Monomethylation of Lysine 20 on Histone H4 Facilitates Chromatin Maturation

Scharf, Annette; Meier, Karin; Seitz, Volker; Kremmer, Elisabeth; Brehm, Alexander; Imhof, Axel

doi:10.1128/mcb.00989-08

Cited by 48 publications

(59 citation statements)

References 63 publications

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“…In this study, mass spectrometry was used to determine the order of H4 PTMs during deposition of histones on DNA templates in the context of Drosophila extracts. Mono-methylation of H4K20 was found to follow acetylation events and to be required for subsequent de-acetylation, implicating H4K20me1 in chromatin assembly via marking the fully assembled nucleosome after histone deposition (79). An unbiased middle-down proteomics was also used to correlate the status of H4K20 methylation relative to the differential potency of cells (80).…”

Section: Figmentioning

confidence: 99%

Histone H4 Lysine 20 (H4K20) Methylation, Expanding the Signaling Potential of the Proteome One Methyl Moiety at a Time

Nuland

Gozani

2016

Molecular & Cellular Proteomics

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Covalent post-translational modifications (PTMs) of proteins can regulate the structural and functional state of a protein in the absence of primary changes in the underlying sequence. Common PTMs include phosphorylation, acetylation, and methylation. Histone proteins are critical regulators of the genome and are subject to a highly abundant and diverse array of PTMs. To highlight the functional complexity added to the proteome by lysine methylation signaling, here we will focus on lysine methylation of histone proteins, an important modification in the regulation of chromatin and epigenetic processes. We review the signaling pathways and functions associated with a single residue, H4K20, as a model chromatin and clinically important mark that regulates biological processes ranging from the DNA damage response and DNA replication to gene expression and silencing. Molecular

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Section: Figmentioning

confidence: 99%

Histone H4 Lysine 20 (H4K20) Methylation, Expanding the Signaling Potential of the Proteome One Methyl Moiety at a Time

Nuland

Gozani

2016

Molecular & Cellular Proteomics

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“…Nucleosome-depleted regions (NDRs) are found surrounding the transcribed units, and the 5 in yeast at the TSS, and they are often associated with histone modifications related to high nucleosome turnover: H4 acetylation (Scharf et al 2009b), H3K4 methylation (Kraushaar et al 2013), and/or the histone variant H2A.Z (Guillemette et al 2005;Zhang et al 2005;Jin and Felsenfeld 2007). Nucleosome turnover in promoter regions is directly affected by ATP-dependent chromatin remodelers such as Ino80, which binds to the 5 ′ NDR and promotes turnover of TSS nucleosomes (Yen et al 2013).…”

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confidence: 99%

A nucleosome turnover map reveals that the stability of histone H4 Lys20 methylation depends on histone recycling in transcribed chromatin

et al. 2015

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Nucleosome composition actively contributes to chromatin structure and accessibility. Cells have developed mechanisms to remove or recycle histones, generating a landscape of differentially aged nucleosomes. This study aimed to create a highresolution, genome-wide map of nucleosome turnover in Schizosaccharomyces pombe. The recombination-induced tag exchange (RITE) method was used to study replication-independent nucleosome turnover through the appearance of new histone H3 and the disappearance or preservation of old histone H3. The genome-wide location of histones was determined by chromatin immunoprecipitation-exonuclease methodology (ChIP-exo). The findings were compared with diverse chromatin marks, including histone variant H2A.Z, post-translational histone modifications, and Pol II binding. Finally, genomewide mapping of the methylation states of H4K20 was performed to determine the relationship between methylation (mono, di, and tri) of this residue and nucleosome turnover. Our analysis showed that histone recycling resulted in low nucleosome turnover in the coding regions of active genes, stably expressed at intermediate levels. High levels of transcription resulted in the incorporation of new histones primarily at the end of transcribed units. H4K20 was methylated in lowturnover nucleosomes in euchromatic regions, notably in the coding regions of long genes that were expressed at low levels. This transcription-dependent accumulation of histone methylation was dependent on the histone chaperone complex FACT. Our data showed that nucleosome turnover is highly dynamic in the genome and that several mechanisms are at play to either maintain or suppress stability. In particular, we found that FACT-associated transcription conserves histones by recycling them and is required for progressive H4K20 methylation.

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“…We have shown in the past that TSA treatment results in a moderate increase of histone acetylation on assembled chromatin in contrast to what is observed in tissue culture cells where TSA treatment results in a strong hyperacetylation of histones (53)(54)(55). During in vitro assembly, the histones are deposited in a preacetylated form, which will not get deacetylated when TSA is present (41). TSA treatment has been shown to prevent the formation of transcriptionally repressed chromatin (39) in Xenopus oocytes and lead to an altered pattern of DNA replication origin activity in human tissue culture cells (40).…”

Section: Discussionmentioning

confidence: 62%

“…S1D and S1E). It is worth mentioning that the presence of TSA does not result in a histone hyperacetylation, which is usually observed in tissue culture cells but induces a moderate increase in the acetylation because of a failure to efficiently remove the acetylation pattern present on histones before assembly (41). The reason for this is unclear but it is probably because of a general lack of site specific histone acetyltransferases in early embryos (34).…”

Section: Resultsmentioning

confidence: 87%

“…By choosing three different time points, we were able to describe the kinetics of the chromatin assembly in vitro at an (41,42) or the coordinated binding and release of chromatin binding factors (41,43,44), the proteomic composition of in vitro and in vivo assembled chromatin has not been compared so far. The recent advancements toward a complete proteomic description of in vivo chromatin assembly (13,26) have now made such comparisons feasible.…”

Section: Discussionmentioning

confidence: 99%

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A Quantitative Proteomic Analysis of In Vitro Assembled Chromatin

Völker-Albert

Pusch

Fedisch

et al. 2016

Molecular & Cellular Proteomics

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The structure of chromatin is critical for many aspects of cellular physiology and is considered to be the primary medium to store epigenetic information. It is defined by the histone molecules that constitute the nucleosome, the positioning of the nucleosomes along the DNA and the non-histone proteins that associate with it. These factors help to establish and maintain a largely DNA sequenceindependent but surprisingly stable structure. Chromatin is extensively disassembled and reassembled during DNA replication, repair, recombination or transcription in order to allow the necessary factors to gain access to their substrate. Despite such constant interference with chromatin structure, the epigenetic information is generally well maintained. Surprisingly, the mechanisms that coordinate chromatin assembly and ensure proper assembly are not particularly well understood. Here, we use label free quantitative mass spectrometry to describe the kinetics of in vitro assembled chromatin supported by an embryo extract prepared from preblastoderm Drosophila melanogaster embryos. The use of a data independent acquisition method for proteome wide quantitation allows a time resolved comparison of in vitro chromatin assembly. A comparison of our in vitro data with proteomic studies of replicative chromatin assembly in vivo reveals an extensive overlap showing that the in vitro system can be used for investigating the kinetics of chromatin assembly in a proteome-wide manner. DNA replication, transcription and repair continuously disturb the conformation of chromatin, which results in a relatively high rate of histone turnover (1) and poses a constant threat to the maintenance of epigenetic information (2, 3). Therefore, chromatin assembly has to be controlled thoroughly to ensure a proper chromatin structure. It is well appreciated that chromatin assembly is a highly regulated multistep process involving synthesis, storage and nuclear transport of histones followed by their deposition onto DNA. Immediately after translation and before the assembly onto DNA, histones are bound by a number of chaperones that assist their folding, posttranslational modification, nuclear transport and prevent nonspecific association with negatively charged cellular molecules (4 -6). Once histones are deposited, chromatin adopts a particular conformation containing specific histone modification patterns (7-9) and a defined composition of associated proteins (10 -13). Crosslinking experiments show that histones H3 and H4 are first deposited as a tetramer, whereas two dimers of H2A and H2B are added at a subsequent stage (14,15). A similar assembly pathway is also observed in an in vitro assembly system where the process of histone deposition and chromatin contraction occurs within 30 s (16,17). Regardless of this apparent rapid compaction, it takes much longer for new chromatin to become indistinguishable from the bulk chromatin in vivo (9, 13).Recent systematic studies revealed that mature chromatin adopts a complex molecular structure containing a ...

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Monomethylation of Lysine 20 on Histone H4 Facilitates Chromatin Maturation

Cited by 48 publications

References 63 publications

Histone H4 Lysine 20 (H4K20) Methylation, Expanding the Signaling Potential of the Proteome One Methyl Moiety at a Time

Histone H4 Lysine 20 (H4K20) Methylation, Expanding the Signaling Potential of the Proteome One Methyl Moiety at a Time

A nucleosome turnover map reveals that the stability of histone H4 Lys20 methylation depends on histone recycling in transcribed chromatin

A Quantitative Proteomic Analysis of In Vitro Assembled Chromatin

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