Cultivating numerically significant soil bacteria. The vast majority of soil bacteria have not been able to be studied in the laboratory because they cannot be grown outside the soil. They are therefore termed unculturable. Most of these belong to groups that are completely unstudied. Advances made in the Janssen lab have overcome this impediment to laboratory cultivation of numerically abundant and globally distributed soil bacteria. This project will develop these advances to generate simple a ....Cultivating numerically significant soil bacteria. The vast majority of soil bacteria have not been able to be studied in the laboratory because they cannot be grown outside the soil. They are therefore termed unculturable. Most of these belong to groups that are completely unstudied. Advances made in the Janssen lab have overcome this impediment to laboratory cultivation of numerically abundant and globally distributed soil bacteria. This project will develop these advances to generate simple and widely applicable methods to enable many of the previously unculturable soil bacteria to be studied. This will allow assessments of their ecological roles and biotechnological potentials to be made.Read moreRead less
Quantum Dot Nanocrystals: Smart Materials for Microbiology. Quantum dots were originally developed for computers but have many advantages over fluorescent dyes currently in use. They can be coupled to larger structures and a excitation with a laser allows simultaneous multiple analyses ("multiplexing"). We propose to adapt these structures for use in microbial ecology because this field is one of the least understood areas in biology. The technology we will develop will have far broader uses, a ....Quantum Dot Nanocrystals: Smart Materials for Microbiology. Quantum dots were originally developed for computers but have many advantages over fluorescent dyes currently in use. They can be coupled to larger structures and a excitation with a laser allows simultaneous multiple analyses ("multiplexing"). We propose to adapt these structures for use in microbial ecology because this field is one of the least understood areas in biology. The technology we will develop will have far broader uses, and will create new diagnostic tools for monitoring and understanding microbial ecosystems would be invaluable in a number of fields. Examples are medical diagnostics, waste-water treatment, bioremediation, food and agriculture, bioprotection and biodiscovery.Read moreRead less
Development and implementation of biodiversity information for sustainable management of South Australian groundwater. Clean potable water is one of the most important resources for human health and a successful economy. Increasingly, subterranean aquifers are used for storage and recovery of water. These aquifers contain dynamic ecosystems, but little is known about species composition or about the importance of the presence of various species for water quality. We will use the latest laborator ....Development and implementation of biodiversity information for sustainable management of South Australian groundwater. Clean potable water is one of the most important resources for human health and a successful economy. Increasingly, subterranean aquifers are used for storage and recovery of water. These aquifers contain dynamic ecosystems, but little is known about species composition or about the importance of the presence of various species for water quality. We will use the latest laboratory techniques and DNA identification methods to provide a template for determining ground water diversity and food web dynamics throughout Australia. This project will lead to a better understanding of how to manage ground water in a sustainable manner.Read moreRead less
Microbial Ecology and Control of Foaming in Anaerobic Digesters. One of the world's most common treatments of biosolids (product of wastewater treatment), anaerobic digestion often suffers from accumulation of biological foam. This foam hinders treatment, personnel health and safety, legal requirements for environmental protection are jeopardised and attempts to control digester foaming are costly. There is a clear lack of knowledge about the organisms involved and causes, therefore no informe ....Microbial Ecology and Control of Foaming in Anaerobic Digesters. One of the world's most common treatments of biosolids (product of wastewater treatment), anaerobic digestion often suffers from accumulation of biological foam. This foam hinders treatment, personnel health and safety, legal requirements for environmental protection are jeopardised and attempts to control digester foaming are costly. There is a clear lack of knowledge about the organisms involved and causes, therefore no informed solutions exist. Molecular DNA techniques, 16SrDNA sequencing and DGGE, will assist in deciphering causes and organisms involved. Research outcomes will present environmental, legal and economical acceptable control strategies for digester foaming to the waste management and water industries.Read moreRead less
To eat or not to eat? How symbiotic bacteria manipulate the phagocytic behaviour of their eukaryotic host. Bacteria often live in close association with eukaryotic cells, ranging from simple amoeba to humans. This project will identify key factors that control their interactions and will yield important information on the evolution of beneficial or harmful relationships.
An evolutionary landscape to better predict our future climate. Soil microbial communities are the most complicated and difficult to study on Earth, but their effects on our climate are profound. This project will examine the evolution of microorganisms and their viruses in soil using novel methods. It will uncover how the evolution of one microbial species influences the evolution of other community members. It will also apply a new model of evolution to the viruses that infect these microorgan ....An evolutionary landscape to better predict our future climate. Soil microbial communities are the most complicated and difficult to study on Earth, but their effects on our climate are profound. This project will examine the evolution of microorganisms and their viruses in soil using novel methods. It will uncover how the evolution of one microbial species influences the evolution of other community members. It will also apply a new model of evolution to the viruses that infect these microorganisms, constructing a viral ‘tree of life’. This improved fundamental understanding of soil communities will be used to study climate feedback from permafrost wetlands, a key and poorly constrained input of global climate models, improving predictions of our future climate.Read moreRead less
Toward a complete view of life on earth via single cell genomics. Genome sequencing has revolutionised biology, but for most microorganisms this revolution has not arrived because the majority cannot be grown in the laboratory. This project will address this grand challenge by targeted sequencing of single cells from the environment that will fill in many major gaps in the microbial tree of life.
Bringing Archaeal biodiversity to life from native Australian herbivores . The aim of this project is to provide deep functional understanding of our recent discovery of novel microbes from the Domain Archaea that inhabit the digestive tracts of native Australian herbivores. These animals are unique natural resources of great cultural, environmental, and economic significance, but increasingly susceptible to habitat change and degradation. Very little is currently known about the microbes that h ....Bringing Archaeal biodiversity to life from native Australian herbivores . The aim of this project is to provide deep functional understanding of our recent discovery of novel microbes from the Domain Archaea that inhabit the digestive tracts of native Australian herbivores. These animals are unique natural resources of great cultural, environmental, and economic significance, but increasingly susceptible to habitat change and degradation. Very little is currently known about the microbes that have co-evolved with these animals, to support their nutrition and health. The project will address these knowledge gaps, and the ensuing discoveries are expected to deliver products and services relevant to environmental health assessment and sustaining the "low methane carbon economy" attributed to these iconic species.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