Project description:Infection with Human cytomegalovirus (HCMV) can result in either productive or non-productive infection, the latter potentially leading to establishment of latency, but the molecular factors that dictate these different infection outcomes are elusive. Macrophages are known targets of HCMV and considered to be permissive for productive infection, while monocytes, their precursors, are thought to support latent infection. Here we reveal that infection of macrophages is more complex than previously appreciated and can result in either productive or non-productive infection. By analyzing the progression of HCMV infection in c and macrophages using single cell transcriptomics, we uncover that the key characteristics that define productive and non-productive cells are the onset of viral gene expression, and activation of Interferon-stimulated genes (ISGs), respectively. We show that the level of viral gene expression, and specifically the expression of the major immediate early factor, IE1, is the principle barrier for establishing productive infection. On the cellular side, induction of ISGs in response to infection surprisingly does not dictate infection outcome, but we find that the cell intrinsic ISG levels is a main determinant of infection outcome. Indeed, intrinsic ISG level is downregulated with monocyte differentiation. We further show that, compared to monocytes, non-productive macrophages maintain slightly higher levels of viral transcripts and are able to reactivate, raising the possibility that they can serve as latency reservoirs in tissues. Moreover, we find that productive infection perturbs macrophage identity and function, likely affecting their immunological role during active infection. Overall, by harnessing the tractable system of monocyte differentiation we decipher the underlying principles that control HCMV infection outcome, and propose macrophages as a new potential HCMV reservoir in tissues.

Project description:Primary infection with human cytomegalovirus (HCMV) results in a lifelong infection due to its ability to establish latent infection, with one characterized viral reservoir being hematopoietic cells. Although reactivation from latency causes serious disease in immunocompromised individuals, our molecular understanding of latency is limited. Here, we delineate viral gene expression during natural HCMV persistent infection by analyzing the massive transcriptome sequencing (RNA-seq) atlas generated by the Genotype-Tissue Expression (GTEx) project. This systematic analysis reveals that HCMV persistence in vivo is prevalent in diverse tissues. Notably, we find only viral transcripts that resemble gene expression during various stages of lytic infection with no evidence of any highly restricted latency-associated viral gene expression program. To further define the transcriptional landscape during HCMV latent infection, we also used single-cell RNA-seq and a tractable experimental latency model. In contrast to some current views on latency, we also find no evidence for any highly restricted latency-associated viral gene expression program. Instead, we reveal that latency-associated gene expression largely mirrors a late lytic viral program, albeit at much lower levels of expression. Overall, our work has the potential to revolutionize our understanding of HCMV persistence and suggests that latency is governed mainly by quantitative changes, with a limited number of qualitative changes, in viral gene expression.

Project description:We have established that human cytomegalovirus (HCMV) infection modulates the biology of target primary blood monocytes, allowing HCMV to use monocytes as 'vehicles' for its systemic spread. HCMV infection of monocytes results in rapid induction of PI(3)K and NF-kB activity. Integrins, which are upstream of the PI(3)K and NF-kB pathways, were shown to be involved in HCMV binding to and entry into fibroblasts, suggesting that receptor-ligand-mediated signaling following viral binding to integrins on monocytes could trigger the functional changes seen in infected monocytes. We now show that integrin engagement and the activation of the integrin/Src-signaling pathway is essential for the induction of HCMV-infected monocyte motility. To investigate how integrin engagement by HCMV triggers monocyte motility, we examined the infected monocyte transcriptome and found that the integrin/Src-signaling pathway regulates the expression of paxillin, which is an important signal transducer in the regulation of actin rearrangement during cell adhesion and movement. Functionally, we observed that paxillin is activated via the integrin/Src-signaling pathway and is required for monocyte motility. Because motility is intimately connected to cellular cytoskeletal organization, a process that is also important in viral entry, we investigated the role paxillin regulation plays in the process of viral entry of monocytes. New results confirmed that HCMV`s ability to enter target monocytes is significantly inhibited in cells deficient in paxillin expression or that had their integrin/Src/paxillin signaling pathway blocked. From our data, HCMV-cell interactions emerge as an essential trigger for the cellular changes that allow for HCMV entry and hematogenous dissemination. Monocytes were mock-infected, HCMV-infected, or pretreated with PP2 inhibitor prior to HCMV infection. There were three samples analyzed per individual replicate. Three replicates are included. comparative studies with a use of the specific Src kinase activity inhibitor

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:Abstract: The transcriptional program associated with herpesvirus latency and the viral genes regulating entry into and exit from latency are poorly understood and controversial. Here, we developed and validated a targeted enrichment platform and conducted large-scale transcriptome analyses of human cytomegalovirus (HCMV) infection. We used both an experimental hematopoietic cell model of latency, and cells from naturally infected, healthy human subjects (clinical) to define the breadth of viral genes expressed. The viral transcriptome derived from experimental infection was highly correlated with that from clinical infection, validating our experimental latency model. These transcriptomes revealed a broader profile of gene expression during infection in hematopoietic cells than previously appreciated. Further, using recombinant viruses that establish a non-reactivating, latent-like or replicative infection in CD34+ hematopoietic progenitors (HPCs), we defined classes of low to moderately expressed genes that are differentially regulated in latent vs. replicative states of infection. Most of these genes have yet to be studied in depth. By contrast, genes that were highly expressed, were expressed similarly in both latent and replicative infection.  From these findings, a model emerges whereby low or moderately expressed genes may have the greatest impact on regulating the switch between viral latency and replication. The core set of viral genes expressed in natural infection and differentially regulated depending on the pattern of infection provides novel insight into the HCMV transcriptome associated with latency in the host and a resource for investigating new virus-host interactions underlying persistence. Significance: Herpesviruses have an extraordinarily complex relationship with their host, persisting for the lifetime of the host by way of a latent infection. Reactivation of replication is associated with significant disease risk, particularly in immunocompromised individuals. We characterize in depth transcriptional profiles of HCMV latency. We show that a broad and concordant viral transcriptome is found in both an experimental model of latency and in asymptomatically infected individuals. We further define genes that are differentially regulated during latent and replicative states- candidates for key regulators controlling the switch between latency and reactivation. This work will help understand the persistence of complex DNA viruses and provides a path towards developing antiviral strategies to control herpesvirus entry into and exit from latency.

Project description:Latent human cytomegalovirus (HCMV) in myeloid cells can be reactivated during cell differentiation and by inflammatory mediators. Expression level of immune regulator IL1R8 has been associated with the differentiation status of myeloid cells. As far, little is known about the role of IL1R8 in the association between reactivation of latent HCMV and differentiation of myeloid cells. To gain additional insights into IL1R8 and latency, a comparative transcriptome analysis was carried out through a unique bioinformatics approach that integrated IL1R8-correlated genes with differentially expressed genes to identify IL1R8-associated significant pathways. The Metascape pathway tool was utilized to perform enrichment analysis. The initial analysis revealed a significant inverse correlation between IL1R8 and viral counts (r = -0.42, z-score = -4.69) at single cell level in HCMV-infected monocytes at 4-14 days postinfection. In contrast to the majority of pathway analysis studies presenting unilateral up- or down-regulation, the current study discovered a number of bilaterally regulated key immune pathways in both lytic and latent infections. Notably, a ~3-fold predominant downregulation of the high-level adaptive immune system pathway was followed by a modestly predominant downregulation of mid-level Lymphocyte and low-level T cell activation pathways in latent infection. More interestingly, a unilateral upregulation pattern was identified exclusively in latent infection for Myeloid leukocyte activation, differentiation, and migration, in which upregulated genes were in concord with IL1R8 negatively correlated genes. The findings in the present study provided a comprehensive view of immunological alterations and a better understanding on the potential role of IL1R8 in the association between HCMV reactivation and myeloid cell differentiation in HCMV infection. The current study, for the first time, presented unique evidence supportive of a IL1R8-associated unilateral upregulation of myeloid leukocyte pathways in latent infection.

Project description:Primary infection with Human cytomegalovirus (HCMV) results in a persistent lifelong infection due to its ability to establish latent infection. During productive HCMV infection, viral genes are expressed in a coordinated cascade that is characteristic of all herpesviruses and traditionally relies on the dependencies of viral genes on protein synthesis and viral DNA replication. In contrast, the transcriptional landscape associated with HCMV latency is still disputed and poorly understood. Here, we examine viral transcriptomic dynamics during the establishment of both productive and latent HCMV infections. These temporal measurements reveal that viral gene expression dynamics along productive infection and their dependencies on protein synthesis and viral DNA replication, do not fully align. This illustrates that the regulation of herpesvirus genes does not represent a simple sequential transcriptional cascade and surprisingly many viral genes are regulated by multiple independent modules. Using our improved classification of viral gene expression kinetics in conjunction with transcriptome-wide measurements of the effects of a wide array of chromatin modifiers, we unbiasedly show that a defining characteristic of latent cells is the unique repression of immediate early (IE) genes. In particular, we demonstrate that IE1 (a central IE protein) expression is the principal barrier for achieving a full productive cycle. Altogether, our findings provide an unbiased and elaborate definition of HCMV gene expression in lytic and latent infection states. 

Project description:HIV-1 latency is a major obstacle to achieve a functional cure for AIDS. To eradicate the viral reservoir, one of the strategies is to specifically reactivate HIV-1-infected cells and followed by elimination with potent immune surveillance. However, present latency-reversing agents (LRAs) are quite dissatisfactory because of their high toxicity and low efficiency. New targets need to be identified to develop more promising LRAs. Here, we found that histone chaperone chromatin assembly factor 1 (CAF-1) promotes HIV-1 latency by forming versatile suppressive nuclear bodies. CAF-1 plays a leading role for the formation of bodies recruiting multi-layer suppressive epigenetic modifiers and maintainers, and is of the characteristic of liquid-liquid phase separation (LLPS). Three distinct disordered regions of CHAF1A subunit coalesce CAF-1 body components by forming LLPS and play a key in maintaining HIV-1 latency. Therefore, disruptive induction of phase-separated CAF-1 body could be an important strategy to reactivate latent HIV-1.

Project description:The barrier to HIV-1 functional cure is caused by a small pool of latently infected resting CD4 T-cells that persist under antiretroviral therapy. Notably this latent reservoir of infected cells will produce replication-competent infectious virus once prolonged suppressive HAART is withdrawn. The reactivation of HIV-1 gene expression in T-cells harboring latent provirus in HIV-1 patients under HAART will likely result in depletion of this latent reservoir due to cytopathic effects and immune clearance. Many studies have investigated small molecules that reactivate HIV-1 gene expression but to date no latency reversal agent (LRA) has been identified to be specific, non-toxic, and effective in primary T-cells isolated from HIV-1 infected individuals undergoing long-term HAART. Stochastic fluctuations in HIV-1 tat gene expression have been attributed to be essential in the viral progression to latency. We hypothesized that exposing Tat to latently infected CD4 T-cells will result in potent latency reversal. Our results indicate the capacity of an engineered Tat to reactivate HIV-1 in latently infected cells from patients to a similar degree as the protein kinase C agonist PMA (Phorbol 12-Myristate 13-Acetate) while showing no T-cell activation nor any significant transcriptome perturbation in primary CD4 T-cells.

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.