Contribution of 6mer seed toxicity to HIV-1 induced cytopathicity

Abstract

AbstractHIV-1 (HIV) infects CD4 positive T cells, the gradual depletion of which can lead to the onset of Acquired Immunodeficiency Syndrome (AIDS) in the absence of antiretroviral therapy (ART). Several forms of cell death have been shown to be involved in HIV-mediated killing of either directly infected or bystander cells. It is still unknown, however, why some cells survive HIV infection and persist as part of the latently infected reservoir that reliably causes recurrent viremia upon ART cessation. Improved understanding of the mechanisms of HIV-mediated cell death could inform innovations designed to clear the latent reservoir. “Death Induced by Survival gene Elimination” (DISE) is an RNA interference (RNAi)-based mechanism that kills cells through short (s)RNAs with toxic 6mer seeds (pos. 2-7 of sRNA). These toxic seeds target reverse complementary seed matches in the 3’UTR of mRNA transcripts to decrease expression of hundreds of genes that are critical for cell survival. In most cells under normal conditions, highly expressed cell-encoded non-toxic microRNAs (miRNAs) block access of toxic sRNAs to the RNA-induced silencing complex (RISC) that mediates RNAi, promoting cell survival. We now report that infection of cells with HIV results in RISC-loading of an HIV-encoded miRNA, v-miRNA HIV-miR-TAR-3p, which kills cells by DISE through a noncanonical (pos. 3-8) 6mer seed. In addition, cellular RISC bound sRNAs shift to lower seed viability. Both these effects also occur with latent HIV provirus reactivation in J-Lat cells, a well-established cell model of HIV latency. Cells lacking expression of miRNA biogenesis genes Drosha, Dicer and Exportin 5 cannot produce protective miRNAs and therefore do not block RISC loading of the v-miRNA HIV-miR-TAR-3p. These mutant cells, as well as cells lacking expression of the RISC component Ago2, are hypersensitive to cell death via DISE induced by HIV infection. More precise targeting of the balance between protective and cytotoxic sRNAs could specifically and transiently increase silencing of cell survival genes to increase DISE. This could be a new addition to a “shock and kill” strategy to enhance depletion of the provirus reservoir during suppressive ART.