The cellular basis of sex-specific responses to virus infection. This project aims to explore how the sex of cells impacts virus infections in culture. To date, the sex of cells in culture has been overlooked as an important source of biological variability, but may be found to affect basic science through to anti-viral drug discovery. Using a model in which a virus can be adapted to grow better in cells of a single sex, this project expects to generate new knowledge about how sex differences im ....The cellular basis of sex-specific responses to virus infection. This project aims to explore how the sex of cells impacts virus infections in culture. To date, the sex of cells in culture has been overlooked as an important source of biological variability, but may be found to affect basic science through to anti-viral drug discovery. Using a model in which a virus can be adapted to grow better in cells of a single sex, this project expects to generate new knowledge about how sex differences impact virus-host interactions. This project expects to provide new insights into sex-based differences in how cells detect and respond to virus infection, and the extent to which the sex of cells impacts viruses in general.Read moreRead less
Why certain viruses don't get along in mosquitoes. The molecular mechanism. The overall goal of this project is to obtain an understanding of how certain insect-only viruses make mosquitoes incapable of transmitting diseases. These viruses, called insect-specific flaviviruses, can be employed as biocontrol agents for mosquito-borne human and veterinary diseases. However as it is currently unknown how exactly they affect mosquitoes, the safety and efficacy of their use can't be predicted. The pro ....Why certain viruses don't get along in mosquitoes. The molecular mechanism. The overall goal of this project is to obtain an understanding of how certain insect-only viruses make mosquitoes incapable of transmitting diseases. These viruses, called insect-specific flaviviruses, can be employed as biocontrol agents for mosquito-borne human and veterinary diseases. However as it is currently unknown how exactly they affect mosquitoes, the safety and efficacy of their use can't be predicted. The proposed project will dissect the very intricate mechanisms of interactions between insect-specific flaviviruses and mosquitoes and explain how exactly they prevent disease transmission. It should generate novel fundamental knowledge, implement innovative methodologies and provide training for students and junior scientist. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210101145
Funder
Australian Research Council
Funding Amount
$414,662.00
Summary
Investigating novel neurobiological mechanisms in rabies infection. This project aims to better understand the biology and functioning of the nervous system using an innovative multi-disciplinary approach informed by the rabies virus. The study intends to identify the molecular mechanism responsible for self-destruction in neurons. The project aims to gain this new knowledge by investigating the novel natural ability of rabies virus to subdue self-destruction mechanism in neurons. The principal ....Investigating novel neurobiological mechanisms in rabies infection. This project aims to better understand the biology and functioning of the nervous system using an innovative multi-disciplinary approach informed by the rabies virus. The study intends to identify the molecular mechanism responsible for self-destruction in neurons. The project aims to gain this new knowledge by investigating the novel natural ability of rabies virus to subdue self-destruction mechanism in neurons. The principal benefit is the gain of detailed knowledge about a fundamental biological mechanism at the intersection of neurobiology and virology. This has the potential to inform future research in areas such as the maintenance of neuronal health in ageing and better control of rabies infections. Read moreRead less
Defining the antiviral effects of Wolbachia in Aedes aegypti mosquitoes. Mosquitoes that carry a bacterium called Wolbachia do not transmit human pathogenic viruses. These mosquitoes are being developed as a biocontrol tool to prevent mosquito-borne diseases. This project aims to define the molecular basis for virus inhibition by Wolbachia. Using unique biological tools including mosquitoes carrying different strains of Wolbachia that do or do not inhibit dengue virus, the project will define ho ....Defining the antiviral effects of Wolbachia in Aedes aegypti mosquitoes. Mosquitoes that carry a bacterium called Wolbachia do not transmit human pathogenic viruses. These mosquitoes are being developed as a biocontrol tool to prevent mosquito-borne diseases. This project aims to define the molecular basis for virus inhibition by Wolbachia. Using unique biological tools including mosquitoes carrying different strains of Wolbachia that do or do not inhibit dengue virus, the project will define how Wolbachia modifies its host to create an antiviral state. The findings will provide insight into how viral pathogens can be suppressed in insect hosts. This may guide future viral disease intervention strategies for diverse areas afflicted by insect-borne viral disease, including human health and agriculture.Read moreRead less
From shape to function: how structured RNA defines insect flaviviruses. The goal of this project is to obtain an understanding of how insect-specific flaviviruses (ISFs) utilise viral noncoding RNAs to enable their replication in mosquitoes. These viruses only replicate in mosquitoes, and not in humans or animals. They can be employed as the biocontrol agents for mosquito-borne diseases as they make mosquitoes incapable of disease transmission. However, it is currently unknown how exactly insect ....From shape to function: how structured RNA defines insect flaviviruses. The goal of this project is to obtain an understanding of how insect-specific flaviviruses (ISFs) utilise viral noncoding RNAs to enable their replication in mosquitoes. These viruses only replicate in mosquitoes, and not in humans or animals. They can be employed as the biocontrol agents for mosquito-borne diseases as they make mosquitoes incapable of disease transmission. However, it is currently unknown how exactly insect-specific flaviviruses affect mosquitoes and this information is vital for informed design of ISF-based interventions. The project will generate new knowledge on functions of noncoding RNAs in ISFs that are hypothesised to have immunomodulatory role in mosquitoes. It will also train students and ECRs.Read moreRead less
Viral and host RNA methylation in mosquitoes. Mosquitoes transmit a variety of viruses to humans and animals through blood feeding. This project aims to investigate one of the most common modifications of RNA molecules, known as N6-methyladenosine (m6A), in an important mosquito vector, Aedes aegypti, and its alterations upon infection with pathogenic as well as mosquito-specific viruses. In addition, m6A modification of viral genomic RNA and its importance in virus replication will be investiga ....Viral and host RNA methylation in mosquitoes. Mosquitoes transmit a variety of viruses to humans and animals through blood feeding. This project aims to investigate one of the most common modifications of RNA molecules, known as N6-methyladenosine (m6A), in an important mosquito vector, Aedes aegypti, and its alterations upon infection with pathogenic as well as mosquito-specific viruses. In addition, m6A modification of viral genomic RNA and its importance in virus replication will be investigated. Expected outcomes of this project include fundamental understanding of RNA methylation in mosquitoes and their role in mosquito biology and virus replication.Read 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
Viral allies: shedding light on beneficial insect viruses. Baculoviruses are rare examples of viruses recognised for their positive impact on human activities. These viruses infect a broad range of insects and have been widely used in biological research, biotechnology and agricultural pest control. This Project aims to elucidate the structure and assembly of these beneficial viruses using advanced structural, biochemical and imaging approaches. The Project is expected to generate high-resolutio ....Viral allies: shedding light on beneficial insect viruses. Baculoviruses are rare examples of viruses recognised for their positive impact on human activities. These viruses infect a broad range of insects and have been widely used in biological research, biotechnology and agricultural pest control. This Project aims to elucidate the structure and assembly of these beneficial viruses using advanced structural, biochemical and imaging approaches. The Project is expected to generate high-resolution models that define hallmarks of a new viral lineage, a significant breakthrough in our understanding of the virosphere, and underpin the future development of innovative baculovirus-based technologies such as selective bioinsecticides for the sustainable control of invasive insects.Read moreRead less