Discovery Early Career Researcher Award - Grant ID: DE140101493
Funder
Australian Research Council
Funding Amount
$368,720.00
Summary
A glycomics approach towards the discovery of novel markers of virus transmission by mosquitoes. The incidence of human and animal diseases caused by mosquito-borne pathogens has increased at an alarming rate globally. This project utilises state-of-the-art glyco-virological approaches and an arbovirus model system to identify new markers associated with virus transmission by mosquitoes. Markers associated with transmission will be identified by establishing global glycan and lectin profiles of ....A glycomics approach towards the discovery of novel markers of virus transmission by mosquitoes. The incidence of human and animal diseases caused by mosquito-borne pathogens has increased at an alarming rate globally. This project utilises state-of-the-art glyco-virological approaches and an arbovirus model system to identify new markers associated with virus transmission by mosquitoes. Markers associated with transmission will be identified by establishing global glycan and lectin profiles of the cells derived from a major mosquito species. This will fill a significant gap in our knowledge of basic transmission mechanisms in mosquitoes. The research strategy is a world-first and the institute is an international leader in this area. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100512
Funder
Australian Research Council
Funding Amount
$365,058.00
Summary
Bird flu in avian species: understanding the mechanisms of disease. This project aims to understand the genesis and pathogenesis of influenza virus in avian species. The project will investigate the role of bacteria in influenza severity in chickens, the role of avian endothelial cells in the emergence of highly pathogenic avian influenza viruses and the susceptibility of Australia’s native black swans to influenza. This project will generate fundamental knowledge that may help reduce the severi ....Bird flu in avian species: understanding the mechanisms of disease. This project aims to understand the genesis and pathogenesis of influenza virus in avian species. The project will investigate the role of bacteria in influenza severity in chickens, the role of avian endothelial cells in the emergence of highly pathogenic avian influenza viruses and the susceptibility of Australia’s native black swans to influenza. This project will generate fundamental knowledge that may help reduce the severity of influenza in avian populations and provide a new insight into the anti-viral response of an iconic Australian bird species.Read moreRead less
Cross-kingdom communications via small non-coding RNAs. This project aims to determine the role of small non-coding RNAs in mosquito-Wolbachia interactions, including Wolbachia microRNAs, concentrating on exchanged microRNAs between the two organisms and explore microRNAs effect on Wolbachia maintenance and its anti-viral property. Small non-coding RNAs play significant roles in various biological processes, including host-microorganism interactions. Recent evidence suggests that small RNAs can ....Cross-kingdom communications via small non-coding RNAs. This project aims to determine the role of small non-coding RNAs in mosquito-Wolbachia interactions, including Wolbachia microRNAs, concentrating on exchanged microRNAs between the two organisms and explore microRNAs effect on Wolbachia maintenance and its anti-viral property. Small non-coding RNAs play significant roles in various biological processes, including host-microorganism interactions. Recent evidence suggests that small RNAs can be exchanged between microorganisms and their hosts and regulate gene expression in the other organism. The endosymbiotic bacterium, Wolbachia, has attracted worldwide attention due to inhibiting replication of various vector-borne pathogens in mosquito vectors.Read moreRead less
Regulatory cellular microRNAs and their role in insect anti-viral responses. This project will use cutting edge approaches to reveal fundamental roles of small ribonucleic acid molecules (microRNAs) in insect anti-viral responses and immunity. By manipulating anti-viral immune responses, the project will assist in the design of novel approaches to pest control and abolish/limit transmission of vector-borne viruses such as Dengue virus.
Discovery Early Career Researcher Award - Grant ID: DE120101512
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Investigating the interaction of microRNAs-Wolbachia-Dengue virus in the mosquito vector, Aedes aegypti. This project focuses on using molecular techniques to discover fundamental roles of small RNA molecules (microRNAs) of a key mosquito vector in bacterial symbiosis and Dengue virus infection. It will lead to development of effective approaches in limiting spread of vector and transmission of life threatening viral diseases.
An interdisciplinary approach to host-pathogen interactions in infection. This project aims to understand the molecular and cellular interactions between host and parasite, as well as providing a quantitative framework for analysing infection dynamics in other systems. Infection involves a complex interaction between the host and the parasite, which is very dynamic and therefore difficult to study by traditional sampling and analysis approaches. This project has combined mathematical modelling w ....An interdisciplinary approach to host-pathogen interactions in infection. This project aims to understand the molecular and cellular interactions between host and parasite, as well as providing a quantitative framework for analysing infection dynamics in other systems. Infection involves a complex interaction between the host and the parasite, which is very dynamic and therefore difficult to study by traditional sampling and analysis approaches. This project has combined mathematical modelling with a novel experimental protocol to allow the study of kinetics of parasite replication in vivo. Expected outcomes will provide significant benefits, such as new avenues for vaccination and immune intervention.Read moreRead less
Understanding the dynamics of malaria infection. Malaria infection kills around one million patients each year and this project involves an interdisciplinary team who will directly measure how the parasite grows and is killed by the immune system. A better understanding of parasite growth and control will help develop better drugs therapy and vaccination for this important infection.
Discovery Early Career Researcher Award - Grant ID: DE130101169
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Understanding how bacteria become sticky. This study will investigate the machinery used by bacteria to build specialised sticky fibres which allow them to attach to surfaces. The outcomes will significantly advance our understanding of how bacteria generate molecular weapons enabling them to survive and to infect humans and animals.
New drugs against parasitic nematodes of livestock animals. New drugs against parasitic nematodes of livestock animals. This project aims to develop an innovative technology platform to deliver novel anti-infectives as biotechnological outcomes, using postgenomics, computing and chemistry. Advanced molecular, computer and chemistry technologies provide unprecedented opportunities to design radically new interventions against socioeconomically important infectious diseases affecting billions of a ....New drugs against parasitic nematodes of livestock animals. New drugs against parasitic nematodes of livestock animals. This project aims to develop an innovative technology platform to deliver novel anti-infectives as biotechnological outcomes, using postgenomics, computing and chemistry. Advanced molecular, computer and chemistry technologies provide unprecedented opportunities to design radically new interventions against socioeconomically important infectious diseases affecting billions of animals worldwide. Anticipated outcomes are the design of radically new chemotherapies to control parasitic diseases, the translation of fundamental research into biotechnological outcomes, international visibility of Australian science, and a solid skills- and knowledge-base in veterinary drug development.Read moreRead less
Epigenetic regulation in bacteria. This project aims to understand the effect of DNA modification on gene regulation in the bacterial organism Escherichia coli, which causes urinary tract infection worldwide. High-throughput DNA sequencing technologies mean one can determine the entire genetic blueprint of a bacterium – its genome – accurately, quickly and cheaply. Single-molecule real-time sequencing provides a complete read-out of a bacterial genome (genetic data) and chemical modifications of ....Epigenetic regulation in bacteria. This project aims to understand the effect of DNA modification on gene regulation in the bacterial organism Escherichia coli, which causes urinary tract infection worldwide. High-throughput DNA sequencing technologies mean one can determine the entire genetic blueprint of a bacterium – its genome – accurately, quickly and cheaply. Single-molecule real-time sequencing provides a complete read-out of a bacterial genome (genetic data) and chemical modifications of the DNA (epigenetic data). Epigenetic data can affect regulation: how genes are switched off and on. This project seeks to harness the power of single-molecule DNA sequencing, together with state-of-the-art genomic and molecular approaches, to better understand the impact of DNA modification on gene regulation in the model bacterial organism, Escherichia coli. This work will support advanced training in bioinformatics and microbiology and improve our understanding of regulation in all bacteria.Read moreRead less