Enhancing Vaccine Efficacy By Harnessing Dendritic Cell Receptors And Their Unique Properties
Funder
National Health and Medical Research Council
Funding Amount
$687,519.00
Summary
Potent vaccination might be achieved by using monoclonal antibodies as magic bullets to target vaccines to special cells in the body. We show that targeting these special cells by using monoclonal antibodies that recognise Clec9A is effective, perhaps because it brings several different immune cells together so that they orchestrate very efficient immune responses. This application investigates how targeting Clec9A allows strong vaccination so that we can apply this to new generation vaccines.
Modulating Immune Responses By Targeting Dendritic Cells Using Dendritic Cell Specific Markers.
Funder
National Health and Medical Research Council
Funding Amount
$197,750.00
Summary
The ability to modulate immune responses would have major health benefits. Dendritic cells (DC) are key regulators of the immune system. Different types of DC possess different cell surface molecules and have differing regulatory functions. We have identified four novel DC surface molecules that can be used to target different types of DC. We aim to use antibodies against these molecules to either enhance the effectiveness of vaccines or to suppress autoimmune diseases.
Antigen Receptor Sharing By Lymphocytes During An Immune Response
Funder
National Health and Medical Research Council
Funding Amount
$286,328.00
Summary
A successful immune response relies on the ability of immune cells to quickly mount a specific offensive against invading foreign pathogens like bacteria or viruses. The specificity of this offensive is governed by receptors that can recognise pathogens. To survive an infection the immune system must rapidly expand the number of immune cells that have receptors that recognise, and can therefore specifically combat, the infection. The underlying theory of immunology, the clonal selection theory, ....A successful immune response relies on the ability of immune cells to quickly mount a specific offensive against invading foreign pathogens like bacteria or viruses. The specificity of this offensive is governed by receptors that can recognise pathogens. To survive an infection the immune system must rapidly expand the number of immune cells that have receptors that recognise, and can therefore specifically combat, the infection. The underlying theory of immunology, the clonal selection theory, states that this expansion is mediated by the proliferation of immune cells selected on the basis of expressing a pathogen specific receptor. We hypothesise that in addition to this proliferation the immune system may also expand the number of immune cells expressing pathogen-specific receptors by transferring these receptors between cells by a means of cell-membrane sharing. Indeed, we have evidence that this does occur both in the test tube and in animals and can function to amplify the number of immune cells that can specifically recognise a pathogen and thereby help with immune response development. This grant aims to further advance our understanding of this novel phenomenon.Read moreRead less
Cells of the immune system need to recognise characteristic viral and bacterial molecules, in order to identify infection. Some immune cells can detect the presence of viral and bacterial DNA. The cells respond by making a number of anti-viral or anti-bacterial molecules, as well as activating other cells to fight the infection. The effect of bacterial DNA can be mimicked by certain short synthetic pieces of DNA. The potent activity of this synthetic DNA (termed CpG DNA ) is being exploited in a ....Cells of the immune system need to recognise characteristic viral and bacterial molecules, in order to identify infection. Some immune cells can detect the presence of viral and bacterial DNA. The cells respond by making a number of anti-viral or anti-bacterial molecules, as well as activating other cells to fight the infection. The effect of bacterial DNA can be mimicked by certain short synthetic pieces of DNA. The potent activity of this synthetic DNA (termed CpG DNA ) is being exploited in a number of clinical trials for treatment of cancer and allergy, as well as to improve vaccinations. Despite the rapid advance towards clinical application, there is still much basic information to learn about how CpG DNA acts on cells. The molecule to which DNA binds in order to activate the cells is called TLR9. TLR9 is not on the surface of cells, but within cells. In a bacterial infection, cells called macrophages engulf and digest bacteria and release the bacterial DNA within the cell, where it binds to TLR9. In other cases, including when CpG DNA is used therapeutically, the DNA needs to be taken up into the cell. Evidence shows that there is a receptor on the cell surface which binds DNA, and takes it into the cell. In this project we propose to identify this DNA uptake receptor. Apart from the use of CpG DNA, there are a number of other proposals for the therapeutic use of DNA. Although it is known that DNA enters into cells, the route for this has not been established. Whilst CpG DNA can activate immune cells, some other distinct DNA molecules can prevent the activation. We will examine whether these inhibitory DNA molecules bind more effectively to TLR9 than the CpG DNA, but do not activate the cell. These inhibitory molecules are proposed as a therapy for the autoimmune disease lupus, which involves inappropriate responses to DNA, and is thought to involve TLR9. In order to develop therapies, a detailed knowledge of how they work is essential.Read moreRead less
Regulation Of T Cell Effector Function In Peripheral Tissues
Funder
National Health and Medical Research Council
Funding Amount
$698,550.00
Summary
Protection from infections relies on different types of immune cells. While some of these cells are found in the blood, others reside in peripheral tissues such as the skin. We will analyse the function of these peripheral immune cells to understand how they work to fight off infections. We will also investigate how so-called memory cells that permanently reside in peripheral tissues can protect from re-infection with similar bacteria or viruses.
The Molecular And Cellular Trajectories Of Clonal Dendritic Cell Development
Funder
National Health and Medical Research Council
Funding Amount
$826,742.00
Summary
Dendritic cells (DCs) are a blood cell type with a crucial role in our immune system. They are made in the bone marrow from stem and progenitor cells. How each of these cells individually makes DCs is complex and dynamic. We seek to understand this using cutting edge technologies to track each cell’s step-by-step role in this important process. This knowledge may help the use of DCs in the treatment of several diseases including autoimmunity and cancer.
The Role Of CD1-restricted T Cells In Health And Disease
Funder
National Health and Medical Research Council
Funding Amount
$431,000.00
Summary
The human immune system requires T cells for survival. Specialised populations of T cells exist that patrol the body and target unwanted lipid molecules expressed by bacteria or by cells that have become abnormal or cancerous. I will identify these T cells in human blood and skin and determine their role in protection against disease. I will explore the types of lipids molecules recognised by these T cells and use this information to help prevent human diseases.
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
Molecular And Cellular Control Of Human Th9 Cell Differentiation In Health And Disease
Funder
National Health and Medical Research Council
Funding Amount
$550,888.00
Summary
T helper 9 (Th9) cells are a recently defined population of CD4+ T cells that have been implicated in immunological disorders ranging from allergy, asthma, inflammatory bowel disease, and cancer, to host defence against fungal and parasitic infections. As such, Th9 cells are extremely important to human health and disease. This project aims to define the mechanisms involved in the generation, regulation and function of human Th9 cells.
Asymmetric Cell Divison In T Cell Development: Consequences For Immunity And Cancer
Funder
National Health and Medical Research Council
Funding Amount
$642,608.00
Summary
Human health depends upon the development of an immune system that can effectively control infection without damaging normal tissue. In this project, we assess a new paradigm by which immune cell development might be controlled, in which an immune cell precursor divides in such a way that its two daughters inherit different molecular constitutents that subsequently regulate the adoption of different cell fate. The likely consequences of this phenomonon on immunity and cancer will be explored.