CD4+ T Cell-independent Immunity Against Salmonellae
Funder
National Health and Medical Research Council
Funding Amount
$550,226.00
Summary
Salmonella typhimurium is an important pathogen in both developed and developing countries where it causes significant HIV-linked morbidity. There is a pressing need to understand how immunity might be established against this organism that will function when the patient is immunocompromised either through age or through a comorbidity like HIV.
Processes Underlying Establishment And Maintenance Of The Latent HIV Resevoir And Potential Impact Of Integrase Inhibitors
Funder
National Health and Medical Research Council
Funding Amount
$318,044.00
Summary
Therapy for HIV-infected individuals is currently able to control the growth of the virus, but cannot eradicate the viral infection. This is due to a pool of CD4+ T lymphocytes which contain HIV DNA in a latent state, ready to reactivate as soon as therapy is interrupted. This project aims to better understand how this pool of latently infected CD4+ T lymphocytes is established and maintained, particularly how it is linked to the essential T cell survival signal from interleukin 7.
Dysregulation Of Cytokine Networks: A Key Determinant Of The Pathogenesis Of Cerebral Malaria.
Funder
National Health and Medical Research Council
Funding Amount
$480,989.00
Summary
Malaria is a parasitic disease that kills some 2 million people each year. It affects the Australian region, e.g. PNG and SE Asia. One of the most serious complications is cerebral malaria (CM). It affects the brain and is often fatal. This project will show whether the early meeting of the malaria parasite with the host's immune system determines if the infection will be a mild, resolving one or a severe, possibly lethal one causing CM. This is highly relevant to vaccine development strategies.
Immunopathological Role Of Monocyte-macrophages In Flavivirus Encephalitis.
Funder
National Health and Medical Research Council
Funding Amount
$445,011.00
Summary
Viral encephalitis is a life-threatening infection of the brain for which there are no reliable treatments. White cells called monocytes enter the brain from the blood and although important in the immune response that destroys the virus, can also damage the brain. Our work focuses on determining how monocytes migrate into the brain in viral infection, what functions they have once inside the brain, and how to exclude a certain types of monocytes that we have found to be particularly damaging.
Genetic Modulation Of The Host Response To Pulmonary TB
Funder
National Health and Medical Research Council
Funding Amount
$540,273.00
Summary
Tuberculosis (TB) is an enormous global health problem. The World Health Organisation estimates that TB, which is caused by infection with the bacteria Mycobacterium tuberculosis, infects 2 billion individuals, leading to 2 million deaths and 8 million new cases of disease per year. Most TB disease is not manifest at the time of infection, but is a reactivation of latent disease in people who do not completely eradicate the primary infection. In a latent infection an effective chronic host respo ....Tuberculosis (TB) is an enormous global health problem. The World Health Organisation estimates that TB, which is caused by infection with the bacteria Mycobacterium tuberculosis, infects 2 billion individuals, leading to 2 million deaths and 8 million new cases of disease per year. Most TB disease is not manifest at the time of infection, but is a reactivation of latent disease in people who do not completely eradicate the primary infection. In a latent infection an effective chronic host response contains dormant TB organisms inside activated macrophages. Cells are recruited to wall off infected macrophages and specific T cells continually induce the activate state with minimal tissue damage (immunopathology). Although currently available antibiotics can kill TB organisms, the treatment is prolonged, expensive, difficult to administer in poorly resourced regions and not effective against multi-drug resistant organisms. New therapies to treat both active disease and prevent reactivation in individuals who are latently infected are urgently required. This proposal will address this problem using a novel approach, namely gene manipulation to augment host immunity to TB and limit concurrent immunopathology. We will construct vectors to increase expression of the key immune molecules, the T lymphocyte activating cytokines IL-12 and IL-23, and the macrophage effector molecules LRG-47 and Indoleamine 2,3-Dioxygenase (IDO). These molecules are known to be involved in TB killing. We will determine if increasing their expression increases the killing capacity of TB-infected macrophages and we will examine how these molecules interact to aid clearance of the TB bacilli. This internationally competitive grant will further our detailed understanding of the complex immune response to TB organisms and lead to the development of novel therapies to treat TB infection and prevent reactivation of latent disease.Read moreRead less
A NOVEL MOUSE MODEL TO INVESTIGATE THE MECHANISMS OF VIRUS-INDUCED ARTHRITIS
Funder
National Health and Medical Research Council
Funding Amount
$336,000.00
Summary
We have developed a novel animal model by which to study arthritic disease caused by insect-transmitted viruses known as arboviruses. The existence of this model and novel reagents provides an excellent opportunity to further explore the basic mechanisms of infectious disease in a complete functioning animal, rather than specific cultured cells. The study will use modern approaches in molecular and cellular biology to achieve this goal. The production by our immune systems of soluble mediators ( ....We have developed a novel animal model by which to study arthritic disease caused by insect-transmitted viruses known as arboviruses. The existence of this model and novel reagents provides an excellent opportunity to further explore the basic mechanisms of infectious disease in a complete functioning animal, rather than specific cultured cells. The study will use modern approaches in molecular and cellular biology to achieve this goal. The production by our immune systems of soluble mediators (cytokines-chemokines) and antibodies is an overwhelming positive aspect of our physiological response to infection by microbes. Protection from disease by these immune compounds can happen naturally, or the body's ability to produce these factors can be exploited to our benefit via the administration of vaccines. However, these factors can also be detrimental to the host contributing to severe disease. For instance, work performed almost 40 years ago showed for the first time that under particular conditions, antibodies against viruses can enhance infection, instead of inhibiting infection as normally seen. In the intervening years work by scientists all over the world has associated antibody-dependent enhancement (ADE) of infection to many types of viruses; ADE is even thought to be a risk factor to serious disease with dengue virus, and has been shown in vitro for the AIDS virus and Ebola virus. We have recently discovered a molecular mechanism which explains how antibody enhances viral infection in vitro. In studies on immune cells infected with Ross River Virus (RRV) we found that infection helped by antibody resulted in the specific disruption to the production of cellular chemicals which are toxic to viruses. Are these mechanisms of antibody-enhanced infection also found in animals? Will such mode of infection cause enhanced disease and tissue pathology (arthritis) in animals?Read moreRead less