Unravelling small RNA regulatory networks to target and control bacteria. Small RNA (sRNA) molecules are critical regulators of bacterial gene expression. These molecules control important phenotypes in the Gram-negative veterinary pathogen Pasteurella multocida. This project aims to identify the range of P. multocida sRNAs and to show how expression of these molecules changes under various growth conditions. Specifically, this project endeavours: to identify the mRNA targets of the sRNAs; to id ....Unravelling small RNA regulatory networks to target and control bacteria. Small RNA (sRNA) molecules are critical regulators of bacterial gene expression. These molecules control important phenotypes in the Gram-negative veterinary pathogen Pasteurella multocida. This project aims to identify the range of P. multocida sRNAs and to show how expression of these molecules changes under various growth conditions. Specifically, this project endeavours: to identify the mRNA targets of the sRNAs; to identify the mechanisms of sRNA-mRNA interaction; to build systems-biology models that describe the sRNA regulatory circuits; to design inhibitors capable of disrupting critical sRNA-mRNA interactions; and to use the new inhibitors to modulate specific phenotypes. The ability to precisely manipulate sRNA regulatory circuits could allow fine control of bacterial phenotypes and could be widely applicable.Read moreRead less
Vaccine against leptospirosis. This project will utilise the information from the determination of the complete genome sequence of Leptospira borgpetersenii serovar Hardjobovis at Monash University. Bioinformatics analysis will be used to allow a global approach to identify all putative vaccine antigens which will be cloned, expressed and purified and their protective capacity investigated.
Structural Characterisation of the Type IX Secretion System. The Type IX Secretion System present in diverse bacteria of veterinary, agricultural, environmental and industrial importance enables effector proteins to be secreted and attached to the cell surface where they contribute to disease pathogenesis or degrade biopolymers of commercial interest. This project aims to determine the structure and assembly mechanism of this complex secretion nanomachine comprising 15 different proteins using s ....Structural Characterisation of the Type IX Secretion System. The Type IX Secretion System present in diverse bacteria of veterinary, agricultural, environmental and industrial importance enables effector proteins to be secreted and attached to the cell surface where they contribute to disease pathogenesis or degrade biopolymers of commercial interest. This project aims to determine the structure and assembly mechanism of this complex secretion nanomachine comprising 15 different proteins using state of the art microscopy. Knowledge of the structure will greatly enhance our understanding of secretion mechanisms and our ability to both inhibit the system to treat disease in animals or manipulate the system for industrial applications providing future economic and environmental benefits to our nation.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100700
Funder
Australian Research Council
Funding Amount
$429,449.00
Summary
A novel bacterial secretion system for applications in nanobiotechnology. This project aims to characterise a new molecular machine, called the S-Pump. Molecular machines drive the complex biology in all cells and are an exciting area of translational research, with broad potential for industrial applications. This project expects to provide fundamental insights into how bacterial S-Pumps contribute to antimicrobial resistance and enhancing food production. Expected outcomes include new tools fo ....A novel bacterial secretion system for applications in nanobiotechnology. This project aims to characterise a new molecular machine, called the S-Pump. Molecular machines drive the complex biology in all cells and are an exciting area of translational research, with broad potential for industrial applications. This project expects to provide fundamental insights into how bacterial S-Pumps contribute to antimicrobial resistance and enhancing food production. Expected outcomes include new tools for molecular machine discovery and identification of ways to adapt molecular machines for biotechnological applications. This work should enhance Australia-UK ties through collaboration, provide benefits toward nanobiotechnology and economic benefits through more efficient food production.Read moreRead less
Alphaherpesvirus recombination: safety implications for attenuated Herpesvirus vaccines. Under certain conditions some herpesviruses, including mild vaccine strains, can recombine to generate virulent viruses. Following findings that this occurred naturally between Australian poultry vaccines, with devastating results, this project will study natural herpesvirus recombination with the aim of allowing vaccines to be used more safely.
Alphaherpesvirus vaccination, recombination and latency; a study in the natural host. Attenuated alphaherpesvirus vaccines are used widely in production and companion animals to help control disease. These vaccines help to prevent clinical signs of disease following challenge with virulent viruses. There is also the potential to use these vaccines to help prevent latent herpesvirus infections, and to limit the opportunities for herpesvirus recombination to occur. This would enhance the ability t ....Alphaherpesvirus vaccination, recombination and latency; a study in the natural host. Attenuated alphaherpesvirus vaccines are used widely in production and companion animals to help control disease. These vaccines help to prevent clinical signs of disease following challenge with virulent viruses. There is also the potential to use these vaccines to help prevent latent herpesvirus infections, and to limit the opportunities for herpesvirus recombination to occur. This would enhance the ability to control disease in animal populations. This project aims to systematically study how vaccines may be used to limit latency and recombination events by studying avian infectious laryngotracheitis virus in the natural host leading to new insights into how vaccines may be used more efficaciously.Read moreRead less
Artificial intelligence to explore and combat eukaryotic pathogens. The revolution in artificial intelligence (AI) provides unprecedented opportunities for integrative analyses of complex multi-omics data sets and for creating radically new strategies to control some of the world’s most serious animal diseases. In a strong partnership with international experts, we will use AI-based methods to make major conceptual advances in our understanding of eukaryotic pathogens and host-pathogen interacti ....Artificial intelligence to explore and combat eukaryotic pathogens. The revolution in artificial intelligence (AI) provides unprecedented opportunities for integrative analyses of complex multi-omics data sets and for creating radically new strategies to control some of the world’s most serious animal diseases. In a strong partnership with international experts, we will use AI-based methods to make major conceptual advances in our understanding of eukaryotic pathogens and host-pathogen interactions, discover the "choke-points" in biological pathways, and develop novel treatments, vaccines and diagnostics. This leap forward will substantially enhance the global profile of pathogen research in Australia, build major capacity in a priority area, and enable access to international research funding and networks.Read moreRead less
Treating Equine Laminitis. This project aims to explore the causes of equine laminitis, and to work with a newly-established Australian biopharma company to develop the world's first anti-laminitis medication. Equine laminitis is a painful, crippling disease of the foot, often necessitating euthanasia, and is the second-most common cause of death in domestic horses. In 2007, a landmark study identified insulin toxicity as a primary cause of laminitis, and subsequent research has identified over- ....Treating Equine Laminitis. This project aims to explore the causes of equine laminitis, and to work with a newly-established Australian biopharma company to develop the world's first anti-laminitis medication. Equine laminitis is a painful, crippling disease of the foot, often necessitating euthanasia, and is the second-most common cause of death in domestic horses. In 2007, a landmark study identified insulin toxicity as a primary cause of laminitis, and subsequent research has identified over-stimulation of the IGF-1 receptor as the most likely mechanism. This project aims to prove that mechanism and to develop an effective treatment.Read moreRead less
Reduction of antibiotic usage in the commercial pig industry. This project intends to identify factors that make a pig enterprise more likely to use high levels of antibiotics and develop alternative, vaccination-based methods for disease control. The development of multi-drug resistance in zoonotic bacterial pathogens (e.g. Salmonella and Campylobacter spp.) in pigs has raised concerns that antimicrobial resistance can be transferred from livestock to humans. Although the epidemiology to suppor ....Reduction of antibiotic usage in the commercial pig industry. This project intends to identify factors that make a pig enterprise more likely to use high levels of antibiotics and develop alternative, vaccination-based methods for disease control. The development of multi-drug resistance in zoonotic bacterial pathogens (e.g. Salmonella and Campylobacter spp.) in pigs has raised concerns that antimicrobial resistance can be transferred from livestock to humans. Although the epidemiology to support a claim that there is a causal association between antimicrobial use in food animals and public health is complex there is universal agreement that use of antimicrobials in food animal production should be minimised. This project intends to deliver outcomes that will reduce antibiotic use on commercial pig farms.Read moreRead less
Evaluating host-parasite interplay in individual tissues. The immune system of the host and the infecting parasite has coevolved into a sophisticated balance of power. This project will explore this balance using Schistosoma japonicum infection in sheep and determine immune mechanisms unleashed by the host in various tissues as well as the response of the parasite to these attacks.