During an immune response a white blood cell, the T lymphocyte, receives a series of signals that manipulate cell survival and proliferation. The team at WEHI will identify the effects of key signals on the molecular control of T cell survival. The results will be used to test a new method for inducing tolerance and dampening unwanted immune responses, such as during tissue graft rejection and autoimmunity.
Applying Quantitative Immunology To The Analysis Of Complex Genetic Diseases
Funder
National Health and Medical Research Council
Funding Amount
$864,596.00
Summary
The immune response of each individual varies. For some, the response invoked by foreign challenge is weak, leading to a lifetime of difficulty with infection. For others, the response is stronger, yielding excellent immunity, but opening the potential for overactive responses to self-material and autoimmune disease. We have a new theory for how the health of our immune system can be measured and we aim to apply it to understand the genesis of the many different forms of human immune diseases.
Understanding the immune response is proving extremely complex and promising results for disease treatments from animal models are often difficult to translate to new clinical therapies. My research is unearthing weaknesses in our current knowledge of the immune system and seeking to replace them with a foundation that can exploit new developments in computer modelling and systems biology. In this way I aim to rationally manipulate the immune response.
Understanding the immune response is proving extremely complex and promising results for disease treatments from animal models are often difficult to translate to new clinical therapies. My research is unearthing weaknesses in our current knowledge of the immune system and seeking to replace them with a foundation that can exploit new developments in computer modelling and systems biology. In this way I aim to rationally manipulate the immune response.
Dendritic cells (DCs) are the body’s sentinels, with three specialized subtypes. They monitor for infections and cancer and then activate immune T cells to clear it. Interestingly, they can all arise from a single cell, but the precise steps are unknown. By literally filming this process and analyzing the movie, we hope to draw the ‘family trees’ that lead to their generation. This knowledge will offer crucial clues as to how to boost or reduce their numbers for medical applications.
Mapping The Steps And Deciphering The Mechanisms Crucial In Dendritic Cell Development.
Funder
National Health and Medical Research Council
Funding Amount
$582,064.00
Summary
Dendritic cells (DCs) are a type of white blood that kick-start immune responses. There are various types of DCs that specialize in, for example, clearing viral, bacterial or fungal infections, and are even used to fight cancer. Understanding how DCs grow, therefore, has many clinical benefits. This project aims to understand these processes and identify new regulators of their growth using cutting edge technologies and strategies.
An investigation into CD1a, a versatile antigen-presenting molecule. This project aims to investigate how T lymphocytes are activated by lipids presented by the skin-associated antigen-presenting molecule, CD1a. Using X-ray crystallography and cellular immunology, we will provide fundamental insight into this poorly understood immunological axis. We will determine the molecular basis for how CD1a presents diverse self and foreign lipids, and how such CD1a-lipid complexes are recognised by the r ....An investigation into CD1a, a versatile antigen-presenting molecule. This project aims to investigate how T lymphocytes are activated by lipids presented by the skin-associated antigen-presenting molecule, CD1a. Using X-ray crystallography and cellular immunology, we will provide fundamental insight into this poorly understood immunological axis. We will determine the molecular basis for how CD1a presents diverse self and foreign lipids, and how such CD1a-lipid complexes are recognised by the responding T cells. This basic science discovery project will provide substantial new knowledge in the burgeoning field of lipid-mediated immunity, which should ultimately lead to new therapies targeting the CD1a lipid display molecule to either prevent immune mediated damage or promote protective immunity as required.Read moreRead less
Investigating gamma/delta T cell receptor recognition determinants. The immune system has evolved to protect hosts from pathogens. T cells are a critical component of the immune system that can recognise infected host cells. However, there remains many facets of T cell function that we do not understand. This project aims to investigate a major aspect of T cell immunity that is poorly understood, namely, gamma/delta T cell immunity. Specifically, using a multi-disciplinary approach, the anticip ....Investigating gamma/delta T cell receptor recognition determinants. The immune system has evolved to protect hosts from pathogens. T cells are a critical component of the immune system that can recognise infected host cells. However, there remains many facets of T cell function that we do not understand. This project aims to investigate a major aspect of T cell immunity that is poorly understood, namely, gamma/delta T cell immunity. Specifically, using a multi-disciplinary approach, the anticipated outcome of the project is to unearth the molecular recognition determinants of gamma/delta T cells. The intended outcome is to provide basic fundamental insights and conceptual advances into a poorly understood, but crucial, component of the immune system. Read moreRead less