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      Herpesviral ICP0 Protein Promotes Two Waves of Heterochromatin Removal on an Early Viral Promoter during Lytic Infection

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      a , b , a , a , b ,
      mBio
      American Society of Microbiology

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          ABSTRACT

          Herpesviruses must contend with host cell epigenetic silencing responses acting on their genomes upon entry into the host cell nucleus. In this study, we confirmed that unchromatinized herpes simplex virus 1 (HSV-1) genomes enter primary human foreskin fibroblasts and are rapidly subjected to assembly of nucleosomes and association with repressive heterochromatin modifications such as histone 3 (H3) lysine 9-trimethylation (H3K9me3) and lysine 27-trimethylation (H3K27me3) during the first 1 to 2 h postinfection. Kinetic analysis of the modulation of nucleosomes and heterochromatin modifications over the course of lytic infection demonstrates a progressive removal that coincided with initiation of viral gene expression. We obtained evidence for three phases of heterochromatin removal from an early gene promoter: an initial removal of histones and heterochromatin not dependent on ICP0, a second ICP0-dependent round of removal of H3K9me3 that is independent of viral DNA synthesis, and a third phase of H3K27me3 removal that is dependent on ICP0 and viral DNA synthesis. The presence of ICP0 in transfected cells is also sufficient to promote removal of histones and H3K9me3 modifications of cotransfected genes. Overall, these results show that ICP0 promotes histone removal, a reduction of H3K9me3 modifications, and a later indirect reduction of H3K27me3 modifications following viral early gene expression and DNA synthesis. Therefore, HSV ICP0 promotes the reversal of host epigenetic silencing mechanisms by several mechanisms.

          IMPORTANCE

          The human pathogen herpes simplex virus (HSV) has evolved multiple strategies to counteract host-mediated epigenetic silencing during productive infection. However, the mechanisms by which viral and cellular effectors contribute to these processes are not well defined. The results from this study demonstrate that HSV counteracts host epigenetic repression in a dynamic stepwise process to remove histone 3 (H3) and subsequently target specific heterochromatin modifications in two distinct waves. This provides the first evidence of a stepwise reversal of host epigenetic silencing by viral proteins. This work also suggests that targets capable of disrupting the kinetics of epigenetic regulation could serve as potential antiviral therapeutic agents.

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          Most cited references44

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          Chromatin remodeling at DNA double-strand breaks.

          DNA double-strand breaks (DSBs) can arise from multiple sources, including exposure to ionizing radiation. The repair of DSBs involves both posttranslational modification of nucleosomes and concentration of DNA-repair proteins at the site of damage. Consequently, nucleosome packing and chromatin architecture surrounding the DSB may limit the ability of the DNA-damage response to access and repair the break. Here, we review early chromatin-based events that promote the formation of open, relaxed chromatin structures at DSBs and that allow the DNA-repair machinery to access the spatially confined region surrounding the DSB, thereby facilitating mammalian DSB repair. Copyright © 2013 Elsevier Inc. All rights reserved.
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            Mapping protein-DNA interactions in vivo with formaldehyde: evidence that histone H4 is retained on a highly transcribed gene.

            We have used formaldehyde-mediated protein-DNA crosslinking within intact cells to examine the in vivo chromatin structure of the D. melanogaster heat shock protein 70 (hsp70) genes. In agreement with previous in vitro studies, we find that the heat shock-mediated transcriptional induction of the hsp70 genes perturbs their chromatin structure, resulting in fewer protein-DNA contacts crosslinkable in vivo by formaldehyde. However, contrary to earlier in vitro evidence that histones may be absent from actively transcribed genes, we show directly, by immunoprecipitation of in vivo-crosslinked chromatin fragments, that at least histone H4 remains bound to hsp70 DNA in vivo, irrespective of its rate of transcription. The formaldehyde-based in vivo mapping techniques described in this work are generally applicable, and can be used both to probe protein-DNA interactions within specific genes and to determine the genomic location of specific chromosomal proteins.
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              Inhibition of the histone demethylase LSD1 blocks α-herpesvirus lytic replication and reactivation from latency

              Reversible methylation of histone tails serve as either positive signals recognized by transcriptional assemblies or negative signals that result in repression 1–4. Invading viral pathogens that depend upon the host cell’s transcriptional apparatus are also subject to the regulatory impact of chromatin assembly and modifications5–8. Here we show that infection by the α-herpesviruses HSV and VZV results in the rapid accumulation of chromatin bearing repressive histone H3-lysine 9 methylation. To enable expression of viral immediate early (IE) genes, both viruses use the cellular transcriptional coactivator HCF-1 to recruit the demethylase LSD1 to the viral immediate early promoters. Depletion of LSD1 or inhibition of its activity with MAO inhibitors results in the accumulation of repressive chromatin and a block to viral gene expression. As HCF-1 is a component of the Set1 and MLL1 histone H3 lysine 4 methyl-transferase complexes 9,10, it thus coordinates modulation of repressive H3-lysine 9 methylation levels with addition of activating H3-lysine 4 trimethylation marks. Strikingly, MAO inhibitors also block the reactivation of HSV from latency in sensory neurons, indicating that the HCF-1 complex is a critical component of the reactivation mechanism. The results support pharmaceutical control of histone modifying enzymes as a strategy for controlling herpesvirus infections.
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                Author and article information

                Journal
                mBio
                MBio
                mbio
                mbio
                mBio
                mBio
                American Society of Microbiology (1752 N St., N.W., Washington, DC )
                2150-7511
                12 January 2016
                Jan-Feb 2016
                : 7
                : 1
                : e02007-15
                Affiliations
                [a ]Department of Microbiology and Immunobiology, Harvard Medical School, Boston, Massachusetts, USA
                [b ]Program in Virology, Harvard Medical School, Boston, Massachusetts, USA
                Author notes
                Address correspondence to David M. Knipe, david_knipe@ 123456hms.harvard.edu .

                J.S.L. and P.R. contributed equally to this article.

                Editor Michael J. Imperiale, University of Michigan

                This article is a direct contribution from a Fellow of the American Academy of Microbiology.

                Article
                mBio02007-15
                10.1128/mBio.02007-15
                4725016
                26758183
                c147ba0b-d776-418c-afdc-3b54e8bd5449
                Copyright © 2016 Lee et al.

                This is an open-access article distributed under the terms of the Creative Commons Attribution-Noncommercial-ShareAlike 3.0 Unported license, which permits unrestricted noncommercial use, distribution, and reproduction in any medium, provided the original author and source are credited.

                History
                : 16 November 2015
                : 20 November 2015
                Page count
                supplementary-material: 3, Figures: 8, Tables: 0, Equations: 0, References: 63, Pages: 11, Words: 7544
                Categories
                Research Article
                Custom metadata
                January/February 2016

                Life sciences
                Life sciences

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