Explaining virus diversity. To prevent virus pandemics, it is necessary to understand how viruses evolve. This project aims to reveal the long-term trends, processes and drivers of RNA virus diversity and evolution. Through the metagenomic sequencing of the viromes of Australian animals that mark evolutionary innovations and transitions this project will reshape our knowledge of virus evolution and disease emergence. Expected outcomes will be a new understanding of how virus diversity is created ....Explaining virus diversity. To prevent virus pandemics, it is necessary to understand how viruses evolve. This project aims to reveal the long-term trends, processes and drivers of RNA virus diversity and evolution. Through the metagenomic sequencing of the viromes of Australian animals that mark evolutionary innovations and transitions this project will reshape our knowledge of virus evolution and disease emergence. Expected outcomes will be a new understanding of how virus diversity is created, how virus phenotypes have changed through time, how often viruses jump to new host species, and how major events in animal evolution have shaped virus diversity. Key benefits include new measures of the viral burden faced by Australia’s native animals and of ecosystem health.Read moreRead less
Revealing the determinants of viral emergence and evolution in fish. Viral diseases pose an ongoing threat to Australian aquaculture. The devastating impact of emerging viruses makes it imperative to understand the factors that allow them to evolve and infect new hosts. We will address these key issues by revealing the diversity, abundance and evolution of viruses in fish sampled along the Australian east coast. The data generated will reveal the untapped biodiversity of fish viruses, the freque ....Revealing the determinants of viral emergence and evolution in fish. Viral diseases pose an ongoing threat to Australian aquaculture. The devastating impact of emerging viruses makes it imperative to understand the factors that allow them to evolve and infect new hosts. We will address these key issues by revealing the diversity, abundance and evolution of viruses in fish sampled along the Australian east coast. The data generated will reveal the untapped biodiversity of fish viruses, the frequency which they jump species boundaries and the determinants of this process, and how they are impacted by host ecology, including whether fish viruses follow a latitudinal gradient in diversity. The data generated will transform our understanding of fish viruses and identify those most likely to impact aquaculture.Read moreRead less
The geometry of genome access: lessons from HIV. Access to the cell’s nucleus, and hence its genome, is of deep scientific and commercial significance. It is controlled by a phase-separated diffusion barrier within the nuclear pore complex. Recent evidence, however, has shown that HIV can cross this barrier with its protective capsid intact, despite it being over one thousand times larger than the limit for passive transport. Combining concepts from soft-matter physics with recombinant assays, t ....The geometry of genome access: lessons from HIV. Access to the cell’s nucleus, and hence its genome, is of deep scientific and commercial significance. It is controlled by a phase-separated diffusion barrier within the nuclear pore complex. Recent evidence, however, has shown that HIV can cross this barrier with its protective capsid intact, despite it being over one thousand times larger than the limit for passive transport. Combining concepts from soft-matter physics with recombinant assays, this project aims to uncover the link between the unique geometry of HIV capsids and their ability to subvert the nucleus’ defenses. The expected outcome is a step-change in the understanding of nuclear access control, with downstream benefits to virology, bio-engineering and bio-technology.Read moreRead less
Viral capsids as high-efficiency nanoreactors. This project aims to develop state-of-the-art single-molecule imaging to visualise DNA synthesis inside authentic retroviral capsids in real time. The project expects to generate new knowledge in the fields of virology, synthetic biology, and nanotechnology by utilising cutting-edge fluorescent labelling reagents and microscopy technology. Expected outcomes include a comprehensive description of retrovirus reverse transcription, development of innov ....Viral capsids as high-efficiency nanoreactors. This project aims to develop state-of-the-art single-molecule imaging to visualise DNA synthesis inside authentic retroviral capsids in real time. The project expects to generate new knowledge in the fields of virology, synthetic biology, and nanotechnology by utilising cutting-edge fluorescent labelling reagents and microscopy technology. Expected outcomes include a comprehensive description of retrovirus reverse transcription, development of innovative biophysical techniques for the study of viruses, and an understanding of the engineering principles at play in natural nano-reactors. This project anticipates contributing advanced capabilities in bionanotechnology, benefiting therapeutic, biotechnology and synthetic biology applications.Read moreRead less
Antarctic virus-host interactions. This project aims to determine how hosts and viruses interact in the natural environment and during alien invasions. Viruses are important in Antarctic aquatic systems, but foreign viruses introduced into Antarctica threaten indigenous species. Despite this awareness, big gaps exist in understanding how viruses interact with their hosts and how Antarctic communities respond to invasion. This knowledge is expected to reveal how life in Antarctica evolved, and pr ....Antarctic virus-host interactions. This project aims to determine how hosts and viruses interact in the natural environment and during alien invasions. Viruses are important in Antarctic aquatic systems, but foreign viruses introduced into Antarctica threaten indigenous species. Despite this awareness, big gaps exist in understanding how viruses interact with their hosts and how Antarctic communities respond to invasion. This knowledge is expected to reveal how life in Antarctica evolved, and provide information useful for developing policy to manage the Antarctic environment with scope for collaborations between industry and researchers to find practical solutions for biotechnology industries.Read moreRead less