Environmental metagenomics, metaproteomics and novel bioactives from microbial communities in Antarctic lakes. This program will derive an integrated understanding of microbial ecology which is essential for determining ways of preserving the health of the World's ecosystems. Through this, Australia will remain a world leader in Antarctic biology, strengthening Australia's reputation in technologically innovative scientific programs of global significance, training local scientists in cutting ed ....Environmental metagenomics, metaproteomics and novel bioactives from microbial communities in Antarctic lakes. This program will derive an integrated understanding of microbial ecology which is essential for determining ways of preserving the health of the World's ecosystems. Through this, Australia will remain a world leader in Antarctic biology, strengthening Australia's reputation in technologically innovative scientific programs of global significance, training local scientists in cutting edge genomic biology and fostering the interests of the international community in sciences ranging from microbial ecology to bioprospecting. Novel biodegradable enzymes will be developed to replace harsh chemicals providing environmentally friendly, cheaper and more effective agents for use in medical, biotechnological, industrial and biodefense applications.Read moreRead less
New Proteins from the Mobile Genome: Structure-Led Discovery. The project will provide full descriptions of proteins with the capacity to become mobilised, as well as providing a source of completely novel genes with commercial potential. The proteins and enzymes discovered, and the metabolic processes with which they are identified, will have applications in a wide range of Australian industries: agriculture, forestry, pollution control and pharmaceutical design. This work therefore offers op ....New Proteins from the Mobile Genome: Structure-Led Discovery. The project will provide full descriptions of proteins with the capacity to become mobilised, as well as providing a source of completely novel genes with commercial potential. The proteins and enzymes discovered, and the metabolic processes with which they are identified, will have applications in a wide range of Australian industries: agriculture, forestry, pollution control and pharmaceutical design. This work therefore offers opportunities for many future directions in biotechnology, an area of growing strength in Australia. Read moreRead less
Polyketides as the conserved basis for diverse marine toxin biosyntheses. Over the past three decades, the frequency and global distribution of harmful marine biotoxin events appears to have increased, and human poisonings have regularly occurred. This project will develop an understanding of the genetics and physiology of toxin-producing marine microorganisms in response to pollution and climatic change that is critical for the management of these species and for the risk assessment of contamin ....Polyketides as the conserved basis for diverse marine toxin biosyntheses. Over the past three decades, the frequency and global distribution of harmful marine biotoxin events appears to have increased, and human poisonings have regularly occurred. This project will develop an understanding of the genetics and physiology of toxin-producing marine microorganisms in response to pollution and climatic change that is critical for the management of these species and for the risk assessment of contaminated seafood. The direct outcomes of this work constitute an easier, more economical and ethical alternative to current toxicity testing. Further benefits of this research will also be tangible for the environmental, biosecurity, fisheries and pharmaceutical sectors of Australian community and industry.Read moreRead less
Characterisation of a powerful molecular motor, the FtsK DNA translocase. The FtsK protein is a fast and powerful molecular motor, a pump that can, and does, move an entire bacterial chromosome. This project will uncover the detail of the mechanism used by this motor to convert the cell's chemical energy source Adenosine Triphosphate (ATP) into movement of DNA; revealing the molecular detail of a fast and powerful motor.
Determinants of substrate preferences and environmental applications of the copper membrane monooxygenases. The project aims to improve sustainability of environmental problems related to methane emissions, nitrogen cycling and pollution. We are developing tools targeting microbial genes correlated to all these issues. Data from these tests provides the information needed for monitoring environmental health and development of sustainable solutions.
Novel ultraviolet radiation filters from extreme environments. This project aims to exploit uncultured microorganisms to produce and characterise novel ultraviolet radiation-filter biosynthesis pathways. Current ultraviolet radiation-filtering compounds are toxic and persistent. There is a need for biodegradable, ultraviolet radiation filters that are safe for use across a variety of health and industrial applications. Over millions of years, the damaging effect of ultraviolet radiation has exer ....Novel ultraviolet radiation filters from extreme environments. This project aims to exploit uncultured microorganisms to produce and characterise novel ultraviolet radiation-filter biosynthesis pathways. Current ultraviolet radiation-filtering compounds are toxic and persistent. There is a need for biodegradable, ultraviolet radiation filters that are safe for use across a variety of health and industrial applications. Over millions of years, the damaging effect of ultraviolet radiation has exerted selective pressure on organisms that has driven the evolutionary diversity of natural radiation-filtering compounds. This project expects to characterise and harness the microbial diversity of unique high ultraviolet radiation ecosystems via synthetic biology to produce industrially and pharmacologically useful ultraviolet radiation filters.Read moreRead less