Discovery Early Career Researcher Award - Grant ID: DE120100691
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Argonaute proteins and the mammalian antiviral response. Awarded the Nobel Prize for Medicine in 2006, RNA interference (RNAi) is a natural process that plants use to attack viruses. Humans possess all of the tools for RNAi, but whether it is used for antiviral defense is unknown. This project aims to uncover this immune process which will open new avenues to treat virus infections, from influenza to HIV.
Dissecting the Parameters for the Generation of Cytotoxic T Lymphocyte Immunity. This project aims to identify mechanisms by which antigen-presenting cells, such as dendritic cells, prime CD8+ T cells to generate effector and memory populations at the molecular level. The specific intention is to identify reagents capable of licensing dendritic cells, and examine the down-stream gene products/pathways generated by these signals using microarray analyses. Such knowledge will provide new insight i ....Dissecting the Parameters for the Generation of Cytotoxic T Lymphocyte Immunity. This project aims to identify mechanisms by which antigen-presenting cells, such as dendritic cells, prime CD8+ T cells to generate effector and memory populations at the molecular level. The specific intention is to identify reagents capable of licensing dendritic cells, and examine the down-stream gene products/pathways generated by these signals using microarray analyses. Such knowledge will provide new insight into CTL generation by providing greater understanding of how multicellular systems function both at the cellular and molecular level.Read moreRead less
Imaging of immune responses to pathogens in vivo. This proposal represents an excellent opportunity for Australian science to participate in state-of-the-art research into the immune system and to be internationally competitive with the best researchers in the field. By combining advanced microscopy techniques with well developed biological models used by researchers at the University of Melbourne, this project will greatly improve our understanding of the dynamic interactions that occur betwee ....Imaging of immune responses to pathogens in vivo. This proposal represents an excellent opportunity for Australian science to participate in state-of-the-art research into the immune system and to be internationally competitive with the best researchers in the field. By combining advanced microscopy techniques with well developed biological models used by researchers at the University of Melbourne, this project will greatly improve our understanding of the dynamic interactions that occur between cells of the immune system during infectious diseases. The insight provided by this project will facilitate the design of better vaccines for protection against diseases, including influenza.Read moreRead less
The role of immuno-exosomes in innate immunity. This project aims to determine the role of exosomes (EV) in innate immunity. Exosomes are extracellular vesicles secreted by mammalian cells that have an important biological function in intercellular communication by transferring biologically active proteins, lipids, and RNAs to neighbouring or distant cells. Following exposure to a foreign organism, cells dynamically change the protein composition of the EV they secrete. While this data supports ....The role of immuno-exosomes in innate immunity. This project aims to determine the role of exosomes (EV) in innate immunity. Exosomes are extracellular vesicles secreted by mammalian cells that have an important biological function in intercellular communication by transferring biologically active proteins, lipids, and RNAs to neighbouring or distant cells. Following exposure to a foreign organism, cells dynamically change the protein composition of the EV they secrete. While this data supports a role for EV as key players in innate immunity, a full understanding of the biological relevance of these vesicles and how they serve as a cellular defence mechanism is lacking. This project will provide significant benefits such as addressing key questions in EV biology and providing new fundamental insights into a novel and poorly understood component of the innate immune response.Read moreRead less
Studies on peripheral T cell memory. Success in vaccination depends on the ability of the immune system to remember prior encounter with an infectious agent. This immune memory appears to work well for certain infections but not others, essentially meaning that for these diseases, effective vaccines remain unavailable. This application describes experiments based on a new leukocyte or white blood cell population that has been overlooked in studies of immune memory. The work involves identifyin ....Studies on peripheral T cell memory. Success in vaccination depends on the ability of the immune system to remember prior encounter with an infectious agent. This immune memory appears to work well for certain infections but not others, essentially meaning that for these diseases, effective vaccines remain unavailable. This application describes experiments based on a new leukocyte or white blood cell population that has been overlooked in studies of immune memory. The work involves identifying how they are formed and how they behave within the body. This work will therefore contribute to the development and production of new-generation vaccines to these so far uncontrollable infectious diseases.Read moreRead less
Defining novel immune checkpoints controlled by stromal cells. This project seeks to use innovative approaches to elucidate the mechanisms that define the earliest steps required to generate immune responses. The proposal builds on discoveries, including novel preliminary data, from a team with world-leading expertise in immunology, virology and stromal cell biology. The expected findings will provide fundamental insights into novel cellular and molecular interactions between stromal tissue comp ....Defining novel immune checkpoints controlled by stromal cells. This project seeks to use innovative approaches to elucidate the mechanisms that define the earliest steps required to generate immune responses. The proposal builds on discoveries, including novel preliminary data, from a team with world-leading expertise in immunology, virology and stromal cell biology. The expected findings will provide fundamental insights into novel cellular and molecular interactions between stromal tissue components and immune cells that initiate and regulate immune responses. Expected benefits include fundamental advances in knowledge, as well as insights that will ultimately benefit biotechnology and therapeutic applications, and in this way support research priorities linked to advanced manufacturing and health.
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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
Discovery Early Career Researcher Award - Grant ID: DE220100185
Funder
Australian Research Council
Funding Amount
$438,712.00
Summary
Decoding the evolution of killer T cell immunity across human lifetime. The immune system is a potent weapon for protection against pathogens. T cells have a central role as their receptors monitor the body for threats. The thymus (organ) educates receptors to discriminate between healthy and infected cells. Receptor diversity and T cell strength change throughout human life. This project aims to unravel how T cells gain and lose optimal receptors and strength. The aims are to understand 1) The ....Decoding the evolution of killer T cell immunity across human lifetime. The immune system is a potent weapon for protection against pathogens. T cells have a central role as their receptors monitor the body for threats. The thymus (organ) educates receptors to discriminate between healthy and infected cells. Receptor diversity and T cell strength change throughout human life. This project aims to unravel how T cells gain and lose optimal receptors and strength. The aims are to understand 1) The role of thymic education in diversifying receptors 2) Whether gradual loss of thymic education affects receptor diversity 3) The molecular mechanisms underlying T cell strength. The project is essential for understanding how optimal T cell immunity is formed, critical if we wish to harness this to improve healthy aging.Read moreRead less