Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347223
Funder
Australian Research Council
Funding Amount
$100,000.00
Summary
Quantitative PCR facility for New England region of NSW. The project will deliver the first real-time PCR facility in the New England Region of NSW for use by University, CSIRO and Industry scientists. The facility will be based at the University of New England and be used by animal scientists, molecular biologists, parasitologists, immunologists and botanists at these institutions, in many cases in collaborative research projects. It will also support the training of seven PhD students and a po ....Quantitative PCR facility for New England region of NSW. The project will deliver the first real-time PCR facility in the New England Region of NSW for use by University, CSIRO and Industry scientists. The facility will be based at the University of New England and be used by animal scientists, molecular biologists, parasitologists, immunologists and botanists at these institutions, in many cases in collaborative research projects. It will also support the training of seven PhD students and a post-doctoral fellow. The facility will be unique to the region and will remove our current need to use facilities in Brisbane or Sydney.Read moreRead less
Development of a live vaccine for gut health in poultry. Development of a live vaccine for gut health in poultry. The project aims to develop a live vaccine against necrotic enteritis, a disease of poultry estimated to cost the global poultry industry $5-6 billion USD/annum. It builds on work that has demonstrated the efficacy of an experimental vaccine. The proven antigen, NetB, will be expressed in live delivery vehicles, including the apicomplexan parasite Eimeria and several bacteria strains ....Development of a live vaccine for gut health in poultry. Development of a live vaccine for gut health in poultry. The project aims to develop a live vaccine against necrotic enteritis, a disease of poultry estimated to cost the global poultry industry $5-6 billion USD/annum. It builds on work that has demonstrated the efficacy of an experimental vaccine. The proven antigen, NetB, will be expressed in live delivery vehicles, including the apicomplexan parasite Eimeria and several bacteria strains particularly suited to use in chickens. Comparative analysis of the different vaccine vehicles will allow evaluation of the relative advantages and disadvantage of the different vehicles for delivery of heterologous vaccine antigens, thus informing the choice of appropriate vectors for this and other vaccine applications.Read moreRead less
Subspecies distribution and virulence of Streptococcus uberis. Streptococcus uberis is a significant cause of bovine mastitis. Attempts to produce a successful vaccine against S. uberis have been hampered by the lack of knowledge of phylogenetic relationships within the species and virulence mechanisms. It is uncertain whether pathogenic strains are clonal or are acquired opportunistically from a diverse population in the environment. This project aims to examine the phylogenetic structure of ....Subspecies distribution and virulence of Streptococcus uberis. Streptococcus uberis is a significant cause of bovine mastitis. Attempts to produce a successful vaccine against S. uberis have been hampered by the lack of knowledge of phylogenetic relationships within the species and virulence mechanisms. It is uncertain whether pathogenic strains are clonal or are acquired opportunistically from a diverse population in the environment. This project aims to examine the phylogenetic structure of S. uberis by multilocus sequence typing and investigate control of virulence gene expression in S. uberis. The information obtained will be used to improve the formulation of a bovine mastitis vaccine developed by RMIT University and Vet Biosearch.Read moreRead less
Modulation of air-conditioning settings to destroy respiratory viruses. This project aims to prove that manipulating the ambient humidity can rapidly degrade airborne viruses. The relationship between ambient humidity and airborne infection is poorly understood for viral pathogens including influenza and the common cold. The project will prove that indoor environmental conditions can be easily manipulated to kill airborne viruses. The findings will be used to develop indoor air humidity control ....Modulation of air-conditioning settings to destroy respiratory viruses. This project aims to prove that manipulating the ambient humidity can rapidly degrade airborne viruses. The relationship between ambient humidity and airborne infection is poorly understood for viral pathogens including influenza and the common cold. The project will prove that indoor environmental conditions can be easily manipulated to kill airborne viruses. The findings will be used to develop indoor air humidity control guidelines targeting the vulnerabilities of the viruses to minimise airborne infection.Read moreRead less
Environmental contamination and pig disease: an Australian microbe evolves. The Australian pig industry produces pork commodities from over 4.75 million pigs per year. Infectious diseases in industrial-scale piggeries can have a devastating effect on pork production, particularly on feed conversion efficiency and growth rates, and can pose downstream environmental contamination and food safety risks. This project aims to assess a current infectious disease problem in pigs by studying a microbe t ....Environmental contamination and pig disease: an Australian microbe evolves. The Australian pig industry produces pork commodities from over 4.75 million pigs per year. Infectious diseases in industrial-scale piggeries can have a devastating effect on pork production, particularly on feed conversion efficiency and growth rates, and can pose downstream environmental contamination and food safety risks. This project aims to assess a current infectious disease problem in pigs by studying a microbe that appears to have uniquely evolved in Australia. These results could inform the rational design of monitoring, prevention and treatment strategies to minimise infection outbreaks in Australian pigs and may result in production benefits to the pork industry, reduced environmental microbial contamination and safer food.Read moreRead less
Study the Utility of Novel Drug Polymer Conjugates. The products likely to arise from the technology described in this proposal could have application in medical, veterinary and agricultural industries. It offers the potential to treat diseases that are at present poorly treated by enabling delivery direct to the diseased organ (e.g. eye - bacterial endophthalmitis). Completion of the project will also assist a fledgling biotech company transition to a development company with a multiple produ ....Study the Utility of Novel Drug Polymer Conjugates. The products likely to arise from the technology described in this proposal could have application in medical, veterinary and agricultural industries. It offers the potential to treat diseases that are at present poorly treated by enabling delivery direct to the diseased organ (e.g. eye - bacterial endophthalmitis). Completion of the project will also assist a fledgling biotech company transition to a development company with a multiple product portfolio, which will have a direct economic benefit to Australia both in terms of potential export earnings and as an employer highly skilled staff. The project will also provide research training and career opportunities for developing Australian based researchers.Read moreRead less
Making Green Guard® greener: enhancing the efficacy of a biopesticide. The project aims to identify naturally occurring micro-organisms to increase the effectiveness of Green Guard ®, which is a biopesticide used against the Australian plague locust. The project will use next-generation sequencing and other molecular techniques to potentially identify candidate microbes or combinations of microbes that can be added to Green Guard to enhance locust susceptibility. The project also aims to quantif ....Making Green Guard® greener: enhancing the efficacy of a biopesticide. The project aims to identify naturally occurring micro-organisms to increase the effectiveness of Green Guard ®, which is a biopesticide used against the Australian plague locust. The project will use next-generation sequencing and other molecular techniques to potentially identify candidate microbes or combinations of microbes that can be added to Green Guard to enhance locust susceptibility. The project also aims to quantify the interactive impact of temperature and nutrition on immune function, disease resistance and host-plant quality of plague locusts; and to explore the combined effects of temperature, habitat and Green Guard, in combination with candidate microbes or pathogens, on the behaviour and collective movement of locusts. It is anticipated that this will have implications for management and control strategies.Read moreRead less