Dissecting The Host X Diet X Microbiota Interactions Supporting Sustainable Weight Loss In Obesity
Funder
National Health and Medical Research Council
Funding Amount
$252,305.00
Summary
There is increasing evidence that the gut microbiome plays an important part in predisposing to obesity. This project seeks to identify whether such an obesogenic microbiota may also influence our ability to maintain weight loss after a period of caloric restriction. Further, we investigate whether dietary fibre can be used to reshape gut microbial population structure and function so as to support sustained weight loss on return to a normal dietary regimen using an obesogenic rat model.
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.
Improving clostridial toxoid production through molecular fermentation maps. This project aims to improve vaccine production by generating detailed molecular maps of fermentation which will be used to design superior fermentation processes with reduced cost. Toxoid vaccines, used routinely in the livestock industry to prevent animal-disease caused by pathogenic Clostridia, are produced using batch fermentation processes. These processes have undergone limited optimisation over the past five deca ....Improving clostridial toxoid production through molecular fermentation maps. This project aims to improve vaccine production by generating detailed molecular maps of fermentation which will be used to design superior fermentation processes with reduced cost. Toxoid vaccines, used routinely in the livestock industry to prevent animal-disease caused by pathogenic Clostridia, are produced using batch fermentation processes. These processes have undergone limited optimisation over the past five decades. Low titres and frequent batch failures greatly affect capital use and represent a significant cost. In addition, current optimisation approaches are limited by the use of expensive and noisy endpoint assays. This project aims to use high-throughput chemistry (multi-omics) that overcome these limitations.Read moreRead less
Harnessing the 'omics revolution to investigate drug response and resistance mechanisms in Giardia duodenalis. This international research project will harness cutting-edge technologies to explore how Giardia, a major global cause of diarrhoeal illness in humans, responds to and becomes resistant to key anti-giardial drugs, providing valuable information for drug preservation and development.
Nucleolus targeting by negative strand RNA viruses. Negative strand viruses (NSVs) include diverse animal pathogens that represent significant threats to Australian livestock industries and access to export markets. The project aims to investigate the interface formed by NSVs with cellular nucleoli in order to determine roles in viral manipulation of cell biology during infection. This project hopes to address a major gap in knowledge in virology regarding the fundamental biology of NSVs, and is ....Nucleolus targeting by negative strand RNA viruses. Negative strand viruses (NSVs) include diverse animal pathogens that represent significant threats to Australian livestock industries and access to export markets. The project aims to investigate the interface formed by NSVs with cellular nucleoli in order to determine roles in viral manipulation of cell biology during infection. This project hopes to address a major gap in knowledge in virology regarding the fundamental biology of NSVs, and is expected to redefine our understanding of the virus-host interactions formed by these important pathogens. By determining the mechanisms of NSV-nucleolus interaction, the project plans to also provide important information for the development of new vaccines/therapeutics for livestock to combat NSVs that target nucleoli.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100965
Funder
Australian Research Council
Funding Amount
$444,582.00
Summary
Understanding nutritional interactions for targeted microbiome manipulation. This project aims to identify how microbial communities, known as microbiomes, can be effectively manipulated to the benefit of their host. Microbiome manipulation has been in the spotlight as a potential solution to maintain or improve the health of several hosts, from threatened coral species to livestock and humans, but the development of industry-scale strategies has been slow. This project proposes to chart the nut ....Understanding nutritional interactions for targeted microbiome manipulation. This project aims to identify how microbial communities, known as microbiomes, can be effectively manipulated to the benefit of their host. Microbiome manipulation has been in the spotlight as a potential solution to maintain or improve the health of several hosts, from threatened coral species to livestock and humans, but the development of industry-scale strategies has been slow. This project proposes to chart the nutritional interactions among microorganisms and to identify cascade effects of microbiome manipulation. This will generate fundamental knowledge on the biological processes underlying community stability and malleability, which will ultimately help engineering optimised microbiomes.Read moreRead less
Lifestyle choices: genomic analysis of niche adaptations in marine Synechococcus. Photosynthetic marine bacteria are very important in the global carbon cycle. This project aims to discover how these bacteria adapt to survive in different marine environments. This is important for understanding how they will be affected by climate change and other environmental alterations.
Discovery Early Career Researcher Award - Grant ID: DE120101549
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Creating a baker's yeast chassis cell via shikimate pathway engineering for production of sustainable, carbon-neutral plastic precursors for the future. From air bags to carpets, tyres and garden hoses, plastics shape our every day life. Coming from fossil fuels most are currently neither sustainable nor renewable. This project will engineer baker's yeast to produce plastic precursors from cane sugar in a fermentation process. This lays the basis for a sugar cane based chemical industry.
Sustainable dollar notes and other polypropylenes from bioderived feedstocks. Fossil fuels provide us with the essential chemicals for our life style. The chemical industry recognizes limited supply and a need to reduce carbon emissions. Microbes are able to supply green chemicals (e.g. bio-ethanol), but efficiencies are often low. This project will develop microbes for the fermentative production of plastics from cane sugar.
Developing an integrated systems and synthetic biology platform to expand the product spectrum of acetogens. This project aims to advance a waste gas fermentation process to enable the production of sustainable aviation fuel molecules for the first time. LanzaTech are world leaders in microbial gas fermentation and have produced ethanol at large scale in China. This project aims to combine the LanzaTech process with systems biology expertise at The University of Queensland to go beyond ethanol t ....Developing an integrated systems and synthetic biology platform to expand the product spectrum of acetogens. This project aims to advance a waste gas fermentation process to enable the production of sustainable aviation fuel molecules for the first time. LanzaTech are world leaders in microbial gas fermentation and have produced ethanol at large scale in China. This project aims to combine the LanzaTech process with systems biology expertise at The University of Queensland to go beyond ethanol to deliver new value-added products such as butanediol and farnesene. To achieve this aim the project will explore, understand and overcome fundamental energy and metabolic limitations in the production microorganism. Achieving the aims will be of direct relevance to SkyNRG and the new Brisbane Bioport on their path to deliver sustainable fuel to Brisbane Airport.Read moreRead less