Project description:Virus-like vesicles (VLVs) are membrane derived cellular vesicles that resemble native envelope viruses in organization and conformation, but lack viral capsid and/or genome. During productive virus infection, both infectious virions and non-infectious VLVs are produced and released into the extracellular space. VLVs have been shown to play a role in intercellular communication and in facilitating virus infection. The study of VLVs in the context of gammaherpesvirus infection has been largely restricted due to the technical difficulty of separating VLVs and virions. Here we report a strategy for using a KSHV mutant deficient in capsid assembly to isolate VLVs during infection. Using Mass Spectrometry analysis, we identified that VLVs contain viral glycoproteins required for cellular entry, and tegument proteins involved in regulating lytic replication. Functional analysis showed that VLVs could activate the RTA promoter, the lytic switch for KSHV, and further induce KSHV lytic gene expression from latency. We used RNA sequencing to do a genome-wide analysis of cellular responses triggered by VLVs, and revealed that PRDM1, a master regulator in cell differentiation, was up-regulated. Our data shows that VLVs play an important role in promoting KSHV lytic replication by inducing PRDM1 expression which activates the RTA promoter. Our study significantly extends our current understanding of VLVs.

Project description:Epstein-Barr virus (EBV) Rta is a latent-lytic molecular switch evolutionarily conserved in all gamma-herpesviruses. In previous studies, doxycycline-inducible Rta was shown to potently produce an irreversible G1 arrest followed by cellular senescence in 293 cells. Here, we demonstrate that in this system the inducible Rta not only reactivates resident genome of EBV but also that of Kaposi’s sarcoma-associated herpesvirus (KSHV), to similar efficiency. However, Rta-induced senescence program was terminated by the robust viral lytic cycle replication that eventually caused cell death. Furthermore, prior to the abrupt expression of immediate-early protein (EBV BZLF1 or KSHV RTA), Rta simultaneously down-regulates cell cycle activators (c-Myc, CDK6, CCND2) and up-regulates senescence-related genes (p21, 14-3-3s). Since Rta is a viral immediate-early transcriptional activator, it is envisioned that during the initial stage of viral reactivation, Rta may engage to modulate the host transcriptome, to halt cell cycle progression, and to maintain an ideal environment for manufacturing infectious virions. Refer to individual Series. This SuperSeries is composed of the following subset Series: GSE24585: Expression profiling of host genes modulated by Epstein-Barr virus (EBV) Rta in HEK293 cells GSE24586: Expression profiling of host genes modulated by Epstein-Barr virus Rta in nasopharyngeal carcinoma cells

Project description:Epstein-Barr virus (EBV) Rta is a latent-lytic molecular switch evolutionarily conserved in all gamma-herpesviruses. In previous studies, doxycycline-inducible Rta was shown to potently produce an irreversible G1 arrest followed by cellular senescence in 293 cells. Here, we demonstrate that in this system the inducible Rta not only reactivates resident genome of EBV but also that of Kaposi’s sarcoma-associated herpesvirus (KSHV), to similar efficiency. However, Rta-induced senescence program was terminated by the robust viral lytic cycle replication that eventually caused cell death. Furthermore, prior to the abrupt expression of immediate-early protein (EBV BZLF1 or KSHV RTA), Rta simultaneously down-regulates cell cycle activators (c-Myc, CDK6, CCND2) and up-regulates senescence-related genes (p21, 14-3-3s). Since Rta is a viral immediate-early transcriptional activator, it is envisioned that during the initial stage of viral reactivation, Rta may engage to modulate the host transcriptome, to halt cell cycle progression, and to maintain an ideal environment for manufacturing infectious virions. This SuperSeries is composed of the SubSeries listed below.

Project description:The establishment of latency is an essential step for the life-long persistent infection and pathogenesis of KaposiM-bM-^@M-^Ys sarcoma-associated herpesvirus (KSHV). While the KSHV genome is chromatin-free in the virions, the viral DNA in latently infected cells has a chromatin structure that is characterized by a specific pattern of activating and repressive histone modifications that ultimately promote latent gene expression while suppressing lytic gene expression. To investigate the molecular events involved in the establishment of the latent chromatin structure during the pre-latency phase of KSHV infection, we performed a comprehensive epigenetic study to analyze the recruitment of chromatin regulatory factors onto the KSHV genome at various time-points following de novo infection of SLK and TIME cells. This showed that the KSHV genome undergoes a biphasic chromatinization following de novo infection. Initially, a transcriptionally active chromatin (euchromatin), characterized by high levels of the H3K4me3 and acetylated H3K27 (H3K27ac) activating histone marks, was deposited on the viral episome and was accompanied by the temporary induction of a limited number of lytic genes. Interestingly, transient expression of the RTA protein facilitated the increases of H3K4me3 and H3K27ac occupancy on the KSHV episome during de novo infection. Between 24-72 hours post-infection, as the levels of these activating histone marks declined on the KSHV genome, the levels of the repressive H3K27me3 and H2AK119ub histone marks increased concomitantly with the decline of lytic gene expression. Importantly, this transition to heterochromatin was dependent on both the Polycomb Repressive Complex 2 and 1. In contrast, upon infection of human gingiva-derived epithelial cells, the KSHV genome underwent a continuously transcription-active euchromatinization, resulting in efficient lytic gene expression. Our data demonstrate that the KSHV genome undergoes a temporally ordered biphasic euchromatin-to-heterochromatin transition in endothelial cells, leading to latent infection, whereas KSHV preferentially adopts a transcriptionally active euchromatin in oral epithelial cells, resulting in lytic gene expression. Our results suggest that the differential epigenetic modification of the KSHV genome in distinct cell types is a potential determining factor for latent infection vs. lytic replication of KSHV. Please see above. 16 hybridizations: ChIP and Input DNA

Project description:The epitranscriptomic modification m6A is a ubiquitous feature of the mammalian transcriptome. It modulates mRNA fate and dynamics to exert regulatory control over numerous cellular processes and disease pathways, including viral infection. Kaposi’s sarcoma-associated herpesvirus (KSHV) reactivation from the latent phase leads to redistribution of m6A topology upon both viral and cellular mRNAs within infected cells. Here we investigate the role of m6A in cellular transcripts upregulated during KSHV lytic replication. Results show that m6A is crucial for the stability of the GPRC5A mRNA, whose expression is induced by the KSHV latent-lytic switch master regulator, the replication and transcription activator (RTA) protein. Moreover, we demonstrate that GPRC5A is essential for efficient KSHV lytic replication by directly regulating NFκB signalling. Overall, this work highlights the central importance of m6A in modulating cellular gene expression to influence viral infection.

Project description:The establishment of latency is an essential step for the life-long persistent infection and pathogenesis of Kaposi’s sarcoma-associated herpesvirus (KSHV). While the KSHV genome is chromatin-free in the virions, the viral DNA in latently infected cells has a chromatin structure that is characterized by a specific pattern of activating and repressive histone modifications that ultimately promote latent gene expression while suppressing lytic gene expression. To investigate the molecular events involved in the establishment of the latent chromatin structure during the pre-latency phase of KSHV infection, we performed a comprehensive epigenetic study to analyze the recruitment of chromatin regulatory factors onto the KSHV genome at various time-points following de novo infection of SLK and TIME cells. This showed that the KSHV genome undergoes a biphasic chromatinization following de novo infection. Initially, a transcriptionally active chromatin (euchromatin), characterized by high levels of the H3K4me3 and acetylated H3K27 (H3K27ac) activating histone marks, was deposited on the viral episome and was accompanied by the temporary induction of a limited number of lytic genes. Interestingly, transient expression of the RTA protein facilitated the increases of H3K4me3 and H3K27ac occupancy on the KSHV episome during de novo infection. Between 24-72 hours post-infection, as the levels of these activating histone marks declined on the KSHV genome, the levels of the repressive H3K27me3 and H2AK119ub histone marks increased concomitantly with the decline of lytic gene expression. Importantly, this transition to heterochromatin was dependent on both the Polycomb Repressive Complex 2 and 1. In contrast, upon infection of human gingiva-derived epithelial cells, the KSHV genome underwent a continuously transcription-active euchromatinization, resulting in efficient lytic gene expression. Our data demonstrate that the KSHV genome undergoes a temporally ordered biphasic euchromatin-to-heterochromatin transition in endothelial cells, leading to latent infection, whereas KSHV preferentially adopts a transcriptionally active euchromatin in oral epithelial cells, resulting in lytic gene expression. Our results suggest that the differential epigenetic modification of the KSHV genome in distinct cell types is a potential determining factor for latent infection vs. lytic replication of KSHV. Please see above.

Project description:Lytic reactivation from latency is critical for the pathogenesis of KSHV. We previously demonstrated that the 691 amino acid KSHV Rta transcriptional transactivator is necessary and sufficient to reactivate the virus from latency. Viral lytic cycle genes, including those expressing additional transactivators and putative oncogenes, are induced in a cascade fashion following Rta expression. In this study, we sought to define Rta’s direct targets during reactivation by generating a conditionally nuclear variant of Rta. WT Rta protein is constitutively localized to cell nuclei, and contains two putative nuclear localization signals (NLSs). Only one NLS (NLS-2; aa 516-530) was required for nuclear localization of Rta, and relocalized eGFP exclusively to cell nuclei. Analyses of Rta NLS mutants demonstrated that proper nuclear localization of Rta was required for transactivation and stimulation of viral reactivation. Fusion of Rta_NLS-1,2 to the hormone binding domain of the murine estrogen receptor generated a variant of Rta whose nuclear localization and ability to transactivate and induce reactivation were tightly controlled post-translationally by the synthetic hormone tamoxifen. We used this strategy in KSHV-infected cells treated with protein synthesis inhibitors to identify direct transcriptional targets of Rta. Only eight KSHV genes were activated by Rta in the absence of de novo protein synthesis. These direct transcriptional targets of Rta were transactivated to different magnitudes, and included the genes nut-1/PAN, ORF57/Mta, ORF56/Primase, K2/vIL-6, ORF37/SOX, K14/vOX, K9/vIRF1, and ORF52. Our data suggest that induction of most of the KSHV lytic cycle genes requires additional protein expression post-Rta. Keywords: Comparative transcriptome analysis by oligonucleotide microarray

Project description:The three-dimensional structure of chromatin via formation of genomic loops allows cellular RNA polymerase II to access distal promoters, thus it has a significant impact on the outcome of gene expression. The Kaposi’s sarcoma-associated herpesvirus (KSHV) entire lytic transcriptional program of 80 plus genes is initiated by a single viral transactivator, K-Rta. Here we examined the relationship between the KSHV genomic structure and K-Rta recruitment sites with unbiased Capture Hi-C analyses. The studies showed that KSHV forms a unique genomic structure, which coordinates a domain-specific viral gene expression program via K-Rta recruitment, and identified a number of direct physical, long-range, and dynamic genomic interactions. Chromatin immunoprecipitation-sequencing analyses identified a limited number of K-Rta recruitment sites in the KSHV genome, including the K12 and PAN RNA promoters. KSHV engineered to harbor point mutations in the K-Rta-responsive elements (RE) at these promoters significantly attenuated not only the direct downstream gene, but also distal viral gene expression in a domain-specific manner. Despite the long distance between two RE sites in the linear orientation, efficient recruitment of K-Rta to either promoter required intact K-Rta REs at both promoters. Finally, inducible genomic loops generated during KSHV reactivation occurred preferentially at K-Rta recruitment sites. Mutation of a K-Rta RE inhibited formation of inducible genomic loops, gene expression of its destination of looping genes, and KSHV replication in de novo infected human gingival epithelial cells. These results suggest that the KSHV genome is programed to form both stable and inducible chromatin hubs for effective KSHV gene expression, and partly explains why K-Rta has such a dominant effect on KSHV lytic gene transcription.

Project description:The three-dimensional structure of chromatin via formation of genomic loops allows cellular RNA polymerase II to access distal promoters, thus it has a significant impact on the outcome of gene expression. The Kaposi’s sarcoma-associated herpesvirus (KSHV) entire lytic transcriptional program of 80 plus genes is initiated by a single viral transactivator, K-Rta. Here we examined the relationship between the KSHV genomic structure and K-Rta recruitment sites with unbiased Capture Hi-C analyses. The studies showed that KSHV forms a unique genomic structure, which coordinates a domain-specific viral gene expression program via K-Rta recruitment, and identified a number of direct physical, long-range, and dynamic genomic interactions. Chromatin immunoprecipitation-sequencing analyses identified a limited number of K-Rta recruitment sites in the KSHV genome, including the K12 and PAN RNA promoters. KSHV engineered to harbor point mutations in the K-Rta-responsive elements (RE) at these promoters significantly attenuated not only the direct downstream gene, but also distal viral gene expression in a domain-specific manner. Despite the long distance between two RE sites in the linear orientation, efficient recruitment of K-Rta to either promoter required intact K-Rta REs at both promoters. Finally, inducible genomic loops generated during KSHV reactivation occurred preferentially at K-Rta recruitment sites. Mutation of a K-Rta RE inhibited formation of inducible genomic loops, gene expression of its destination of looping genes, and KSHV replication in de novo infected human gingival epithelial cells. These results suggest that the KSHV genome is programed to form both stable and inducible chromatin hubs for effective KSHV gene expression, and partly explains why K-Rta has such a dominant effect on KSHV lytic gene transcription.

Project description:Abstract: The Kaposi’s sarcoma-associated herpesvirus (KSHV) is an important oncogenic virus previously shown to be neurotropic, but studies on neuronal cells infection and pathogenesis are still very limited. Here we characterized the effects of KSHV infection on neuronal SH-SY5Y cells by the recombinant virus rKSHV219, which expresses both GFP and RFP to reflect latent and lytic phases of infection. We demonstrated that infected cells have a faster growth rate and the KSHV infection can be sustained. Interestingly, the infected cells can transition spontaneously back and forth between lytic and latent phases of infections, producing progeny viruses but without any adverse effects on cell growth. In addition, transcriptome analysis of viral and cellular genes in latent and lytic cells showed that unlike other infected cell lines, the latently infected cells expressed both latent and most, but not all the lytic genes required for infectious virion production. The uniquely expressed viral genes by the lytic cells were mainly involved in the early steps of virus binding. Some of the cellular genes that were deregulated in both latent and lytically infected cells are involved in cell adhesion, in cell signal pathways and tumorigenesis. The downregulated cellular CCDN1, PAX5, NFASC and upregulated CTGF, BMP4, YAP1, LEF1 and HLA-DRB1 genes were found to be associated with the cell adhesion molecules (CAM), hippo signaling and cancer. These deregulated genes may be involved in creating an environment that are unique in the neuronal cells to sustain cell growth upon KSHV infection not observed in other infected cell types. IMPORTANCE: Our study has provided evidence that the neuronal SH-SY5Y cells displayed unique cellular responses upon KSHV infection. Unlike other infected cells, this neuronal cell displayed a more rapid growth rate upon infection and can spontaneously transition back and forth between latent and lytic phases of infection. Unlike other latently infected cells, a number of lytic genes were also expressed in the latent phase of infection in addition to the established latent viral genes. They may play a role in deregulating a number of host genes that are involved in cell signaling and tumorigenesis in order to sustain the infection and growth advantages for the cells. Our study has provided novel insights on KSHV infection of neuronal cells and a potential new model for further studies to explore the underlying mechanism in viral and host interaction for neuronal cells, and the association of KSHV with neuronal diseases.