Devil Facial Tumour Disease: Cytogenetic Clues to Transmission and Development. Devil Facial Tumour Disease is a fatal cancer that is decimating Tasmanian devils. Preliminary work suggests that tumours from different animals have identical sets of highly abnormal chromosomes, including a giant marker chromosome. We will use DNA probes to 'paint' abnormal tumour chromosomes to discover markers for diagnosis, and identify genes contributing to tumour development and immune suppression. Most import ....Devil Facial Tumour Disease: Cytogenetic Clues to Transmission and Development. Devil Facial Tumour Disease is a fatal cancer that is decimating Tasmanian devils. Preliminary work suggests that tumours from different animals have identical sets of highly abnormal chromosomes, including a giant marker chromosome. We will use DNA probes to 'paint' abnormal tumour chromosomes to discover markers for diagnosis, and identify genes contributing to tumour development and immune suppression. Most importantly, we will test our hypothesis that tumours all arose from a single ancestral cancer cell that is transmitted between animals. A cellular transmission has frightening implications for spread of disease, but will allow us to develop appropriate therapeutic strategies to save a unique Australian marsupial from extinction.Read moreRead less
The functional characterisation of a novel immune response in plants. This project aims to identify the role of pathogenicity-related-1 proteins in plants and characterise a new disease resistance pathway. By focusing on the interaction between key plant and pathogen proteins, this proposal seeks to advance the understanding of how the pathogen causes disease. The expected outcomes from these advances include the generation of new tools to manage plant diseases whilst building strong internation ....The functional characterisation of a novel immune response in plants. This project aims to identify the role of pathogenicity-related-1 proteins in plants and characterise a new disease resistance pathway. By focusing on the interaction between key plant and pathogen proteins, this proposal seeks to advance the understanding of how the pathogen causes disease. The expected outcomes from these advances include the generation of new tools to manage plant diseases whilst building strong international collaborations. This project should provide significant benefits for generating new leads for plant disease management leading to enhanced food security.Read moreRead less
Characterisation of a novel disease immunity pathway in plants. This project aims to understand the mechanisms by which the novel signalling molecule, CAPE1, contributes to
plant immunity. Studies to date have confirmed that CAPE1 inhibits plant diseases but it is unknown how. This
project aims to provide a seminal advance to the field by elucidating how the peptide is generated, how it is
perceived by the plant and the processes by which peptide contributes to plant defence. The expected outcom ....Characterisation of a novel disease immunity pathway in plants. This project aims to understand the mechanisms by which the novel signalling molecule, CAPE1, contributes to
plant immunity. Studies to date have confirmed that CAPE1 inhibits plant diseases but it is unknown how. This
project aims to provide a seminal advance to the field by elucidating how the peptide is generated, how it is
perceived by the plant and the processes by which peptide contributes to plant defence. The expected outcomes
of this project will include a detailed characterisation of a novel plant defence pathway as well the education and
training of next generation of plant scientists. Achieving these outcomes would provide the basis for new
innovative disease management strategies through the manipulation of this novel pathway.Read moreRead less
Immunological mechanisms underlying the protective immune responses induced by botulinum oil adjuvanted vaccine. Botulism is recognised as an important bacterial pathogen in commercial beef cattle in Australia and around the world. Development of affective, well-researched vaccine against Clostridium botulinum is a high priority for the cattle industry. A novel oil adjuvanted vaccine (Singvac from Fort Dodge Pty Ltd) has advantage over conventional vaccines as it provides full protection follo ....Immunological mechanisms underlying the protective immune responses induced by botulinum oil adjuvanted vaccine. Botulism is recognised as an important bacterial pathogen in commercial beef cattle in Australia and around the world. Development of affective, well-researched vaccine against Clostridium botulinum is a high priority for the cattle industry. A novel oil adjuvanted vaccine (Singvac from Fort Dodge Pty Ltd) has advantage over conventional vaccines as it provides full protection following a single administration. The aims of this study are to investigate the immunological mechanisms underlying the protective response by this novel vaccine using bovine and murine models. This study will discover new control measures for botulism in Australia.Read moreRead less
Development of new tools for surveillance of chlamydial infections in sheep. This project aims to improve health in sheep and reduce on-farm losses for Australian producers, by developing new serological tests for chlamydial infections in sheep. These infections can result in significant on-farm losses and loss of trade in the live export industry. Currently, surveillance of chlamydial infections is hindered by outdated serological tools that are unreliable and difficult to interpret. The ser ....Development of new tools for surveillance of chlamydial infections in sheep. This project aims to improve health in sheep and reduce on-farm losses for Australian producers, by developing new serological tests for chlamydial infections in sheep. These infections can result in significant on-farm losses and loss of trade in the live export industry. Currently, surveillance of chlamydial infections is hindered by outdated serological tools that are unreliable and difficult to interpret. The serological tests to be developed aim to be species-specific tests to detect the most important chlamydial sheep pathogens. This in turn endeavours to improve domestic surveillance, reducing on-farm losses and costs, and improve market opportunities for Australian sheep exporters as well as informing veterinary populations on best practice treatment.Read moreRead less
Biotechnology applications in the veterinary pharmaceutical industry: Pharmacological manipulation of ovarian function in domestic animals. The purpose of this research is to develop a humane, simple, safe, effective means of sterilizing female domestic animals without the need for surgical intervention. This novel experimental strategy is to target the supply of dormant eggs in the ovaries of female mammals. Every female mammal is born with a finite supply of eggs in the ovarian cortex. These c ....Biotechnology applications in the veterinary pharmaceutical industry: Pharmacological manipulation of ovarian function in domestic animals. The purpose of this research is to develop a humane, simple, safe, effective means of sterilizing female domestic animals without the need for surgical intervention. This novel experimental strategy is to target the supply of dormant eggs in the ovaries of female mammals. Every female mammal is born with a finite supply of eggs in the ovarian cortex. These cells cannot divide and so when this store is exhausted, reproduction ceases. Our strategy is to develop pharmaceutical reagents that will destroy this dormant egg population, thereby rendering the animals instantaneously and irreversibly infertile.Read moreRead less
What role does wildlife play in emergency disease? The case of the feral pig. Wildlife populations have been responsible for many disease emergencies with economic and human health impacts, but our current understanding limits their management. This project focuses on the feral pig, an introduced wildlife species. It will develop an understanding of disease spread in feral pigs and from feral pigs to cattle. Using feral pig disease genetics, climate and environmental data, disease spread models ....What role does wildlife play in emergency disease? The case of the feral pig. Wildlife populations have been responsible for many disease emergencies with economic and human health impacts, but our current understanding limits their management. This project focuses on the feral pig, an introduced wildlife species. It will develop an understanding of disease spread in feral pigs and from feral pigs to cattle. Using feral pig disease genetics, climate and environmental data, disease spread models will be developed. These models will be used to better manage emergency disease outbreaks in feral pigs and other wildlife species. This project will deliver practical outcomes, such as the best method of discovering disease and the most effective methods to control emergency animal diseases in wildlife and domestic animals.Read moreRead less
Systemic gene silencing in Arabidopsis, and relevance to plant biology. Gene silencing is a highly conserved process in plants and animals. It is of fundamental importance to gene regulation, virus defence, genome response to environment, and genome evolution. Remarkably, when gene silencing is triggered in plants it can spread throughout the organism. The aim of this project is to define the mechanism of intercellular movement of gene silencing in plants, and its relevance to plant growth and d ....Systemic gene silencing in Arabidopsis, and relevance to plant biology. Gene silencing is a highly conserved process in plants and animals. It is of fundamental importance to gene regulation, virus defence, genome response to environment, and genome evolution. Remarkably, when gene silencing is triggered in plants it can spread throughout the organism. The aim of this project is to define the mechanism of intercellular movement of gene silencing in plants, and its relevance to plant growth and defence against pathogens. Expected outcomes include increased understanding of intercellular genetic signalling in plants and its role in plant growth and disease resistance. The findings may also shed new light on mechanisms of gene silencing in animals.Read moreRead less
Investigating a new paradigm for plant-pathogen interactions; Identification of host-selective toxin proteins in the wheat pathogen Stagonospora nodorum. Stagonospora nodorum is a fungus that causes leaf and glume blotch disease on wheat. This disease alone causes $55 million dollars in yield losses per annum. Traditional breeding methods have yielded crops that are only mildly resistant leaving control of the disease to be worryingly reliant on fungicides. This project aims to identify and char ....Investigating a new paradigm for plant-pathogen interactions; Identification of host-selective toxin proteins in the wheat pathogen Stagonospora nodorum. Stagonospora nodorum is a fungus that causes leaf and glume blotch disease on wheat. This disease alone causes $55 million dollars in yield losses per annum. Traditional breeding methods have yielded crops that are only mildly resistant leaving control of the disease to be worryingly reliant on fungicides. This project aims to identify and characterise proteins that the fungus secretes to cause disease on wheat. By identifying these proteins, it is anticipated that strategies, both traditional and modern, could be employed to enable better control of the disease. This in turn would help provide a long term and secure supply of wheat and wheat based products to the community.Read moreRead less
Proteome mapping of the model fungal plant pathogen Stagonospora nodorum using LC-LC-MS/MS. Stagonospora nodorum is a fungus that causes leaf and glume blotch disease on wheat. This disease alone causes $55 million dollars in yield losses per annum in Australia. This project aims to identify the proteins produced by Stagonospora nodorum through the development of a new proteomics technique. Two clear benefits to the community resulting from this project will emerge. The first will be the expert ....Proteome mapping of the model fungal plant pathogen Stagonospora nodorum using LC-LC-MS/MS. Stagonospora nodorum is a fungus that causes leaf and glume blotch disease on wheat. This disease alone causes $55 million dollars in yield losses per annum in Australia. This project aims to identify the proteins produced by Stagonospora nodorum through the development of a new proteomics technique. Two clear benefits to the community resulting from this project will emerge. The first will be the expert training of a student in proteomics, a skill that is keenly sought. Secondly, the identification of these pathogen proteins will lead to new strategies to better control the disease and secure the supply of wheat.Read moreRead less