The Mezzanine T Cell Response: Intervening At The Coal Face
Funder
National Health and Medical Research Council
Funding Amount
$765,585.00
Summary
In an initial immune response, specialised cells in lymph nodes tell T cells to multiply; the stimulated T cells depart and enter target tissue (e.g. lung in the case of flu). We describe a new response whereby the target tissue itself can tell T cells to multiply further. This response in target tissues reveals a new way of altering immune responses. This is especially important as in many diseases, the primary lymph node response has already occurred, so cannot be therapeutically intervened.
The Role Of Co-signalling Receptors In Cytotoxic Lymphocyte Activity During Infection And Cancer
Funder
National Health and Medical Research Council
Funding Amount
$739,657.00
Summary
Cytotoxic lymphocytes (CLs) are immune cells that detect and kill cancer cells. CLs recognise ‘stress’ proteins on cancer cells through specialised receptors, and this provides the signal for them to kill. However, some cancer cells, such as leukemic cells, can interfere with this recognition to avoid killing by immune cells. This project will investigate the mechanism of recognition and killing of cancer cells by CLs, using both mouse models and cells from patients with acute myeloid leukemia.
The Mechanisms Of Epithelial Cell Survival That Govern Thymus Function
Funder
National Health and Medical Research Council
Funding Amount
$620,967.00
Summary
The thymus is an organ dedicated to the production of crucial immune cells, called T lymphocytes. Cancer treatments, such as radiation or chemotherapy, destroy thymic function and impair immune recovery in patients. We aim to uncover molecular processes that govern the life and death decisions of cells in the thymus. Our goal is to then use this information to develop treatments to protect this critical organ from damage and improve immune recovery following radiation or chemotherapy.
Targeting Caspase 8 In T-Cell Homeostasis And Disease
Funder
National Health and Medical Research Council
Funding Amount
$1,215,780.00
Summary
Chronic infectious diseases such as HIV, hepatitis B and tuberculosis impose a massive global health burden and new treatments are desperately needed. This proposal investigates a new approach to improve immune responses and clear chronic infections. Our multidisciplinary team will define the molecular and cellular biology underlying this approach and translate our findings by re-purposing a drug already approved for other indications in humans.
A specialised set of T lymphocytes called Mucosal Associated Invariant T (MAIT) cells react against bacteria and yeast, and reside at mucosal sites where the body's immune defences are most easily breached, e.g. respiratory tract and intestinal mucosa. This study investigates the role of MAIT cells in both protection and pathology in bacterial infections. Controlling MAIT cells could help in treating these conditions.
Antigen Presentation, Recognition And The Immune Response
Funder
National Health and Medical Research Council
Funding Amount
$14,927,045.00
Summary
This program focuses on understanding the development of immunity during infection or inflammatory diseases using a broad array of techniques to dissect the function of various immune cell types and to explore the relationship between structure and function of important cell surface molecules. These studies will improve our ability to design new generation vaccines for combating infectious diseases, controlling cancer, or limiting autoimmune or inflammatory diseases.
A Structural Investigation Into The T-cell Response To Epstein Barr Virus Infection
Funder
National Health and Medical Research Council
Funding Amount
$549,000.00
Summary
X-ray crystallography is an essential tool for solving the three-dimensional structure of proteins. Proteins control the biological processes within the cell and it is the precise shape of proteins that determines how they function. Depending on the particular sequence of the amino acids, the so-called building unit of the proteins, the protein molecule bends and forms a distinct, complex shape. This specific three-dimensional shape allows the protein to undertake its specific function, such as ....X-ray crystallography is an essential tool for solving the three-dimensional structure of proteins. Proteins control the biological processes within the cell and it is the precise shape of proteins that determines how they function. Depending on the particular sequence of the amino acids, the so-called building unit of the proteins, the protein molecule bends and forms a distinct, complex shape. This specific three-dimensional shape allows the protein to undertake its specific function, such as binding to other proteins, acting as an enzyme or interacting with nucleic acids. To determine how a protein acts, it is vital to know the precise three-dimensional shape at the atomic level. This proposal is concerned with understanding the precise shape of proteins that control the immune response to Epstein Barr Virus. Epstein Barr Virus is an ubiquitous human pathogen that has being linked to a number of cancers. This work will further our understanding of the immune response to Epstein Barr Virus.Read moreRead less
Antigen Presentation, Recognition And The Immune Response
Funder
National Health and Medical Research Council
Funding Amount
$15,780,848.00
Summary
This program focuses on understanding the development of immune response to viruses and other infectious agents using a broad array of techniques to dissect the function of various immune cell types and to explore the relationship between structure and function of important cell surface molecules. These studies will improve our ability to design new generation vaccines for combating infectious diseases, controlling cancer, or limiting autoimmune diseases like diabetes.
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.
Understanding Universal Immunity To Influenza Viruses
Funder
National Health and Medical Research Council
Funding Amount
$687,975.00
Summary
A/Prof Kedzierska’s work combines cutting-edge basic research with unique clinical studies to define how to generate protective immunity against the pandemic and newly emerged influenza viruses. This research will identify key factors that drive the severe and fatal influenza disease in high-risk groups, including the young, elderly, pregnant women and Indigenous Austraians. Findings on the optimal human immunity to influenza viruses will be applicable to other infectious diseases and cancers.