Discovery Early Career Researcher Award - Grant ID: DE160100615
Funder
Australian Research Council
Funding Amount
$348,200.00
Summary
Harnessing chain-forming diatoms for improved lipid biofuel production. The aim of this project is to unlock the molecular secrets of highly productive chain-forming diatom microalgae that allow them to produce high levels of biofuel lipids. The formation of multicellular chains appears key to the success of some of the most widespread and productive diatom species. Through a combination of systems biology, bioinformatics, and genetics experiments, this project aims to investigate the relationsh ....Harnessing chain-forming diatoms for improved lipid biofuel production. The aim of this project is to unlock the molecular secrets of highly productive chain-forming diatom microalgae that allow them to produce high levels of biofuel lipids. The formation of multicellular chains appears key to the success of some of the most widespread and productive diatom species. Through a combination of systems biology, bioinformatics, and genetics experiments, this project aims to investigate the relationship between chain formation and biofuel lipid productivity in Chaetoceros diatoms, and to discover genes and molecules that encode and influence these traits. The knowledge and technology generated as a result may improve biofuel yields, increase the robustness of species growing in open pond systems, and reduce processing costs such as de-watering.Read moreRead less
Function and application of novel proteins from sponge symbionts. This project aims to determine the function of eukaryotic-like proteins (ELPs) from bacterial symbionts of sponges and apply this knowledge to develop new tools for biotechnology. This project will use innovative microscopy techniques and gene expression studies to define the molecular and cellular interactions of ELPs with sponges and how this is influenced by changing environmental conditions. ELPs will be further used to create ....Function and application of novel proteins from sponge symbionts. This project aims to determine the function of eukaryotic-like proteins (ELPs) from bacterial symbionts of sponges and apply this knowledge to develop new tools for biotechnology. This project will use innovative microscopy techniques and gene expression studies to define the molecular and cellular interactions of ELPs with sponges and how this is influenced by changing environmental conditions. ELPs will be further used to create new, artificial interactions between bacteria and eukaryotes. This project will provide fundamental knowledge on the evolution and function of newly discovered ELPs found in both beneficial and pathogenic bacteria and paves the way to control symbiosis for biotechnological applications.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE200100043
Funder
Australian Research Council
Funding Amount
$389,000.00
Summary
Rapid Molecular (Bio)material Imaging by Infrared and Raman Microscopies. This project aims to undertake fast probe-free biochemical/chemical imaging of heterogeneity within cells and materials surfaces with new infrared and Raman imaging. It will generate new fundamental knowledge on: cell heterogeneity and dynamic processes; technologies for optimising cell printing; understanding toxicity of microplastics; and protocols for measuring materials of technological relevance. Expected outcomes inc ....Rapid Molecular (Bio)material Imaging by Infrared and Raman Microscopies. This project aims to undertake fast probe-free biochemical/chemical imaging of heterogeneity within cells and materials surfaces with new infrared and Raman imaging. It will generate new fundamental knowledge on: cell heterogeneity and dynamic processes; technologies for optimising cell printing; understanding toxicity of microplastics; and protocols for measuring materials of technological relevance. Expected outcomes include: interdisciplinary collaborations in new protocols for in-vitro drug development; cell printing technologies; environmental impacts of microplastics; and materials design. Expected benefits include innovative approaches to early stage drug design; improved environmental controls and advances in innovative materials.Read moreRead less
Enhanced coral stress tolerance via manipulation of prokaryotic symbionts. The project aims to develop a novel approach to improve environmental stress tolerance in corals. Coral reefs are under threat from a range of stressors that have led to massive declines in coral cover and health worldwide. There is now great concern that the rate of environmental change is outpacing the natural capacity of corals to acclimatise, adapt and survive. Although it is important to address the root causes of cl ....Enhanced coral stress tolerance via manipulation of prokaryotic symbionts. The project aims to develop a novel approach to improve environmental stress tolerance in corals. Coral reefs are under threat from a range of stressors that have led to massive declines in coral cover and health worldwide. There is now great concern that the rate of environmental change is outpacing the natural capacity of corals to acclimatise, adapt and survive. Although it is important to address the root causes of climate change, a focus on strategies to mitigate its impacts is also required. This project explores the potential to augment the capacity of corals to tolerate stress through the manipulation of their associated prokaryotic communities. This project may result in novel coral reef restoration approaches.Read moreRead less
New photobioreactor to up-scale axenic cultures of microalgae. This project aims to deliver a scalable photo-bioreactor for the large scale axenic culture of microalgae to close the technology gap for research and development in the Australian algae biotechnology sector. Algae biotechnology is a rapidly emerging area, particularly in biofuel production. The project aims to test and demonstrate a photo-bioreactor for its applicability to produce sufficient algae biomass to study a low abundance p ....New photobioreactor to up-scale axenic cultures of microalgae. This project aims to deliver a scalable photo-bioreactor for the large scale axenic culture of microalgae to close the technology gap for research and development in the Australian algae biotechnology sector. Algae biotechnology is a rapidly emerging area, particularly in biofuel production. The project aims to test and demonstrate a photo-bioreactor for its applicability to produce sufficient algae biomass to study a low abundance photosynthetic protein complex to advance knowledge of coral bleaching.Read moreRead less