A “Goldilocks” live attenuated poultry vaccine for Infectious Coryza. This project aims to develop a safe and effective vaccine for Infectious Coryza using a live-attenuated vaccine approach. Infectious coryza is an acute respiratory disease of chickens and is caused by the bacterial pathogen, Avibacterium paragallinarum. Infectious Coryza can be controlled by appropriate biosecurity practises and this has been successful in the Australian context to date. However, in the USA, Europe and other e ....A “Goldilocks” live attenuated poultry vaccine for Infectious Coryza. This project aims to develop a safe and effective vaccine for Infectious Coryza using a live-attenuated vaccine approach. Infectious coryza is an acute respiratory disease of chickens and is caused by the bacterial pathogen, Avibacterium paragallinarum. Infectious Coryza can be controlled by appropriate biosecurity practises and this has been successful in the Australian context to date. However, in the USA, Europe and other equatorial regions, infectious Coryza remains an unsolved problem. The expected outcome of this project is a cross-serovar protective vaccine to prevent infectious coryza for use in endemic countries and to act as a biosecurity measure to protect Australia's poultry industry against an incursion of this disease.Read moreRead less
Reducing the health & economic burden of Campylobacter using a live vaccine. The aim of the project is to develop a vaccine to reduce Campylobacter bacteria in chickens. Campylobacters cause disease in both poultry and humans. Poultry products are the most common source of human infections. By reducing Campylobacter in poultry, the transfer to humans will be reduced. The expected outcomes arising from this work will be a reduction of the economic burden of poultry losses, in an Australian indust ....Reducing the health & economic burden of Campylobacter using a live vaccine. The aim of the project is to develop a vaccine to reduce Campylobacter bacteria in chickens. Campylobacters cause disease in both poultry and humans. Poultry products are the most common source of human infections. By reducing Campylobacter in poultry, the transfer to humans will be reduced. The expected outcomes arising from this work will be a reduction of the economic burden of poultry losses, in an Australian industry valued at $2.8 billion/year, and an improvement in food safety, thus helping to reduce the burden of foodborne illness, estimated to be $1.2 billion dollars/year. This project is, therefore, poised to benefit the Australian economy, specifically primary producers and the general public, by targeted vaccination of poultry.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200100367
Funder
Australian Research Council
Funding Amount
$389,008.00
Summary
Characterisation of avian circovirus protein complexes. This project aims to better understand how the beak and feather disease virus (BFDV) is assembled. The virus affects Australian native birds, which are currently endangered or critically endangered and has the potential to disrupt native ecosystems. By using interdisciplinary research, this project will generate fundamental knowledge by which BFDV protein complexes are formed. The intended outcomes of the project include the identification ....Characterisation of avian circovirus protein complexes. This project aims to better understand how the beak and feather disease virus (BFDV) is assembled. The virus affects Australian native birds, which are currently endangered or critically endangered and has the potential to disrupt native ecosystems. By using interdisciplinary research, this project will generate fundamental knowledge by which BFDV protein complexes are formed. The intended outcomes of the project include the identification of key binding interfaces involved in viral formation processes. This information intends to guide cost-effective delivery of potential anti-viral options or vaccines for endangered Australian native parrots, and for use as a model to target other pathogenic DNA viruses of interest.Read moreRead less
How to make antibiotics in pig feed redundant, naturally. Antimicrobial resistance has become a major issue in human and veterinary medicine being partially caused by the use of in-feed antimicrobials in farm animals. This project aims to completely eliminate antimicrobials from piglet feeds. The key differential approach is based on helping the physiology of the animal rather than testing interventions against bacteria. The project will consist of developing a novel nutritional strategy of natu ....How to make antibiotics in pig feed redundant, naturally. Antimicrobial resistance has become a major issue in human and veterinary medicine being partially caused by the use of in-feed antimicrobials in farm animals. This project aims to completely eliminate antimicrobials from piglet feeds. The key differential approach is based on helping the physiology of the animal rather than testing interventions against bacteria. The project will consist of developing a novel nutritional strategy of naturally (through maternal conditioning) boosting the natural appetite and the capacity to digest in piglets early in life. The anticipated outcome is that the new peri-natal program will result in minimal bacterial proliferation and diarrhoea thus, negating the need for in-feed antimicrobials in piglets. Read moreRead less
Improving diagnostic accuracy and treatment options for equine PPID. Equine Pituitary Pars Intermedia Dysfunction (PPID) is a common, chronic and potentially life-threatening disease of older horses and ponies. Although a treatment is available, the disease is poorly understood and there are some concerns that the current diagnostic technology is not delivering accurate results. Thus, this project aims to develop a more accurate diagnostic test for PPID, while exploring the relationship between ....Improving diagnostic accuracy and treatment options for equine PPID. Equine Pituitary Pars Intermedia Dysfunction (PPID) is a common, chronic and potentially life-threatening disease of older horses and ponies. Although a treatment is available, the disease is poorly understood and there are some concerns that the current diagnostic technology is not delivering accurate results. Thus, this project aims to develop a more accurate diagnostic test for PPID, while exploring the relationship between PPID and metabolic syndrome, to generate new insights into the cause and consequences of both diseases. As an added benefit, the project will assist horseracing laboratories to improve their detection methods for peptide doping in younger competition horses.
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Discovery Early Career Researcher Award - Grant ID: DE230101284
Funder
Australian Research Council
Funding Amount
$397,003.00
Summary
Insect-specific virus host restriction. Mosquito-borne viruses are a topic of intense research due to their complex biology, ecology and evolution, and their potential to produce unpredictable outbreaks of disease in both humans and animals. Insect-specific viruses (ISVs) are viruses that replicate solely in mosquito cell and are unable to infect vertebrate tissues. This project aims to assess the biodiversity of ISVs in the Australian mosquito population and identify key factors behind their re ....Insect-specific virus host restriction. Mosquito-borne viruses are a topic of intense research due to their complex biology, ecology and evolution, and their potential to produce unpredictable outbreaks of disease in both humans and animals. Insect-specific viruses (ISVs) are viruses that replicate solely in mosquito cell and are unable to infect vertebrate tissues. This project aims to assess the biodiversity of ISVs in the Australian mosquito population and identify key factors behind their restriction in vertebrates. The objectives of the studies proposed will answer clearly defined important biological questions about ISVs, while also delivering technological advances, novel reagents and potential commercial outcomes for the control and prevention of arboviral disease. Read moreRead less
Next-generation genomic resources to tackle parasitic diseases of animals. The revolution in genomics provides unprecedented opportunities to tackle destructive parasitic diseases affecting billions of animals worldwide. Through a synergy of leading-edge technologies and a strong partnership with BGI International, this project aims to deliver major conceptual advances in the understanding of parasitism; an unparalleled skills-base in genomics and bioinformatics; innovative new molecular technol ....Next-generation genomic resources to tackle parasitic diseases of animals. The revolution in genomics provides unprecedented opportunities to tackle destructive parasitic diseases affecting billions of animals worldwide. Through a synergy of leading-edge technologies and a strong partnership with BGI International, this project aims to deliver major conceptual advances in the understanding of parasitism; an unparalleled skills-base in genomics and bioinformatics; innovative new molecular technologies; and new treatments and diagnostic tests as biotechnological outcomes. This leap forward in Australia will substantially enhance the global profile of parasitology research, training and employment opportunities for early career scientists, and improve access to international research funding and networks. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220101221
Funder
Australian Research Council
Funding Amount
$453,614.00
Summary
Revealing bat antibody recognition mechanism against bat-borne viruses. Bats act as asymptomic reservoir hosts for numerous zoonotic viruses that are lethal in humans, indicating that the bat immune system can control these viruses. However, little is known about bat immunity including how bat antibodies recognise bat-borne viruses. This project aims to study bat anti-viral antibodies by utilising innovative protein engineering, cutting-edge cryo-EM technology and single-cell isolation and seque ....Revealing bat antibody recognition mechanism against bat-borne viruses. Bats act as asymptomic reservoir hosts for numerous zoonotic viruses that are lethal in humans, indicating that the bat immune system can control these viruses. However, little is known about bat immunity including how bat antibodies recognise bat-borne viruses. This project aims to study bat anti-viral antibodies by utilising innovative protein engineering, cutting-edge cryo-EM technology and single-cell isolation and sequencing. The project seeks to uncover bat-borne zoonotic virus glycoprotein architecture and reveal how bat antibodies function to inhibit viral infection. Expected outcomes will be new insight and tools to combat emerging and yet to emerge pathogens, enabling pandemic preparedness and increasing global biosecurity.
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New vaccines and diagnostics to control viral disease in farmed crocodiles. Infection of farmed crocodiles with West Nile virus (WNV) causes lesions in the skin that render the hides unsuitable for high quality leather products. This results in >$20 million lost revenue to the Australian crocodile industry annually. We have developed a novel technology to generate safe and effective vaccines and diagnostic tests for WNV in animals. We aim to 1) conduct vaccine trials in farmed crocodiles to dete ....New vaccines and diagnostics to control viral disease in farmed crocodiles. Infection of farmed crocodiles with West Nile virus (WNV) causes lesions in the skin that render the hides unsuitable for high quality leather products. This results in >$20 million lost revenue to the Australian crocodile industry annually. We have developed a novel technology to generate safe and effective vaccines and diagnostic tests for WNV in animals. We aim to 1) conduct vaccine trials in farmed crocodiles to determine the optimum dose formulation and immunisation regime to provide long-lived protection against WNV disease; 2) validate pen-side tests to rapidly diagnose WNV infection in crocodiles on farms; and 3) transfer the technology to a manufacturing facility to ensure a commercial supply of the vaccines and diagnostic tests. Read moreRead less
Novel Babesia proteins and their roles in the pathogenesis of tick fever. This project aims at gaining a deep understanding of the biology of Babesia parasites and how they cause tick fever in cattle. The project expects to discover novel parasite proteins involved in the development and persistence of tick fever and identify their functional role in infection. The main expected outcome is the discovery of parasite proteins that are critical for infection and pathogenesis of cattle tick fever. T ....Novel Babesia proteins and their roles in the pathogenesis of tick fever. This project aims at gaining a deep understanding of the biology of Babesia parasites and how they cause tick fever in cattle. The project expects to discover novel parasite proteins involved in the development and persistence of tick fever and identify their functional role in infection. The main expected outcome is the discovery of parasite proteins that are critical for infection and pathogenesis of cattle tick fever. The findings will contribute to the development of future novel vaccines to control tick fever, with significant economic benefits for the beef and dairy industries worldwide.Read moreRead less