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
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.
Structural insights of virus-glycan interactions. Influenza virus, rotavirus and Dengue virus infect the body by adhering to certain types of sugars on the human cell surface. This project will develop a detailed structural understanding of how viruses interact with those sugar molecules for the development of novel drugs and vaccines to combat influenza and rotaviral infections.
How bacteria form resistant aggregates and biofilms. This research aims to use interdisciplinary approaches to advance fundamental knowledge on bacterial aggregates and biofilms. These bacterial clusters are a significant problem as they have extraordinary resistance to disinfectants and antibiotics, and currently no effective methods are available to disrupt them. The expected outcomes of this project are to dissect how autotransporters, the most common group of bacterial cell-surface proteins, ....How bacteria form resistant aggregates and biofilms. This research aims to use interdisciplinary approaches to advance fundamental knowledge on bacterial aggregates and biofilms. These bacterial clusters are a significant problem as they have extraordinary resistance to disinfectants and antibiotics, and currently no effective methods are available to disrupt them. The expected outcomes of this project are to dissect how autotransporters, the most common group of bacterial cell-surface proteins, promote aggregation and biofilm formation, and to develop inhibitors that prevent the formation of these damaging bacterial clusters. Ultimately, this new knowledge will help address the increasing economic and social burden of industrial, environmental and biomedical biofilms.Read moreRead less
Unraveling autotransporter function in bacterial aggregates and biofilms. Autotransporters are a large family of bacterial proteins that play a central role in pathogenesis. They promote the formation of cell clusters and biofilms, which are mechanisms for bacterial resistance to host immune factors and antibiotics. Currently, the precise mode of action of autotransporters is unknown. This project will examine the interplay between the structure and function of key autotransporter proteins. It ....Unraveling autotransporter function in bacterial aggregates and biofilms. Autotransporters are a large family of bacterial proteins that play a central role in pathogenesis. They promote the formation of cell clusters and biofilms, which are mechanisms for bacterial resistance to host immune factors and antibiotics. Currently, the precise mode of action of autotransporters is unknown. This project will examine the interplay between the structure and function of key autotransporter proteins. It is expected that the outcomes of this research will establish how these proteins mediate aggregation and biofilm formation. It may also provide three-dimensional structures of proteins that are strongly immunogenic and may represent targets for future vaccine design, as well as identify molecules that inhibit autotransporter function.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220101221
Funder
Australian Research Council
Funding Amount
$453,614.00
Summary
Revealing bat antibody recognition mechanism against bat-borne viruses. Bats act as asymptomic reservoir hosts for numerous zoonotic viruses that are lethal in humans, indicating that the bat immune system can control these viruses. However, little is known about bat immunity including how bat antibodies recognise bat-borne viruses. This project aims to study bat anti-viral antibodies by utilising innovative protein engineering, cutting-edge cryo-EM technology and single-cell isolation and seque ....Revealing bat antibody recognition mechanism against bat-borne viruses. Bats act as asymptomic reservoir hosts for numerous zoonotic viruses that are lethal in humans, indicating that the bat immune system can control these viruses. However, little is known about bat immunity including how bat antibodies recognise bat-borne viruses. This project aims to study bat anti-viral antibodies by utilising innovative protein engineering, cutting-edge cryo-EM technology and single-cell isolation and sequencing. The project seeks to uncover bat-borne zoonotic virus glycoprotein architecture and reveal how bat antibodies function to inhibit viral infection. Expected outcomes will be new insight and tools to combat emerging and yet to emerge pathogens, enabling pandemic preparedness and increasing global biosecurity.
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How auto-transporter proteins mediate bacterial interactions. This project aims to investigate the structure-function relationships that underpin key auto-transporter roles in bacterial cell adhesion, aggregation and biofilm formation. Auto-transporter proteins are extremely common in bacteria where they play a central role in controlling bacterial interactions with other bacteria, with human cells, and with surfaces. This project will define the molecular mechanisms underlying these processes. ....How auto-transporter proteins mediate bacterial interactions. This project aims to investigate the structure-function relationships that underpin key auto-transporter roles in bacterial cell adhesion, aggregation and biofilm formation. Auto-transporter proteins are extremely common in bacteria where they play a central role in controlling bacterial interactions with other bacteria, with human cells, and with surfaces. This project will define the molecular mechanisms underlying these processes. This will have significant benefits, such as providing the basis for the development of approaches to block auto-transporter functions that contribute to the establishment of persistent and difficult to treat bacterial infections.Read moreRead less
The molecular mechanism of bacterial ABC toxins. This project aims to establish that the ABC family of bacterial protein toxins, the main virulence factors in many species of naturally-occurring bacterial pathogens of insect pests, represent a protein machinery that cells and other organisms may use to deliver bioactive proteins to specific cells. ABC toxins are the main virulence factors in many species of naturally-occurring bacterial pathogens of insect pests. This project aims to establish t ....The molecular mechanism of bacterial ABC toxins. This project aims to establish that the ABC family of bacterial protein toxins, the main virulence factors in many species of naturally-occurring bacterial pathogens of insect pests, represent a protein machinery that cells and other organisms may use to deliver bioactive proteins to specific cells. ABC toxins are the main virulence factors in many species of naturally-occurring bacterial pathogens of insect pests. This project aims to establish that ABC toxins represent a new protein machinery that may be used more widely throughout cells and other organisms to direct the intercellular delivery of bioactive proteins in a highly cell-specific manner. The project expects these findings to enable the development of biopesticides based on ABC toxins, and generic intercellular protein delivery devices for biotechnological use.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230101284
Funder
Australian Research Council
Funding Amount
$397,003.00
Summary
Insect-specific virus host restriction. Mosquito-borne viruses are a topic of intense research due to their complex biology, ecology and evolution, and their potential to produce unpredictable outbreaks of disease in both humans and animals. Insect-specific viruses (ISVs) are viruses that replicate solely in mosquito cell and are unable to infect vertebrate tissues. This project aims to assess the biodiversity of ISVs in the Australian mosquito population and identify key factors behind their re ....Insect-specific virus host restriction. Mosquito-borne viruses are a topic of intense research due to their complex biology, ecology and evolution, and their potential to produce unpredictable outbreaks of disease in both humans and animals. Insect-specific viruses (ISVs) are viruses that replicate solely in mosquito cell and are unable to infect vertebrate tissues. This project aims to assess the biodiversity of ISVs in the Australian mosquito population and identify key factors behind their restriction in vertebrates. The objectives of the studies proposed will answer clearly defined important biological questions about ISVs, while also delivering technological advances, novel reagents and potential commercial outcomes for the control and prevention of arboviral disease. Read moreRead less