Antigen Presentation, Recognition And The Immune Response
Funder
National Health and Medical Research Council
Funding Amount
$15,738,750.00
Summary
The early events in immunity require various molecular interactions. We will examine the structural and biophysical basis for some of these interactions, including those associated with transplant rejection and autoimmunity. We will explore the impact of variation in immune response genes on immune evasion and disease susceptibility. Our basic research will determine the mechanisms by which the immune system discriminates between different self and micro-organism associated determinants. We will ....The early events in immunity require various molecular interactions. We will examine the structural and biophysical basis for some of these interactions, including those associated with transplant rejection and autoimmunity. We will explore the impact of variation in immune response genes on immune evasion and disease susceptibility. Our basic research will determine the mechanisms by which the immune system discriminates between different self and micro-organism associated determinants. We will address the structural and biochemical basis for operation of an immune molecule called tapasin and unravel the basis for how some viruses escape the function of this molecule, thus allowing their immune evasion. We will also explore the use of modified small proteins called peptides in a humanized model of gluten hypersensitivity resembling that of Celiac disease. The molecular basis of the natural human immune system's capacity to recognise and reject grafts will be examined. This complements work aimed at improving the prediction of clinical graft rejection in transplantation. Dendritic cells play a central role in immunity, responsible for capturing material, whether from micro-organisms or self tissues, and presenting it to cells of the immune system. Our program will study the development and immunological function of the different dendritic cell subtypes. We will determine the relative contribution of each to the maintenance of immune tolerance and to the induction of immunity to several pathogens, including herpes simplex virus and malaria. Novel dendritic cell surface molecules that we have discovered will be tested for their ability to enhance the effectiveness of vaccines. Overall, this program utilises a broad array of immunological techniques designed to dissect the development and function of various immune system cell types and determine the structure-function relationships between important cell surface molecules involved in immunity.Read moreRead less
Molecular Regulation Of Blood Cell Production And Function
Funder
National Health and Medical Research Council
Funding Amount
$18,333,174.00
Summary
The blood-forming system is an intricately controlled balance of cell proliferation, maturation and functional activity that is essential for oxygen transport throughout the body, blood clotting, and effective immune responses. Defining the genes and molecules that orchestrate blood cell production and function is crucial, not only for understanding the role of blood in health, but for establishing the bases of blood cell disorders such as autoimmunity and leukaemia, and for devising new clinica ....The blood-forming system is an intricately controlled balance of cell proliferation, maturation and functional activity that is essential for oxygen transport throughout the body, blood clotting, and effective immune responses. Defining the genes and molecules that orchestrate blood cell production and function is crucial, not only for understanding the role of blood in health, but for establishing the bases of blood cell disorders such as autoimmunity and leukaemia, and for devising new clinical strategies for fighting these lethal diseases. This program is conducted by a large, established team of investigators that have made world-class contributions to understanding blood cell formation and function for more than 30 years. Their work established the modern era of molecular haematology via discovery and analysis of blood cell hormones (colony-stimulating factors or CSFs), their receptors and intracellular mediators, which resulted in development of treatments for millions of cancer patients. The program is a multidisciplinary, team approach to fundamental biological questions with a focus on potential clinical and commercial outcomes involving collaborations with clinical medicine and the pharmaceutical industry. Research will focus on meshing novel genetic approaches in mice with translation studies in humans to identify new validated targets for therapeutic intervention in blood cell diseases, as well as building on the team s expertise in cytokine action with emphasis on the actions of the suppressor of cytokine signalling (SOCS) molecules, a key family of proteins that controls cytokine actions.Read moreRead less
The Molecular Basis Of Bacterial Infectious Diseases
Funder
National Health and Medical Research Council
Funding Amount
$16,230,996.00
Summary
Bacterial infectious diseases are a serious threat to human health, accounting for over 10 million deaths each year. This multidisciplinary collaborative team is investigating the complex interactions between major disease-causing bacteria and their human hosts, in order to determine how they cause disease. These studies will make a major contribution to fundamental knowledge in this field. This information is also essential for the development of cheaper and more effective vaccines, as well as ....Bacterial infectious diseases are a serious threat to human health, accounting for over 10 million deaths each year. This multidisciplinary collaborative team is investigating the complex interactions between major disease-causing bacteria and their human hosts, in order to determine how they cause disease. These studies will make a major contribution to fundamental knowledge in this field. This information is also essential for the development of cheaper and more effective vaccines, as well as novel drugs. These are urgently needed to reduce death and illness due to bacterial infectious diseases in the 21st century. 11Read moreRead less
The development of vaccines and better treatments for HIV-AIDS and Hepatitis C are urgent global health priorities. This Program will undertake studies to better understand effective immunity against HIV and hepatitis C, allowing the rational design and testing of novel vaccines and treatments. The Program brings together a team of researchers with skills in basic virology and immunology with those providing expertise in translating findings in the laboratory into human clinical trials.
This Program Grant has three investigators, Professor Denis Moss, Dr Rajiv Khanna and Dr Scott Burrows, each of whom has collaborated on two previous Program Grants. The group is well known in the area of herpesvirus immunology and have published numerous scientific papers in leading medical journals. This program grant focuses on two human herpesviruses. The first is called Epstein-Barr virus which causes glandular fever and is associated with arange of human cancers. The second virus is human ....This Program Grant has three investigators, Professor Denis Moss, Dr Rajiv Khanna and Dr Scott Burrows, each of whom has collaborated on two previous Program Grants. The group is well known in the area of herpesvirus immunology and have published numerous scientific papers in leading medical journals. This program grant focuses on two human herpesviruses. The first is called Epstein-Barr virus which causes glandular fever and is associated with arange of human cancers. The second virus is human cytomegalovirus which can cause birth defects and problems in transplant patients. In this program we are investigating how the body�s immune system controls these viruses to exploit this information to develop new treatments.Read moreRead less
Host Parasite Interactions: Disease, Pathogenesis And Control
Funder
National Health and Medical Research Council
Funding Amount
$13,738,897.00
Summary
Our program will investigate two major global parasitic diseases: malaria and leishmaniasis. We will explore how the parasites identify and invade the host. This is a critical stage of the infection and we will characterise proteins involved as they are potential targets for drugs and vaccines against the parasites. Many of these recognition and interaction components are excellent candidates for the development of vaccines to interrupt the cycle of infection. We are also unravelling metabolic p ....Our program will investigate two major global parasitic diseases: malaria and leishmaniasis. We will explore how the parasites identify and invade the host. This is a critical stage of the infection and we will characterise proteins involved as they are potential targets for drugs and vaccines against the parasites. Many of these recognition and interaction components are excellent candidates for the development of vaccines to interrupt the cycle of infection. We are also unravelling metabolic pathways unique to the parasites using a mixture of genetic and computational tools complemented with sophisticated instrumentation to chemically identify the parasite�s entire repertoire of metabolic compounds. These pathways, absent from human hosts, are also highly vulnerable and we will feed the key steps into the drug development facet of the program. Our program also looks at how the parasites cause disease and how the host responds to the disease. We will explore the reactions of the immune system to infection and consequences of the body�s (often only partially successful) attempts to fight off the disease.Read moreRead less
This program brings together a team of researchers from The Walter and Eliza Hall Institute of Medical Research to study how the body regulates antibody production to fight disease. Antibodies are made by B-cells and are essential for a functional immune system. B cells circulate in the body, searching for signs of infection. When they encounter an invader, they mature, with the help of other immune cells, into antibody-producing cells. A small proportion of the cells are set aside as _memory� c ....This program brings together a team of researchers from The Walter and Eliza Hall Institute of Medical Research to study how the body regulates antibody production to fight disease. Antibodies are made by B-cells and are essential for a functional immune system. B cells circulate in the body, searching for signs of infection. When they encounter an invader, they mature, with the help of other immune cells, into antibody-producing cells. A small proportion of the cells are set aside as _memory� cells that can rapidly become antibodyproducing cells should the same infection occur again in the future. This is the basis of vaccination. This program aims to understand how a B cell changes into an antibody-producing cell, by studying the genes that are known to be required for the cells to form, or to do their work. We will study animals whose immune systems are under- or over-active, to find out what part of the antibody-producing process is faulty. Using this information, we hope eventually to be able to study diseases of antibody producing cells in humans (as occur in allergy, asthma, rheumatoid arthritis and leukaemia), to be able to identify the precise cause of the problem, and to suggest a therapy. This information may also be used to improve the outcome of vaccination where an enhanced antibody response is desired.Read moreRead less
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