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Evolutionary history and impact of adeno-associated viruses in Australia. Recently accrued evidence identifies Australia as an ideal closed-model system in which to elucidate the evolutionary history of a group of non-pathogenic viruses, known as adeno-associated viruses (AAVs). This project aims to trace back the evolutionary history of AAVs for tens of millions of years via molecular fossil imprints left behind by ancient viral invasions of Australian marsupial genomes. Concurrently, the poten ....Evolutionary history and impact of adeno-associated viruses in Australia. Recently accrued evidence identifies Australia as an ideal closed-model system in which to elucidate the evolutionary history of a group of non-pathogenic viruses, known as adeno-associated viruses (AAVs). This project aims to trace back the evolutionary history of AAVs for tens of millions of years via molecular fossil imprints left behind by ancient viral invasions of Australian marsupial genomes. Concurrently, the potential impact that these viral invasions had on the evolutionary development of their ancestral hosts will be investigated. This could facilitate previously unattainable insights into both AAV and marsupial evolution, with broader implications relevant to the advancement of the fields of virology and mammalian evolution.Read moreRead less
Contact Networks, Immunity, and Evolution in Competing Cancer Epidemics. The project aims to evaluate evolutionary interactions between two transmissible cancer epidemics affecting Tasmanian devils and quantify their feedback on infection risk and epidemic behaviour. Using contact tracing and a phylogenetic framework we aim to quantify how tumour lineages evolve with each generation of infection and their effects on susceptibility to infection and disease progression. We expect to reveal the hos ....Contact Networks, Immunity, and Evolution in Competing Cancer Epidemics. The project aims to evaluate evolutionary interactions between two transmissible cancer epidemics affecting Tasmanian devils and quantify their feedback on infection risk and epidemic behaviour. Using contact tracing and a phylogenetic framework we aim to quantify how tumour lineages evolve with each generation of infection and their effects on susceptibility to infection and disease progression. We expect to reveal the host immuno-genetic basis underpinning cancer suppression and the adaptive capacity of populations in response to infectious diseases. This should significantly improve our ability to understand and manage this and other epidemic outbreaks in wildlife, as well as advancing our knowledge in cancer ecology and evolution.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170101116
Funder
Australian Research Council
Funding Amount
$370,159.00
Summary
Adaptations in Tasmanian devil facial tumour disease. This project aims to understand how defence mechanisms against infectious diseases arise and evolve in nature. Infectious diseases exert strong evolutionary pressures on populations, forcing the development of adaptive strategies to fight the costs of infection. The project aims to determine individual differences in response to infection and how these affect population-scale transmission and evolutionary dynamics under natural and managed sc ....Adaptations in Tasmanian devil facial tumour disease. This project aims to understand how defence mechanisms against infectious diseases arise and evolve in nature. Infectious diseases exert strong evolutionary pressures on populations, forcing the development of adaptive strategies to fight the costs of infection. The project aims to determine individual differences in response to infection and how these affect population-scale transmission and evolutionary dynamics under natural and managed scenarios. This is expected to reveal populations’ adaptive capability and resilience against diseases and the effects of management interventions in controlling disease outbreaks and preventing population declines or extinctions.Read moreRead less
Identifying genes that influence clinical course and susceptibility in multiple sclerosis. This project aims to identify the genetic basis of multiple sclerosis (MS), the most common neurologic disease in young Australian adults. MS urgently needs research to identify predisposition, aid early diagnosis and provide bona fide molecular targets for new therapies. This will benefit people with MS and those susceptible to it. Crucial new knowledge identified will benefit other major areas of MS rese ....Identifying genes that influence clinical course and susceptibility in multiple sclerosis. This project aims to identify the genetic basis of multiple sclerosis (MS), the most common neurologic disease in young Australian adults. MS urgently needs research to identify predisposition, aid early diagnosis and provide bona fide molecular targets for new therapies. This will benefit people with MS and those susceptible to it. Crucial new knowledge identified will benefit other major areas of MS research including epidemiology, immunology and neurobiology. Collaboration of 8 major Australian institutions is also important for this project and future studies. The team will have access to a new national MS GeneBank (platform) with samples from 2240 patients that should generate findings important to world-wide MS genetic knowledge.Read moreRead less
Modelling and control of mosquito-borne diseases in Darwin using long-term monitoring. Management of mosquito populations is a high public health priority because these insects can spread diseases such as malaria, dengue, Ross River virus, Barmah Forest virus, Murray Valley encephalitis, Japanese encephalitis and Kunjin/West Nile virus. Our research into the effectiveness of mosquito control programs in Darwin is of immediate national relevance and priority given the need to Safeguard Australia ....Modelling and control of mosquito-borne diseases in Darwin using long-term monitoring. Management of mosquito populations is a high public health priority because these insects can spread diseases such as malaria, dengue, Ross River virus, Barmah Forest virus, Murray Valley encephalitis, Japanese encephalitis and Kunjin/West Nile virus. Our research into the effectiveness of mosquito control programs in Darwin is of immediate national relevance and priority given the need to Safeguard Australia from invasive diseases. There is an urgency to undertake our research because global environmental change and increasing movements of people (particularly military personnel) from overseas regions where these diseases are endemic is increasing the vulnerability of northern Australia to the (re)establishment of mosquito borne diseases.Read moreRead less