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Biology and evolution of intracellular parasitism. This project will investigate the development of intracellular parasitism in environmental amoebae. The outcomes of this work will help to understand the mechanisms by which bacteria have evolved to survive inside cells and in some cases cause disease.
An interdisciplinary approach to host-pathogen interactions in infection. This project aims to understand the molecular and cellular interactions between host and parasite, as well as providing a quantitative framework for analysing infection dynamics in other systems. Infection involves a complex interaction between the host and the parasite, which is very dynamic and therefore difficult to study by traditional sampling and analysis approaches. This project has combined mathematical modelling w ....An interdisciplinary approach to host-pathogen interactions in infection. This project aims to understand the molecular and cellular interactions between host and parasite, as well as providing a quantitative framework for analysing infection dynamics in other systems. Infection involves a complex interaction between the host and the parasite, which is very dynamic and therefore difficult to study by traditional sampling and analysis approaches. This project has combined mathematical modelling with a novel experimental protocol to allow the study of kinetics of parasite replication in vivo. Expected outcomes will provide significant benefits, such as new avenues for vaccination and immune intervention.Read moreRead less
Bacterial vesicles transport their bioactive cargo to the host nucleus. This project aims to investigate how bacterial membrane vesicles transport their cargo to the nucleus of cells and its impact on host cell functions. Bacteria use membrane vesicles as a means of communication with the host, but the full extent of their effects on host cells has yet to be fully elucidated. This project expects to generate new knowledge in the field using cutting-edge imaging and molecular biology approaches. ....Bacterial vesicles transport their bioactive cargo to the host nucleus. This project aims to investigate how bacterial membrane vesicles transport their cargo to the nucleus of cells and its impact on host cell functions. Bacteria use membrane vesicles as a means of communication with the host, but the full extent of their effects on host cells has yet to be fully elucidated. This project expects to generate new knowledge in the field using cutting-edge imaging and molecular biology approaches. The work should provide significant benefits, particularly towards the development of membrane vesicles in gene therapy, gene editing and other applications. Read moreRead less
Wolbachia endosymbionts: novel strain dynamics in Australian Drosophila. This project aims to understand Wolbachia infections across Australian Drosophila flies. Wolbachia bacteria that live inside the cells of insects and other invertebrates are widely seen as a promising tool for pest and disease control. This project will assess the population distribution, host phenotypic effects, population dynamics and evolutionary context of multiple Wolbachia infections across Australian Drosophila flies ....Wolbachia endosymbionts: novel strain dynamics in Australian Drosophila. This project aims to understand Wolbachia infections across Australian Drosophila flies. Wolbachia bacteria that live inside the cells of insects and other invertebrates are widely seen as a promising tool for pest and disease control. This project will assess the population distribution, host phenotypic effects, population dynamics and evolutionary context of multiple Wolbachia infections across Australian Drosophila flies. The outcome will include new and novel strains for applied projects, new information on the fate of Wolbachia infections, and new insights into the factors that dictate the fate of Wolbachia infections across populations.Read moreRead less
Troublesome ticks: a new molecular toolkit to investigate zoonotic tick-borne pathogens in Australia. This project will use the latest molecular diagnostic techniques to address unanswered questions about potential tick-transmitted diseases of humans and companion animals in Australia. The study will identify 'hot-spots' for tick-borne pathogens, identify areas of potential risk for humans, and investigate vector-host-pathogen interactions nationwide.
Ecology and transmission of tick-borne disease in Australia. Ecology and transmission of tick-borne disease in Australia. This project aims to determine the bacterial, protozoal and viral biodiversity in wildlife ticks and their native mammal hosts, and provide new information about the biology and transmission dynamics of these microorganisms and their potential to cause disease in wildlife, domesticated animals and humans. Anticipated outcomes are improved diagnostic tests and management proto ....Ecology and transmission of tick-borne disease in Australia. Ecology and transmission of tick-borne disease in Australia. This project aims to determine the bacterial, protozoal and viral biodiversity in wildlife ticks and their native mammal hosts, and provide new information about the biology and transmission dynamics of these microorganisms and their potential to cause disease in wildlife, domesticated animals and humans. Anticipated outcomes are improved diagnostic tests and management protocols for tick-borne disease in Australia.Read moreRead less
Molecular dissection of malaria parasite motility and host-cell invasion across the lifecycle. Malaria parasites move in a unique way, gliding across cell surfaces and infecting host cells using a unique molecular motor. This research aims to understand the molecular mechanics behind parasite movement and use this to develop novel drugs that might throw a spanner in the parasite motor, blocking movement and thereby preventing malaria disease.
Herpesvirus entry into mammalian hosts. Herpesviruses infect most mammals and cause much chronic disease. Our poor understanding of their host entry pathways limits infection control. The olfactory neuroepithelium has been identified as a key entry portal for both a murid herpesvirus and a human pathogen, Herpes simplex virus, suggesting that many herpesviruses use this route. Virions cross the olfactory mucus on neuronal cilia, then either infect neurons or transfer to glial cells for local spr ....Herpesvirus entry into mammalian hosts. Herpesviruses infect most mammals and cause much chronic disease. Our poor understanding of their host entry pathways limits infection control. The olfactory neuroepithelium has been identified as a key entry portal for both a murid herpesvirus and a human pathogen, Herpes simplex virus, suggesting that many herpesviruses use this route. Virions cross the olfactory mucus on neuronal cilia, then either infect neurons or transfer to glial cells for local spread. This project will identify key receptor interactions and map the extent of invasion. By advancing our basic understanding of these important viruses and their uptake at an abundantly exposed but little explored anatomical site, the project can establish a basis for vaccinating against chronic disease.Read moreRead less
New methods for integrating population structure and stochasticity into models of disease dynamics. Epidemics, such as the 2007 equine 'flu outbreak and 2009 swine 'flu pandemic, highlight the need to make informed decisive responses. This project will develop new methods that incorporate two important aspects of disease dynamics---host structure and chance---into mathematical models, and determine their impact in terms of controlling infections.
Emergence of a virulent strain of West Nile virus causing fatal equine encephalitis in south-eastern Australia. In 2011 a large outbreak of encephalitis in horses occurred in south-eastern Australia that was caused by a new virus that is transmitted by mosquitoes and is related to West Nile virus, known to cause severe disease in humans and horses. This project will study this new virus and develop improved methods for diagnosis and control of this disease.