Biomimetic Synthesis of Dimeric Natural Products. The aim of this research is to use nature as a source of inspiration and direction to improve and develop synthetic organic chemistry. Through targeted total syntheses this project will investigate and learn about the highly sophisticated way nature utilises dimerizations to rapidly generate molecular complexity. This project will demonstrate the power of this biomimetic strategy by synthesising a wide variety of complex dimeric natural products ....Biomimetic Synthesis of Dimeric Natural Products. The aim of this research is to use nature as a source of inspiration and direction to improve and develop synthetic organic chemistry. Through targeted total syntheses this project will investigate and learn about the highly sophisticated way nature utilises dimerizations to rapidly generate molecular complexity. This project will demonstrate the power of this biomimetic strategy by synthesising a wide variety of complex dimeric natural products including phenylethanoids, alkaloids, lignans, terpenes and coumarins. The expected outcome will be uniquely efficient synthetic strategies that significantly surpass all previous approaches and new synthetic methodology that will be of broad use in organic synthesis.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120102113
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Total synthesis inspired by nature. This project aims to improve and develop the way in which we make organic substances; our medicines, agrochemicals, and designed materials. This will be achieved through biomimetics; which harnesses the power of evolution by mimicking how nature synthesises organic compounds.
Discovery Early Career Researcher Award - Grant ID: DE130101350
Funder
Australian Research Council
Funding Amount
$373,038.00
Summary
A synthetic biology approach for mining the secondary metabolomes of fungal phytopathogens. Synthetic biology approaches will be employed to identify the secondary metabolites produced by the two important wheat pathogens, Stagonospora nodorum and Mycosphaerella graminicola. This will lead to the discovery of novel chemicals and facilitate our understanding of the roles of secondary metabolites in wheat diseases.
New Protocols for the Chemical Synthesis of Biologically Relevant Systems. Enzyme- and metal-catalysed processes will be developed and exploited for the purpose of establishing concise syntheses of biologically active and otherwise inaccessible natural products and their analogues. The range of structures to be targeted is structurally diverse and these have the potential to act as agrochemicals and/or as therapeutic agents for the treatment of a range of disease states in mammals including bact ....New Protocols for the Chemical Synthesis of Biologically Relevant Systems. Enzyme- and metal-catalysed processes will be developed and exploited for the purpose of establishing concise syntheses of biologically active and otherwise inaccessible natural products and their analogues. The range of structures to be targeted is structurally diverse and these have the potential to act as agrochemicals and/or as therapeutic agents for the treatment of a range of disease states in mammals including bacterial and viral infections, neuro-degenerative conditions and impaired cognitive function. Anti-angiogenic compounds that control otherwise unregulated cellular growth may also arise from these studies. The generation of new, homochiral metabolites for use in chemoenzymatic synthesis should also emerge from this project.Read moreRead less
Harnessing strain for chemical synthesis: The cyclopropane angle. This project aims to develop new reaction pathways of cyclopropanes, the smallest and most strained monocyclic ring systems, but which are also stable and easily prepared. Cyclopropanes have unique capacities to serve as highly effective building blocks in the synthesis of a wide range of otherwise difficult to access and biologically active molecular frameworks. This project will use cyclopropanes to rapidly assemble biologically ....Harnessing strain for chemical synthesis: The cyclopropane angle. This project aims to develop new reaction pathways of cyclopropanes, the smallest and most strained monocyclic ring systems, but which are also stable and easily prepared. Cyclopropanes have unique capacities to serve as highly effective building blocks in the synthesis of a wide range of otherwise difficult to access and biologically active molecular frameworks. This project will use cyclopropanes to rapidly assemble biologically active systems, especially pharmaceutically or agrochemically valuable natural products and relevant analogues.Read moreRead less
Enabling Methodologies for the Synthesis of Biologically Active Compounds. This project seeks to establish flexible methods of chemical synthesis for creating new molecular scaffolds capable of achieving selective enzyme inhibition. The approach aims to exploit the vast and biologically-programmed structural diversity associated with natural products. Unique, small molecule organic compounds will be obtained that reveal details of the operation of key enzymes in bacterial and mammalian systems. ....Enabling Methodologies for the Synthesis of Biologically Active Compounds. This project seeks to establish flexible methods of chemical synthesis for creating new molecular scaffolds capable of achieving selective enzyme inhibition. The approach aims to exploit the vast and biologically-programmed structural diversity associated with natural products. Unique, small molecule organic compounds will be obtained that reveal details of the operation of key enzymes in bacterial and mammalian systems. Such new knowledge would allow for the design of highly selective therapeutic agents relevant to the treatment of a range of diseases including bacterial infections, diabetes and cancer. The high-end scientific training and privileged forms of matter arising from this work would provide major benefit to the biotech sector.Read moreRead less
Chemically re-engineering bioactive natural products using fragment based drug design. Current drug and agrichemical discovery technologies are under immense pressure to meet the future pharmaceutical and agriculture demand created by population growth. This project will develop a novel technology concept that re-engineers the chemical features of bioactive natural products optimising medicine and agrichemical discovery.
Generation and exploitation of novel fermentation products in the synthesis of biologically active organic compounds with therapeutic potential. Collections of new micro-organisms and their metabolites suitable for use in the synthesis of potential therapeutic agents will be established. The combined application of molecular biological, microbiological and chemical synthesis techniques in a concerted manner in the one location will lead to major new opportunities for Australian industry.
Synthesis and Biological Evaluation of Australian Sponge Metabolites. The development of concise and flexible syntheses of Australian marine natural products and analogues of ecological/therapeutic significance will emerge. Such activities will lead to the identification and evaluation of molecular entities of value in managing marine environments and help to enhance chemical synthesis capacity in Australia.