Integrated management of pathogenic monogenean (flatworm) parasite infections in warm water finfish aquaculture. Sea cage farming of warm water finfish is expanding worldwide, with potential for lucrative aquaculture industries. These, however, are threatened by monogenean (flatworm) parasites that weaken and can kill sea-caged fishes. Current control methods provide only short-term solutions and increase production costs. Monogeneans jeopardize the fledgling kingfish industry in South Austra ....Integrated management of pathogenic monogenean (flatworm) parasite infections in warm water finfish aquaculture. Sea cage farming of warm water finfish is expanding worldwide, with potential for lucrative aquaculture industries. These, however, are threatened by monogenean (flatworm) parasites that weaken and can kill sea-caged fishes. Current control methods provide only short-term solutions and increase production costs. Monogeneans jeopardize the fledgling kingfish industry in South Australia and remain pests in Japanese yellowtail aquaculture (value, AUS$2.4 billion/year). With Australian and Japanese industry partners, our innovative field and laboratory approach will revolutionize management of fish parasites with direct life-cycles. Outcomes include: integrated long-term strategies to manage parasites; lower production costs; ability for new finfish industries to thrive.Read moreRead less
Fighting disease on farms: how do vaccinations drive evolution of new pathogen strains? Vaccinating against some types of infectious diseases can drive evolution of new variants of the pathogen. This project will show how bacterial populations evolve in response to vaccination in farms, leading to new vaccination strategies and improved vaccine formulations to better control diseases that are caused by highly variable bacteria.
A pan-genome reverse vaccinology approach to disease prevention in farmed fish. Evolution of new pathogen strains causes major problems in vaccinated animals because these variants can reinfect and cause severe disease in previously protected animals. This project will use state-of-the-art genomics to find new targets that are essential to all strain variants, enabling development of broadly cross-protective vaccines for farmed animals.
Advanced animal breeding in aquaculture: using genome-wide molecular breeding values for rapid animal improvement in the silver-lipped pearl oyster. The primary impediment to achieving rapid genetic progress in aquaculture is an inability to accurately and rapidly identify high-performance animals for selection as parents in animal breeding programs. This project aims to develop an innovative genomic selection breeding system for the silver-lipped pearl oyster to overcome current limitations ass ....Advanced animal breeding in aquaculture: using genome-wide molecular breeding values for rapid animal improvement in the silver-lipped pearl oyster. The primary impediment to achieving rapid genetic progress in aquaculture is an inability to accurately and rapidly identify high-performance animals for selection as parents in animal breeding programs. This project aims to develop an innovative genomic selection breeding system for the silver-lipped pearl oyster to overcome current limitations associated with traditional animal improvement methods. The use of genomic selection will not only transform the Australian pearl oyster industry, but it will also showcase the potential of genomic selection in aquaculture globally. Furthermore, knowledge gained from this project can also be applied to a variety of other Australian aquaculture species to accelerate the uptake of this technology.Read moreRead less