Determining the impact of protozoan pathogens and strongyle worms on prime lamb production. This research will benefit wool and prime lamb industries nation-wide as sheep scouring is prevalent in high-rainfall areas across Australia. Data generated from the project will be used to educate farmers and reduce the financial burden of sheep scouring. This project will also enhance Australia's reputation in the disease management sector and will result in reduced risk to public health due to a better ....Determining the impact of protozoan pathogens and strongyle worms on prime lamb production. This research will benefit wool and prime lamb industries nation-wide as sheep scouring is prevalent in high-rainfall areas across Australia. Data generated from the project will be used to educate farmers and reduce the financial burden of sheep scouring. This project will also enhance Australia's reputation in the disease management sector and will result in reduced risk to public health due to a better understanding and management of zoonotic parasite and microbacterial contamination of carcasses and water catchments.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
Imperfect vaccination drives herpesvirus evolution through recombination. Vaccines are used to help control disease caused by herpesviruses in animals, but some vaccination programs may drive the evolution and spread of herpesviruses with increased fitness (transmissibility, replication and virulence) through recombination. This project aims to study an important avian herpesvirus (infectious laryngotracheitis virus) in the natural host (poultry) to gain fundamental knowledge of how vaccination ....Imperfect vaccination drives herpesvirus evolution through recombination. Vaccines are used to help control disease caused by herpesviruses in animals, but some vaccination programs may drive the evolution and spread of herpesviruses with increased fitness (transmissibility, replication and virulence) through recombination. This project aims to study an important avian herpesvirus (infectious laryngotracheitis virus) in the natural host (poultry) to gain fundamental knowledge of how vaccination programs influence the emergence of diverse recombinant viruses, and identify which types of vaccination programs are best at preventing the emergence of fitter and more virulent viruses. The results are expected to inform vaccination practices to allow more effective control of these viruses in poultry and other animals.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140100735
Funder
Australian Research Council
Funding Amount
$395,204.00
Summary
Understanding infectious laryngotracheitis virus recombination. This project will study the factors that lead to recombination between strains of infectious laryngotracheitis virus (ILTV) concomitant with increased virulence. In previous studies of ILTV, two new genotypes of virulent field strains were shown to be independent recombinants derived from distinct attenuated ILTV commercial vaccines. These strains became the dominant field viruses responsible for widespread and severe disease outbre ....Understanding infectious laryngotracheitis virus recombination. This project will study the factors that lead to recombination between strains of infectious laryngotracheitis virus (ILTV) concomitant with increased virulence. In previous studies of ILTV, two new genotypes of virulent field strains were shown to be independent recombinants derived from distinct attenuated ILTV commercial vaccines. These strains became the dominant field viruses responsible for widespread and severe disease outbreaks in Australian poultry flocks. This project will enhance understanding of the conditions that led to these deleterious natural recombination events and enable the industry to avoid the emergence of new virulent field strains in the future. Read moreRead less
Application of DNA vaccination to the control of gastrointestinal nematodes in livestock. Gastrointestinal nematode parasites inflict great losses in sheep and cattle and reliance on anthelmintic drugs for their control is problematic. Vaccination would provide a better alternative but has been difficult to achieve. This proposal aims to apply novel DNA vaccination strategies to the development of parasite vaccines through optimisation of DNA delivery, development of new vaccination vectors and ....Application of DNA vaccination to the control of gastrointestinal nematodes in livestock. Gastrointestinal nematode parasites inflict great losses in sheep and cattle and reliance on anthelmintic drugs for their control is problematic. Vaccination would provide a better alternative but has been difficult to achieve. This proposal aims to apply novel DNA vaccination strategies to the development of parasite vaccines through optimisation of DNA delivery, development of new vaccination vectors and modulation of immune responses by co-delivery of cytokine genes. The results of these studies will not only add a new approach to vaccine development against gastrointestinal parasites but will also contribute to our knowledge of DNA vaccination in large animals.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210101063
Funder
Australian Research Council
Funding Amount
$462,948.00
Summary
Bacterial cell invasion factors as vaccine targets. This project aims to determine the virulence factors responsible for cellular invasion and systemic spread of Mycoplasma bovis, and use genome editing technologies (CRISPR-Cas9) to create gene knock out mutants that cannot invade host cells and test their potential as vaccine candidates in animals. Mycoplasma bovis is an emerging cause of mastitis, the most important infectious disease in the dairy industry, and causes significant economic loss ....Bacterial cell invasion factors as vaccine targets. This project aims to determine the virulence factors responsible for cellular invasion and systemic spread of Mycoplasma bovis, and use genome editing technologies (CRISPR-Cas9) to create gene knock out mutants that cannot invade host cells and test their potential as vaccine candidates in animals. Mycoplasma bovis is an emerging cause of mastitis, the most important infectious disease in the dairy industry, and causes significant economic losses. The vaccine candidates developed in this project are expected to be used to control outbreaks of mastitis, and to improve biosecurity, production and animal welfare in the Australian and global dairy industries.Read moreRead less
Liver fluke: improving disease control through understanding of parasite diversity, drug resistance and better diagnosis. The benefits from this research include: (i) development of knowledge that will allow a better use of existing drug formulations to protect livestock from fasciolosis, potentially generating economic benefits to Australian producers of up to $50-80m/year; (ii) improved application of new commercial therapies for fasciolosis in ruminants, improving producer prosperity; (iii) ....Liver fluke: improving disease control through understanding of parasite diversity, drug resistance and better diagnosis. The benefits from this research include: (i) development of knowledge that will allow a better use of existing drug formulations to protect livestock from fasciolosis, potentially generating economic benefits to Australian producers of up to $50-80m/year; (ii) improved application of new commercial therapies for fasciolosis in ruminants, improving producer prosperity; (iii) enhanced training opportunities for graduate students that will build human capacity in technologies such as molecular diagnostics which have a wide application across the animal sectors; (iv) enhancement of our capacity to respond to unexpected future threats in production animals.Read moreRead less
Equine rhinitis A virus; molecular pathogenesis and methods for control. The horse industry in Australia is primarily based in rural locations and is a major contributor to the national economy both in terms of direct economic contribution to gross domestic product and as a major employer of people in regional Australia. The research proposed in this project will improve our understanding of the pathogenesis of a virus that causes respiratory disease in horses that is related to the virus that c ....Equine rhinitis A virus; molecular pathogenesis and methods for control. The horse industry in Australia is primarily based in rural locations and is a major contributor to the national economy both in terms of direct economic contribution to gross domestic product and as a major employer of people in regional Australia. The research proposed in this project will improve our understanding of the pathogenesis of a virus that causes respiratory disease in horses that is related to the virus that causes foot and mouth disease in ruminants and swine. The technology developed during this project would have a global market.Read moreRead less
Application of in vivo electroporation to DNA immunisation. The in vivo delivery of plasmid DNA induces immune responses to the encoded protein vaccine. In large animals including humans, DNA vaccination needs to be further improved before becoming a commercial reality, at least partially due to the very low levels of expression in vivo. In vivo electroporation has proven to be an effective way to enhance the level of protein expression and increase DNA vaccine efficacy. We combine enhanced in ....Application of in vivo electroporation to DNA immunisation. The in vivo delivery of plasmid DNA induces immune responses to the encoded protein vaccine. In large animals including humans, DNA vaccination needs to be further improved before becoming a commercial reality, at least partially due to the very low levels of expression in vivo. In vivo electroporation has proven to be an effective way to enhance the level of protein expression and increase DNA vaccine efficacy. We combine enhanced in vivo expression using electroporation with the co-delivery of plasmids encoding cytokines to enhance and modulate DNA vaccine in sheep. We will apply our findings to bovine viral diarrhoea virus (BVDV), both as an animal model for humans and as an economically important diseases of livestock.Read moreRead less
Role of Pasteurella surface polysaccharides in pathogenesis and immunity. Livestock infections cause major economic losses worldwide. The bacterium Pasteurella multocida causes multiple diseases in a range of livestock, including hemorrhagic septicaemia in cattle and fowl cholera in poultry. Two surface polysaccharide structures, capsule and lipopolysaccharide, are crucial for P. multocida to cause disease. Our data indicate that varying the amount/content of these structures also affects vaccin ....Role of Pasteurella surface polysaccharides in pathogenesis and immunity. Livestock infections cause major economic losses worldwide. The bacterium Pasteurella multocida causes multiple diseases in a range of livestock, including hemorrhagic septicaemia in cattle and fowl cholera in poultry. Two surface polysaccharide structures, capsule and lipopolysaccharide, are crucial for P. multocida to cause disease. Our data indicate that varying the amount/content of these structures also affects vaccine performance. This project aims to identify how the production of these P. multocida structures are controlled and if changes to these structures affect its ability to infect different animals/birds. Using this information, the project aims to develop state-of-the-art livestock vaccines with superior disease coverage.Read moreRead less