria-derived compound that inhibits hyphae. Changing cell shape between yeast and hyphae is a prototype developmental switch enabling fungi to escape stressful environments, while hyphal invasion promotes fungal infections of animals and plants that endanger food security and biodiversity. By using interdisciplinary approaches of microbiology and chemistry, the expected outcomes are to generate deep knowledge of an important microbial process and how it could be modulated, characterise a new bacterial compound and build research capacity at the nexus of biology and chemistry to benefit discoveries in academia and industry.Read moreRead less
Mechanism of secretion of large clostridial toxins . This project aims to investigate how the large clostridial toxins are secreted from important animal bacterial pathogens. This project expects to generate new knowledge about how bacteria interact with hosts through protein secretion, using a collaborative and interdisciplinary approach and cutting-edge techniques. Expected outcomes of this project include building a deep understanding of the role of export machinery in toxin secretion from ba ....Mechanism of secretion of large clostridial toxins . This project aims to investigate how the large clostridial toxins are secreted from important animal bacterial pathogens. This project expects to generate new knowledge about how bacteria interact with hosts through protein secretion, using a collaborative and interdisciplinary approach and cutting-edge techniques. Expected outcomes of this project include building a deep understanding of the role of export machinery in toxin secretion from bacteria, and the identification of new systems by which this is achieved. This should provide significant benefits, such as gaining new insights into new bacterial protein export mechanisms, with the aim of identifying targets for future veterinary disease interventions or biotechnological applications.Read moreRead less
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