Heterotrophically grown microalgae as a feed source for the Australian aquaculture industry. The Australian aquaculture industry has rapidly grown in the past decade producing premium quality, high value species, e.g. tuna and oyster. In the new millennia it is predicted that the Australia aquaculture industry will be the most profitable area within the Australian seafood industry. An integral component for the long-term sustainability of the Australian aquaculture industry is the availability o ....Heterotrophically grown microalgae as a feed source for the Australian aquaculture industry. The Australian aquaculture industry has rapidly grown in the past decade producing premium quality, high value species, e.g. tuna and oyster. In the new millennia it is predicted that the Australia aquaculture industry will be the most profitable area within the Australian seafood industry. An integral component for the long-term sustainability of the Australian aquaculture industry is the availability of top-quality microalgal concentrates, shelf-stable pastes or live feeds, which provide the nutritional requirements of aquatic species in the hatcheries. This project will develop novel microalgal production strategies that would add value to the Australian aquaculture industry.Read moreRead less
Physico-chemical Controls on Growth, Toxicity and Succession of Microcystis and Anabaena Species in Sydney Water Supply Reservoirs. Insight into the forms of nutrients that are most readily assimilated by Microcystis and Anabaena species prevalent in Lake Burragorang and other Sydney water supply reservoirs will assist in determining the key drivers to occurrence of blooms of these organisms, particularly when combined with an understanding of the spatial and temporal distribution of the forms o ....Physico-chemical Controls on Growth, Toxicity and Succession of Microcystis and Anabaena Species in Sydney Water Supply Reservoirs. Insight into the forms of nutrients that are most readily assimilated by Microcystis and Anabaena species prevalent in Lake Burragorang and other Sydney water supply reservoirs will assist in determining the key drivers to occurrence of blooms of these organisms, particularly when combined with an understanding of the spatial and temporal distribution of the forms of nutrients, the dynamics of transformation between these various forms and the key parameters of light and temperature. In addition, the particular forms in which nutrients are acquired may influence the extent of toxin production. Thus, the findings of the project will also assist in elucidating the conditions under which toxin generation is expected.Read moreRead less
Characterization of bioadhesives from marine diatom slimes and their interactions with different substrata; developing environmentally friendly, foul-release coatings. This project represents a collaborative effort between Melbourne University, the Department of Defense and Akzo Nobel to develop new, environmentally friendly strategies to modify and/or prevent marine slime adhesion in anti-foul coatings or paint. Fouling by diatom slimes occurs at great expense to industry and the Australian N ....Characterization of bioadhesives from marine diatom slimes and their interactions with different substrata; developing environmentally friendly, foul-release coatings. This project represents a collaborative effort between Melbourne University, the Department of Defense and Akzo Nobel to develop new, environmentally friendly strategies to modify and/or prevent marine slime adhesion in anti-foul coatings or paint. Fouling by diatom slimes occurs at great expense to industry and the Australian Navy, adding up to 60% annually to the cost of propulsive fuel consumption in shipping. We will characterize the chemical and physical properties of the slime adhesives in order to understand how organisms control adhesion, and use these principles to develop new technology, anti-foul paints.Read moreRead less
Predictive ichthyotoxicity, diagnostics and risk assessment of harmful algal blooms impacting on the Tasmanian salmonid aquaculture industry. We aim to define through a combination of laboratory culture exposure and live cage bioassay experiments the minimum cell concentrations of harmful microalgae (Karenia, Heterosigma, Noctiluca, Chaetoceros) that can cause salmonid mortalities or are a factor in compromising fish health or reducing fish farm productivity. The diagnostic pathology and fish be ....Predictive ichthyotoxicity, diagnostics and risk assessment of harmful algal blooms impacting on the Tasmanian salmonid aquaculture industry. We aim to define through a combination of laboratory culture exposure and live cage bioassay experiments the minimum cell concentrations of harmful microalgae (Karenia, Heterosigma, Noctiluca, Chaetoceros) that can cause salmonid mortalities or are a factor in compromising fish health or reducing fish farm productivity. The diagnostic pathology and fish behaviour caused by different harmful algal taxa will be carefully documented to assist fish health inspectors in the routine diagnosis of algal toxicosis ot compromised fish health. Ultimately, this information will be integrated into a risk assessment strategy for the Tasmanian salmonid industry to manage fish stocks during times of harmful algal bloom events.Read moreRead less
Regulation of saxitoxin production in bacteria and algae. In Australia, toxic algal blooms have had a devastating impact on marine and freshwater resources. In collaboration with a biotechnology company, this project will develop exciting new methods based on information regarding the genetics of the toxin, to monitor and potentially mitigate the effects of algal blooms on water supplies and aquaculture industries. We will use this method to determine the impact of light and salinity in regulati ....Regulation of saxitoxin production in bacteria and algae. In Australia, toxic algal blooms have had a devastating impact on marine and freshwater resources. In collaboration with a biotechnology company, this project will develop exciting new methods based on information regarding the genetics of the toxin, to monitor and potentially mitigate the effects of algal blooms on water supplies and aquaculture industries. We will use this method to determine the impact of light and salinity in regulating toxin production in cyanobacteria and algae.Read moreRead less
Environmental drivers for production of the toxin, cylindrospermopsin, by the cyanobacterium Cylindrospermopsis raciborskii. Water authorities spend significant resources to monitor and control algal blooms. A significant part of this is monitoring freshwater toxic algal blooms that can impact on drinking water and recreational uses. One of the difficulties in monitoring blooms is that the toxin content of individual species can vary considerably. It is unclear whether this is caused by changes ....Environmental drivers for production of the toxin, cylindrospermopsin, by the cyanobacterium Cylindrospermopsis raciborskii. Water authorities spend significant resources to monitor and control algal blooms. A significant part of this is monitoring freshwater toxic algal blooms that can impact on drinking water and recreational uses. One of the difficulties in monitoring blooms is that the toxin content of individual species can vary considerably. It is unclear whether this is caused by changes in environmental conditions, i.e. nutrient, light, temperature. This project would provide the link between environmental conditions and toxin production to improve the ability to predict and monitor toxin production.Read moreRead less
Uncovering the genetic basis for saxitoxin production in Australian marine and freshwater systems: novel molecular tools for management. In Australia, toxic algal blooms have had a devastating impact on marine and freshwater resources. In collaboration with a biotechnology company, this project will use an innovative method to design a molecular genetic tool to monitor, research and potentially mitigate the effects of saxitoxin production on water supplies and aquaculture industries. In working ....Uncovering the genetic basis for saxitoxin production in Australian marine and freshwater systems: novel molecular tools for management. In Australia, toxic algal blooms have had a devastating impact on marine and freshwater resources. In collaboration with a biotechnology company, this project will use an innovative method to design a molecular genetic tool to monitor, research and potentially mitigate the effects of saxitoxin production on water supplies and aquaculture industries. In working with monitoring authorities throughout Australia, we will produce a specific, sensitive and cost-effective technology that will ultimately be applicable worldwide. Read moreRead less
Taxonomic discrimination and compositional analysis of microalgae using Fourier-transform infrared (FT-IR) spectroscopy. The project aims to develop an automated system using infrared spectroscopy that can rapidly and inexpensively identify algae and quantify their chemical composition. The system, which would be based on statistical models developed from infrared spectral information, has the potential to enable rapid identification of blue-green algae at the strain level, allowing new algal bl ....Taxonomic discrimination and compositional analysis of microalgae using Fourier-transform infrared (FT-IR) spectroscopy. The project aims to develop an automated system using infrared spectroscopy that can rapidly and inexpensively identify algae and quantify their chemical composition. The system, which would be based on statistical models developed from infrared spectral information, has the potential to enable rapid identification of blue-green algae at the strain level, allowing new algal blooms to be rapidly compared with those known to be toxic. Compositional analysis using infrared spectroscopy has the potential to measure all major classes of macromolecules simultaneously and precisely, at the single cell level, in a non-destructive manner that does not involve polluting chemicals.Read moreRead less
Effects of environmental factors on ecophysiological performance in the toxic cyanobacterium Nodularia. Nodularia is a toxic cyanobacterium that causes problem blooms in Australian waters and worldwide. The effects of environmental conditions on physiological processes in Nodularia are poorly understood and information on the effects on macromolecular synthesis and photosynthesis in Nodularia is limited. This project is of fundamental biological importance, making a major contribution to under ....Effects of environmental factors on ecophysiological performance in the toxic cyanobacterium Nodularia. Nodularia is a toxic cyanobacterium that causes problem blooms in Australian waters and worldwide. The effects of environmental conditions on physiological processes in Nodularia are poorly understood and information on the effects on macromolecular synthesis and photosynthesis in Nodularia is limited. This project is of fundamental biological importance, making a major contribution to understanding the impacts of environmental conditions on the physiological performance and ecology of Nodularia. The research has significance, both nationally and internationally, for the prediction of algal blooms in coastal and estuarine ecosystems, and will increase our knowledge of the factors controlling growth and toxicity of Nodularia worldwide. Read moreRead less
Are nutrients the key driver in stimulating toxic algae in subtropical water reservoirs? This project aims to determine the key factors causing blooms of the toxic algae, Cylindrospermopsis raciborskii, which dominates many freshwater reservoirs throughout Queensland. Little is known of why blooms of this species occur. Without the development of this understanding and research capacity to tackle this issue in Queensland, the severity of the problem is likely to increase, putting ever-greater ....Are nutrients the key driver in stimulating toxic algae in subtropical water reservoirs? This project aims to determine the key factors causing blooms of the toxic algae, Cylindrospermopsis raciborskii, which dominates many freshwater reservoirs throughout Queensland. Little is known of why blooms of this species occur. Without the development of this understanding and research capacity to tackle this issue in Queensland, the severity of the problem is likely to increase, putting ever-greater pressure on drinking water supplies. The outcomes from this project would therefore be an increased capacity to predict blooms, and identification of management options for reducing the occurrence of blooms to ensure a cost-effective and safe water supply.Read moreRead less