Discovery Early Career Researcher Award - Grant ID: DE190101053
Funder
Australian Research Council
Funding Amount
$421,656.00
Summary
Archaeal vesicles: new insights into viral evolution and DNA transfer. This project aims to determine the basis for plasmid and membrane vesicle generation and DNA transfer at the cellular and molecular level. Recent discovery of plasmid vesicles, which transfer plasmid DNA between host cells using viral capsid-like membrane vesicles, suggests they may be an evolutionary precursor for virus particles. The expected project outcomes include the first substantive characterisation of membrane vesicl ....Archaeal vesicles: new insights into viral evolution and DNA transfer. This project aims to determine the basis for plasmid and membrane vesicle generation and DNA transfer at the cellular and molecular level. Recent discovery of plasmid vesicles, which transfer plasmid DNA between host cells using viral capsid-like membrane vesicles, suggests they may be an evolutionary precursor for virus particles. The expected project outcomes include the first substantive characterisation of membrane vesicles in the phylum Euryarchaeota, how plasmid vesicles are generated and transmitted, and new insights into how viruses may evolve. This may lead to new avenues for preventing viral transmission and supporting development of new and improved applications biotechnology and the safe delivery of vaccines or genes in animals and humans.Read moreRead less
Maintaining fidelity in viral Ribonucleic acid (RNA) polymerases. This project will provide informed insights into the dynamics of viruses that currently impact a healthy start to life, ageing well and productively, and preventative healthcare. The analysis of viruses that cause gastroenteritis outbreaks will increase our understanding of how these viruses replicate and spread.
Development of SELEX technology (Systematic Evolution of Ligands by EXponential enrichment). A recently developed in vitro genetic selection technique has allowed the isolation of oligonucleotides that can bind target molecules with high affinity and specificity. The strategy know as SELEX (Systematic Evolution of Ligands by EXponential enrichment) uses protein biochemistry and PCR technology, with subsequent repeated rounds of selection and amplification, to screen vast libraries of oligonucle ....Development of SELEX technology (Systematic Evolution of Ligands by EXponential enrichment). A recently developed in vitro genetic selection technique has allowed the isolation of oligonucleotides that can bind target molecules with high affinity and specificity. The strategy know as SELEX (Systematic Evolution of Ligands by EXponential enrichment) uses protein biochemistry and PCR technology, with subsequent repeated rounds of selection and amplification, to screen vast libraries of oligonucleotides (RNA or DNA) for their ability to bind target proteins. This procedure will be developed by UNSW in collaboration with the biotech company BTF Plc., Ltd., to be used in two applications. The first is the research interest of UNSW and involves the development of aptamers against hepatitis C virus. The second lies within the interests of BTF and will involve the development of aptamers against the water borne pathogen Cryptosporidium parvum.Read moreRead less
Molecular and antibody analysis of cytomegalovirus (CMV) infection of fetal and placental cells. CMV is a beta herpesvirus with many unknown molecular mechanisms associated with cellular infection. The virus infects placental cells in vivo, although pathogenesis of viral damage to these cells has been extremely difficult to study in vitro. We have commenced a study to i) demonstrate the molecular accompaniments of infection of placental cells in vitro, ii) determine the genotypic characteristics ....Molecular and antibody analysis of cytomegalovirus (CMV) infection of fetal and placental cells. CMV is a beta herpesvirus with many unknown molecular mechanisms associated with cellular infection. The virus infects placental cells in vivo, although pathogenesis of viral damage to these cells has been extremely difficult to study in vitro. We have commenced a study to i) demonstrate the molecular accompaniments of infection of placental cells in vitro, ii) determine the genotypic characteristics of congenital CMV infections, in collaboration with Abbott Diagnostics, and iii) produce an in vivo model of CMV infection to demonstrate the pathogenesis of cellular injury. The combination of molecular expertise at UNSW with monoclonal antibody expertise from Abbott Diagnostics mean this project is unique worldwide.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989564
Funder
Australian Research Council
Funding Amount
$150,000.00
Summary
State-of-the-art facility for human and animal virus research in the Canberra and surrounding regions. New viral diseases continue to emerge and old viruses re-emerge to pose a threat to human and animal health. To combat these, we propose a dedicated viral disease research facility. The centre will include experienced researchers, biotechnology companies and government agencies working on discovery, prevention and treatment of viral diseases. Forging strong scientific links between these organi ....State-of-the-art facility for human and animal virus research in the Canberra and surrounding regions. New viral diseases continue to emerge and old viruses re-emerge to pose a threat to human and animal health. To combat these, we propose a dedicated viral disease research facility. The centre will include experienced researchers, biotechnology companies and government agencies working on discovery, prevention and treatment of viral diseases. Forging strong scientific links between these organisations will considerably enhance the productivity of these researchers, increase their collaborative and scientific outputs and allow for training of students in the latest technologies. The facility will provide researchers with cutting-edge instrumentation for nationally and internationally important projects that would benefit human health.Read moreRead less
Anthocyanin Inhibitors to the Influenza Virus. The increasing resistance of circulating influenza strains to current anti-viral inhibitors has prompted an investigation to screen, design, synthesize and evaluate a new class of natural product based inhibitors to the virus employing novel and innovative mass spectrometry, computational and structural approaches. Preliminary studies reveal they offer benefits in terms of a different mode of binding to influenza neuraminidase, remote from many know ....Anthocyanin Inhibitors to the Influenza Virus. The increasing resistance of circulating influenza strains to current anti-viral inhibitors has prompted an investigation to screen, design, synthesize and evaluate a new class of natural product based inhibitors to the virus employing novel and innovative mass spectrometry, computational and structural approaches. Preliminary studies reveal they offer benefits in terms of a different mode of binding to influenza neuraminidase, remote from many known resistance mutations, and may have specific practicality against N1 neuraminidase in H1N1 and H5N1 viruses responsible for all pandemics of the 20th and 21st centuries. The research will enable the potential of these inhibitors to be fully assessed at the molecular level for the first time.Read moreRead less
Revealing the evolutionary and ecological dynamics of avian influenza virus. This project aims to understand how avian influenza virus (AIV) emerges, evolves and spreads in wild birds. AIV has the potential to devastate the poultry industry and cause human pandemics, but the factors that shape the genetic diversity of AIV in its wild bird reservoir are poorly understood. The project plans to combine genomic, ecological and phylogenetic approaches to reveal key aspects of AIV evolution, as well a ....Revealing the evolutionary and ecological dynamics of avian influenza virus. This project aims to understand how avian influenza virus (AIV) emerges, evolves and spreads in wild birds. AIV has the potential to devastate the poultry industry and cause human pandemics, but the factors that shape the genetic diversity of AIV in its wild bird reservoir are poorly understood. The project plans to combine genomic, ecological and phylogenetic approaches to reveal key aspects of AIV evolution, as well as the risk for future viral emergence. Using sampling sites in Australia and Antarctica, it plans to investigate AIV diversity, the evolutionary dynamics of AIV in wild birds and poultry, and the role played by environmental transmission in AIV ecology.Read moreRead less
The effect of age on regulatory T cell control of the innate and adaptive antiviral immune responses. Viral pathogens are a lead cause of infant mortality in the world. This project will define how T regulatory cells limit protective antiviral immune responses in the young. This information is critical for the development of potent antiviral vaccines that are effective from the newborn period without inducing autoimmunity. It will also provide novel insight into the way T regulatory cells can b ....The effect of age on regulatory T cell control of the innate and adaptive antiviral immune responses. Viral pathogens are a lead cause of infant mortality in the world. This project will define how T regulatory cells limit protective antiviral immune responses in the young. This information is critical for the development of potent antiviral vaccines that are effective from the newborn period without inducing autoimmunity. It will also provide novel insight into the way T regulatory cells can be manipulated both to dampen immunity, which can be used to develop strategies to reduce immune mediated disease and limit transplant rejection. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200100977
Funder
Australian Research Council
Funding Amount
$419,016.00
Summary
How ecology shapes the viromes of wild birds. This project will reveal the host factors associated with the diversity, evolution and dynamics of viruses using state-of-the-art metatranscriptomics in Australian wild birds. The structure of virus communities and their associated ecological drivers in wild animal hosts remain a black-box, even though they are the largest source of viral diversity in nature. This project expects to generate key insights into host-associated drivers of viral communit ....How ecology shapes the viromes of wild birds. This project will reveal the host factors associated with the diversity, evolution and dynamics of viruses using state-of-the-art metatranscriptomics in Australian wild birds. The structure of virus communities and their associated ecological drivers in wild animal hosts remain a black-box, even though they are the largest source of viral diversity in nature. This project expects to generate key insights into host-associated drivers of viral community dynamics and the subsequent effect of anthropogenic factors such as urbanisation and poultry production. Identifying host factors that affect viral ecology in wild birds will constitute a cornerstone in understanding the emergence of virulent viruses and/or their spread to poultry or humansRead moreRead less
Australian Laureate Fellowships - Grant ID: FL170100022
Funder
Australian Research Council
Funding Amount
$3,402,903.00
Summary
Redefining virus ecology and evolution. This project aims to employ novel genomic analyses of viruses from Australian fauna to resolve major questions in RNA virus ecology and evolution, and is expected to reveal the basic processes that shape the virosphere, determine how viruses jump species to emerge and cause disease in new hosts, and how viruses evolve new levels of virulence. The research will provide a new understanding of how viruses evolve and contribute to global ecosystems and develop ....Redefining virus ecology and evolution. This project aims to employ novel genomic analyses of viruses from Australian fauna to resolve major questions in RNA virus ecology and evolution, and is expected to reveal the basic processes that shape the virosphere, determine how viruses jump species to emerge and cause disease in new hosts, and how viruses evolve new levels of virulence. The research will provide a new understanding of how viruses evolve and contribute to global ecosystems and develop new bioinformatics tools to identify and analyse highly divergent genome sequences through studying meta-transcriptomic data from diverse animal phyla, from prokaryotes and basal eukaryotes, from iconic native mammalian species and their major invasive pests. The benefits provided will include determining the viromes of native and invasive species and enhancing the efforts to protect iconic Australian species from infectious disease.Read moreRead less