Mechanisms Of B Cell Immunodominance To Influenza Virus
Funder
National Health and Medical Research Council
Funding Amount
$617,611.00
Summary
Current influenza vaccines elicit poor protection against viruses undergoing rapid change or emerging from animal reservoirs. We will define the basis for why highly conserved sites of virus vulnerability, such as the hemagglutinin "stem" domain, are poorly targeted by current vaccines and will assess novel hemagglutinin stem-based vaccines in macaque models of human influenza. Our results will guide the rational design of next-generation vaccines for influenza.
Understanding And Controlling Viral Escape In Influenza
Funder
National Health and Medical Research Council
Funding Amount
$433,156.00
Summary
Introduction of a new influenza strain into human circulation leads to a rapid global spread of the virus (e.g. H1N1-09 pandemic) due to minimal antibody immunity. Established T-cell immunity towards conserved viral regions promotes rapid recovery. However, the protective immunity exerts pressure on influenza, leading to "escape" mutations. We will unravel how the viral mutants emerge and propose strategies for T cell-based protective immunity and vaccine design against influenza.
Interactions Between H5N1 And The Respiratory Epithelium
Funder
National Health and Medical Research Council
Funding Amount
$623,065.00
Summary
This project examines the hypothesis that the severity of H5N1 infection is due to activation of signalling pathways in the lung not activated by human influenza and leads to fluid accumulation in the lungs death of respiratory cells. This study will improve our understanding of influenza infection and identify targets for treatment of H5N1.
Antibody-Dependent Cellular Cytotoxicity Based Immunity To Influenza
Funder
National Health and Medical Research Council
Funding Amount
$677,938.00
Summary
Pandemic influenza causes widespread disease, death and panic. Producing vaccines to new strains takes time. There is a need to produce vaccines that provide partial protection against unknown strains. We identified a type of anti-influenza antibody in people with prior influenza infection that may assist in reducing disease from new influenza strains. We will study these antibodies, understanding how effective they against influenza, with a view to making improved anti-influenza vaccines.
How The Placental Protein Syncytin Impairs Maternal Immune Responses To Influenza
Funder
National Health and Medical Research Council
Funding Amount
$609,862.00
Summary
Pregnant women are known to be highly susceptible to certain viral infections, especially influenza, which results in severe illness and even death. The reason for this transitory susceptibility are unknown. We have found that a protein, Syncytin, has the ability to impair maternal immune responses to influenza We now will determine how it does this and discover potential interventions to reverse these effects.
PB1-F2 Is Critical To Influenza A Virus Pathogenicity Through Activation Of The Inflammasome
Funder
National Health and Medical Research Council
Funding Amount
$663,919.00
Summary
Fatal Influenza A virus infections are excessive inflammation. We identified the IAV protein PB1-F2 as critical in driving excessive inflammation via activating the host inflammasome complex. Our study evaluates PB1-F2-mediated inflammation contribution to inflammatory responses. Identifying PB1-F2 in emerging IAV strains is invaluable in aiding health policy makers to quickly assess fatal IAV pandemics. Our research will potentially identify treatment targets towards reducing this inflammation
Generation Of Protective Immunity Against Severe Influenza Disease In Indigenous Australians
Funder
National Health and Medical Research Council
Funding Amount
$1,630,970.00
Summary
Hospitalisation and death rates from influenza are high in the Indigenous population, especially when a new virus emerges. There is an urgent need for a vaccine that protects against all influenza strains. T cells recognising conserved viral regions elicit such protection. As T cells are restricted by proteins called HLAs, which vary across ethnicities, we will define T cell regions for HLAs prominent in Indigenous Australians and define how to generate protective immunity against influenza.
Real Time Visualisation Of T Cell Cycling During Influenza Immune Responses
Funder
National Health and Medical Research Council
Funding Amount
$589,679.00
Summary
Influenza remains a major health threat, particularly in the elderly population. Here we will unravel the mechanisms underlying the expansion of killer T cells, a crucial part of the anti-influenza immune response. Using intravital multi-photon microscopy, we will follow the cell cycle dynamics of individual T cells in real time during different stages of influenza. We will further elucidate how ageing impacts on T cell proliferation. Together, this will provide insight into the mechanisms of an ....Influenza remains a major health threat, particularly in the elderly population. Here we will unravel the mechanisms underlying the expansion of killer T cells, a crucial part of the anti-influenza immune response. Using intravital multi-photon microscopy, we will follow the cell cycle dynamics of individual T cells in real time during different stages of influenza. We will further elucidate how ageing impacts on T cell proliferation. Together, this will provide insight into the mechanisms of anti-viral immunity and immuno-senescence.Read moreRead less
Understanding Influenza-specific T Cell Immunity In The Indigenous Population
Funder
National Health and Medical Research Council
Funding Amount
$870,112.00
Summary
Hospitalisation and death rates from influenza are high in the Indigenous population. There is an urgent need for one-shot universal vaccine that protects against seasonal and pandemic strains. T cells recognising conserved viral regions can elicit such protection. As T cells are restricted by proteins called HLAs, variable between different ethnicities, we will define T cell regions and their HLA restrictions in the Indigenous population to propose strategies for universal T cell-based protecti ....Hospitalisation and death rates from influenza are high in the Indigenous population. There is an urgent need for one-shot universal vaccine that protects against seasonal and pandemic strains. T cells recognising conserved viral regions can elicit such protection. As T cells are restricted by proteins called HLAs, variable between different ethnicities, we will define T cell regions and their HLA restrictions in the Indigenous population to propose strategies for universal T cell-based protective immunity and vaccine design against influenza.Read moreRead less
Cell Surface Lectin Receptors For Attachment And Entry Of Influenza Viruses Into Cells Of The Innate Immune System
Funder
National Health and Medical Research Council
Funding Amount
$530,094.00
Summary
Influenza virus is a leading cause of respiratory infection and death worldwide. Infection of humans is initiated when the virus contacts cells lining the respiratory tract. Infection of epithelial cells leads to virus amplification whereas infection of immune cells results in virus destruction. Despite extensive research efforts, it is not clear how the virus infects these cells. This project aims to identify receptors on human cells used by influenza virus to attach to and infect immune cells.