Project description:Lytic replication is essential for persistent infection of Kaposi’s sarcoma-associated herpesvirus (KSHV) and the pathogenesis of related diseases, and many cellular pathways are hijacked by KSHV proteins to initiate and control the lytic replication of this virus. However, the machinery involved in KSHV lytic replication from the early to the late phases remains largely undetermined. We previously revealed that KSHV ORF45 plays important roles in late transcription and translation. In the present study, we reveal that the Forkhead box proteins FoxK1 and FoxK2 are ORF45-binding proteins and are essential for KSHV lytic gene expression and virion production and that depletion of FoxK1 or FoxK2 significantly suppresses the expression of many late viral genes. FoxK1 and FoxK2 directly bind to the promoters of several late viral genes, ORF45 augments the promoter binding and transcriptional activity of FoxK1 and FoxK2, and then FoxK1 or FoxK2 cooperates with ORF45 to promote late viral gene expression. Our findings suggest that ORF45 interacts with FoxK1 and FoxK2 and promotes their occupancy on a cluster of late viral promoters and their subsequent transcriptional activity; consequently FoxK1 and FoxK2 promote late gene expression to facilitate KSHV lytic replication.

Project description:Here we show that HSV-1 infection promoted PTBP1 nucleocytoplasmic translocation. PTBP1, an RNA binding protein, interacted with both cellular and viral RNA. Suppression of PTBP1 expression blocked HSV-1 lytic infection. Furthermore, we observed that acute PTBP1 suppression during HSV-1 lytic infection promoted HSV-1 latency that occurred with cell type conversion from fibroblast cells to neuronal-like cells. This demonstrates that a cellular factor PTBP1 plays an essential role in viral RNA nuclear export and in HSV-1 lytic infection. Additionally, a cell type conversion based on PTBP1 suppression may provide a basic model for delineation of host and viral factors governing HSV-1 lytic and latent infection within the same cell lineage of transcription regulation.

Project description:Foxk proteins are transcriptional regulators implicated in key biological processes such as glycolysis, autophagy and cell cycle regulation, among others. Here we employ targeted morpholino knockdown to deplete Foxk1, Fokx2, and Foxk2-1 proteins in developing zebrafish embryos. We demonstrate that the loss of Foxk transcription factors causes genome-wide transcriptional misregulation, characterised by upregulation of autophagy-related genes and downregulation of cell cycle regulators. The phenotype is embryonic lethal with the majority of embryos not surviving past 24hpf.

Project description:Autophagy is the primary catabolic process triggered in response to starvation. Although autophagic regulation within the cytosolic compartment is well established, it is becoming clear that nuclear events also regulate the induction or repression of autophagy. Nevertheless, a thorough understanding of the mechanisms by which sequence-specific transcription factors modulate expression of genes required for autophagy is lacking. Here, we identify Foxk proteins (Foxk1 and Foxk2) as transcriptional repressors of autophagy in muscle cells and fibroblasts. Interestingly, Foxk1/2 serve to counter-balance another forkhead transcription factor, Foxo3, which induces an overlapping set of autophagic and atrophic targets in muscle. Foxk1/2 specifically recruits Sin3A-HDAC complexes to restrict acetylation of histone H4 and expression of critical autophagy genes. Remarkably, mTOR promotes the transcriptional activity of Foxk1 by facilitating nuclear entry to specifically limit basal levels of autophagy in nutrient-rich conditions. Our study highlights an ancient, conserved mechanism whereby nutritional status is interpreted by mTOR to restrict autophagy by repressing essential autophagy genes via Foxk-Sin3-mediated transcriptional control. Examination of (1) chromatin binding of Foxk1 and Sin3A in non-starved myoblasts and (2) gene expression profiling upon either starvation or siRNA-mediated depletion of Foxk1 relative to a non-starved control.

Project description:We used inducible Neuro-2a cell lines with stable expression of FOXK1 and FOXF1. The cells were induced to express FOX protein under doxycycline for 36 hours and then infected with HSV-1 for five hours. The cells were collected and cleaved, and total RNA was extracted for RNAseq analysis

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:Autophagy is the primary catabolic process triggered in response to starvation. Although autophagic regulation within the cytosolic compartment is well established, it is becoming clear that nuclear events also regulate the induction or repression of autophagy. Nevertheless, a thorough understanding of the mechanisms by which sequence-specific transcription factors modulate expression of genes required for autophagy is lacking. Here, we identify Foxk proteins (Foxk1 and Foxk2) as transcriptional repressors of autophagy in muscle cells and fibroblasts. Interestingly, Foxk1/2 serve to counter-balance another forkhead transcription factor, Foxo3, which induces an overlapping set of autophagic and atrophic targets in muscle. Foxk1/2 specifically recruits Sin3A-HDAC complexes to restrict acetylation of histone H4 and expression of critical autophagy genes. Remarkably, mTOR promotes the transcriptional activity of Foxk1 by facilitating nuclear entry to specifically limit basal levels of autophagy in nutrient-rich conditions. Our study highlights an ancient, conserved mechanism whereby nutritional status is interpreted by mTOR to restrict autophagy by repressing essential autophagy genes via Foxk-Sin3-mediated transcriptional control.

Project description:gut Metagenome of red fox and corsac fox

Project description:We report a HSV-1 encoded miRNA present during lytic infection that influences replication efficiency in a tissue culture model. miRNAs were identified using high-throughput sequencing of HSV-1 infected epithelial cells. Functional assays were performed by mutating the miRNA coding region and testing grow of the mutant in vitro. Construction of a miRNA library and sequencing to reveal novel viral miRNAs from lytically infected cells

Project description:Herpes simplex virus type I (HSV-1) establishes a latent infection that evades the host's defense system, and the latent virus can be reactivated by some stimulation. At present,a key problem in the latent studies of HSV-1 has not been clarified, that is, HSV-1 mainly selectively latent in neurons. Therefore, we have found the host transcription factor EGR in Neuro-2a cells by RNA-seq. EGR1 regulates HSV-1 replication and latency by binding to the viral genome or recruiting co-factors. Our data intend to find the role and mechanism of EGR family repressing HSV-1 replication and promoting HSV-1 latency. This study will provide a theoretical basis for the development of drugs to treat of HSV-1 infection.