The Role Of Self Reactive T Cells In The Normal TCR Repertoire
Funder
National Health and Medical Research Council
Funding Amount
$363,601.00
Summary
The immune system is highly regulated and sophisticated in order to distinguish foreign invaders from our own body. Once control is lost in this system, mistakes can happen, and autoimmunity, attack of ones self may result. Surprisingly potentially dangerous ‘fighter’ T cells can be readily found in healthy individuals whom are free from autoimmunity. The aim of this project is to understand how we can survive with these potentially harmful T cells around and what may activate them.
Delineating Immune Circuits For Innate And Adaptive Immune Protection
Funder
National Health and Medical Research Council
Funding Amount
$876,005.00
Summary
The immune system provides the essential frame-work to protect us against infection, disease and to heal tissues after trauma. This is achieved by a complex but elegant network of different types of white blood cells. Understanding the molecular wiring of these cells will provides fundamental insights to how the body fights pathogen infections and cancer and lays the foundation to therapeutic approaches to vaccination and disease treatments.
Induction Of Natural T-Regulatory Cells By Thymic Dendritic Cell Populations
Funder
National Health and Medical Research Council
Funding Amount
$413,775.00
Summary
In this study, we will determine the roles of the antigen presenting cells, namely denderitic cells, in the induction of T-regulatory cell (T-reg) developemnt in the thymus. T-reg cells play important roles in controlling the development of autoimmunity. This study will help to understand the possible causes of autoimmune diseases and to develop new treatments for these diseases.
The Role Of C-Cbl In The Regulation Of T Cell Signalling And Development
Funder
National Health and Medical Research Council
Funding Amount
$527,250.00
Summary
c-Cbl is a member of a multi-adaptor protein family that can interact with many signalling proteins via its different domains. Cbl proteins have been implicated as negative regulators of signalling pathways involving protein tyrosine kinases (PTKs). PTKs are enzymes which add phosphate groups to tyrosine residues on other protein substrates, and the process of tyrosine phosphorylation acts as a potent biochemical switch to turn signalling cascades on and off. Studies of Cbl-deficient (knockout) ....c-Cbl is a member of a multi-adaptor protein family that can interact with many signalling proteins via its different domains. Cbl proteins have been implicated as negative regulators of signalling pathways involving protein tyrosine kinases (PTKs). PTKs are enzymes which add phosphate groups to tyrosine residues on other protein substrates, and the process of tyrosine phosphorylation acts as a potent biochemical switch to turn signalling cascades on and off. Studies of Cbl-deficient (knockout) mice show that Cbl proteins are important in regulating the development of, and signalling by, cells of the immune system called T cells. c-Cbl knockout mice show greatly enhanced PTK-signalling responses and deregulated activity of a PTK called ZAP-70. The mechanism of this is not known, but analysis of a c-Cbl mutant mouse shows that this is not dependent on the tyrosine kinase binding (TKB) domain of c-Cbl. Therefore other functional domains of Cbl must be responsible for the increased signalling response in the c-Cbl knockout mouse. One candidate is the highly conserved RING finger domain which can modify Cbl-associated PTKs by addition of ubiquitin molecules. Ubiquitination of a protein often, but not always, leads to its degradation, and this could be how Cbl controls the strength and duration of signalling in T cells. However there may be other functions of the conserved RING finger yet to be identified. c-Cbl itself is prominently and very rapidly modified by tyrosine phosphorylation on tyrosine 737 by the Fyn PTK following T cell activation, but the role of this modification is not known and could also be essential for c-Cbl s function in T cells. We plan to investigate the roles of the RING finger domain and Fyn-mediated tyrosine phosphorylation in c-Cbl regulation of T cell signalling by analyzing knock-in mice that carry specific mutations disrupting the RING finger or tyrosine 737 in the c-Cbl gene.Read moreRead less
Co-ordinating The Intrinsic And Extrinsic Arms Of Hematopoiesis
Funder
National Health and Medical Research Council
Funding Amount
$615,286.00
Summary
The cell types of the blood, such as red and white blood cells, are produced in the bone marrow from a rare stem cell. The stem cell uses a handfull of important master-regulatory genes that act in a hierarchy to promote the blood cell differentiation process. This research aims to understand how these master-regulators function in isolation and together in producing the white blood cells that are required for our immune response to microbes, vaccination and to prevent cancer.
The Transcriptional Control Of The Dendritic Cell Lineages
Funder
National Health and Medical Research Council
Funding Amount
$669,872.00
Summary
The immune system can discriminate between invading microorganisms and the body's own tissues. Dendritic cells are specialised to alert the immune system in the case of infection. In this project we aim to understand how dendritic cells are generated and how they function to control the immune response. We will achieve this aim by using state of the art genomic technologies to describe the genetic programme of dendritic cells. We hope that this knowledge will enable us to better harness the immu ....The immune system can discriminate between invading microorganisms and the body's own tissues. Dendritic cells are specialised to alert the immune system in the case of infection. In this project we aim to understand how dendritic cells are generated and how they function to control the immune response. We will achieve this aim by using state of the art genomic technologies to describe the genetic programme of dendritic cells. We hope that this knowledge will enable us to better harness the immune response in situations such as vaccination.Read moreRead less
The cell types of the blood, such as red and white blood cells, are produced in the bone marrow from a rare stem cell. The stem cell uses a handful of important master-regulatory genes that act in a hierarchy to promote the blood cell differentiation process. This research aims to understand how these master-regulators function in isolation and together in producing the white blood cells that are required for our immune response to microbes, vaccination and to prevent cancer.
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.
Stem Cell Based Strategies For Re-establishing T Cell Immunity In Aging And Disease.
Funder
National Health and Medical Research Council
Funding Amount
$845,777.00
Summary
The thymus is the organ responsible for producing T cells, a key cell type in the body’s immune system. Certain cancer treatments damage the thymus, compromising the immune system and leaving patients susceptible to opportunistic infections. This proposal will develop clinically applicable strategies for generating functional human thymic mini-organs that could eventually help restore the immune system of people receiving treatment for cancer.
While current influenza vaccines blunt winter epidemics, they must be updated frequently to keep up with virus mutation and they do not protect against pandemics caused by new flu viruses (such as bird flu). This program will define how flu virus interacts with the immune system to generate immunity mediated particularly by “killer” T cells. We will use this knowledge to develop and evaluate vaccines that induce long-lasting T-cell immunity that can protect against both seasonal and pandemic flu ....While current influenza vaccines blunt winter epidemics, they must be updated frequently to keep up with virus mutation and they do not protect against pandemics caused by new flu viruses (such as bird flu). This program will define how flu virus interacts with the immune system to generate immunity mediated particularly by “killer” T cells. We will use this knowledge to develop and evaluate vaccines that induce long-lasting T-cell immunity that can protect against both seasonal and pandemic flu.Read moreRead less