Specific gene inhibition through functional genomics and high through-put small molecule screening. This project will utilise functional genomic technologies in an attempt to identify genes in childhood neuroblastoma as potential candidates for the future development of molecular-targeted gene therapy. By screening large 'libraries' of chemical compounds, we aim to identify compounds with the ability to specifically inhibit these gene targets. This project will therefore define novel molecular t ....Specific gene inhibition through functional genomics and high through-put small molecule screening. This project will utilise functional genomic technologies in an attempt to identify genes in childhood neuroblastoma as potential candidates for the future development of molecular-targeted gene therapy. By screening large 'libraries' of chemical compounds, we aim to identify compounds with the ability to specifically inhibit these gene targets. This project will therefore define novel molecular targets and possibly facilitate the future development of new therapeutic approaches to treating neuroblastoma. In addition, the project will develop know-how that can be utilised by both the industry partner and the broader research community and will introduce to Australian science novel techniques and skills. Read moreRead less
Enhanced biocatalysis in organic solvents for pharmaceutical biotransformation. Enzymes such as hydrolases play an important role in biotechnology because of their extreme versatility with respect to substrate specificity and stereoselectivity. The use of lipases as catalysts for optical isomer-specific organic reactions is often limited by unacceptably low enantioselectivities. We will investigate recombinant enzymes cloned from thermophilic lipolytic bacteria for synthetic reactions in orga ....Enhanced biocatalysis in organic solvents for pharmaceutical biotransformation. Enzymes such as hydrolases play an important role in biotechnology because of their extreme versatility with respect to substrate specificity and stereoselectivity. The use of lipases as catalysts for optical isomer-specific organic reactions is often limited by unacceptably low enantioselectivities. We will investigate recombinant enzymes cloned from thermophilic lipolytic bacteria for synthetic reactions in organic solvents, especially chiral resolution of mixtures in the production of pharmaceutical intermediates. Genetic improvement of lipase enantiospecificity and regioselectivity will be achieved using in vitro evolution by recombination and screening. The outcome will be cost-effective production superior biocatalysts with specifically enhanced regiospecific, enantioselective and hydrolytic characteristics.
Read moreRead less
New Techniques for Structural Biology and Directed Molecular Evolution. This PhD program will equip an Australian graduate with advanced training in techniques in molecular genetics and protein chemistry that are currently in high demand by the biotechnology industry, and also provide him/her with direct experience of an industrial R&D laboratory environment. Moreover, it will establish a basis for further collaboration between a leading University-based research laboratory and an established R& ....New Techniques for Structural Biology and Directed Molecular Evolution. This PhD program will equip an Australian graduate with advanced training in techniques in molecular genetics and protein chemistry that are currently in high demand by the biotechnology industry, and also provide him/her with direct experience of an industrial R&D laboratory environment. Moreover, it will establish a basis for further collaboration between a leading University-based research laboratory and an established R&D company that will lead to development of new techniques for use in biotechnology in Australia and overseas.Read moreRead less