Biochemical Analysis Of Akt 3-specific Signal Transduction
Funder
National Health and Medical Research Council
Funding Amount
$349,375.00
Summary
The Akt family of enzymes consists of 3 protein kinases (Akt 1,2 and 3) and has been shown to regulate many normal cellular processes such as cell proliferation, growth, survival and motility, as well as the growth of new blood vessels. All these processes are critical for cancers to grow. However, few studies have distinguished the roles of the individual family members. Our preliminary data revealed Akt3 is far more active than the other two forms. Furthermore, using our unique Akt3 specific a ....The Akt family of enzymes consists of 3 protein kinases (Akt 1,2 and 3) and has been shown to regulate many normal cellular processes such as cell proliferation, growth, survival and motility, as well as the growth of new blood vessels. All these processes are critical for cancers to grow. However, few studies have distinguished the roles of the individual family members. Our preliminary data revealed Akt3 is far more active than the other two forms. Furthermore, using our unique Akt3 specific antibody, we find Akt 3 protein and activity levels are high in rapidly proliferating ovarian cancer cell lines and in primary ovarian tumours. The aim of this proposal is to characterise the mode and role of signalling via Akt3, including the identification of targeted substrates and signaling pathways and the outcomes of Akt3 driven signaling on cellular properties. These studies will provide important clues to understanding how this family member functions in both health and disease. Elucidation of the basis of Akt3 dependent signalling will open the possibility for the development of drugs that interfere with Akt3 function (for example in high Akt 3 expressing tumours like those of the ovary). In the long term, extension of our profiling studies to other tumour types will give a novel insight into the extent of Akt3 de-regulation as a key mediator of cancer formation.Read moreRead less
Development of therapeutic agents that target carbonic anhydrase enzymes. This research will discover new chemical entities (compounds) that may lead to therapies for the treatment of cancer, glaucoma and malaria. The research underpins a mechanism to add value to our compounds before partnering with industry to transform the discoveries made here to deliverable therapies that could benefit the health of millions, thus offering a potentially high value contribution to the Australian economy. The ....Development of therapeutic agents that target carbonic anhydrase enzymes. This research will discover new chemical entities (compounds) that may lead to therapies for the treatment of cancer, glaucoma and malaria. The research underpins a mechanism to add value to our compounds before partnering with industry to transform the discoveries made here to deliverable therapies that could benefit the health of millions, thus offering a potentially high value contribution to the Australian economy. The experience and commitment of the multi-disciplinary network of researchers offers exceptional training and employment opportunities for tomorrow's scientists in techniques for discovery and characterisation of novel chemicals, and their interaction with disease targets.Read moreRead less
Chemical inhibition: a new approach to investigate the role of a key protease, CtHtrA, from Chlamydia trachomatis. Infertility in women frequently results from infection with Chlamydia trachomatis. This project will develop an inhibitor compound against a important protein from this bacteria. This will establish a new scientific approach to study Chlamydia trachomatis. This project will also contribute to the development of new treatments for infertility.
Australian Laureate Fellowships - Grant ID: FL0992138
Funder
Australian Research Council
Funding Amount
$3,100,000.00
Summary
Towards antibacterials without resistance. Innovative automation technologies will be used to create and investigate a revolutionary new approach to disable pathogenic superbugs, bacteria resistant to multiple antibiotics. The chemicals created and proteins evaluated in this research program will advance fundamental knowledge about the molecular weapons that bacteria produce to cause disease; deliver social and economic benefits to Australia through the development of potential new antibacterial ....Towards antibacterials without resistance. Innovative automation technologies will be used to create and investigate a revolutionary new approach to disable pathogenic superbugs, bacteria resistant to multiple antibiotics. The chemicals created and proteins evaluated in this research program will advance fundamental knowledge about the molecular weapons that bacteria produce to cause disease; deliver social and economic benefits to Australia through the development of potential new antibacterial treatments; contribute to Australia's continued international leading role in drug discovery research; enhance international links and attract industry investment in Australia; and provide a stimulating research training environment to inspire and motivate the next generation of scientists.Read moreRead less
Special Research Initiatives - Grant ID: SR0354892
Funder
Australian Research Council
Funding Amount
$40,000.00
Summary
The Australian Protease Network. Proteases are pivotal enzymes during birth, life, ageing and death of all organisms. Proteases regulate most physiological processes by controlling protein activation, synthesis and turnover and are essential for replication and spread of viruses, bacteria and parasites that cause infectious diseases. Blockbuster drugs and diagnostics already target a few proteases. Australians have made innovative contributions individually to understanding and regulating these ....The Australian Protease Network. Proteases are pivotal enzymes during birth, life, ageing and death of all organisms. Proteases regulate most physiological processes by controlling protein activation, synthesis and turnover and are essential for replication and spread of viruses, bacteria and parasites that cause infectious diseases. Blockbuster drugs and diagnostics already target a few proteases. Australians have made innovative contributions individually to understanding and regulating these enzymes. However this initiative aims to network their efforts by value-adding to the current protease research through promoting national and international collaborations to improve our understanding of biology, and encourage exploitation of proteases/inhibitors/receptors for pharmaceutical and industrial applications.Read moreRead less
Structure-based inhibitor design of VAP-1/SSAO for the treatment of respiratory dirsorders and other major inflammatory diseases. Inflammatory diseases, such as asthma, rheumatoid arthritis and multiple sclerosis, are widespread and often poorly treated in Australia and elsewhere. Inhibitors of the recently studied VAP-1/SSAO protein are predicted to effectively treat the inflammation symptoms of one or more of these diseases. A structure-based approach to discover these new medicines should pro ....Structure-based inhibitor design of VAP-1/SSAO for the treatment of respiratory dirsorders and other major inflammatory diseases. Inflammatory diseases, such as asthma, rheumatoid arthritis and multiple sclerosis, are widespread and often poorly treated in Australia and elsewhere. Inhibitors of the recently studied VAP-1/SSAO protein are predicted to effectively treat the inflammation symptoms of one or more of these diseases. A structure-based approach to discover these new medicines should provide a means to identify patentable compounds, with high potency, efficacy and safety. If this approach is successful, an Australian pharmaceutical company will be one of the first to the market with this new medicine to treat these chronic diseases.Read moreRead less
Enhancing the performance of existing industrial enzymes through the application of new chemical modification technology. Enzymes have many uses in industry, replacing undesirable chemicals which adversely effect human & animal health & the environment. Enzymes offer advantages in effectiveness, biodegradability, specificity and safety. The concern with enzymes, in industrial applications, is that enzyme performance is degraded by a harsh chemical and/or physical environment. The aim of this stu ....Enhancing the performance of existing industrial enzymes through the application of new chemical modification technology. Enzymes have many uses in industry, replacing undesirable chemicals which adversely effect human & animal health & the environment. Enzymes offer advantages in effectiveness, biodegradability, specificity and safety. The concern with enzymes, in industrial applications, is that enzyme performance is degraded by a harsh chemical and/or physical environment. The aim of this study is to improve the performance of industrially significant enzymes by enhancing resistance to chemical & physical degradation or inactivation. This will be achieved by modifying the enzymes using new technology that we have developed. This will improve cost effectiveness of existing industrial enzymes & create opportunities for new uses of enzymes.Read moreRead less
Biosynthetic LEGO: enzymatic redesign to produce new vancomycin analogues. This project aims to uncover the reengineering potential of the biosynthetic machinery that produces glycopeptide antibiotics by advancing our understanding of how the core peptide production line functions. Natural product biosynthesis often produces complex peptide structures, with one important example being the glycopeptide antibiotics. This project expects to generate new knowledge about enzymatic peptide biosynthesi ....Biosynthetic LEGO: enzymatic redesign to produce new vancomycin analogues. This project aims to uncover the reengineering potential of the biosynthetic machinery that produces glycopeptide antibiotics by advancing our understanding of how the core peptide production line functions. Natural product biosynthesis often produces complex peptide structures, with one important example being the glycopeptide antibiotics. This project expects to generate new knowledge about enzymatic peptide biosynthesis using a highly interdisciplinary approach and previously developed tools. The anticipated outcomes of this project will be an enhanced understanding of how such complex peptide biosynthesis is performed, which is knowledge vital for future efforts to reengineer such biosynthetic peptide assembly lines as a series of modular LEGO blocks to produce new bioactive peptides.Read moreRead less
Defining peptide structure and function: the shape of things to come. In this project we develop new and general ways of chemically defining the structure and function of natural peptides. This then provides a basis of potential therapies to treat a number of diseases currently confronting Australia's aging population, for example, cataract, Alzheimer's disease, cancer, and cardiovascular disease.