From genotype to phenotype - systems biology bridging the gap. This project is basic research at the forefront of international science and deals with a fundamental question of modern biology: 'How do genes determine the makeup of an organism?' The main outcome will be a deeper understanding of the internal working mechanisms of a higher organism. The project combines some of the most advanced systems technologies - genomics, proteomics, metabonomics, fluxomics and computational biology in a nov ....From genotype to phenotype - systems biology bridging the gap. This project is basic research at the forefront of international science and deals with a fundamental question of modern biology: 'How do genes determine the makeup of an organism?' The main outcome will be a deeper understanding of the internal working mechanisms of a higher organism. The project combines some of the most advanced systems technologies - genomics, proteomics, metabonomics, fluxomics and computational biology in a novel and unique way. This combination is in itself a major advancement of scientific methods that will accelerate discovery in the field of systems biology. In this respect, the project is a premier example of the priority goal Breakthrough Science and of the national research priority Frontier Technologies.Read moreRead less
Functionally characterizing mammalian microRNAs and mRNA interactions controlling cell division. This project addresses some of the most burning issues in molecular biology and genetic research, and the results will be widely applicable to a broad range of fields, including biotechnology, animal breeding, agricultural production, genetic engineering, medical science, and computational biology. By understanding the regulatory potential of microRNA molecules, we will understand more about species ....Functionally characterizing mammalian microRNAs and mRNA interactions controlling cell division. This project addresses some of the most burning issues in molecular biology and genetic research, and the results will be widely applicable to a broad range of fields, including biotechnology, animal breeding, agricultural production, genetic engineering, medical science, and computational biology. By understanding the regulatory potential of microRNA molecules, we will understand more about species diversity, regulatory networks, and plant and animal development. The early adoption of multi-gigabase next-generation sequencing technology in Australia provides rare and exciting opportunity to lead the world in genome-scale research, and to ensure that Australia has the necessary skill base to remain internationally competitive in this field.Read moreRead less
The prediction of sleep/wake behaviour based on physiological and social factors. The prevalence of shiftwork has increased in Australia over the last few decades. Shiftworkers obtain less sleep, have greater difficulty maintaining good relationships, have poorer health, and are more likely to be injured at work than others. Using the largest dataset of its kind, we will substantially contribute to understanding the relationships between work hours, sleep, performance and safety. Ultimately, the ....The prediction of sleep/wake behaviour based on physiological and social factors. The prevalence of shiftwork has increased in Australia over the last few decades. Shiftworkers obtain less sleep, have greater difficulty maintaining good relationships, have poorer health, and are more likely to be injured at work than others. Using the largest dataset of its kind, we will substantially contribute to understanding the relationships between work hours, sleep, performance and safety. Ultimately, the project will answer a question critical to workplace safety - how much time off between shifts is needed to be alert and safe at work? The project will also produce tools to help industry design fatigue-friendly rosters, improving the safety, productivity and general well-being of shiftworkers in Australia and overseas.Read moreRead less
ARC Centre for Complex Systems. The Australian Centre for Complex Systems brings together leading researchers from several disciplines and institutions to conduct research on questions fundamental to understanding and managing complex systems. Its core research program, based on the theme of computation in and by networks of agents, has two interwoven strands. The science strand addresses questions about emergent properties, natural computation, and nonlinear dynamics. The engineering strand add ....ARC Centre for Complex Systems. The Australian Centre for Complex Systems brings together leading researchers from several disciplines and institutions to conduct research on questions fundamental to understanding and managing complex systems. Its core research program, based on the theme of computation in and by networks of agents, has two interwoven strands. The science strand addresses questions about emergent properties, natural computation, and nonlinear dynamics. The engineering strand addresses issues about methodology, modelling toolkits, and management and control. Practical applications are advanced via collaborative projects that address key issues in biology, environment, and socio-economics.Read moreRead less
Traversing a treacherous landscape: Modelling caterpillar movement and behaviour on whole plants at multiple scales. How caterpillars move on plants and where they feed is central to developing plants resistant to these insect pests. Our research program will generate computer models of caterpillar behaviour on virtual plants that interact in realistic ways with the changing structure of the plant as it grows, its micro-architecture and environment. We provide a set of tools that will form the ....Traversing a treacherous landscape: Modelling caterpillar movement and behaviour on whole plants at multiple scales. How caterpillars move on plants and where they feed is central to developing plants resistant to these insect pests. Our research program will generate computer models of caterpillar behaviour on virtual plants that interact in realistic ways with the changing structure of the plant as it grows, its micro-architecture and environment. We provide a set of tools that will form the cornerstone of important future research agendas in the ecology of foraging caterpillars, optimisation of insecticide spray application, and the development of novel genetically transformed plants for insect control central to the future of Australian agriculture.
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