System identification of microstructure in the brain using magnetic resonance. Magnetic Resonance Imaging technologies will be exploited to probe the microstructure of the brain, using powerful Bayesian optimisation techniques and innovative uses of magnetic resonance. The project will in particular develop non-invasive imaging methods to quantify iron content in the brain, important for research on dementia and Alzheimer's disease.
The recirculation of myeloid dendritic cells. This project aims to understand dendritic cell recirculation. It will use virological tools to track dendritic cell migration, and identify key decision points. Expected outcomes include enhanced capacity in basic research and greater interdisciplinary collaboration between virology and immunology research groups. Significant benefits will include a new understanding of how G protein coupled receptor signalling and other tissue cues guide dendritic c ....The recirculation of myeloid dendritic cells. This project aims to understand dendritic cell recirculation. It will use virological tools to track dendritic cell migration, and identify key decision points. Expected outcomes include enhanced capacity in basic research and greater interdisciplinary collaboration between virology and immunology research groups. Significant benefits will include a new understanding of how G protein coupled receptor signalling and other tissue cues guide dendritic cell recirculation, and what consequences the recirculation has for immune cell function. This understanding will significantly advance our basic understanding of the immune system.Read moreRead less
Complex dynamical systems: inferring form and function of interacting biological systems. Often in biology a large number of simple parts interacting according to simple rules can result in behaviour that is rich and varied. This project aims to develop the mathematics of complex systems theory to describe how such collections of simple interacting parts can form large complicated structures, and to deduce what dynamical behaviour can result.
Is FGF21 the master regulator of protein intake? The project plans to bring together two major, rapidly growing disciplines – nutritional geometry and metabolic signalling – to address a topic of fundamental biological significance: the regulation of protein intake. A specific capacity to regulate protein intake has been shown for organisms spanning slime moulds to humans, yet the controlling mechanisms remain elusive. The project aims to test the hypothesis that fibroblast growth factor 21, rel ....Is FGF21 the master regulator of protein intake? The project plans to bring together two major, rapidly growing disciplines – nutritional geometry and metabolic signalling – to address a topic of fundamental biological significance: the regulation of protein intake. A specific capacity to regulate protein intake has been shown for organisms spanning slime moulds to humans, yet the controlling mechanisms remain elusive. The project aims to test the hypothesis that fibroblast growth factor 21, released from the liver under low protein nutrition, is a master regulator of protein intake. Understanding the mechanisms of protein appetite may have implications for organismal biology, understanding social interactions, the structure of food webs and the health and welfare of food and companion animals and humans.Read moreRead less
Systems Biology Of Asthma Development In Early Childhood
Funder
National Health and Medical Research Council
Funding Amount
$763,800.00
Summary
Recent studies have established that both human genetic susceptibility and viral infections during early childhood are important drivers of asthma development. It has also been noted that asthmatics’ airways are colonized with different bacteria to non-asthmatics. In this project we will examine how genetic susceptibility and interactions between bacteria and viruses in children's airways promote the development of allergy and asthma.
High-resolution multiscale modelling of pandemics: COVID-19 and beyond. The project aims to develop high-resolution computational models for pandemic mitigation and control, focussing on the novel coronavirus and its emerging variants, and leveraging demographic, genomic and epidemiological data. It expects to rigorously compare multi-scale effects of complex vaccination and social distancing strategies and quantify optimal responses under the COVID-19 induced uncertainty. The intended outcomes ....High-resolution multiscale modelling of pandemics: COVID-19 and beyond. The project aims to develop high-resolution computational models for pandemic mitigation and control, focussing on the novel coronavirus and its emerging variants, and leveraging demographic, genomic and epidemiological data. It expects to rigorously compare multi-scale effects of complex vaccination and social distancing strategies and quantify optimal responses under the COVID-19 induced uncertainty. The intended outcomes include computational models of how the most infectious viral variants emerge and spread in presence of interventions, how to predict the outbreaks, and which are the most vulnerable communities. This should make a significant economic and social impact, improving population health while maintaining a resilient economy.Read moreRead less
Understanding The Pathogenesis, Phenotypic Variation And Risk Prediction Of Childhood Asthma Using Computational Approaches
Funder
National Health and Medical Research Council
Funding Amount
$122,714.00
Summary
Asthma is a common respiratory illness in Australia. It is important to be able to predict who gets asthma, because those who get early treatment tend to fare better. We plan to run complex tests on data collected from hundreds of Australian children. The collected data includes genetic variations, chest infections, and differences in immune responses. From this data we hope to achieve a better understanding of the driving forces behind asthma, and to make better predictions for those at risk.
Integrative Genomics And Prediction Of Cardiovascular Disease
Funder
National Health and Medical Research Council
Funding Amount
$766,820.00
Summary
Technologies that measure whole molecular systems are just beginning to reveal the complexity of living organisms and the underlying molecular networks that govern them. Cardiovascular diseases emerge out of these networks as a result of genetic and molecular perturbations. This project aims to characterize the role molecular networks play in cardiovascular disease risk as well as how they react to genetic risk factors. In doing so, it will identify potential therapeutics and personalized approa ....Technologies that measure whole molecular systems are just beginning to reveal the complexity of living organisms and the underlying molecular networks that govern them. Cardiovascular diseases emerge out of these networks as a result of genetic and molecular perturbations. This project aims to characterize the role molecular networks play in cardiovascular disease risk as well as how they react to genetic risk factors. In doing so, it will identify potential therapeutics and personalized approaches to target pathogenesis.Read moreRead less
System Biology Approaches To Uncovering Non-coding RNAs' Roles In Characterising Cancer Subtypes
Funder
National Health and Medical Research Council
Funding Amount
$318,768.00
Summary
I aim to investigate non-coding RNAs (ncRNAs)’ roles in cancer development, and how they characterise cancer subtypes. The outcomes of the proposed research are twofold: computational methods to stratify tumor subtypes and computational methods to identify groups of ncRNAs acting as drivers for each cancer subtype. The research outcomes will enable prediction of new patients’ cancer subtypes and contribute to the design of efficient treatment therapies.
Molecular Regulation Of Eosinophil Production: A Basis For Intervention In Inflammatory Disease
Funder
National Health and Medical Research Council
Funding Amount
$609,281.00
Summary
Eosinophils are rare blood cells that play a key role in the pathology of asthma and other inflammatory diseases. Asthma afflicts hundreds of millions of people worldwide, and excess eosinophils are common in many patients. We aim to define the cells involved in eosinophil development, and we will use cutting-edge technologies to identify new eosinophil regulators that may serve as drug targets or as novel entry points for development of therapeutics for asthma or other inflammatory diseases.