Characterising post-translational modifications in bacterial proteins. This project represents the first global attempt to characterize post-translational modifications in bacterial proteins using the tools of proteomics. Modifications to proteins are key elements in altering their function. In bacteria, modifications are important in cell-cell adhesion, signalling and triggering of the immune response. Characterisation of modified proteins and their sites of modification represents an opportuni ....Characterising post-translational modifications in bacterial proteins. This project represents the first global attempt to characterize post-translational modifications in bacterial proteins using the tools of proteomics. Modifications to proteins are key elements in altering their function. In bacteria, modifications are important in cell-cell adhesion, signalling and triggering of the immune response. Characterisation of modified proteins and their sites of modification represents an opportunity to understand how bacterial cell populations communicate in the environment, as well as aid in understanding pathogenesis in medical, veterinary and food-borne pathogens. Therefore, improved vaccine targets and therapeutics, as well as method-based products, may be generated by this project.Read moreRead less
Chemical synthesis of cancer-associated glycoproteins. Glycosylation of proteins is an extremely common event which plays an important role in a variety of biological processes. Aberrant glycosylation and over-production of glycoproteins is associated with numerous cancer types (including breast, prostate, ovarian and small lung) and are recognised as promising agents for disease diagnosis and vaccine development. A range of cancer-associated glycoproteins will be synthesised in this research p ....Chemical synthesis of cancer-associated glycoproteins. Glycosylation of proteins is an extremely common event which plays an important role in a variety of biological processes. Aberrant glycosylation and over-production of glycoproteins is associated with numerous cancer types (including breast, prostate, ovarian and small lung) and are recognised as promising agents for disease diagnosis and vaccine development. A range of cancer-associated glycoproteins will be synthesised in this research program using a number of novel chemical technologies. These glycoproteins will be used to develop cancer vaccines and diagnostics. Cancer is a severe burden on the Australian community and on the economy, therefore this research will be of significant benefit to Australia.Read moreRead less
Functional Genomics and Host Cell Specificity of Herpesviruses. Herpesviruses cause severe diseases in many species, but research on their large DNA genomes has been difficult due to the need to use animal cell cultures for the generation of virus mutants. The cloning of complete herpesvirus genomes as Bacterial Artificial Chromosomes (BACs) has revolutionized herpesvirus genomics, and it is now possible to examine herpesvirus gene functions in unprecedented detail using elegant new mutation tec ....Functional Genomics and Host Cell Specificity of Herpesviruses. Herpesviruses cause severe diseases in many species, but research on their large DNA genomes has been difficult due to the need to use animal cell cultures for the generation of virus mutants. The cloning of complete herpesvirus genomes as Bacterial Artificial Chromosomes (BACs) has revolutionized herpesvirus genomics, and it is now possible to examine herpesvirus gene functions in unprecedented detail using elegant new mutation techniques. The project, based on two related equine herpesviruses, will identify new targets for antiviral drugs or vaccines. These herpesvirus BAC systems represent frontier science that greatly facilitates the study of links between genome and phenome.Read moreRead less
Functional and structural diversity of the cathepsin L peptidase from the human blood fluke Schistosoma mansoni. Peptidases are enzymes that are important in many infectious and physiological disease states. For example, they are used by infectious pathogens to enter human tissues and survive inside their bodies. The same type of enzymes also contribute to tissue damage in many pathological processes in humans such as cancer, arithritis and osteoporosis. There is an urgent need to define their s ....Functional and structural diversity of the cathepsin L peptidase from the human blood fluke Schistosoma mansoni. Peptidases are enzymes that are important in many infectious and physiological disease states. For example, they are used by infectious pathogens to enter human tissues and survive inside their bodies. The same type of enzymes also contribute to tissue damage in many pathological processes in humans such as cancer, arithritis and osteoporosis. There is an urgent need to define their structure and properties so that we can employ rational approaches to develop new drugs that can combat these diseases and ailments. Read moreRead less
Understanding the dynamics of T cell responses to chronic infection. The health, social, and economic impact of chronic infections on the Australian and global populations is enormous. A major obstacle to the development of vaccines against chronic infections is that we have a poor understanding of immune responses to persistent infections. We aim to use bioinformatics and mathematical modelling to understand immune responses to persistent viruses so that we can improve the long-term immune cont ....Understanding the dynamics of T cell responses to chronic infection. The health, social, and economic impact of chronic infections on the Australian and global populations is enormous. A major obstacle to the development of vaccines against chronic infections is that we have a poor understanding of immune responses to persistent infections. We aim to use bioinformatics and mathematical modelling to understand immune responses to persistent viruses so that we can improve the long-term immune control of chronic viral infections such as the human immunodeficiency virus (HIV). This project will strengthen Australian research in the area of interdisciplinary approaches to immunology, which is becoming crucial to interpreting the rapidly increasing volume of data obtained using advanced experimental techniques.Read moreRead less
Aminopeptidases involved in regulating the amino acid pool in malaria parasites. Aminopeptidases are pivotal to the normal functions of all cells. Abnormalities in their function and/or structure results in tissue damage in many pathological processes in humans such as cancer, neuronal diseases and hormonal action. They are also critical to viral, bacterial and parasitic infections as they are employed to remove amino acids from the host for use in building their own proteins. This project bring ....Aminopeptidases involved in regulating the amino acid pool in malaria parasites. Aminopeptidases are pivotal to the normal functions of all cells. Abnormalities in their function and/or structure results in tissue damage in many pathological processes in humans such as cancer, neuronal diseases and hormonal action. They are also critical to viral, bacterial and parasitic infections as they are employed to remove amino acids from the host for use in building their own proteins. This project brings national and international expertise together to define the structure and biological properties of these essential enzymes so that in the future we can employ rational approaches to develop new drugs that can combat these diseases and ailments.Read moreRead less
Understanding the T cell repertoire in health and disease. Immune recognition of viruses usually involves a large number of different 'killer T cells' that kill cells infected by virus. However, during prolonged infection or in the elderly the number of different killer T cells that recognise the virus is greatly reduced. This reduction in the diversity of the immune response allows the virus to avoid immune recognition, and leads to more severe infection. We aim to understand how diversity is ....Understanding the T cell repertoire in health and disease. Immune recognition of viruses usually involves a large number of different 'killer T cells' that kill cells infected by virus. However, during prolonged infection or in the elderly the number of different killer T cells that recognise the virus is greatly reduced. This reduction in the diversity of the immune response allows the virus to avoid immune recognition, and leads to more severe infection. We aim to understand how diversity is generated in the immune response, and how it becomes narrowed with age or prolonged infection. This information can be used to design vaccines for persistent infections such as HIV, and to improve immune control of infection in the elderly.Read moreRead less
Mechanisms of chronic infection, immunotolerance and coevolution in avian circovirus infections. This project will generate fundamental new knowledge into the pathogenesis of persistent, chronic viral diseases in a wide range of animal hosts. Furthermore, beak and feather disease virus is listed as a Key Threatening Process under the Endangered Species Protection Act (1992) to at least sixteen endangered Australian bird species. Very little is known about the host-virus interactions that occur d ....Mechanisms of chronic infection, immunotolerance and coevolution in avian circovirus infections. This project will generate fundamental new knowledge into the pathogenesis of persistent, chronic viral diseases in a wide range of animal hosts. Furthermore, beak and feather disease virus is listed as a Key Threatening Process under the Endangered Species Protection Act (1992) to at least sixteen endangered Australian bird species. Very little is known about the host-virus interactions that occur during the early stages of infection or why some birds recover yet others develop full blown disease. This project will provide new knowledge that can be used to counteract its effects on current and future endangered species recovery program.Read moreRead less
The dynamics of viral latency in chronic infection. Although many acute infections can now be controlled, we still suffer from a large number of chronic infections such as HIV or herpes that cannot be eradicated. Many of these infections persist because they can lie dormant in a 'latent' state. How this latent state is established, and how long it lasts are important to understand if we want to control these infections. We have assembled a team of mathematicians, immunologists and virologists in ....The dynamics of viral latency in chronic infection. Although many acute infections can now be controlled, we still suffer from a large number of chronic infections such as HIV or herpes that cannot be eradicated. Many of these infections persist because they can lie dormant in a 'latent' state. How this latent state is established, and how long it lasts are important to understand if we want to control these infections. We have assembled a team of mathematicians, immunologists and virologists in order to study latent infection at the cellular level, and within infected monkeys. This will provide the first insights into the dynamics of latency - how these cells are produced and die - and should lead to novel approaches to controlling chronic infection.Read moreRead less
Innovative green technology for bio-particle engineering. Approximately 40% of new pharmaceuticals are poorly soluble in bodily fluids. In many cases this leads to poor bioavailability, and consequent undesirable side effects as a result of high compensating dosages and generally poor patient compliance. These issues will be addressed by developing a green technology for the re-engineering of pharmaceuticals with the objective of increasing bioavilability. The research programme falls within th ....Innovative green technology for bio-particle engineering. Approximately 40% of new pharmaceuticals are poorly soluble in bodily fluids. In many cases this leads to poor bioavailability, and consequent undesirable side effects as a result of high compensating dosages and generally poor patient compliance. These issues will be addressed by developing a green technology for the re-engineering of pharmaceuticals with the objective of increasing bioavilability. The research programme falls within the Designated Research Priority of Frontier Technologies for Building and Transforming Australian Industries. Read moreRead less