Project description:HIV, although manageable as a chronic condition, currently lacks a safe or scalable cure. Antiretroviral therapy (ART) effectively suppresses HIV replication, preventing disease progression and transmission to sexual partners. However, ART does not affect established 'reservoirs', which are rare cell populations harboring integrated, intact proviruses that can reignite viral replication if ART is discontinued. Cytotoxic T-lymphocytes (CTL) exert sustained pressure on reservoirs of HIV-infected cells that persist through years of antiretroviral therapy (ART). This selects for latently-infected cells, but also potentially for cells that express HIV but possess intrinsic CTL resistance. In this study we confirm the existence of HIV-infected CD4+ T-cells that survive rigorous CTL attack and map CTL susceptibility to cell identities and states defined by single-cell multi-omics (using 10X based ECCITE-seq) and functional metabolic profiling. Our results provide an atlas for elucidating features of CTL resistance in HIV reservoirs, and identify oxidative stress as a therapeutic target to facilitate reservoir elimination.

Project description:Persistent HIV reservoirs in CD4⁺ T-cells impede efforts to cure HIV infection. We identified overexpression of enhancer of zeste homolog 2 (EZH2) in HIV-infected CD4⁺ T-cells that survive cytotoxic T lymphocyte (CTL) exposure, suggesting a mechanism of CTL resistance. Inhibition of EZH2 with the FDA-approved drug tazemetostat increased surface expression of major histocompatibility complex class I (MHC-I) on CD4⁺ T-cells, counteracting HIV Nef–mediated MHC-I downregulation. This enhancement improved CTL-mediated elimination of HIV-infected cells and suppressed viral replication in vitro. In a participant-derived xenograft mouse model, tazemetostat elevated MHC-I and the pro-apoptotic protein BIM in CD4⁺ T-cells, facilitating CD8⁺ T-cell–mediated reduction of HIV reservoir seeding. Additionally, tazemetostat promoted sustained skewing of CD8⁺ T-cells toward less differentiated and less exhausted phenotypes. Our findings reveal EZH2 overexpression as a novel mechanism of CTL resistance and support the clinical evaluation of tazemetostat to enhance immune-mediated clearance of HIV reservoirs.

Project description:Dynamic Antigen Expression and Intrinsic CTL Resistance in HIV-1 Reservoir Clones

Project description:Suppressive HAART does not eradicate HIV-1 and viral DNA persists as a stably integrated form in the absence of viral particle production. As a consequence, latent reservoirs are refractory to antiretroviral drugs and invisible to immune surveillance. The largest latent reservoir consists of resting memory CD4+ T cells. These cells can resume viral infection when activated through antigen recognition, causing bursts of viremia (blips). Current therapies targeting latent HIV-1 have focused primarily on the M-bM-^@M-^\shock and killM-bM-^@M-^] approach, which employs M-bM-^@M-^\anti-latencyM-bM-^@M-^] drugs M-bM-^@M-^S most notably histone deacetylase (HDAC) inhibitors M-bM-^@M-^S to reactivate and flush latent provirus from its cellular reservoirs in the absence of global T cell activation. This approach is predicated on the notions that viral reactivation will lead to the demise of the infected cell, and that HAART will prevent spreading of the infection. On the contrary, recent evidence indicates that latently infected CD4+ T cells of HIV-1 patients on HAART survive in vitro viral reactivation with the HDAC inhibitor, SAHA, even when co-cultured with autologous CD8+ cytotoxic T lymphocytes (CTL). Moreover, it remains to be addressed the impact of anti-latency drugs on viral reservoirs undergoing low-level ongoing replication, inherently more resistant to the cytopathic effects of HIV-1 and residing in anatomical sites hard to reach for some antiretroviral drugs (e.g. macrophages). As a consequence, there is a need to develop alternative therapeutic approaches aimed at eliminating or decreasing the latent reservoir. Progress in that direction has been hindered by the lack of biomarkers uniquely or differentially expressed on latently infected compared to their uninfected counterparts. To gain insight into the cellular mechanisms that take place in the context of latency, and with the goal of identifying distinctive markers that distinguish latently infected CD4+ T cells, we have used an in vitro model developed in our laboratory to study the expression profile of latently infected CD4+ T cells by microarray analysis. We have used a culture system, previously established in our laboratory, to generate and isolate quiescent latently infected CD4+ T cells in vitro. In this in vitro HIV-1 latency model, CD4+ T cells are activated, infected with full length, replication competent HIV-1, and then returned to quiescence in the presence of IL-7, yielding a culture of quiescent latently infected and uninfected cells. We showed that HIV-1 p24gag expressed during viral replication persists in the cytoplasm of latently infected cells for several days before being degraded. Therefore, we exploited the presence of cytoplasmic p24gag to sort latently infected from uninfected cells by FACS from the same initial cell culture. Total RNA was isolated from sorted latently infected and uninfected cells generated from CD4+ T cells of four different donors. Paired RNA samples from infected and uninfected cells were labeled with Cy3 and Cy5 to allow dual-color competitive hybridization. Moreover, to control for the dye bias in our experiments, we implemented a dye swap protocol (reciprocal labeling) for paired RNA samples from 2 donors. Samples were analyzed by dual-color competitive hybridization on the Agilent whole human genome microarrays (41,000 unique probes). This is the first comparative genomic profiling of primary latently infected resting memory CD4+ T cells versus their uninfected counterparts sorted from the same culture. Microarray analyses performed in this study revealed profound differences between latently infected and uninfected cells. Of relevance are genes involved, not only in previously described pathways related with transcriptional and post-transcriptional regulation, but affecting proliferation, survival, cell cycle progression and cell metabolism. This could explain why latently infected cells have been resistant to reactivation with current anti-latency approaches. Thus, targeting of more downstream steps, such as the ones identified in this study, may be able to enhance viral flushing from refractory latent reservoirs. In addition, we identified a panel of surface makers differentially expressed in latently infected cells, which seem worth investigating for their potential use as biomarkers. Indeed, they might allow the enrichment of this latent reservoir for molecular in depth studies, for monitoring the size of the latent reservoir in the clinical setting, as well as for the development of new therapeutic strategies aimed at eradicating this reservoir.

Project description:To identify candidate mechanisms that may confer CTL resistance to HIV reservoir harboring cells, we studied differential intrinsic sensitivity to CTL killing in primary CD4+ T-cells. Human CD4+ T cells were divided into either a “real” condition, where half of the cells were labeled with CFSE and pulsed with the HIV-Env peptide RLRDLLLIVTR (RR11), while the other half received no peptide and were labeled with CTFR, or a “mock” condition where cells were similarly labeled but received no peptide. Both conditions were then co-cultured with the corresponding HIV-specific CTL clone. Our result showed that the comparison between the ‘real survivors’ to the ‘real bystanders’ identified 1,061 differentially expressed genes (DEGs) by setting a threshold as FDR<0.05: 743 upregulated and 318 downregulated. Among these genes, we observed expression profiles that were consistent with specific selection of over-expression of BCL2, and under-expression of caspase-2 and PARP in the ‘real survivor’ cells that resisted elimination by CTL.

Project description:Latent HIV reservoirs are extremely stable which pose a tremendous challenge to eradicate HIV. Here, we show that HIV explores the integrated stress response (ISR) signaling to establish its quiescent infection, refractory to the clearance for its persistence. HA15, a recently characterized specific ISR agonist, activates ATF4/CHOP signaling to not only disrupt HIV latency but also reduce HIV+ cells in the primary CD4+ T cell model of HIV latency without the induction of cell death in the HIV negative primary CD4+ T cells and the impact of viability in resting CD4+ T cells isolated from people living with HIV (PLWH). Mechanistically, the reduction of HIV+ cells by ISR/ATF4 activation is associated with the enhancement of cellular apoptosis. However, this mainly occurs in the HIV translation negative CD4+ T cells. In fact, ISR/ATF4 activation-induced cell death largely occurs in HIV transcription active (HIV gag-pol) CD4+ T cells. This is involved in HIV RNA-induced innate immune IFIT signaling. During the acute SIV infection in the rhesus macaques, the induction of ATF4 is associated with decrease of SIV reservoir in the intestine in vivo. When further tested in the resting CD4+ T cells isolated from PLWH on ART, the induction of ISR/ATF4 signaling by HA15 reduced HIV DNA reservoir. These findings support that inactivation of ISR/ATF4 signaling is associated with the maintenance of the stable and quiescent HIV reservoirs while enforced ISR/ATF4 signaling reduces translation quiescent HIV reservoirs in CD4+ T cells.

Project description:Suppressive HAART does not eradicate HIV-1 and viral DNA persists as a stably integrated form in the absence of viral particle production. As a consequence, latent reservoirs are refractory to antiretroviral drugs and invisible to immune surveillance. The largest latent reservoir consists of resting memory CD4+ T cells. These cells can resume viral infection when activated through antigen recognition, causing bursts of viremia (blips). Current therapies targeting latent HIV-1 have focused primarily on the “shock and kill” approach, which employs “anti-latency” drugs – most notably histone deacetylase (HDAC) inhibitors – to reactivate and flush latent provirus from its cellular reservoirs in the absence of global T cell activation. This approach is predicated on the notions that viral reactivation will lead to the demise of the infected cell, and that HAART will prevent spreading of the infection. On the contrary, recent evidence indicates that latently infected CD4+ T cells of HIV-1 patients on HAART survive in vitro viral reactivation with the HDAC inhibitor, SAHA, even when co-cultured with autologous CD8+ cytotoxic T lymphocytes (CTL). Moreover, it remains to be addressed the impact of anti-latency drugs on viral reservoirs undergoing low-level ongoing replication, inherently more resistant to the cytopathic effects of HIV-1 and residing in anatomical sites hard to reach for some antiretroviral drugs (e.g. macrophages). As a consequence, there is a need to develop alternative therapeutic approaches aimed at eliminating or decreasing the latent reservoir. Progress in that direction has been hindered by the lack of biomarkers uniquely or differentially expressed on latently infected compared to their uninfected counterparts. To gain insight into the cellular mechanisms that take place in the context of latency, and with the goal of identifying distinctive markers that distinguish latently infected CD4+ T cells, we have used an in vitro model developed in our laboratory to study the expression profile of latently infected CD4+ T cells by microarray analysis.

Project description:Identifying cellular mechanisms maintaining HIV-1 latency in the viral reservoir is crucial for devising effective cure strategies. Here we developed a flow cytometry-fluorescent in situ hybridization (flow-FISH) approach using a combination of probes that detects abortive and elongated HIV-1 transcripts for ex vivo isolation and characterization of viral reservoir cells in peripheral blood from people with HIV-1. Following the isolation of three distinct cell populations from CD4+ T cells (i.e. cells harboring transcriptionally latent HIV-1, cells harboring transcriptionally active HIV-1, or uninfected cells), we determined their transcriptomic profile by RNA sequencing (RNAseq). Supervised gene expression analysis identified several differentially expressed mitochondrial genes in infected cell populations compared to uninfected cells, but also in latently infected compared to productively infected CD4+ T cells. Our transcriptomic profiling data shows an association between diminished mitochondrial functioning and the transcriptional activity of the viral reservoir. These findings underline the relevance of metabolic regulation in HIV-1 infection, and support the development of strategies modulating immunometabolism to target viral latency.

Project description:Treatment with latency-reversing agents (LRAs) alone has been ineffective in reducing HIV-1 reservoirs in people living with HIV-1 (PLWH) who are on antiretroviral therapy (ART), due to inefficiencies in reservoir reactivation and adaptive immune responses. However, NK cells activated with cytokines may be able to target HIV-1 reservoirs more effectively. To explore the therapeutic potential of NK cells, we expanded blood NK cells from multiple donors ex vivo into CD56brightCD16+ “eNK” cells using artificial antigen-presenting cells (aAPCs) expressing membrane-bound IL21. eNK cells express multiple activating receptors and are highly cytotoxic against specific target cells. They can also kill HIV-infected CD4+ T cells via antibody-dependent cell-mediated cytotoxicity (ADCC) using broadly neutralizing antibodies (bNAbs) against HIV-1 Env gp120/gp41. Notably, eNK cells from PLWH on ART efficiently killed autologous HIV-1+ T cells reactivated by a combination of vorinostat (SAHA) and IL-15 or an IL-15 superagonist (N-803), as evidenced by declines in proviral load, inducible HIV-1 mRNA, and virus release. Adoptive immunotherapy with eNK cells combined with LRA treatment thus presents a promising strategy to reduce the latent HIV-1 reservoir in PLWH.

Project description:A major obstacle for HIV eradication is the persistence of latent reservoirs, cells harboring replication competent yet transcriptionally silent proviruses. These reservoirs, composed primarily of CD4+ T cells, cannot be targeted by the host immune system or by combination anti-retroviral therapy (cART). Upon cessation of cART, a rapid viral rebound occurs. In order to develop effective HIV cure therapies, a better understanding of the factors and host programd governing latency establishment and/or maintenance must be obtained. To achieve this goal, we treated a CD4+T cell-based model of latency (J-Lat 10.6) with Latency Reversing Agents (LRAs) and performed bulk RNA-seq to predict host transcriptional programs activated, and potentially involved, in latent HIV reactivation. Our findings suggest that a novel small molecule (EPH-334) reactivates latent HIV by activating an oxidative stress transcriptional program linked to activation of MAPKs and downstream master regulators. Interestingly, the pan histone deacetylase inhibitor SAHA also induces oxidative stress programs potentially linking sensing of redox state aletartions with activation of cell signaling and transcriptioonal programs culminating on latent HIV reactivation.