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Understanding T cell immunity induced by infection. We aim to understand how killer T cells are “programmed” upon activation and acquire their characteristic functions and how these are maintained into immunological memory. This proposal will provide insights important for the design and improvement of vaccine strategies to fight pathogens such as influenza, HIV and even tumors.
Cellular and molecular networks controlling protective immunity. This research aims to understand how a handful of master-regulator genes act to program immune cells required for immune responses to microbes, vaccination and to prevent cancer. It will provide a fundamental advance in our understanding of immune cell development and impact strategies aimed at the prevention and treatment of pathogen infections.
Optimising the body's immune response with a Nanopatch that delivers biomolecules to the skin. The team is developing a new improved way to vaccinate against deadly infectious diseases such as influenza and malaria. They believe their Nanopatch technology will boost the power of seasonal influenza vaccination and could even solve vaccine shortages in an influenza pandemic. This is because the Nanopatch needs much less vaccine per person than a conventional syringe. They also predict that vaccine ....Optimising the body's immune response with a Nanopatch that delivers biomolecules to the skin. The team is developing a new improved way to vaccinate against deadly infectious diseases such as influenza and malaria. They believe their Nanopatch technology will boost the power of seasonal influenza vaccination and could even solve vaccine shortages in an influenza pandemic. This is because the Nanopatch needs much less vaccine per person than a conventional syringe. They also predict that vaccines delivered with a Nanopatch will require less refrigeration than conventional vaccines and can be safely administered by individuals without medical training, making the benefits of vaccination accessible to more people more cheaply, even in remote areas.Read moreRead less
Foreign DNA is a danger signal for mammalian cells. This project investigates how cells normally respond to foreign DNA, and is relevant to understanding how the body fights infections, particularly by viruses. The results will help us to design more effective treatments for infectious disease. Studying responses to DNA will also promote the design of new treatments for the autoimmune disease lupus, and help improve technologies or treatments where DNA is introduced into cells or tissues. This ....Foreign DNA is a danger signal for mammalian cells. This project investigates how cells normally respond to foreign DNA, and is relevant to understanding how the body fights infections, particularly by viruses. The results will help us to design more effective treatments for infectious disease. Studying responses to DNA will also promote the design of new treatments for the autoimmune disease lupus, and help improve technologies or treatments where DNA is introduced into cells or tissues. This includes gene therapy, new strategies for vaccination, and the production of proteins as drugs by biotechnology. The project will promote National Research Priorities in the areas of preventative healthcare, ageing well ageing productively, breakthrough science and new technologies.Read moreRead less
Mechanisms of subversion of malarial immunity. This project will aim to understand how the Malaria parasite, which causes one of the world’s deadliest diseases, evades immunity. It will provide novel understanding of immunity against malaria and impact on current strategies to develop an efficacious vaccine or treatment for malaria.
Genetic networks controlling lymphocyte differentiation. White blood cells are produced in the bone marrow from a rare stem cell. This research aims to understand how a handful of master-regulator genes act in the stem cells to produce the white blood cells that are required for our immune response to microbes, vaccination and to prevent cancer.
A molecular and functional investigation of innate-like T cells of the immune system. This project will investigate innate-like T cells, which are at a crossroad between innate and adaptive immunity. A complete knowledge of the cellular function and balance of these cells will offer potential for new immunotherapies associated with infectious and autoimmune disorders.
An investigation into the basis of the T-cell mediated adaptive immune response. Understanding the adaptive immune response to human pathogens is critically important to develop strategies to combat infection. This project will provide a better understanding of how T cells combat viral infection, and will lead to fundamental advances in our understanding of viral immunity and the development of novel immunotherapeutic strategies.
The role of the innate immune response in the asymptomatic nature of viral infections in bats. Bats are natural reservoirs to a variety of viruses, including many that are lethal in humans and other mammals. This project will generate fundamental information on the mechanisms involved in the asymptomatic nature of viral infections in bats and contribute towards the development of new antiviral strategies for other susceptible species.
Drivers of effective T cell immunity. This project aims to investigate the mechanisms underpinning an effective immune response. In doing so, the project expects to decipher the various determinants of T cell immunity and explore how these determinants are integrated to generate effective immunity. The project will use a multidisciplinary approach to investigate antigen abundance and developmental, structural, and molecular aspects of T cells, expecting to significantly enhance our fundamental u ....Drivers of effective T cell immunity. This project aims to investigate the mechanisms underpinning an effective immune response. In doing so, the project expects to decipher the various determinants of T cell immunity and explore how these determinants are integrated to generate effective immunity. The project will use a multidisciplinary approach to investigate antigen abundance and developmental, structural, and molecular aspects of T cells, expecting to significantly enhance our fundamental understanding of mechanisms underpinning functional T cell responses, build interdisciplinary collaborations, and significantly advance the field of T cell biology.Read moreRead less