Project description:The three-dimensional structure of the genome is a regulator of transcription and cell function; HIV-1 infection can influence host cell function, but the degree to which this is mediated through changes to host chromatin architecture is unclear. We interrogated genome-wide chromatin organization and the structure of chromatin around latently infected HIV-1 integration sites using Hi-C and ATAC-seq and combined these data with RNA transcriptional analysis of the provirus and neighboring genes in HIV-inducible cellular models. We found chromatin interaction networks around integrated HIV-1 are predominantly preserved with respect to uninfected cells, proving the lack of an obligate association between latent integration and major chromatin remodeling. Instead, we find that induction of proviral transcription may lead to local changes in chromatin accessibility downstream from the 3’ LTR, demonstrating that HIV-1 can alter local cellular chromatin structure post-integration. Using long-read Nanopore RNA-seq, we interrogated the local host and HIV-1 transcriptomes and observed that 1-5% of HIV-1 transcripts initiated at the 5’ LTR promoter extended into the flanking cellular genome, generating chimeric virus-host RNAs. Thus, integration leading to latency (and provirus activation) may not lead to obligate global chromatin rearrangements; we also observed, previously unreported, novel changes in chromatin accessibility during HIV-1 transcription.

Project description:HIV integrates semi-randomly into the genome of immune cells and thus proviruses that persist in patients under long-term, highly active suppressive therapy can be detected in various positions (inside and outside) and orientations (same, convergent and divergent) respective to genes, promoters, and enhancers. Thus, this integration landscape heterogeneity can influence HIV transcription activity thereby dictating proviral fate (active vs latent). However, the effect of the integration site to proviral transcription activity has so far remained elusive. Here we integrate open-source, large-scale datasets including epigenetics, transcriptome, and 3D genome architecture to interrogate the chromatin states, transcription activity landscape, nuclear sub-compartments, and topological associated domains around HIV integration sites in CD4+ T cell-based models to decipher ‘codes’ in the human genome shaping proviral transcription. As part of this integrated approach, here we collect nucleosome occupancy profiles in Jurkat CD4+ T cells.

Project description:HIV-1-infected cells that persist despite antiretroviral therapy (ART) are frequently considered ‘‘transcriptionally silent,’’ but active viral gene expression may occur in some cells, challenging the concept of viral latency. Applying an assay for profiling the transcriptional activity and the chromosomal locations of individual proviruses, we describe a global genomic and epigenetic map of transcriptionally active and silent proviral species and evaluate their longitudinal evolution in persons receiving suppressive ART. Using genome-wide epigenetic reference data, we show that proviral transcriptional activity is associated with activating epigenetic chromatin features in linear proximity of integration sites and in their inter- and intrachromosomal contact regions. Transcriptionally active proviruses were actively selected against during prolonged ART; however, this pattern was violated by large clones of virally infected cells that may outcompete negative selection forces through elevated intrinsic proliferative activity. Our results suggest that transcriptionally active proviruses are dynamically evolving under selection pressure by host factors.

Project description:Sustained, drug-free control of HIV-1 replication is naturally achieved in less than 0.5% of infected persons (“elite controllers”, ECs), despite the presence of a replication-competent viral reservoir. Such an ability to spontaneously maintain undetectable plasma viremia is a major objective of functional cure efforts, yet the characteristics of proviral reservoirs in ECs remain to be determined. Using single-genome, near full-length next-generation sequencing and chromosomal integration site analysis, we here show that proviral reservoirs of ECs frequently consist of oligoclonal to near monoclonal clusters of identical intact proviral sequences. In contrast to persons treated with long-term antiretroviral therapy, intact proviral species from ECs displayed highly distinct chromosomal integration sites in the human genome and were preferentially located in centromeric satellite DNA or in KRAB-ZNF genes on chromosome 19, both of which are associated with heterochromatin features. Moreover, integration sites of intact proviruses from ECs showed increased distance to host transcriptional start sites and accessible chromatin and were enriched for repressive chromatin marks. These data suggest that a distinct proviral reservoir configuration represents a structural correlate of natural viral control, and that quality rather than quantity of viral reservoirs can be an important distinguishing feature for a functional cure of HIV-1 infection. Moreover, failure to detect intact proviral sequences despite analyzing > 1.5 billion peripheral blood mononuclear cells in one EC raises the possibility that a sterilizing cure of HIV-1 infection, previously only observed following allogeneic hematopoietic stem cell transplantation, may be feasible in rare instances.

Project description:Sustained, drug-free control of HIV-1 replication is naturally achieved in less than 0.5% of infected persons (“elite controllers”, ECs), despite the presence of a replication-competent viral reservoir. Such an ability to spontaneously maintain undetectable plasma viremia is a major objective of functional cure efforts, yet the characteristics of proviral reservoirs in ECs remain to be determined. Using single-genome, near full-length next-generation sequencing and chromosomal integration site analysis, we here show that proviral reservoirs of ECs frequently consist of oligoclonal to near monoclonal clusters of identical intact proviral sequences. In contrast to persons treated with long-term antiretroviral therapy, intact proviral species from ECs displayed highly distinct chromosomal integration sites in the human genome and were preferentially located in centromeric satellite DNA or in KRAB-ZNF genes on chromosome 19, both of which are associated with heterochromatin features. Moreover, integration sites of intact proviruses from ECs showed increased distance to host transcriptional start sites and accessible chromatin and were enriched for repressive chromatin marks. These data suggest that a distinct proviral reservoir configuration represents a structural correlate of natural viral control, and that quality rather than quantity of viral reservoirs can be an important distinguishing feature for a functional cure of HIV-1 infection. Moreover, failure to detect intact proviral sequences despite analyzing > 1.5 billion peripheral blood mononuclear cells in one EC raises the possibility that a sterilizing cure of HIV-1 infection, previously only observed following allogeneic hematopoietic stem cell transplantation, may be feasible in rare instances.

Project description:The reservoir of latently HIV-1 infected cells is heterogeneous. To achieve an HIV-1 cure the reservoir of activatable proviruses should be removed, whereas permanently silenced proviruses may be tolerated. We have developed a method to assess the proviral nuclear microenvironment in single cells. Latently HIV-1 infected cells were transduced with a zinc finger protein specifically binding to the HIV-1 promoter, producing a fluorescent signal as the viral transactivator Tat is recruited to the HIV-1 promoter. In these cells we assessed the proviral chromatin composition simultaneously with the proviral activation. By linking the Tat promoter recruitment to viral activation, we dissected the mechanisms of HIV-1 reactivation and the consequences of HIV-1 production. A pulse of promoter-associated Tat was identified that contrasts to the continuous production of viral proteins. As expected, promoter H3K4me3 led to massive expression of the provirus following T cell stimulation. However, the activation induced cell cycle arrest and death resulted in an expanded surviving cell fraction with proviruses encapsulated in repressive chromatin. Further, this model can be used to reveal mechanisms of action of small molecules. In a proof-of-concept study we determine the effect of CBP/P300-inhibitor GNE049. We found that only active enhancers, associated with H3K4me1 and H3K27ac, efficiently recruit Tat, as GNE049 that specifically inhibits enhancer H3K27ac also depletes promoter Tat. Despite the absence of Tat, HIV-1 latency reversal still occurred. Single cell assessment of the chromatin composition of the latent HIV-1 proviruses revealed how T cell stimulation modulates the proviral activity and the subsequent fate of the infected cell.

Project description:Integration of the HIV-1 provirus in the host genome ensures a persistent supply of latently infected cells. This latent reservoir is recalcitrant to antiretroviral therapy (ART) making lifelong treatment the only option for patients. The â??shock and killâ?? strategy aims to eradicate latent HIV by reactivating proviral gene expression followed by ART treatment. Gene specific transcriptional activation can be achieved using the RNA-guided CRISPR-Cas9 system comprising small guide RNAs (sgRNAs) with a nuclease deficient Cas9 mutant (dCas9) fused to the VP64 transactivation domain (dCas9-VP64).  We engineered this system to target 23 sites within the LTR promoter of HIV-1 and identified a â??hotspotâ?? for activation. We studied the functionality of activating sgRNAs to transcriptionally modulate the latent proviral genome across multiple different in vitro latency cell models including several J-Lat, ACH2 J1.1 and the CEM T cell model comprising a single clonal population of integrated mCherry-IRES-Tat from a full-length HIV LTR (LChIT).  While we observed variable responses of latent cell models to well-characterized chemical stimuli, we detected consistent efficient activation of latent virus mediated by activator sgRNAs.  In addition, transcriptome analysis of chemically treated cells revealed massive non-specific gene dysregulation whereas by comparison, dCas9-VP64/sgRNAs induced specific activation of the integrated provirus.  In conclusion, we show the potential for CRISPR-mediated gene activation systems to provide enhanced efficiency and specificity in a targeted latency reactivation strategy. This represents a promising approach to a â??functional cureâ?? of HIV/AIDS. Three experimental conditions (sgRNA control, TNF treated and sgRNA against the LTR of HIV-1) were analyzed in triplicate using two sequencing lanes

Project description:HIV-1 integration introduces ectopic transcription factor binding sites into host chromatin. We postulate that the integrated provirus serves as an ectopic enhancer that recruits additional transcriptional factors to the integration locus, increases chromatin accessibility, changes 3D chromatin interactions, and enhances both retroviral and host gene expression. We used 4 well-characterized HIV-1-infected cell line clones having unique integration sites and low to high levels of HIV-1 expression. Using single-cell DOGMA-seq, which captured the heterogeneity of HIV-1 expression and host chromatin accessibility, we found that HIV-1 transcription correlated with HIV-1 accessibility and host chromatin accessibility. HIV-1 integration increased local host chromatin accessibility within ~5–30 kb distance. CRISPRa and CRISPRi-mediated HIV-1 promoter activation and inhibition confirmed integration site-dependent HIV-1-driven changes of host chromatin accessibility. HIV-1 did not drive chromatin confirmation changes at the genomic level (by Hi-C) or the enhancer connectome (by H3K27Ac HiChIP). Using 4C-seq to interrogate HIV-1-chromatin interactions, we found that HIV-1 interacted with host chromatin ~100–300 kb from the integration site. By identifying chromatin regions having both increased transcription factor activity (by ATAC-seq) and HIV-1-chromtain interaction (by 4C-seq), we identified enrichment of ETS, RUNT, STAT, and ZNF transcription factor binding that may mediate HIV-1-host chromatin interactions. Our study found that HIV-1 promoter activity increased host chromatin accessibility, increased HIV-1-host chromatin interactions in an integration site dependent manner, within the existing chromatin boundaries without impacting broader host chromatin structure.

Project description:HIV-1 integration introduces ectopic transcription factor binding sites into host chromatin. We postulate that the integrated provirus serves as an ectopic enhancer that recruits additional transcriptional factors to the integration locus, increases chromatin accessibility, changes 3D chromatin interactions, and enhances both retroviral and host gene expression. We used 4 well-characterized HIV-1-infected cell line clones having unique integration sites and low to high levels of HIV-1 expression. Using single-cell DOGMA-seq, which captured the heterogeneity of HIV-1 expression and host chromatin accessibility, we found that HIV-1 transcription correlated with HIV-1 accessibility and host chromatin accessibility. HIV-1 integration increased local host chromatin accessibility within ~5–30 kb distance. CRISPRa and CRISPRi-mediated HIV-1 promoter activation and inhibition confirmed integration site-dependent HIV-1-driven changes of host chromatin accessibility. HIV-1 did not drive chromatin confirmation changes at the genomic level (by Hi-C) or the enhancer connectome (by H3K27Ac HiChIP). Using 4C-seq to interrogate HIV-1-chromatin interactions, we found that HIV-1 interacted with host chromatin ~100–300 kb from the integration site. By identifying chromatin regions having both increased transcription factor activity (by ATAC-seq) and HIV-1-chromtain interaction (by 4C-seq), we identified enrichment of ETS, RUNT, STAT, and ZNF transcription factor binding that may mediate HIV-1-host chromatin interactions. Our study found that HIV-1 promoter activity increased host chromatin accessibility, increased HIV-1-host chromatin interactions in an integration site dependent manner, within the existing chromatin boundaries without impacting broader host chromatin structure.

Project description:HIV-1 integration introduces ectopic transcription factor binding sites into host chromatin. We postulate that the integrated provirus serves as an ectopic enhancer that recruits additional transcriptional factors to the integration locus, increases chromatin accessibility, changes 3D chromatin interactions, and enhances both retroviral and host gene expression. We used 4 well-characterized HIV-1-infected cell line clones having unique integration sites and low to high levels of HIV-1 expression. Using single-cell DOGMA-seq, which captured the heterogeneity of HIV-1 expression and host chromatin accessibility, we found that HIV-1 transcription correlated with HIV-1 accessibility and host chromatin accessibility. HIV-1 integration increased local host chromatin accessibility within ~5–30 kb distance. CRISPRa and CRISPRi-mediated HIV-1 promoter activation and inhibition confirmed integration site-dependent HIV-1-driven changes of host chromatin accessibility. HIV-1 did not drive chromatin confirmation changes at the genomic level (by Hi-C) or the enhancer connectome (by H3K27Ac HiChIP). Using 4C-seq to interrogate HIV-1-chromatin interactions, we found that HIV-1 interacted with host chromatin ~100–300 kb from the integration site. By identifying chromatin regions having both increased transcription factor activity (by ATAC-seq) and HIV-1-chromtain interaction (by 4C-seq), we identified enrichment of ETS, RUNT, STAT, and ZNF transcription factor binding that may mediate HIV-1-host chromatin interactions. Our study found that HIV-1 promoter activity increased host chromatin accessibility, increased HIV-1-host chromatin interactions in an integration site dependent manner, within the existing chromatin boundaries without impacting broader host chromatin structure.