In Vivo Imaging Of Protective And Malignant B Cell Function
Funder
National Health and Medical Research Council
Funding Amount
$431,412.00
Summary
B cells are responsible for producing antibody that protects us from infection. Disruption of healthy B cell function can lead to a myriad of diseases including immunodeficiency, autoimmunity and blood cancers such as leukaemia. The aim of my work is to use powerful microscopy to visualise how mutated B cells interact with their surrounding environment in real-time. These studies will allow the development of new treatments for cancer and immune conditions that target these interactions.
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
Immune Surveillance Of The CNS During Malaria Infection
Funder
National Health and Medical Research Council
Funding Amount
$617,857.00
Summary
Infections in the central nervous system (CNS) can have profound neurological complications. Neurological disease caused by cerebral malaria (CM) is a lethal complication in humans. We have established a new model of longitudinal imaging of T cell responses in the brain during experimental CM in mice infected with Plasmodium berghei ANKA. This project will investigate the mechanisms of CNS injury and provide fundamental information about T cell responses in the CNS during infection.
Defining The Coordination Of Immune Responses To Pathogens
Funder
National Health and Medical Research Council
Funding Amount
$640,210.00
Summary
Understanding how immune responses are coordinated is critical for the design of new therapies and vaccines to target infectious diseases and cancers. This project will utilise advanced imaging combined with novel tools to dissect the complex interactions that occur between immune cells as they are activated and patrol the body to eliminate infectious pathogens.
The initial step of T cell activation of how the external ligand binding is translated to an increase of receptor phosphorylation at the cytoplasmic side is remain poorly understood. It is believed that the loss of immune recognition in cancer and over reactivity in auto-immune diseases are caused by abnormality of this transmembrane signalling transduction. Clarification of this molecular machinery can provide a molecular basis of those diseases and guidelines of more effective therapies.
Identifying The Ontogeny And Fate Of T Follicular Helper Cells By Two-photon Photoconversion
Funder
National Health and Medical Research Council
Funding Amount
$623,070.00
Summary
The aim of this proposal is to investigate immune cells called T follicular helper cells using a novel microscopy-based method that we have developed. This method lets us ‘tag’ these cells in a way that enables us to distinguish them from all other cells and follow them as they migrate to different immunological compartments during the response. T follicular helper cells are important for protective immune responses against pathogens and a better understanding of this T cell subset will aid vacc ....The aim of this proposal is to investigate immune cells called T follicular helper cells using a novel microscopy-based method that we have developed. This method lets us ‘tag’ these cells in a way that enables us to distinguish them from all other cells and follow them as they migrate to different immunological compartments during the response. T follicular helper cells are important for protective immune responses against pathogens and a better understanding of this T cell subset will aid vaccine design.Read moreRead less
In Vivo Imaging Of Virus-specific T Cell Responses In The Skin
Funder
National Health and Medical Research Council
Funding Amount
$332,258.00
Summary
Effective vaccination against many viral infections such as Herpes Simplex Virus (HSV) may be achieved by directing the cells of the immune system to specific sites in the body where they can lie in wait against the disease. To direct the immune system in this way, we must first understand how immune cells orchestrate themselves in tissues. This project will utilise advanced imaging techniques to study immune cells in real time to understand how they protect against viral infections in the skin.
MPM Non-invasive Imaging Of Biological Interactions Following Drug Delivery With Micro-nanoprojection Patches.
Funder
National Health and Medical Research Council
Funding Amount
$403,612.00
Summary
The overarching aim of my research is to develop and evaluate effective, practical and reproducible physical methods for delivering genes and drugs to specific immunologically-sensitive cells in the skin to ultimately treat and vaccinate against human diseases. I recently patented a method using arrays of nano-scale projections on a patch to accurately, efficiently and safely deliver biomolecules not just to specific skin cells, but also to organelles within them. Conceptually, the delivery devi ....The overarching aim of my research is to develop and evaluate effective, practical and reproducible physical methods for delivering genes and drugs to specific immunologically-sensitive cells in the skin to ultimately treat and vaccinate against human diseases. I recently patented a method using arrays of nano-scale projections on a patch to accurately, efficiently and safely deliver biomolecules not just to specific skin cells, but also to organelles within them. Conceptually, the delivery device is a set of microscopic nanoneedles coated with drug substance and applied to the skin as a small patch. The device is practical, needle-free and pain-free. The aim of this current project is to use the micro-nanoprojection array patches-configured to uniquely deliver biomolecules to cells within given strata-to find: 1) what delivery sites of antigen-expression plasmid- toll like receptor (TLR) agonist lead to strong humoral immune responses in the intact animal. 2) whether delivery of different TLR agonists have different effects on the maturation and migration of the different professional antigen presenting cells (APCs) in the skin, as visualised locally by Multi-Photon Microscopy (MPM). 3) whether differences in APC maturation and migration are associated with different systemic antibody responses. We will identify optimal delivery sites of drugs-vaccines to the skin (layer, cells targeted, duration of delivery) with MPM for desired systemic immune responses. This will have important contributions towards improving immunotherapeutics of major diseases via skin targeting with micro-nanoprojection array patch technologies (and other methods).Read moreRead less