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.
A Novel Molecular Mechanism Controlling Myelopoiesis
Funder
National Health and Medical Research Council
Funding Amount
$878,439.00
Summary
The immune system is comprised of many different cell types, each with a specialised function. Many are short-lived and must be continually replenished throughout life. Abnormalities in this process underlie many human diseases, including immunodeficiency, autoimmunity and cancer. We have discovered a novel molecular mechanism that is critical for the production of immune cells. This project will investigate how this mechanism is controlled and the impacts on myelodysplastic syndromes.
Targeting Adenosine Mediated Immunosuppression To Enhance CAR T Cell Activity
Funder
National Health and Medical Research Council
Funding Amount
$633,447.00
Summary
The use of white blood cells genetically engineered to eradicate cancer cells specifically has been a major breakthrough in cancer treatment. These cells (CAR T cells) are very effective in blood cancers, but do not currently work well in other cancers. This is due to the immune suppressing nature of the cancer environment. I propose to use strategies to overcome this by genetically reprogramming the CAR T cells to be resistant to suppression by the cancer and therefore be more effective.
Dendritic cells are essential components of our immune systems. They are located throughout our body and provide the first line of defence against invading microbes. Dendritic cells sense the invader and send out signals to recruit our immune cells to the site of infection. Our research aims to understand how our dendritic cell network is set up and how it functions to promote our immune health.
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-presenting cells control immune responses. Different types of these cells do different jobs and affect different diseases. We wish to control these processes by determining how the cells live and die. In particular we are interested in controlling the local immune responses during rejection of islet transplantation, which can cure type 1 diabetes.
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.
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.
Controlling Life And Death Of Dendritic Cell Subsets For Immunomodulation
Funder
National Health and Medical Research Council
Funding Amount
$639,577.00
Summary
Dendritic cells are pivotal in orchestrating immune responses; for example, they can turn immune cells into assassins to kill virus infections. Their function is so diverse that different dendritic cells do different jobs. There are many genes that control life and death of cells but those that are important for each specialised dendritic cell have not been comprehensively studied. Drugs that affect the proteins made by such genes selectively may be a new way of controlling immune responses.
Pathogenesis Of Persistent Human Virus Infections Of Global Significance
Funder
National Health and Medical Research Council
Funding Amount
$6,571,328.00
Summary
The study will investigate why humans cannot eradicate particular viruses (HIV-AIDS, cytomegalovirus and herpes simplex virus), the long term effects of these viruses and ways to improve control. Current treatments can only partly suppress the levels of these viruses, because they persist in certain parts of the body called reservoirs, only to resurge later causing disease. Thus, the overall aim of the research program is to discover the mechanisms by which these viruses are able to successfully ....The study will investigate why humans cannot eradicate particular viruses (HIV-AIDS, cytomegalovirus and herpes simplex virus), the long term effects of these viruses and ways to improve control. Current treatments can only partly suppress the levels of these viruses, because they persist in certain parts of the body called reservoirs, only to resurge later causing disease. Thus, the overall aim of the research program is to discover the mechanisms by which these viruses are able to successfully persist within reservoirs in the human body. The research program brings together a group of 6 leading scientists and clinicians located at 3 sites in 2 Australian cities. The team is comprised of experts in the study of HIV-AIDS, cytomegalovirus and herpes simplex virus who will combine their knowledge and expertise to speed up the process of research on these viruses that are of major health importance. Studies will also utilise a number of cutting edge technologies that now make it possible to much more rapidly and precisely determine how viruses cause disease. Advances in our understanding of how viruses persist may form the basis for treatments aimed at controlling persistent infections and the serious diseases caused by these viruses.Read moreRead less