A functional genomic approach for understanding metal ion adaptation in marine cyanobacteria. Unicellular marine cyanobacteria constitute 20-40% of total marine chlorophyll biomass and carbon fixation, and hence significantly impact the global carbon cycle and are very relevant to combating global warming. This research will reveal some of the major mechanisms by which marine cyanobacteria have adapted to metal levels in coastal and oligotrophic environments. Thus these results will help us und ....A functional genomic approach for understanding metal ion adaptation in marine cyanobacteria. Unicellular marine cyanobacteria constitute 20-40% of total marine chlorophyll biomass and carbon fixation, and hence significantly impact the global carbon cycle and are very relevant to combating global warming. This research will reveal some of the major mechanisms by which marine cyanobacteria have adapted to metal levels in coastal and oligotrophic environments. Thus these results will help us understand the distribution and diversity of these organisms in relation to global primary productivity. They will also lead to the development of more robust biomarkers for metal stress and pollution in coastal environments.Read moreRead less
Microbial sulphatises in the rhizosphere and their control by interactions with plants. Plant-microbe interactions are critical in mobilizing soil sulphur for crop growth. This project will identify the microbes responsible for delivering sulphur to two major Australian crops, and will examine how the plants stimulate this activity in their root zone. The results have potential application for sustainable agriculture in Australia.
Australian Laureate Fellowships - Grant ID: FL140100021
Funder
Australian Research Council
Funding Amount
$2,700,000.00
Summary
Building virtual cyanobacteria: moving beyond the genomics era. Building virtual cyanobacteria: moving beyond the genomics era. This project aims to establish a new understanding of complex biological systems through the development of computational models of single cells and global ecosystems. The project will focus on globally important photosynthetic bacteria that underlie the entire marine food web. This project aims to characterise the diversity and abundance of photosynthetic bacteria acro ....Building virtual cyanobacteria: moving beyond the genomics era. Building virtual cyanobacteria: moving beyond the genomics era. This project aims to establish a new understanding of complex biological systems through the development of computational models of single cells and global ecosystems. The project will focus on globally important photosynthetic bacteria that underlie the entire marine food web. This project aims to characterise the diversity and abundance of photosynthetic bacteria across Australia's marine habitats and unravel the genetic basis for their adaptation to different environments. This data will be integrated with biochemical and physiological studies to create quantitative models at the cellular and global ecosystem scales. This project aims to develop new biomonitoring technologies, which combined with these models, will enable assessment of the health of Australia's marine ecosystems.Read moreRead less
Managing acid mine drainage in northern Australia using microbial mats. One of the most difficult environmental issues for the mining industry is acid mine drainage (AMD) that can lead to significant environmental damage. This project aims to identify microbes and characterise their roles in AMD formation in north Australia. We will use our new knowledge to design and trial microbial mats for the treatment of AMD. A successful AMD microbial treatment technology will minimise the risk of acid run ....Managing acid mine drainage in northern Australia using microbial mats. One of the most difficult environmental issues for the mining industry is acid mine drainage (AMD) that can lead to significant environmental damage. This project aims to identify microbes and characterise their roles in AMD formation in north Australia. We will use our new knowledge to design and trial microbial mats for the treatment of AMD. A successful AMD microbial treatment technology will minimise the risk of acid runoff and metal seepage into rivers and through groundwater. AMD treatment technology we develop in the tropics where we experience the extremes of dry and wet seasons will require only minor modification to operate in temperate climates however the reverse is not true. Read moreRead less
Improving the efficacy of pseudomonad biocontrol bacteria. This project intends to characterise the genetic basis for colonisation and persistence on plant seeds and roots by biocontrol bacteria. Pseudomonas biocontrol bacteria offer the potential to suppress agricultural crop pathogens without the need for expensive and potentially harmful agrochemicals. However, the application of these bacteria in the field is currently limited. A key reason for this is their unreliable capacity for root colo ....Improving the efficacy of pseudomonad biocontrol bacteria. This project intends to characterise the genetic basis for colonisation and persistence on plant seeds and roots by biocontrol bacteria. Pseudomonas biocontrol bacteria offer the potential to suppress agricultural crop pathogens without the need for expensive and potentially harmful agrochemicals. However, the application of these bacteria in the field is currently limited. A key reason for this is their unreliable capacity for root colonisation and persistence. The project aims to analyse the factors critical for plant colonisation. These analyses may facilitate the successful application of biocontrol bacteria for protecting Australian crops from pathogens.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
Environmental genomics and novel bioactives from microbial communities on living marine surfaces. This project has three linked benefits to Australia. One, it is the first study to use environmental genomics analysis in an Australian marine ecosystem, thus bringing into the Australian scientific community the cutting edge technology for studying diverse microbial communities. Two, by using this technology we will be able to investigate Australian marine biodiversity to an unprecedented extent. ....Environmental genomics and novel bioactives from microbial communities on living marine surfaces. This project has three linked benefits to Australia. One, it is the first study to use environmental genomics analysis in an Australian marine ecosystem, thus bringing into the Australian scientific community the cutting edge technology for studying diverse microbial communities. Two, by using this technology we will be able to investigate Australian marine biodiversity to an unprecedented extent. Three, this newly revealed diversity will then be mined for novel bioactives for use in pharmaceutical and other human health applications. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120102610
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
The role of deep-sea microorganisms in nutrient cycling in the Southern Ocean. This project aims to learn how surface water microbes that are important in global nutrient cycling adapt to life when they sink to the deep sea. This will teach us about the roles that surface water and deep sea microbes play in maintaining the health of marine environments.
Effect of predation on virulence traits of opportunistic pathogens. The project aims to determine if increased fitness of bacteria in animal or human hosts (increased virulence) can occur due to indirect rather than direct selective pressure, particularly pressure on bacteria arising from predation by protozoa. Protozoa feed on many pathogenic bacteria (e.g. those that cause cholera and chronic infections) in the ocean, and warming oceans are predicted to increase predation. Knowing the effect o ....Effect of predation on virulence traits of opportunistic pathogens. The project aims to determine if increased fitness of bacteria in animal or human hosts (increased virulence) can occur due to indirect rather than direct selective pressure, particularly pressure on bacteria arising from predation by protozoa. Protozoa feed on many pathogenic bacteria (e.g. those that cause cholera and chronic infections) in the ocean, and warming oceans are predicted to increase predation. Knowing the effect of warming oceans on marine bacteria and the emergence of virulence in bacteria that are subject to predation in the environment can inform design of tools for monitoring the risk of infection outbreaks. Benefits would be realised by academic researchers, clinicians and policy-makers interested in optimising the tracking of infection threats.Read moreRead less
Defining how bacteriophage shape the biofilm lifecycle of bacteria. Bacteriophages are viruses that infect bacteria and they represent a significant selective pressure that drives the evolution of bacteria. We will study the genetic mechanisms by which genes encoded by a bacteriophage can contribute to increased survival of bacteria in the environment.