A Canadian research team at the IRCM in Montreal, led by molecular
virologist Eric A. Cohen, PhD, made a significant discovery on how HIV escapes
the body's antiviral responses. The team uncovered how an HIV viral protein
known as Vpu tricks the immune system by using its own regulatory process to
evade the host's first line of defence.
The study's goal was to determine how HIV manages to compromise antiviral
responses in the initial period of infection, also called the acute infection
stage, during which the virus establishes itself in the body. The acute
infection is considered a critical period in determining the complexity, extent
and progression of the disease. It is also during this stage that HIV
establishes latent infection in long-lasting cellular reservoirs. These viral
reservoirs, which harbour the virus out of sight from the immune system and
antiviral drugs, represent the primary barrier to a cure.
"An important component in this process is a group of proteins collectively
called type 1 Interferons, which are the immune system's first line of defence
against viral infections and are known to have a beneficial role in the early
stages of HIV infection," says Dr. Cohen, Director of the Human Retrovirology
research unit at the IRCM. "The problem is that HIV has developed mechanisms to
suppress the Interferon response and, until now, little was known about how this
was achieved."
Most of the Interferon is produced by a very small population of immune
cells called pDCs (plasmacytoid dendritic cells), responsible for providing
immediate defence against infections. PDCs patrol the body to detect invaders
and, when they recognize the presence of a pathogen, they secrete Interferon.
The Interferon then triggers a large array of defence mechanisms in nearby
cells, creating an antiviral state that prevents the dissemination and,
ultimately, the expansion of the virus.
"When pDCs encounter HIV-infected cells, the production of Interferon is
regulated by a protein located on the infected cell's surface called BST2,"
explains Mariana Bego, PhD, first author of the study and research associate in
Dr. Cohen's laboratory. "BST2 has the ability to bind to and activate a receptor
called ILT7, found on the surface of pDCs, which, in turns, sends a signal that
suppresses the production of Interferon and halts its defensive functions.
Interestingly, BST2 is also responsible for restricting HIV production by
trapping the virus at the cell surface before it can exit infected cells and
disseminate. However, HIV uses the viral protein Vpu to counteract BST2
antiviral activity."
"With this study, we uncovered a unique mechanism whereby HIV exploits the
regulatory process between BST2 and ILT7 to limit the body's antiviral response,
which allows the virus to spread and leads to persistent infection," adds Dr.
Bego. "We found that HIV, through Vpu, takes advantage of the role played by
BST2 by maintaining its ability to activate ILT7 and limit the production of
Interferon, all the while counteracting its direct antiviral activity on HIV
production."
"The hope for a definitive cure and an effective vaccine has been
frustrated by HIV's endless propensity to subvert the host's defences and
persist in small populations of long-lasting reservoirs despite antiretroviral
therapy," describes Dr. Cohen, who also leads CanCURE, a team of leading
Canadian researchers working towards an HIV cure. "Our findings can provide
tools to enhance antiviral responses during the early stages of infection. By
blocking Vpu's action, we could prevent early viral expansion and dissemination,
while also allowing pDCs to trigger effective antiviral responses. We believe
that such interventions during primary infection have the potential to limit the
establishment and complexity of viral reservoirs, a condition that seems
required to achieve a sustained HIV remission."
"The discovery by Drs. Bego and Cohen, which explains how the virus can't
be held down or wiped out during early periods of infection, will bring us
closer to ending HIV/AIDS," says Robert Reinhard, CanCURE Community Liaison. "By
filling an important gap in knowledge, this new study will advance research for
an HIV cure."
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