Project description:HIV-1 infected patients virally suppressed by antiviral treatment harbor a persistent reservoir of replication competent latent HIV-1 infected cells, which constitute the main roadblock to a cure. A main strategy for HIV cure aims to stimulate viral gene expression in latently infected cells so that they can be cleared. Crucial for the design of drugs referred to as “latency-reversing agents” (LRAs) is the identification of molecular targets for latency reversal. The regulatory factors physically associated with and repressing the latent HIV-1 promoter or 5’LTR would provide ideal putative molecular targets for latency reversal. However, due to technical limitations, the comprehensive and unbiased identification of host proteins associated with the latent or active integrated HIV LTR in infected cells not been possible. Here we use dCas9 targeted chromatin and histone enrichment strategy coupled to mass spectrometry (Catchet-MS), to purify the locus-associated dCas9 bait, guided downstream of the HIV-1 transcriptional start site (TSS) in latent and activated HIV-1 infected T cells to identify the 5’LTR bound latent and active regulatory complexes. Catchet-MS identified both previously described as well as novel host factors distinctly associated with the latent versus transcriptionally active HIV-1 5’LTR. Within the identified factors we find the transcription factor IKZF1 to be a novel repressor of the HIV-1 promoter required for maintenance of latency, and thus a molecular target for latency reversal. Finally, we identify the FDA approved drug, Iberdomide, which targets IKZF1 for degradation to be a novel LRA, which reversed latency in latent ex vivo HIV-1 infected primary CD4+ T cells and in cells isolated from HIV-1 infected, aviremic participants.

Project description:Attenuated poxviruses are safe and capable to express foreign antigens. Poxviruses are applied in veterinary vaccination and explored as candidate vaccines for humans. However, poxviruses express multiple genes encoding proteins that interfere with components of the innate and adaptive immune response. This manuscript describes two strategies aimed to improve the immunogenicity of the highly attenuated, host-range restricted poxvirus NYVAC: deletion of the viral gene encoding type-I interferon-binding protein and development of attenuated replication-competent NYVAC. We evaluated these newly generated NYVAC mutants, encoding HIV-1 env, gag, pol and nef, for their ability to stimulate HIV-specific CD8 T-cell responses from blood mononuclear cells of HIV-infected subjects. The new vectors were evaluated and compared to the parental NYVAC vector in dendritic cells (DCs), RNA expression arrays, HIV gag expression and direct and cross-presentation assays in vitro. Deletion of type-I interferon-binding protein enhanced expression of interferon and interferon-induced genes in DCs, and increased maturation of infected DCs. Restoration of replication competence induced activation of pathways involving antigen processing and presentation. Also, replication-competent NYVAC showed increased Gag expression in infected cells, permitting enhanced cross-presentation to HIV-specific CD8 T cells and proliferation of HIV-specific memory CD8 T-cells. The recombinant NYVAC combining both modifications induced interferon-induced genes and genes involved in antigen processing and presentation, as well as increased Gag expression. This combined replication-competent NYVAC is a promising candidate for the next generation of HIV vaccines. RNA expression obtained from DCs infected by NYVAC-C-dB19R and NYVAC-C-KC-dB19R compared to RNA expression obtained from DCs infected by NYVAC-C Supplementary file 'normalized_data_Human_V3_V2.txt' reports data for ILMN identifiers common to platforms HumanRef8V2 and HumanRef8V3.

Project description:Latent HIV-1 infection poses a major challenge in complete viral remission and cure. HIV-1 latency is a multi-dimensional, dynamic process and many aspects of how the viral latency is established and maintained still remains incompletely characterized. Here, we have investigated the host chromatin organization and transcriptomic changes in active- and latently-infected SupT1 cells. We employed an in vitro model of HIV-1 latency in SupT1 cells using a dual-reporter virus, HIVGKO, which enables high purity sorting and characterization of active- and latently-infected cells. We found a significant divergence in chromatin organization and gene expression pattern between active and latent infection compared to uninfected cells. Latent infection results in a repressive reorganization of the host chromatin, while active infection leads to an overall increase in chromatin accessibility. A stronger correlation was also observed between chromatin accessibility and gene expression in latent infection, which was manifested in a greater alteration of the cellular transcriptome in latent than active infection, for both proteincoding and long-non-coding RNAs (lncRNAs). We identified a number of novel lncRNAs associated with either active and latent infection. A reversal in expression pattern of latency-associated lncRNAs following PMA-induced reactivation indicated their infection state-specific expression and potential roles in HIV-1 latency. Taken together, this integrated, comparative study revealed that latent HIV-1 infection requires a substantially greater alteration in cellular epigenome and transcriptome. Understanding of the distinct cellular states conducive to active and latent infection may support devising strategies for specific modulation of host cellular functions as a curative intervention for HIV-1.

Project description:Latent HIV-1 infection poses a major challenge in complete viral remission and cure. HIV-1 latency is a multi-dimensional, dynamic process and many aspects of how the viral latency is established and maintained still remains incompletely characterized. Here, we have investigated the host chromatin organization and transcriptomic changes in active- and latently-infected SupT1 cells. We employed an in vitro model of HIV-1 latency in SupT1 cells using a dual-reporter virus, HIVGKO, which enables high purity sorting and characterization of active- and latently-infected cells. We found a significant divergence in chromatin organization and gene expression pattern between active and latent infection compared to uninfected cells. Latent infection results in a repressive reorganization of the host chromatin, while active infection leads to an overall increase in chromatin accessibility. A stronger correlation was also observed between chromatin accessibility and gene expression in latent infection, which was manifested in a greater alteration of the cellular transcriptome in latent than active infection, for both proteincoding and long-non-coding RNAs (lncRNAs). We identified a number of novel lncRNAs associated with either active and latent infection. A reversal in expression pattern of latency-associated lncRNAs following PMA-induced reactivation indicated their infection state-specific expression and potential roles in HIV-1 latency. Taken together, this integrated, comparative study revealed that latent HIV-1 infection requires a substantially greater alteration in cellular epigenome and transcriptome. Understanding of the distinct cellular states conducive to active and latent infection may support devising strategies for specific modulation of host cellular functions as a curative intervention for HIV-1.

Project description:Attenuated poxviruses are safe and capable to express foreign antigens. Poxviruses are applied in veterinary vaccination and explored as candidate vaccines for humans. However, poxviruses express multiple genes encoding proteins that interfere with components of the innate and adaptive immune response. This manuscript describes two strategies aimed to improve the immunogenicity of the highly attenuated, host-range restricted poxvirus NYVAC: deletion of the viral gene encoding type-I interferon-binding protein and development of attenuated replication-competent NYVAC. We evaluated these newly generated NYVAC mutants, encoding HIV-1 env, gag, pol and nef, for their ability to stimulate HIV-specific CD8 T-cell responses from blood mononuclear cells of HIV-infected subjects. The new vectors were evaluated and compared to the parental NYVAC vector in dendritic cells (DCs), RNA expression arrays, HIV gag expression and direct and cross-presentation assays in vitro. Deletion of type-I interferon-binding protein enhanced expression of interferon and interferon-induced genes in DCs, and increased maturation of infected DCs. Restoration of replication competence induced activation of pathways involving antigen processing and presentation. Also, replication-competent NYVAC showed increased Gag expression in infected cells, permitting enhanced cross-presentation to HIV-specific CD8 T cells and proliferation of HIV-specific memory CD8 T-cells. The recombinant NYVAC combining both modifications induced interferon-induced genes and genes involved in antigen processing and presentation, as well as increased Gag expression. This combined replication-competent NYVAC is a promising candidate for the next generation of HIV vaccines.

Project description:Human immunodeficiency virus (HIV-1) infects and depletes CD4+ T helper cells and can persist within these cells in a latent state during treatment with effective antiretroviral therapy (ART). A latent viral reservoir represents a major barrier to a cure for HIV-1 infection. A longstanding obstacle to understanding the reservoir has been the inability to identify and characterize latent cells without activating them and disrupting their resting state. To address this challenge, we have developed an HIV-1-induced lineage tracing (HILT) humanized mouse model that irreversibly marks HIV-infected cells. The system employs a genetically encoded Cre-lox switch transduced into hematopoietic stem cells which are transplanted into immunodeficient mice. Infection of CD4+ T cells in HILT mice with a Cre-expressing HIV clone irreversibly marks infected cells by switching dsRedExpress2 to EGFP expression, a phenotype that is maintained in cell harboring proviruses that are transcriptionally silent during ART. Single cell RNA sequencing (scRNAseq) of infected T cells in the presence or absence of ART reveals HIV infection in diverse CD4+ T cell transcriptional lineages indicating that infected cells with active or suppressed transcription exist in many different T cell lineages. We examined genetic pathways that are more frequently altered in infected cells when compared with uninfected bystander cells. A comparison of pathways that are regulated in opposite directions in acute versus early ART-treated (persistent) infection identified EIF2α-, sirtuin-, and ILK-signaling pathways which contain known transcriptional regulators of HIV transcription. Lastly, we find that resveratrol, a drug that impact sirtuin pathways can influence latency establishment in an acute infection setting.

Project description:Aguilera 2014 - HIV latency. Interaction between HIV proteins and immune response This model is described in the article: Studying HIV latency by modeling the interaction between HIV proteins and the innate immune response. Aguilera LU, Rodríguez-González J. J. Theor. Biol. 2014 Nov; 360: 67-77 Abstract: HIV infection leads to two cell fates, the viral productive state or viral latency (a reversible non-productive state). HIV latency is relevant because infected active CD4+ T-lymphocytes can reach a resting memory state in which the provirus remains silent for long periods of time. Despite experimental and theoretical efforts, the causal molecular mechanisms responsible for HIV latency are only partially understood. Studies have determined that HIV latency is influenced by the innate immune response carried out by cell restriction factors that inhibit the postintegration steps in the virus replication cycle. In this study, we present a mathematical study that combines deterministic and stochastic approaches to analyze the interactions between HIV proteins and the innate immune response. Using wide ranges of parameter values, we observed the following: (1) a phenomenological description of the viral productive and latent cell phenotypes is obtained by bistable and bimodal dynamics, (2) biochemical noise reduces the probability that an infected cell adopts the latent state, (3) the effects of the innate immune response enhance the HIV latency state, (4) the conditions of the cell before infection affect the latent phenotype, i.e., the existing expression of cell restriction factors propitiates HIV latency, and existing expression of HIV proteins reduces HIV latency. This model is hosted on BioModels Database and identified by: BIOMD0000000573. To cite BioModels Database, please use: BioModels Database: An enhanced, curated and annotated resource for published quantitative kinetic models. To the extent possible under law, all copyright and related or neighbouring rights to this encoded model have been dedicated to the public domain worldwide. Please refer to CC0 Public Domain Dedication for more information.

Project description:BACKGROUND: Combination antiretroviral therapy (cART) is able to control HIV-1 viral replication, however long-lived latent infection in resting memory CD4+ T-cells persist. The mechanisms for establishment and maintenance of latent infection in resting memory CD4+ T-cells remain unclear. Previously we have shown that HIV-1 infection of resting CD4+ T-cells co-cultured with CD11c+ myeloid dendritic cells (mDC) produced a population of non-proliferating T-cells with latent infection. Here we asked whether different antigen presenting cells (APC), including subpopulations of DC and monocytes, were able to induce post-integration latent infection in resting CD4+ T-cells, and examined potential cell interactions that may be involved using RNA-seq. RESULTS: mDC (CD1c+), SLAN+ DC and CD14+ monocytes were most efficient in stimulating proliferation of CD4+ T-cells during syngeneic culture and in generating post-integration latent infection in non-proliferating CD4+ T-cells following HIV-1 infection of APC-T-cell co-cultures. In comparison, plasmacytoid DC (pDC) and B-cells did not induce latent infection in APC-T-cell co-cultures. We compared the RNA expression profiles of APC subpopulations that could and could not induce latency in non-proliferating CD4+ T-cells. Gene expression analysis, comparing the mDC, SLAN+ DC and CD14+ monocyte subpopulations to pDC identified 53 upregulated genes that encode proteins expressed on the plasma membrane that could signal to CD4+ T-cells via cell-cell interactions (32 genes), immune checkpoints (IC) (5 genes), T-cell activation (9 genes), regulation of apoptosis (5 genes), antigen presentation (1 gene) and through unknown ligands (1 gene). CONCLUSIONS: APC subpopulations from the myeloid lineage, specifically mDC subpopulations and CD14+ monocytes, were able to efficiently induce post-integration HIV-1 latency in non-proliferating CD4+ T-cells in vitro. Inhibition of key pathways involved in mDC-T-cell interactions and HIV-1 latency may provide novel targets to eliminate HIV latency. mRNA profiles of sorted, pure antigen presenting cells including, CD1c+ myleoid dendirtic cells (mDC), SLAN+ mDC, CD14+ monocytes and plasmacytoid DC (pDC), were generated using next generation sequencing in triplicate, using Illumina Illumina Hiseq 2000.

Project description:Human immunity relies on the coordinated responses of many cellular subsets and functional states. Inter-individual variations in cellular composition and communication could thus potentially alter host protection. Here, we explore this hypothesis by applying single-cell RNA-Seq to examine viral responses among the dendritic cells (DCs) of three elite controllers (ECs) of HIV-1 infection. We discover a highly functional antiviral DC state in ECs whose fractional abundance after in vitro exposure to HIV-1 correlates with higher CD4+ T cell counts and lower HIV-1 viral loads, and that effectively primes polyfunctional T cell responses in vitro. We identify and validate select immunomodulators that increase the fractional abundance of this state in primary peripheral blood mononuclear cells (PBMCs) from healthy individuals in vitro.

Project description:Human immunity relies on the coordinated responses of many cellular subsets and functional states. Inter-individual variations in cellular composition and communication could thus potentially alter host protection. Here, we explore this hypothesis by applying single-cell RNA-Seq to examine viral responses among the dendritic cells (DCs) of three elite controllers (ECs) of HIV-1 infection. We discover a highly functional antiviral DC state in ECs whose fractional abundance after in vitro exposure to HIV-1 correlates with higher CD4+ T cell counts and lower HIV-1 viral loads, and that effectively primes polyfunctional T cell responses in vitro. We identify and validate select immunomodulators that increase the fractional abundance of this state in primary peripheral blood mononuclear cells (PBMCs) from healthy individuals in vitro.