A Dendritic Cell Subset Targeting Approach For Defining Immune Function And Tailoring Immunotherapy
Funder
National Health and Medical Research Council
Funding Amount
$692,753.00
Summary
Dendritic cells are important sentinel cells of the immune system that orchestrate our immune responses against invading pathogens. There are different types of dendritic cells and they perform different jobs. We have a series of antibodies that can recognise markers on the surface of different dendritic cells populations. We can use these antibodies as homing devices to deliver foreign material to individual dendritic cell subpopulations and thereby manipulate the type of immune response genera ....Dendritic cells are important sentinel cells of the immune system that orchestrate our immune responses against invading pathogens. There are different types of dendritic cells and they perform different jobs. We have a series of antibodies that can recognise markers on the surface of different dendritic cells populations. We can use these antibodies as homing devices to deliver foreign material to individual dendritic cell subpopulations and thereby manipulate the type of immune response generated. Effectively, we aim to tailor immune responses to fight a particular bacteria, virus, parasite, or even cancer cells. The current proposal will extend the number of antibodies we test for their ability to generate tailored immunity. We will examine a number of new molecules for their ability to shuttle foreign material to dendritic cells and their ability to stimulate immune responses. Next, we will test these homing devices as vaccines and their ability to prevent or treat cancer. Our aim is to develop a robust, highly efficient, generic, vaccination approach for cancer immunotherapy.Read moreRead less
I am an immunologist determining the development and function of the dendritic cell system, including its role in autoimmunity and resistance to infection.
Transcriptional Regulation Of Terminal T Cell Differentiation By Blimp-1
Funder
National Health and Medical Research Council
Funding Amount
$411,404.00
Summary
Memory cells stand at the end of immune reactions and determine the success or failure of vaccination. T cells in are considered essential in tumour surveillance, clearance of infections and in providing help for antibody decretion. Blimp-1 is a major factor controling the differentiation of effector T cells. We aim to study its role in the generation of memory T cells which will help to develop better stratagies for immunization and for the treatment of immunodedeficiency and autoimmunity.
Developmental Stages Of In Vivo And In Vitro-generated Dendritic Cell Subsets And Regulation Of T Cell Differentiation.
Funder
National Health and Medical Research Council
Funding Amount
$88,087.00
Summary
Dendritic cells (DC) represent a diverse family of white blood cells that form a sentinel network throughout the body involved in the detection and eradication of pathogens and cancer cells. DC can originate from different precursor cells in the bone marrow. It is therefore possible that different types of DC perform differing functions. For instance, DC not only initiate immune responses but are also able to silence them. However, the ability of DC to instruct and orchestrate the immune respons ....Dendritic cells (DC) represent a diverse family of white blood cells that form a sentinel network throughout the body involved in the detection and eradication of pathogens and cancer cells. DC can originate from different precursor cells in the bone marrow. It is therefore possible that different types of DC perform differing functions. For instance, DC not only initiate immune responses but are also able to silence them. However, the ability of DC to instruct and orchestrate the immune response may not only depend upon their origins but also on where they encounter pathogens or cancer cells and what other signals are associated with this encounter. Due to their specialized capacity to instruct the immune response (e.g. T cells, B cells and NK cells) of impending danger, DC are used experimentally to more efficiently deliver vaccines to the immune response so as to eradicate cancer or infectious disease. However, in order to successfully use DC to deliver vaccines, one must first understand how these cells normally behave in the body and what signals can alter their functional ability to orchestrate immune responses. We can generate DC outside the body from their precursors. We can also isolate DC from the circulation. This project seeks to identify how various physiologic stimuli differentially regulate the functional behaviour of DC subsets and how this then influences the DC's ability to instruct the developing T cell immune response. Furthermore, whether these signals are the same for DC generated outside the body with those isolated from the blood. Of particular interest is whether differing types of DC and differing stages of their maturity will differentially influence the T cell's ability to secrete immune response hormones and to recognize and kill cancer cells. The findings of this study have direct implications of how to best harness DC to effectively deliver vaccines and generate potent immune responses against cancer and infectious disease.Read moreRead less
This project is based upon the observation that the mammalian immune system can distinguish between its own genetic material (DNA) and the DNA of infectious agents such as bacteria. This has implications for understanding how the immune system copes with infection, and also for design of new therapies and vaccines. Our central aim is to define how the recognition system for foreign DNA works. The cells that respond most vigorously to foreign DNA are large white blood cells called macrophages. We ....This project is based upon the observation that the mammalian immune system can distinguish between its own genetic material (DNA) and the DNA of infectious agents such as bacteria. This has implications for understanding how the immune system copes with infection, and also for design of new therapies and vaccines. Our central aim is to define how the recognition system for foreign DNA works. The cells that respond most vigorously to foreign DNA are large white blood cells called macrophages. We are investigating how a key protein that is required for these responses functions and what genes it turns on. The type of immune responses initiated by foreign DNA may be useful in treatment of allergies and cancer, and for improving vaccinations.Read moreRead less
Investigation Into The Immunogenicity Of Dendritic Cell-derived Exosomes
Funder
National Health and Medical Research Council
Funding Amount
$257,036.00
Summary
Dendritic cells are essential in immune responses. They have unique capacity to stimulate lymphocytes specific to viruses, bacteria and cancers. They are extremely rare and difficult to isolate. We have developed a method of culture which gives a continuous supply of dendritic cells. Cells produced in our culture also produce a high yield of acellular membranous particles called 'exosomes' which have been previously been very difficult to isolate and characterise. Some preliminary reports sugges ....Dendritic cells are essential in immune responses. They have unique capacity to stimulate lymphocytes specific to viruses, bacteria and cancers. They are extremely rare and difficult to isolate. We have developed a method of culture which gives a continuous supply of dendritic cells. Cells produced in our culture also produce a high yield of acellular membranous particles called 'exosomes' which have been previously been very difficult to isolate and characterise. Some preliminary reports suggest that exosomes can induce or modify immune responses and that they have enormous immunotherapeutic potential. Further study of their clinical application is limited by the difficulty of isolating enough dendritic cells from which to isolate exosomes. This study will involve production and characterisation of exosomes from our unique murine dendritic cell culture system. Exosomes isolated will be assessed in terms of potential for immunotherapeutic treatment of disease such as cancer, viral infection and autoimmunity.Read moreRead less
The Regulation And Differentiation Potential Of Human Memory B Lymphocytes
Funder
National Health and Medical Research Council
Funding Amount
$227,036.00
Summary
Antibody produced by our immune system plays a critical role in protecting us from infectious disease. Remarkably our ability to make antibodies is much faster the second time we see the infection. This memory of the previous attack occurs due to the formation of memory B cells that circulate in the blood, sometimes for years, looking for the same intruders. If they detect the infection they rapidly become activated and remake the antibody. These memory cells are very important for our protectio ....Antibody produced by our immune system plays a critical role in protecting us from infectious disease. Remarkably our ability to make antibodies is much faster the second time we see the infection. This memory of the previous attack occurs due to the formation of memory B cells that circulate in the blood, sometimes for years, looking for the same intruders. If they detect the infection they rapidly become activated and remake the antibody. These memory cells are very important for our protection. Vaccines operate by tricking the immune system into making these memory cells, even though the body hasn't seen the actual disease. Although clearly vital for our health little is known about the activation and antibody production by human B memory cells. This project will redress our lack of knowledge by performing a comprehensive evaluation of the properties of this important cell type.Read moreRead less
Heterosubtypic T Cell-inducing Vaccines For Influenza In Humans
Funder
National Health and Medical Research Council
Funding Amount
$352,307.00
Summary
Bird flu virus poses a large risk to the world if it mutates to become easily spread between people. If this occurs vaccines will be made to the mutated strain but there will be a time lag before these are available. We have been working on a novel vaccine that induces protective T cell immunity to parts of the virus that are common to all influenza strains and will be effective against any new virus. Our information from animal models will be used to create a human vaccine of this type .