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
New analgesics based on µ-conotoxins: structure-based design of helical mimetics. Diseases in which voltage-gated sodium channels are implicated are contributors to morbidity and mortality in the Australian population, and this project promises to provide new leads for the future development of drugs to treat such diseases, in particular analgesics for the treatment of chronic pain. The generation of these leads will entail the development of new approaches to mimicking key regions of peptides a ....New analgesics based on µ-conotoxins: structure-based design of helical mimetics. Diseases in which voltage-gated sodium channels are implicated are contributors to morbidity and mortality in the Australian population, and this project promises to provide new leads for the future development of drugs to treat such diseases, in particular analgesics for the treatment of chronic pain. The generation of these leads will entail the development of new approaches to mimicking key regions of peptides and proteins in drug-like molecules. This is a highly interdisciplinary project, spanning structural biology, molecular design, medicinal chemistry, molecular biology and electrophysiology, and the training of PhD graduates with such broad experience represents another national benefit of the project.Read moreRead less
Intrinsically Unstructured Proteins (IUPs): NMR characterization, prediction, and application to malarial proteome. Determination of protein structures with longer DR by NMR will enrich the DR dataset and provide a deeper understanding of protein structure-function relationships and protein folding pathways. The proposal will also provide valuable information in the key applied area of target selection in structural biology. Not all current web services are freely accessible and available servi ....Intrinsically Unstructured Proteins (IUPs): NMR characterization, prediction, and application to malarial proteome. Determination of protein structures with longer DR by NMR will enrich the DR dataset and provide a deeper understanding of protein structure-function relationships and protein folding pathways. The proposal will also provide valuable information in the key applied area of target selection in structural biology. Not all current web services are freely accessible and available services can be improved further by using more reliable training dataset or more effective algorithms, development of a national DR predictor will help Australian structural biologists increase the success rate of structure determination and provide greater insight into a range of proteomes.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
Modulation of cellular metabolism by protein and peptide peroxides. Oxidation of peptides and proteins by a wide range of reactive radicals and other oxidants, in the presence of oxygen, generates protein peroxides. These species are now recognised to be key intermediates in both the deterioration of foods (e.g. development of rancidity and off-flavours, changes in colour and texture) and a number of human diseases, including cancer, heart disease and ageing. How these peroxides cause biological ....Modulation of cellular metabolism by protein and peptide peroxides. Oxidation of peptides and proteins by a wide range of reactive radicals and other oxidants, in the presence of oxygen, generates protein peroxides. These species are now recognised to be key intermediates in both the deterioration of foods (e.g. development of rancidity and off-flavours, changes in colour and texture) and a number of human diseases, including cancer, heart disease and ageing. How these peroxides cause biological perturbations is poorly understood. The proposed studies will provide valuable information as to how these peroxides affect cellular metabolism and provide key leads as to strategies which may prevent such damage.Read moreRead less
Mechanistic studies on the oxidation of amino acids, peptides and proteins and its biological consequences. Exposure of amino acids and proteins to radicals, oxidants, UV light, and metal ions results in oxidation, with consequent alteration to protein structure and function. It has been shown that these reactions occur during food spoilage, exposure of plants to excess UV light, and in a number of human diseases (e.g. heart disease and cancer). Despite evidence for a key role for protein oxidat ....Mechanistic studies on the oxidation of amino acids, peptides and proteins and its biological consequences. Exposure of amino acids and proteins to radicals, oxidants, UV light, and metal ions results in oxidation, with consequent alteration to protein structure and function. It has been shown that these reactions occur during food spoilage, exposure of plants to excess UV light, and in a number of human diseases (e.g. heart disease and cancer). Despite evidence for a key role for protein oxidation in these events, the fundamental chemistry and biochemistry of protein oxidation is incompletely understood. This is addressed in this project. Knowledge of the mechanisms of these reactions is a vital pre-requisite to the rational design of preventative strategies that might enhance food quality, minimise UV damage and enhance human health.Read moreRead less
Protein And Peptide Alpha Turns. All life is controlled by the structures and functions of proteins. Major components of proteins are alpha helices that are combinations of alpha turns. Different types of alpha turns exist in proteins but have not been well studied. This project will discover and classify alpha turns in proteins, create the first small molecules that contain alpha turns outside of complex protein environments, and provide a better understanding of their chemical, structural and ....Protein And Peptide Alpha Turns. All life is controlled by the structures and functions of proteins. Major components of proteins are alpha helices that are combinations of alpha turns. Different types of alpha turns exist in proteins but have not been well studied. This project will discover and classify alpha turns in proteins, create the first small molecules that contain alpha turns outside of complex protein environments, and provide a better understanding of their chemical, structural and biological properties. Results will teach scientists important details about protein structure and function, train scientists at a frontier of chemistry-biology research, and may contribute to national priorities by triggering new approaches to medicines and novel materials.Read moreRead less
Membrane structure and lipid interactions of the pore-forming toxin Equinatoxin II by NMR. The structure of Equinatoxin II, a pore-forming protein, will be determined in model cell membranes using solid-state NMR spectroscopy. The relationship of molecular structure to bioactivity and the nature of the pore-forming mechanism of this toxin will be determined. The results will aid in understanding how toxins lyse cells and could lead to the design of improved antibiotic peptides. Currently the st ....Membrane structure and lipid interactions of the pore-forming toxin Equinatoxin II by NMR. The structure of Equinatoxin II, a pore-forming protein, will be determined in model cell membranes using solid-state NMR spectroscopy. The relationship of molecular structure to bioactivity and the nature of the pore-forming mechanism of this toxin will be determined. The results will aid in understanding how toxins lyse cells and could lead to the design of improved antibiotic peptides. Currently the structure of membrane proteins are difficult to determine and the newly developed techniques used for the structural determination of this membrane-associated protein will be suitable for studying other membrane proteins and receptors of pharmaceutical importance.Read moreRead less
Nucleotides for bioelectronics. Bioelectronics is a key component of nanobiotechnology, a new field that merges the science of biological molecules (DNA, proteins etc.) with electronics and semiconductor physics. We have recently introduced redox-labelled nucleotides that enable the production of electrochemically-active DNA and RNA for genetic, forensic and nanotechnology applications. This project further develops redox nucleotides for use in electronic devices.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0346895
Funder
Australian Research Council
Funding Amount
$450,000.00
Summary
A Mass Directed Molecular Resolution Laboratory. The proposed "Mass Directed Molecular Resolution Laboratory" combines an integrated suite of instrumentation housed in purpose built laboratories with technical expertise to provide an unique "one stop shop" to meet the burgeoning mass spectrometry needs of the chemical community in the Melbourne area. This truly collaborative effort will service the needs of 17 research groups with 92 PhD students and post doctoral researchers and will enhance ex ....A Mass Directed Molecular Resolution Laboratory. The proposed "Mass Directed Molecular Resolution Laboratory" combines an integrated suite of instrumentation housed in purpose built laboratories with technical expertise to provide an unique "one stop shop" to meet the burgeoning mass spectrometry needs of the chemical community in the Melbourne area. This truly collaborative effort will service the needs of 17 research groups with 92 PhD students and post doctoral researchers and will enhance existing excellence in a range of areas. Finally, the laboratory will provide opportunities to: collaborate and consult with industry; train postgraduate students in instrumentation used at the cutting edge of chemical and biochemical sciences.Read moreRead less