The Human Immunodeficiency Virus (HIV) is a virus that infects and kills the cells of your immune system. This infection eventually leads to the Acquired Immune Deficiency Syndrome (AIDS). An important aspect in preventing infection is to study how HIV enters immune cells and how infection spreads. Our lab is researching drugs to block the entry of HIV in immune cells, which can hopefully be used together with existing anti-HIV drugs to slow down the spread of the virus and the onset of AIDS.
Elucidating The Flexibility Of Coreceptor Engagement By HIV-1 Important For Macrophage Tropism And Escape From Entry Inhibitors
Funder
National Health and Medical Research Council
Funding Amount
$635,506.00
Summary
CCR5 antagonists are a new type of anti-HIV-1 drug that stops the virus from entering cells. We have evidence to suggest that the ability of CCR5 antagonists to function properly is linked to the ability of HIV-1 to infect a type of immune cell called macrophages. In this proposal, we will investigate precisely how HIV-1 enters macrophage cells, and then determine how this may influence the outcome of patients who are receiving these drugs as part of their clinical care.
A Novel RNA Repressor Element Regulates HIV-1 Replication
Funder
National Health and Medical Research Council
Funding Amount
$341,453.00
Summary
HIV-1 causes acquired immunodeficiency syndrome, with up to 40 million infected people and 5 million infected annually. The spatio-temporal regulation of HIV-1 reverse transcription has recently been recognised as a possible new drug target. Our research has revealed a novel repressor of reverse transcripiton (RRT). The RRT plays a major role in regulating the spatio-temporal regulation of reverse transcripiton. Targetting the RRT function would be a novel means to combat HIV-1 infection.
Addressing The Major Challenges In HIV Vaccine And Cure Research
Funder
National Health and Medical Research Council
Funding Amount
$16,136,755.00
Summary
HIV remains one of the defining global health challenge of our times. 37 million people are living with HIV with 2 million new infections each year. Despite advances in management of HIV infection with antiretroviral therapy, there is still no cure, no effective vaccine, and several co-infections reduce life expectancy. This program assembles Australia’s leading HIV researchers to use innovative basic and translational science to tackle priority areas in controlling the HIV epidemic.
Cell Type Specific Biologic Responses To HIV Infection
Funder
National Health and Medical Research Council
Funding Amount
$636,242.00
Summary
The way in which HIV alters the internal environment of its target cells to facilitate its growth will be examined. These changes enhance its ability to gain a toehold in the human body after entering the genital tract and its persistence for life in the brain and elsewhere in the body.
Elucidating The Mechanism Of Action Of Dendrimer Nanoparticles Against HIV
Funder
National Health and Medical Research Council
Funding Amount
$559,354.00
Summary
Dendrimers are nanoparticles with highly branched structures and they are being developed as topical microbicides to prevent the sexual transmission of HIV. This study will determine how dendrimers block HIV entry into host cells so that we can design more effective inhibitors and microbicides.
Successful HIV remission and cure, where patients can live normally without daily drug therapy and risk of transmitting infectious virus, will critically depend on understanding the mechanisms that control the expression of viral messenger RNA and proteins. This project further explores the mechanisms controling poorly understood steps in the proecssing of viral mRNA that are required for HIV protein produciton, and identifies new targets and strategies to drive HIV into permanent remission.
Elucidating Unique Molecular Mechanisms Involved In HIV-1 Subtype C Pathogenicity
Funder
National Health and Medical Research Council
Funding Amount
$710,989.00
Summary
Most people infected with human immunodeficiency virus (HIV) have subtype C virus (C-HIV) and live in Southern Africa and Central Asia. These regions are where the HIV pandemic is at its worst. However, we know very little about C-HIV. We have evidence that C-HIV evolves differently compared to other HIV-1 subtypes, which impacts the way it leads to AIDS. This project aims to characterise these unique molecular mechanisms, which may lead to vaccines and drugs that are optimised for C-HIV.
The Role Of Chemokines In Establishing HIV Latency
Funder
National Health and Medical Research Council
Funding Amount
$372,049.00
Summary
Although antiviral therapy is effective in controlling HIV, therapy must be continued life-long because the virus cannot be cleared from long lived infected CD4+ T cells that are silently or latently infected. In this proposal we will explore the mechanism of how HIV can enter these resting CD4+ T-cells and establish long lived latent infection. Understanding this process may potentially lead to new strategies to cure HIV infection.
How Does A Host Cell Stimulatory Factor Stabilize The HIV-1 Reverse Transcription Complex?
Funder
National Health and Medical Research Council
Funding Amount
$631,883.00
Summary
We have identified a host cell activity which HIV uses to infect cells. The activity assists the uniques ability of HIV to convert its genome to a form which inserts itself into the host cell DNA. If we can identify the protein responsible for this activity we may be able to target it for drug development. Targetting host cell proteins rather than virus proteins for new drug may have advantages in preventing the acquisition of drug resistance.