[HTML][HTML] On the generation of the MSD-Ѱ class of defective HIV proviruses

AT Das, AO Pasternak, B Berkhout - Retrovirology, 2019 - Springer
AT Das, AO Pasternak, B Berkhout
Retrovirology, 2019Springer
Antiretroviral therapy (ART) can effectively suppress ongoing HIV replication and block
disease progression, but the infection is never cured due to the persistence of a small pool
of latently infected cells hosting integrated replication-competent HIV proviruses. However,
the vast majority of HIV proviruses in ART-treated patients are replication-incompetent due
to a variety of genetic defects. Most defective proviruses (around 90%) contain large internal
deletions or are G-to-A hypermutated, resulting in destruction of most if not all viral open …
Abstract
Antiretroviral therapy (ART) can effectively suppress ongoing HIV replication and block disease progression, but the infection is never cured due to the persistence of a small pool of latently infected cells hosting integrated replication-competent HIV proviruses. However, the vast majority of HIV proviruses in ART-treated patients are replication-incompetent due to a variety of genetic defects. Most defective proviruses (around 90%) contain large internal deletions or are G-to-A hypermutated, resulting in destruction of most if not all viral open reading frames, which is consistent with the idea that cytotoxic T cells (CTLs) effectively remove cells that produce viral antigens. An intriguing subclass of defective proviruses (around 10%) that are consistently detected in such patients carry a small deletion or a point mutation in a relatively precise and well conserved region near the 5ʹ end of the HIV genome, in the area that encodes the major splice donor (MSD) site and the packaging signal Ѱ in the viral RNA genome. Why this subclass of proviruses is defective has never been properly understood. We now propose a mechanistic scenario for how these MSD-Ѱ mutations can prevent viral protein expression. Based on ample results in literature, we argue that MSD inactivation triggers the activity of the 5ʹ-polyadenylation site, resulting in the production of ultra-short non-protein-coding HIV transcripts.
Springer