Envelope Glycoprotein Determinants Of Pathogenic, Macrophage-tropic HIV-1 And Their Role In HIV-1 Disease Progression
Funder
National Health and Medical Research Council
Funding Amount
$442,500.00
Summary
Human immunodeficiency virus type 1 (HIV-1) causes AIDS and, to date, has infected 20 thousand people in Australia and 40 million worldwide. In addition to T-cells of the immune system, HIV-1 can also infect cells of the monocyte-macrophage lineage found in blood, brain, lymph node, lungs, bone marrow, skin and brain. HIV-1 strains that can infect these cells are called macrophage-tropic (M-tropic) strains. Infected macrophages are a major source of new HIV-1 produced in the body, and they compl ....Human immunodeficiency virus type 1 (HIV-1) causes AIDS and, to date, has infected 20 thousand people in Australia and 40 million worldwide. In addition to T-cells of the immune system, HIV-1 can also infect cells of the monocyte-macrophage lineage found in blood, brain, lymph node, lungs, bone marrow, skin and brain. HIV-1 strains that can infect these cells are called macrophage-tropic (M-tropic) strains. Infected macrophages are a major source of new HIV-1 produced in the body, and they complicate therapy by the current drugs used to treat HIV-1 infection because infection is often latent (or dormant) and, unlike T-cells, they are long lived and may continue to produce new virus for the duration of their normal life span. HIV-1 virus from patients with advanced disease (i.e. AIDS) can infect macrophages better than virus from patients at early stages of disease (i.e. just after infection, or during the asymptomatic or healthy period). Therefore, the increased ability of HIV-1 to infect macrophages, i.e., enhanced M-tropism, is an important factor contributing to the development of AIDS in people with HIV-1 infection. However, what causes HIV-1 to increase it's ability to infect macrophages and cause AIDS is unknown. This proposal aims to identify features of HIV-1 that are important for enhanced M-tropism and HIV-1 disease progression. We expect to find that the virus gradually changes during the course of infection to forms that can bind to receptor molecules on the cell more tightly, and to forms that need fewer receptors on the cell surface for infection. We believe that these forms of HIV-1 virus are now better able to infect macrophages, which naturally only have small amounts of receptors on their surface, and also can infect and kill T-cells better, leading to AIDS. This study will contribute to a greater understanding of how HIV-1 causes AIDS, which is necessary for the development of new drugs to treat HIV-1 infection.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
Roles Of Virus-integrin Interactions And Rotavirus Modulation Of Host Cell Responses In Viral Pathogenesis
Funder
National Health and Medical Research Council
Funding Amount
$474,000.00
Summary
Rotaviruses are the main cause of severe gastroenteritis in children, and cause 1 in 27 Australian children under the age of 5 years to spend time in hospital. There is currently no rotavirus vaccine available. We aim to discover how rotavirus interacts with host cells. This information is necessary to formulate a safe and effective vaccine, or a therapeutic agent that can block virus growth in host cells. Previously, we showed that rotavirus attaches to cells and enters them using several membe ....Rotaviruses are the main cause of severe gastroenteritis in children, and cause 1 in 27 Australian children under the age of 5 years to spend time in hospital. There is currently no rotavirus vaccine available. We aim to discover how rotavirus interacts with host cells. This information is necessary to formulate a safe and effective vaccine, or a therapeutic agent that can block virus growth in host cells. Previously, we showed that rotavirus attaches to cells and enters them using several members of the integrin protein family that are present on the surface of the cells. Integrins are critical for cell adhesion, survival and communication. In this project, we will identify how rotavirus usage of integrins modulates cell functions. This will help us understand how rotavirus causes disease, how virus spreads in the body and how the immune response defends us from rotavirus. Rotavirus binds integrins using particular stretches of protein sequence that we have shown are also present in other human viral pathogens that cause hepatitis, AIDS and measles. We will determine if these other viruses also recognize integrins.Read moreRead less