Removing the impediment to large-scale selective breeding of Australian barramundi: deciphering and manipulating the genetic basis of sex change. This project will determine the genetic basis of sex control in barramundi and develop technologies to allow barramundi hatcheries to have increased control over reproduction leading to more efficient propagation and removing impediments to selective breeding.
Understanding fish-killing mechanisms by harmful algal blooms: towards the design of effective mitigation strategies. Fish-killing microalgal blooms cause multi-million dollar losses to global aquaculture and wild fisheries. This project brings together leading Australian and Canadian research teams, applying sophisticated cell line and biologically active molecule technologies, to elucidate precise fish-kill mechanisms and design effective mitigation strategies.
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.
Characterisation of vital carbohydrate synthases in pathogenic oomycetes. This project aims to understand the mechanisms that control cell wall stability in the fish pathogen, Saprolegnia parasitica. The biochemical properties and function of vital enzymes involved in cell wall biosynthesis will be determined using innovative approaches at the interface of biochemistry, microbiology, cell biology, and structural biology. Next generation ion mobility mass spectrometry will be used to solve challe ....Characterisation of vital carbohydrate synthases in pathogenic oomycetes. This project aims to understand the mechanisms that control cell wall stability in the fish pathogen, Saprolegnia parasitica. The biochemical properties and function of vital enzymes involved in cell wall biosynthesis will be determined using innovative approaches at the interface of biochemistry, microbiology, cell biology, and structural biology. Next generation ion mobility mass spectrometry will be used to solve challenging structural questions that cannot be tackled with conventional techniques. Expected outcomes include new knowledge on challenging membrane proteins that allows development of novel strategies for disease control in aquaculture. The data may also be applicable to crop protection from related plant pathogens.Read moreRead less
Reducing skeletal malformations in cultured marine fish using gene expression, improved nutrition and advanced system operation. Reducing malformations in farmed fish will benefit the Australian economy and society by providing greater quantities of cheaper, higher quality fish. Increased farmed fish production, currently worth ~$300 million p.a., will increase exports and decrease imports (currently ~50% of all Australian consumed fish). To benefit are the important regional farming operations ....Reducing skeletal malformations in cultured marine fish using gene expression, improved nutrition and advanced system operation. Reducing malformations in farmed fish will benefit the Australian economy and society by providing greater quantities of cheaper, higher quality fish. Increased farmed fish production, currently worth ~$300 million p.a., will increase exports and decrease imports (currently ~50% of all Australian consumed fish). To benefit are the important regional farming operations in QLD, NSW, SA, NT, TAS and WA. In particular, the largest industry in Tasmania will profit by having a viable new species to farm (striped trumpeter) reducing risk due to climate change and global oversupply of salmon. Another important benefactor will be the rapidly expanding yellowtail kingfish industry. Read moreRead less
Alternate diets for a sustainable aquaculture industry: neuroethology of feeding in barramundi. Our unique approach to identify the sensory requirements of farmed barramundi and develop new alternative feeds will 1. Improve barramundi production by increasing growth rates, 2. Enhance acceptance and ingestion of food pellets, thereby reducing leaching of nutrients vital to the fish and detrimental to the environment, 3. Help produce formulated diets that will offer the advantages of nutritional c ....Alternate diets for a sustainable aquaculture industry: neuroethology of feeding in barramundi. Our unique approach to identify the sensory requirements of farmed barramundi and develop new alternative feeds will 1. Improve barramundi production by increasing growth rates, 2. Enhance acceptance and ingestion of food pellets, thereby reducing leaching of nutrients vital to the fish and detrimental to the environment, 3. Help produce formulated diets that will offer the advantages of nutritional consistency, storage convenience, reduced feed waste and pollution and 4. Lower costs allowing for the successful and profitable production of barramundi and potentially other finfish. Read moreRead less
Triggering the dormant capacity of fish to make omega 3 fatty acids. Marine fisheries cannot expand further, leaving aquaculture (fish farming) with the challenge of meeting the growing demand for fish, whose consumption is known to enhance human health. Fish oil is an essential component of the feed used in aquaculture, but there is a decreasing global supply of this commodity. This innovative nutritional biochemistry project boosts the capacity of fish to produce their own fish oil from vegeta ....Triggering the dormant capacity of fish to make omega 3 fatty acids. Marine fisheries cannot expand further, leaving aquaculture (fish farming) with the challenge of meeting the growing demand for fish, whose consumption is known to enhance human health. Fish oil is an essential component of the feed used in aquaculture, but there is a decreasing global supply of this commodity. This innovative nutritional biochemistry project boosts the capacity of fish to produce their own fish oil from vegetable oils in their diet. Therefore, this project will enable the expansion of aquaculture as an economically and environmentally sustainable means to produce the highest quality, nourishing fish for human consumption.Read moreRead less