The molecular pathogenesis of Equine rhinitis A virus, a major respiratory pathogen of horses. The equine industry in Australia is worth $15 billion a year. Equine respiratory disease costs Victoria, alone, $5-10 million per year. Equine rhinitis A virus is a major cause of acute febrile respiratory disease in horses. This project aims to develop an infectious clone to study the pathogenesis of the disease, and subunit antigens for use as vaccines. These reagents will increase our understand ....The molecular pathogenesis of Equine rhinitis A virus, a major respiratory pathogen of horses. The equine industry in Australia is worth $15 billion a year. Equine respiratory disease costs Victoria, alone, $5-10 million per year. Equine rhinitis A virus is a major cause of acute febrile respiratory disease in horses. This project aims to develop an infectious clone to study the pathogenesis of the disease, and subunit antigens for use as vaccines. These reagents will increase our understanding of the pathogenesis of ERAV and will lead to experimental vaccines which will be tested in horses.Read moreRead less
Kernel methods for the analysis of whole bacterial genomes. This project addresses the fundamental scientific problem of the identification of regulatory regions and specific promoters within bacterial genomes, with a focus upon two organisms of great social, economic and bioterrism significance. From the machine learning perspective, the project will be the first to produce a kernel-based approach directly tailored to the problem of the detection of regulatory regions. The methods developed wil ....Kernel methods for the analysis of whole bacterial genomes. This project addresses the fundamental scientific problem of the identification of regulatory regions and specific promoters within bacterial genomes, with a focus upon two organisms of great social, economic and bioterrism significance. From the machine learning perspective, the project will be the first to produce a kernel-based approach directly tailored to the problem of the detection of regulatory regions. The methods developed will be made available through a straightforward web-based interface, allowing biologists throughout the world to utilize the approach as a tool to be applied to a progressively widening class of bacterial genomes, and even to eukaryotes. Read moreRead less
Bacterial mechanisms of gold mobilisation and precipitation with applications to mineral processing and exploration. The development of a comprehensive model for the biogeochemical behaviour of gold in the environment will aid mineral explorers to interpret existing exploration data and to develop better exploration strategies. Moreover, this project aims to develop the basis for a new geomicrobiological gold exploration method by identifying organisms and microbial gene sequences that could be ....Bacterial mechanisms of gold mobilisation and precipitation with applications to mineral processing and exploration. The development of a comprehensive model for the biogeochemical behaviour of gold in the environment will aid mineral explorers to interpret existing exploration data and to develop better exploration strategies. Moreover, this project aims to develop the basis for a new geomicrobiological gold exploration method by identifying organisms and microbial gene sequences that could be used as biomarkers for mineralisation. This research will also provide the fundamental information required to copy nature and engineer new cost-efficient and environmentally friendly technologies for gold processing using microorganisms that occur naturally in Australian soils. Read moreRead less
Metagenomics and the genetic basis of ecology and evolution of communities - complex microbial communities in industrial processes as excellent paradigms. Benefits accrue on two fronts: the international reputation of Australian science in contributing significantly to two new, challenging and highly topical questions in ecology and evolution, and in pioneering a route to better efficiency and control of an important industrial process. Wastewater is rich in organic phosphorus that is damaging t ....Metagenomics and the genetic basis of ecology and evolution of communities - complex microbial communities in industrial processes as excellent paradigms. Benefits accrue on two fronts: the international reputation of Australian science in contributing significantly to two new, challenging and highly topical questions in ecology and evolution, and in pioneering a route to better efficiency and control of an important industrial process. Wastewater is rich in organic phosphorus that is damaging to the environment if untreated, but current understanding enables only rudimentary control of the microbial communities that are the basis of the treatment process. The work will provide unprecedented insight into the mechanisms underpinning the dynamics of phosphorus absorbing microbes in industrial facilities by integrating from gene-to-ecosystem.Read moreRead less
EXTRACELLULAR ELECTRON TRANSFER IN BIO-ELECTROCHEMICAL SYSTEMS. Water quality and supply are critical issues in Australia. This project investigates the role of bacteria in maintaining a good freshwater quality, and the influence of environmental parameters on this. It will enable us to assess the role of bacteria on greenhouse gas emissions in a variety of environments. As a result, processes can be developed to alleviate high emissions while simultaneously producing green energy. The proteomic ....EXTRACELLULAR ELECTRON TRANSFER IN BIO-ELECTROCHEMICAL SYSTEMS. Water quality and supply are critical issues in Australia. This project investigates the role of bacteria in maintaining a good freshwater quality, and the influence of environmental parameters on this. It will enable us to assess the role of bacteria on greenhouse gas emissions in a variety of environments. As a result, processes can be developed to alleviate high emissions while simultaneously producing green energy. The proteomics study will deliver, aside from knowledge, redox proteins which find their way to diagnostics and fuel cells. This project substantiates Australia based research at the forefront and enables international anchoring of our expertise.Read moreRead less
Function and application of novel proteins from sponge symbionts. This project aims to determine the function of eukaryotic-like proteins (ELPs) from bacterial symbionts of sponges and apply this knowledge to develop new tools for biotechnology. This project will use innovative microscopy techniques and gene expression studies to define the molecular and cellular interactions of ELPs with sponges and how this is influenced by changing environmental conditions. ELPs will be further used to create ....Function and application of novel proteins from sponge symbionts. This project aims to determine the function of eukaryotic-like proteins (ELPs) from bacterial symbionts of sponges and apply this knowledge to develop new tools for biotechnology. This project will use innovative microscopy techniques and gene expression studies to define the molecular and cellular interactions of ELPs with sponges and how this is influenced by changing environmental conditions. ELPs will be further used to create new, artificial interactions between bacteria and eukaryotes. This project will provide fundamental knowledge on the evolution and function of newly discovered ELPs found in both beneficial and pathogenic bacteria and paves the way to control symbiosis for biotechnological applications.Read moreRead less
Genetic manipulation of Clostridium sporogenes. The overall objective of this project is to develop genetic methods for the manipulation of the anaerobic bacterium Clostridium sporogenes. Specifically, the project aims to manipulate this microorganism so that genes encoding enzymes that convert prodrugs to anticancer drugs can be introduced and stably maintained on its chromosome. The significance of the project is that the resultant bacteria, and others constructed using these methods, will th ....Genetic manipulation of Clostridium sporogenes. The overall objective of this project is to develop genetic methods for the manipulation of the anaerobic bacterium Clostridium sporogenes. Specifically, the project aims to manipulate this microorganism so that genes encoding enzymes that convert prodrugs to anticancer drugs can be introduced and stably maintained on its chromosome. The significance of the project is that the resultant bacteria, and others constructed using these methods, will then be able to be tested for their ability to act as specific drug delivery systems for use in the treatment of solid tumours.Read moreRead less
Interspecies electron transfer in biotechnology. While the project is fundamental in nature, it has direct technological gains to a wide range of biotechnology processes, and in particular, mixed culture anaerobic biotechnology. It therefore promotes Australian bioenergy, biofuel, and commodity renewable chemicals industries, and contributes to the national research priority of an Environmentally Sustainable Australia. In addition, this is a fast moving, high impact area that will demonstrate e ....Interspecies electron transfer in biotechnology. While the project is fundamental in nature, it has direct technological gains to a wide range of biotechnology processes, and in particular, mixed culture anaerobic biotechnology. It therefore promotes Australian bioenergy, biofuel, and commodity renewable chemicals industries, and contributes to the national research priority of an Environmentally Sustainable Australia. In addition, this is a fast moving, high impact area that will demonstrate excellence in Australian research on an international scale. The exciting multidisciplinary nature of the project, excellent management team, and high-class partners will also provide for an excellent experience for the three PhD candidates to be educated through the project.Read moreRead less
Use of Organic Residues in Edible Mushroom Production. The aims are to develop growth and casing materials for mushroom production based on organic wastes. Casing peat is the most expensive raw ingredient used in mushroom production and there are major concerns over supply due to increasing environmental concerns in supplier countries and quarantine issues such as the recent foot and mouth outbreak in Europe. This project will develop alternatives to imported peats as casing materials and invest ....Use of Organic Residues in Edible Mushroom Production. The aims are to develop growth and casing materials for mushroom production based on organic wastes. Casing peat is the most expensive raw ingredient used in mushroom production and there are major concerns over supply due to increasing environmental concerns in supplier countries and quarantine issues such as the recent foot and mouth outbreak in Europe. This project will develop alternatives to imported peats as casing materials and investigate a range of organic residues which can be used as basic growth media for button and exotic mushrooms. This will increase the viability and sustainability of the mushroom industry in Australia.Read moreRead less
Exploring and harnessing mobile DNA: Integrons and gene cassettes in natural populations of Bacteria. Bacteria respond rapidly to environmental change by acquiring new genes via lateral gene transfer. The integron/gene cassette system is important in this process as it is found in an increasingly broad range of bacteria. As well as being common, we have shown that the system is associated with an unprecedented amount of genetic novelty. Here we explore the limits of this novelty and its con ....Exploring and harnessing mobile DNA: Integrons and gene cassettes in natural populations of Bacteria. Bacteria respond rapidly to environmental change by acquiring new genes via lateral gene transfer. The integron/gene cassette system is important in this process as it is found in an increasingly broad range of bacteria. As well as being common, we have shown that the system is associated with an unprecedented amount of genetic novelty. Here we explore the limits of this novelty and its contribution to bacterial evolution. In so doing we have the potential to identify new commercially important genes and develop enabling technologies. These discoveries could produce beneficial outcomes for exploitation by a wide range of Australian industries.Read moreRead less