Using RNA interference to combat the worst emerging disease of wildlife. This project aims to develop a novel method of disease control in wildlife. It will use recent advances in RNA interference technology to knockdown virulence genes in an emerging pathogen that threatens biodiversity. Pathogens such as the amphibian chytrid fungus continue to cause widespread extinction and urgently require better control methods. RNA interference has been used to increase disease resistance to fungi in plan ....Using RNA interference to combat the worst emerging disease of wildlife. This project aims to develop a novel method of disease control in wildlife. It will use recent advances in RNA interference technology to knockdown virulence genes in an emerging pathogen that threatens biodiversity. Pathogens such as the amphibian chytrid fungus continue to cause widespread extinction and urgently require better control methods. RNA interference has been used to increase disease resistance to fungi in plants but adapting this approach for animals will have wide relevance in combatting fungi and other pathogens. The specific outcomes of this method will be to increase survival rates in a broad range of frog species to improve the success of captive release programs worldwide and hence save frogs from extinction.Read moreRead less
Bacterial and host drivers of chlamydial blindness in koalas. Chlamydial infection of the eyes is a significant cause of disease and death in koalas, contributing to the ongoing decline of this native species. Little is known about what influences the outcome of these infections, challenging efforts to manage and control koala chlamydial blindness. This project aims to evaluate whether differences in the infecting Chlamydia pecorum strains or the koala immune response, are associated with the ou ....Bacterial and host drivers of chlamydial blindness in koalas. Chlamydial infection of the eyes is a significant cause of disease and death in koalas, contributing to the ongoing decline of this native species. Little is known about what influences the outcome of these infections, challenging efforts to manage and control koala chlamydial blindness. This project aims to evaluate whether differences in the infecting Chlamydia pecorum strains or the koala immune response, are associated with the outcome of chlamydial ocular infection. In addition to helping us to understand and prevent blindness in koalas, this project should significantly expand our knowledge of the koala immune system and generate an array of koala immunological assays, outcomes that may benefit all koala conservation efforts.Read moreRead less
Linking immunomodulation and latency in alphaherpesvirus infection. Herpesviruses cause major diseases in humans and all domestic animal species. Latency forms a significant part of the evolutionary success of herpesviruses, by enabling transmission of the virus throughout the lifetime of the host. Our work has shown that an alphaherpesvirus protein can divert the host’s immune response to become more antibody-mediated and less T cell-mediated. This study explores the consequences of this immune ....Linking immunomodulation and latency in alphaherpesvirus infection. Herpesviruses cause major diseases in humans and all domestic animal species. Latency forms a significant part of the evolutionary success of herpesviruses, by enabling transmission of the virus throughout the lifetime of the host. Our work has shown that an alphaherpesvirus protein can divert the host’s immune response to become more antibody-mediated and less T cell-mediated. This study explores the consequences of this immune diversion, and examines whether this reduced T cell response enables the development of latent infections. Disrupting the virus-host balance by alterations to this conserved viral protein will enable novel approaches to controlling these economically significant viruses.Read moreRead less
Host-tumour interplay in Tasmanian devils with devil facial tumour disease: can immune cells be harnessed for therapy? Tasmanian devils only exist naturally in Tasmania and Devil Facial Tumour Disease, an infectious cancer, could cause the extinction of the Tasmanian devil. This project will determine if Devil Facial Tumour Disease reduces the effectiveness of the devil's immune system and test if activated immune cells can protect against this disease.
Evaluating host-parasite interplay in individual tissues. The immune system of the host and the infecting parasite has coevolved into a sophisticated balance of power. This project will explore this balance using Schistosoma japonicum infection in sheep and determine immune mechanisms unleashed by the host in various tissues as well as the response of the parasite to these attacks.
Immunisation to protect against transmissible cancers in Tasmanian devils. This project aims to identify the immune escape mechanisms that the transmissible cancers, Devil Facial Tumour Disease (DFTD) use to avoid being killed by the immune system. Since the discovery of the second transmissible cancer (DFT2) mystery surrounds whether the devils immune system can respond to this cancer, hence this project will investigate the immune response to DFT2. The final aims are to develop a vaccine with ....Immunisation to protect against transmissible cancers in Tasmanian devils. This project aims to identify the immune escape mechanisms that the transmissible cancers, Devil Facial Tumour Disease (DFTD) use to avoid being killed by the immune system. Since the discovery of the second transmissible cancer (DFT2) mystery surrounds whether the devils immune system can respond to this cancer, hence this project will investigate the immune response to DFT2. The final aims are to develop a vaccine with the potential to protect healthy devils and cure devils with DFTD.Read moreRead less