A new understanding of the initial
interactions of human immunodeficiency virus type 1 (HIV-1) and dendritic cells
is described by Boston University School of Medicine (BUSM) researchers in a
study currently featured in the Proceedings of the National Academy of Sciences
(PNAS).
With
over 2.5 million new HIV infections diagnosed annually and earlier detection
becoming more common, better understanding of early virus-host interactions
could have a great impact on future research and drug therapy.
In this
study, the researchers describe a novel mechanism of HIV-1 spread by dendritic cells.
These cells, which are present at the body's mucosal surfaces, are the focus of
research because they are among the first cells to encounter HIV-1 and trigger
the immune system. While previous work has focused on the HIV-1 envelope
glycoprotein method of interactions, this research details the role of a
molecule called GM3, which arises from the host itself and is used by the virus
for attachment and spread.
Since
this virus invasion method depends on the molecules originating from the host,
"it is a stealth entry mechanism, likely not detected by the cell, so HIV
can spread quickly," says Dr. Rahm Gummuluru, associate professor in the
department of microbiology at BUSM and senior author of the study.
Despite
the cleverness of the virus, this unique contact between HIV-1 and dendritic
cells may offer a new direction for anti-viral therapies. "Resistance to
therapy, which often challenges physicians, is unlikely to occur in drugs that
target this interaction, as these drugs would have the benefit of acting on the
host, instead of the virus," Gummuluru.
Further
research in this field may identify specific targets and offer hope for
preventing HIV infections.
Provided
by Boston University Medical Center
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