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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
Molecular Interactions with an antibiotic target in DNA replication. This project aims to develop and use new technologies to address mechanistic aspects of anti-bacterial compounds in development, and of the development of resistance to them. The project will focus on the sliding clamp subunit of the bacterial replicative polymerase by studying its association with many other proteins in vitro and in vivo, using novel techniques in solid-state NMR, single-molecule fluorescence and molecular mic ....Molecular Interactions with an antibiotic target in DNA replication. This project aims to develop and use new technologies to address mechanistic aspects of anti-bacterial compounds in development, and of the development of resistance to them. The project will focus on the sliding clamp subunit of the bacterial replicative polymerase by studying its association with many other proteins in vitro and in vivo, using novel techniques in solid-state NMR, single-molecule fluorescence and molecular microbiology. The outcomes are expected to be an increased understanding of bacterial DNA replication and mechanisms of antibiotic action and resistance. This project expects to generate new knowledge to assist in combatting antibiotic resistance in Gram-negative bacterial pathogens.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120103084
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Targeting bacterial superbugs: novel approaches for optimisation of antibiotic combinations and resistance prevention. This project will elucidate the mechanistic basis to optimally combine available beta-lactam antibiotics to prevent resistance of gram-negative 'superbugs'. The interdisciplinary project will substantially contribute to solving the global crisis due to multidrug-resistant bacteria and inform the design of effective new antibiotics.
Targeting an impending global disaster: the mismatch between increasingly drug-resistant superbugs and development of new antibiotics. This project will develop much-needed novel antibiotics for treating infections caused by bacteria that are resistant to all current antibiotics. It will make a significant contribution to the global medical challenge of a shortage of new antibiotics.
Enabling aerosol delivery of phages to defeat antibiotic-resistant bacteria. This project aims to explore the use of bacteriophages towards producing a safe, natural, and highly effective alternative to traditional antibiotics. Respiratory infections caused by multidrug-resistant Gram-negative bacteria are a major health problem worldwide, and cost Australia over $150 million annually. Some 5,000 Australians die each year from antibiotic resistant infections. The project aims to produce efficac ....Enabling aerosol delivery of phages to defeat antibiotic-resistant bacteria. This project aims to explore the use of bacteriophages towards producing a safe, natural, and highly effective alternative to traditional antibiotics. Respiratory infections caused by multidrug-resistant Gram-negative bacteria are a major health problem worldwide, and cost Australia over $150 million annually. Some 5,000 Australians die each year from antibiotic resistant infections. The project aims to produce efficacious and stable formulations of bacteriophages for easy delivery by inhalation as aerosols with a long shelf-life, making them a commercially viable product. The expected research outcome can lead to an economic and efficient technology to produce phage powders for novel treatment strategies of infections by inhalation.Read moreRead less
Structure-based design of inhibitors of HIV-1 integrase. This project will produce compounds that block human immunodeficiency virus (HIV) replication. These compounds will benefit the 17000 Australians and more than 34 million people worldwide who are currently suffering with this terrible disease.
Harnessing the potential of metals in biocatalysis. The project aims to use an integrated, multi-disciplinary approach to study the properties of a group of related but functionally diverse enzymes; binuclear metallohydrolases (BMHs). These enzymes are of great relevance to protein engineers aiming to produce potent agents for bioremediation and pharmacologists interested in developing drugs. Elucidating and modulating the mode of action of BMHs is thus our main objective and should provide esse ....Harnessing the potential of metals in biocatalysis. The project aims to use an integrated, multi-disciplinary approach to study the properties of a group of related but functionally diverse enzymes; binuclear metallohydrolases (BMHs). These enzymes are of great relevance to protein engineers aiming to produce potent agents for bioremediation and pharmacologists interested in developing drugs. Elucidating and modulating the mode of action of BMHs is thus our main objective and should provide essential information to fully exploit the potential of these enzymes for practical applications. In particular, understanding how metal ions interact with BMHs and how this contributes to their reactivity is crucial to optimally understand their biotechnological potential.Read moreRead less