Bacterial poly-histidine triad proteins. The poly-histidine triad (Pht) proteins are a poorly characterised family of surface proteins expressed by the genus Streptococcus and other Gram-positive genera. Recent studies suggest an important role for Pht proteins in survival of these bacteria in low zinc (Zn) environments. The project hypothesis is that Pht proteins specifically recruit Zn from the extracellular environment and somehow make it available to ATP binding cassette (ABC) transport syst ....Bacterial poly-histidine triad proteins. The poly-histidine triad (Pht) proteins are a poorly characterised family of surface proteins expressed by the genus Streptococcus and other Gram-positive genera. Recent studies suggest an important role for Pht proteins in survival of these bacteria in low zinc (Zn) environments. The project hypothesis is that Pht proteins specifically recruit Zn from the extracellular environment and somehow make it available to ATP binding cassette (ABC) transport systems located in the bacterial plasma membrane, beneath the cell wall, facilitating Zn uptake by the bacterium. The aim of this project is to conduct comprehensive molecular characterization of the interactions between Pht proteins, Zn and ABC transporters, and the role of the histidine triad motifs in these interactions.Read moreRead less
Targeted isolation of specific marine bacterial species associated with higher organsims for the purpose of discovering new antimicrobial compounds. Specific bacterial species that are commonly found in association with marine plants and animals often produce active secondary metabolites. The aim of this project is to apply our understanding of these bacterial-host associations to the targeted isolation of novel antimicrobials from the marine environment. While these new compounds will undoubted ....Targeted isolation of specific marine bacterial species associated with higher organsims for the purpose of discovering new antimicrobial compounds. Specific bacterial species that are commonly found in association with marine plants and animals often produce active secondary metabolites. The aim of this project is to apply our understanding of these bacterial-host associations to the targeted isolation of novel antimicrobials from the marine environment. While these new compounds will undoubtedly have a number of commercial applications this project focuses on the development of products for dental hygiene in animals. Generally, the urgent need for new antimicrobial compounds to combat the growing number of microbes that are resistant to current antibiotics highlights the importance of this project.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.
The development and evaluation of a new therapy for the prevention and treatment of bacterial infections in hospitals. The technology used in this project will enable products to be developed from the Australian dairy industry which may safely provide protection and treatment for diarrhoea acquired in hospitals for which there are few effective options. The product will be cost effective and can be used as a public health tool to control outbreaks in those most susceptible to severe disease.
Discovery Early Career Researcher Award - Grant ID: DE140100963
Funder
Australian Research Council
Funding Amount
$395,220.00
Summary
Biofilms and quorum sensing in pneumococcal biology. Bacteria survive in their environmental niches by development of complex multicellular communities (biofilms), not by operating as individuals. Communication between bacteria is critical for biofilm formation, and is linked to their capacity to exchange DNA within and between species (competence). This is achieved by secretion and detection of small chemical signalling molecules (quorum sensing). Two such systems operate in the pneumococcus, a ....Biofilms and quorum sensing in pneumococcal biology. Bacteria survive in their environmental niches by development of complex multicellular communities (biofilms), not by operating as individuals. Communication between bacteria is critical for biofilm formation, and is linked to their capacity to exchange DNA within and between species (competence). This is achieved by secretion and detection of small chemical signalling molecules (quorum sensing). Two such systems operate in the pneumococcus, a model Gram-positive organism. This project aims to elucidate the mechanism whereby these quorum sensing systems interact and collaborate to regulate biofilm formation and competence, phenotypes critical for bacterial survival. This knowledge will enable future development of novel antimicrobials. Read moreRead less
How auto-transporter proteins mediate bacterial interactions. This project aims to investigate the structure-function relationships that underpin key auto-transporter roles in bacterial cell adhesion, aggregation and biofilm formation. Auto-transporter proteins are extremely common in bacteria where they play a central role in controlling bacterial interactions with other bacteria, with human cells, and with surfaces. This project will define the molecular mechanisms underlying these processes. ....How auto-transporter proteins mediate bacterial interactions. This project aims to investigate the structure-function relationships that underpin key auto-transporter roles in bacterial cell adhesion, aggregation and biofilm formation. Auto-transporter proteins are extremely common in bacteria where they play a central role in controlling bacterial interactions with other bacteria, with human cells, and with surfaces. This project will define the molecular mechanisms underlying these processes. This will have significant benefits, such as providing the basis for the development of approaches to block auto-transporter functions that contribute to the establishment of persistent and difficult to treat bacterial infections.Read moreRead less
Molecular characterisation of antibiotic resistance genes in Salmonella enterica and Escherichia coli recovered from food-producing animals and humans. Antibiotic resistance is an accelerating global problem. Antibiotic resistance genes are located on mobile genetic elements which can be horizontally transferred between distantly related bacteria. It is becoming increasingly apparent that healthy humans carry populations of resistant bacteria as part of the normal microbial flora. This project w ....Molecular characterisation of antibiotic resistance genes in Salmonella enterica and Escherichia coli recovered from food-producing animals and humans. Antibiotic resistance is an accelerating global problem. Antibiotic resistance genes are located on mobile genetic elements which can be horizontally transferred between distantly related bacteria. It is becoming increasingly apparent that healthy humans carry populations of resistant bacteria as part of the normal microbial flora. This project will characterise the antibiotic resistance gene arrangements among populations of bacteria which belong to the Enterobacteriaceae. These resistant bacteria represent a threat to human and veterinary health because they are readily ingested as part of the food chain and represent reservoirs for the spread of antibiotic resistance genes to pathogens.Read moreRead less
The protein O-glycosylation pathway of Neisseria: a model system for O-glycosylation of bacterial proteins with potential use in biotechnology. Proteins can be modified by the addition of sugar molecules. This process, called glycosylation, has been studied for some time in humans and other higher organisms, but is relatively new in the field of bacteria. This study will use the bacterium Neisseria as a model system for this process and work to harness the system for use in biotechnology.
Roles for quorum sensing and biofilm formation by Vibrio cholerae in resistance to protozoan grazing. This research will benefit Australia through an increased fundamental understanding of how our model bacterium, Vibrio cholerae, survives in the environment. This could lead to the development of strategies that control bacterial biofilms, a significant medical and industrial concern. This project will also be of benefit through the training of postgraduate students in environmental microbiology ....Roles for quorum sensing and biofilm formation by Vibrio cholerae in resistance to protozoan grazing. This research will benefit Australia through an increased fundamental understanding of how our model bacterium, Vibrio cholerae, survives in the environment. This could lead to the development of strategies that control bacterial biofilms, a significant medical and industrial concern. This project will also be of benefit through the training of postgraduate students in environmental microbiology and is expected to result in the publication and presentation of data in quality journals and conferences, which increases the profile of Australian science.Read moreRead less
Defining domains within Mycoplasma hyopneumoniae surface proteins that interact with host extracellular matrix: efficacy testing of candidate vaccines in swine. Over 90% of Australian commercial pig production facilities are affected by Mycoplasma hyopneumoniae, the causative agent of swine enzootic pneumonia. This disease causes economic losses in Australia of over $20 million per annum and up to $1 billion per annum in major swine rearing countries worldwide. This project will determine the p ....Defining domains within Mycoplasma hyopneumoniae surface proteins that interact with host extracellular matrix: efficacy testing of candidate vaccines in swine. Over 90% of Australian commercial pig production facilities are affected by Mycoplasma hyopneumoniae, the causative agent of swine enzootic pneumonia. This disease causes economic losses in Australia of over $20 million per annum and up to $1 billion per annum in major swine rearing countries worldwide. This project will determine the protective efficacy of new generation vaccines against M. hyopneumoniae, which aim to block the colonisation process and prevent disease .Read moreRead less