The visualization of large organized chromatin domains enriched in the H3K9me2 mark within a single chromosome in a single cell

Despite considerable efforts, our understanding of the organization of higher order chromatin conformations in single cells and how these relate to chromatin marks remains poor. We have earlier invented the Chromatin In Situ Proximity (ChrISP) technique to determine proximities between chromatin fibers within a single chromosome. Here we used ChrISP to identify chromosome 11-specific hubs that are enriched in the H3K9me2 mark and that project toward the nuclear membrane in finger-like structures. Conversely, chromosome 11-specfic chromatin hubs, visualized by the presence of either H3K9me1 or H3K9me3 marks, are chromosome-wide and largely absent at the nuclear periphery. As the nuclear periphery-specific chromatin hubs were lost in the induced reduction of H3K9me2 levels, they likely represent Large Organization Chromatin in Lysine Methylation (LOCK) domains, previously identified by ChIP-seq analysis. Strikingly, the downregulation of the H3K9me2/3 marks also led to the chromosome-wide compaction of chromosome 11, suggesting a pleiotropic function of these features not recognized before. The ChrISP-mediated visualization of dynamic chromatin states in single cells thus provides an analysis of chromatin structures with a resolution far exceeding that of any other light microscopic technique.     

Repressive but not activating epigenetic modifications are aberrant on the inactive X chromosome in live cloned cattle

X inactivation is the process of a chromosome-wide silencing of the majority of genes on the X chromosome during early mammalian development. This process may be aberrant in cloned animals. Here we show that repressive modifications, such as methylation of DNA, and the presence of methylated histones, H3K9me2 and H3K27me3, exhibit distinct aberrance on the inactive X chromosome in live clones. In contrast, H3K4me3, an active gene marker, is obviously missing from the inactive X chromosome in all cattle studied. This suggests that the disappearance of active histone modifications (H3K4me3) seems to be more important for X inactivation than deposition of marks associated with heterochromatin (DNA methylation, H3K27me3 and H3K9me2). It also implies that even apparently normal clones may have subtle abnormalities in repressive, but not activating epigenetic modifications on the inactive X when they survive to term. We also found that the histone H3 methylations were enriched and co-localized at q21-31 of the active X chromosome, which may be associated with an abundance of LINE1 repeat elements.     

Holocarboxylase synthetase synergizes with methyl CpG binding protein 2 and DNA methyltransferase 1 in the transcriptional repression of long-terminal repeats

Holocarboxylase synthetase (HLCS) is a chromatin protein that facilitates the creation of histone H3 lysine 9-methylation (H3K9me) gene repression marks through physical interactions with the histone methyltransferase EHMT-1. HLCS knockdown causes a depletion of H3K9me marks in mammalian cell cultures and severe phenotypes such as short lifespan and low stress resistance in Drosophila melanogaster. HLCS displays a punctuate distribution pattern in chromatin despite lacking a strong DNA-binding domain. Previous studies suggest that the binding of HLCS to chromatin depends on DNA methylation. We tested the hypothesis that HLCS interacts physically with the DNA methyltransferase DNMT1 and the methyl CpG binding protein MeCP2 to facilitate the binding of HLCS to chromatin, and that these interactions contribute toward the repression of long-terminal repeats (LTRs) by H3K9me marks. Co-immunoprecipitation and limited proteolysis assays provided evidence suggesting that HLCS interacts physically with both DNMT1 and MeCP2. The abundance of H3K9me marks was 207% greater in the LTR15 locus in HLCS overexpression human embryonic kidney HEK293 cells compared with controls. This gain in H3K9me was inversely linked with a 87% decrease in mRNA coding for LTRs. Effects of HLCS abundance on LTR expression were abolished when DNA methylation marks were erased by treating cells with 5-azacytidine. We conclude that interactions between DNA methylation and HLCS are crucial for mediating gene repression by H3K9me, thereby providing evidence for epigenetic synergies between the protein biotin ligase HLCS and dietary methyl donors.     

Chromatin‐level regulation of the fragmented dothistromin gene cluster in the forest pathogen Dothistroma septosporum

Genes required for fungal secondary metabolite production are usually clustered, co‐regulated and expressed in stationary growth phase. Chromatin modification has an important role in co‐regulation of secondary metabolite genes. The virulence factor dothistromin, a relative of aflatoxin, provided a unique opportunity to study chromatin level regulation in a highly fragmented gene cluster that is switched on during early exponential growth phase. We analysed three histone modification marks by ChIP‐qPCR and gene deletion in the pine pathogen Dothistroma septosporum to determine their effects on dothistromin gene expression across a time course and at different loci of the dispersed gene cluster. Changes in gene expression and dothistromin production were associated with changes in histone marks, with higher acetylation (H3K9ac) and lower methylation (H3K9me3, H3K27me3) during early exponential phase at the onset of dothistromin production. But while H3K27me3 directly influenced dothistromin genes dispersed across chromosome 12, effects of H3K9 acetylation and methylation were orchestrated mainly through a centrally located pathway regulator gene DsAflR. These results revealed that secondary metabolite production can be controlled at the chromatin‐level despite the genes being dispersed. They also suggest that patterns of chromatin modification are important in adaptation of a virulence factor for a specific role in planta.     

Differential Localization and Independent Acquisition of the H3K9me2 and H3K9me3 Chromatin Modifications in the Caenorhabditis elegans Adult Germ Line

Histone methylation is a prominent feature of eukaryotic chromatin that modulates multiple aspects of chromosome function. Methyl modification can occur on several different amino acid residues and in distinct mono-, di-, and tri-methyl states. However, the interplay among these distinct modification states is not well understood. Here we investigate the relationships between dimethyl and trimethyl modifications on lysine 9 of histone H3 (H3K9me2 and H3K9me3) in the adult Caenorhabditis elegans germ line. Simultaneous immunofluorescence reveals very different temporal/spatial localization patterns for H3K9me2 and H3K9me3. While H3K9me2 is enriched on unpaired sex chromosomes and undergoes dynamic changes as germ cells progress through meiotic prophase, we demonstrate here that H3K9me3 is not enriched on unpaired sex chromosomes and localizes to all chromosomes in all germ cells in adult hermaphrodites and until the primary spermatocyte stage in males. Moreover, high-copy transgene arrays carrying somatic-cell specific promoters are highly enriched for H3K9me3 (but not H3K9me2) and correlate with DAPI-faint chromatin domains. We further demonstrate that the H3K9me2 and H3K9me3 marks are acquired independently. MET-2, a member of the SETDB histone methyltransferase (HMTase) family, is required for all detectable germline H3K9me2 but is dispensable for H3K9me3 in adult germ cells. Conversely, we show that the HMTase MES-2, an E(z) homolog responsible for H3K27 methylation in adult germ cells, is required for much of the germline H3K9me3 but is dispensable for H3K9me2. Phenotypic analysis of met-2 mutants indicates that MET-2 is nonessential for fertility but inhibits ectopic germ cell proliferation and contributes to the fidelity of chromosome inheritance. Our demonstration of the differential localization and independent acquisition of H3K9me2 and H3K9me3 implies that the trimethyl modification of H3K9 is not built upon the dimethyl modification in this context. Further, these and other data support a model in which these two modifications function independently in adult C. elegans germ cells.     

Epigenetic characterization of chromatin in cycling cells of pedunculate oak, Quercus robur L.

Cycling cells of Quercus robur have a simple nuclear organization where most of the heterochromatin is visible as DAPI-positive chromocenters, which correspond to DAPI bands at the (peri)centromeric region of each of the 24 chromosomes of the oak complement. Immunofluorescence using 5-mC revealed dispersed distribution of the signal throughout the interphase nucleus/chromosomes without enrichment within DAPI-positive chromocenters/bands, suggesting that DNA methylation was not restricted to constitutive heterochromatin, but was associated with both euchromatic and heterochromatic domains. While H3K9ac exhibited typical euchromatin-specific distribution, the distributional pattern of histone methylation marks H3K9me1, H3K27me2, and H3K4me3 showed some specificity. The H3K9me1 and H3K27me2, both heterochromatin-associated marks, were not restricted to chromocenters, but showed additional dispersed distribution within euchromatin, while H3K27me2 mark also clustered in foci that did not co-localize with chromocenters. Surprisingly, even though H3K4me3 was distributed in the entire chromatin, many chromocenters were enriched with this euchromatin-specific modification. We discuss the distribution of the epigenetic marks in the context of the genome composition and lifestyle of Q. robur.     

Cytogenetic mapping with centromeric bacterial artificial chromosomes contigs shows that this recombination‐poor region comprises more than half of barley chromosome 3H

Genetic maps are based on the frequency of recombination and often show different positions of molecular markers in comparison to physical maps, particularly in the centromere that is generally poor in meiotic recombinations. To decipher the position and order of DNA sequences genetically mapped to the centromere of barley (Hordeum vulgare) chromosome 3H, fluorescence in situ hybridization with mitotic metaphase and meiotic pachytene chromosomes was performed with 70 genomic single‐copy probes derived from 65 fingerprinted bacterial artificial chromosomes (BAC) contigs genetically assigned to this recombination cold spot. The total physical distribution of the centromeric 5.5 cM bin of 3H comprises 58% of the mitotic metaphase chromosome length. Mitotic and meiotic chromatin of this recombination‐poor region is preferentially marked by a heterochromatin‐typical histone mark (H3K9me2), while recombination enriched subterminal chromosome regions are enriched in euchromatin‐typical histone marks (H3K4me2, H3K4me3, H3K27me3) suggesting that the meiotic recombination rate could be influenced by the chromatin landscape.     

Chromosome-wide analysis of parental allele-specific chromatin and DNA methylation

To reveal the extent of domain-wide epigenetic features at imprinted gene clusters, we performed a high-resolution allele-specific chromatin analysis of over 100 megabases along the maternally or paternally duplicated distal chromosome 7 (Chr7) and Chr15 in mouse embryo fibroblasts (MEFs). We found that reciprocal allele-specific features are limited to imprinted genes and their differentially methylated regions (DMRs), whereas broad local enrichment of H3K27me3 (BLOC) is a domain-wide feature at imprinted clusters. We uncovered novel allele-specific features of BLOCs. A maternally biased BLOC was found along the H19-Igf2 domain. A paternal allele-specific gap was found along Kcnq1ot1, interrupting a biallelic BLOC in the Kcnq1-Cdkn1c domain. We report novel allele-specific chromatin marks at the Peg13 and Slc38a4 DMRs, Cdkn1c upstream region, and Inpp5f_v2 DMR and paternal allele-specific CTCF binding at the Peg13 DMR. Additionally, we derived an imprinted gene predictor algorithm based on our allele-specific chromatin mapping data. The binary predictor H3K9ac and CTCF or H3K4me3 in one allele and H3K9me3 in the reciprocal allele, using a sliding-window approach, recognized with precision the parental allele specificity of known imprinted genes, H19, Igf2, Igf2as, Cdkn1c, Kcnq1ot1, and Inpp5f_v2 on Chr7 and Peg13 and Slc38a4 on Chr15. Chromatin features, therefore, can unequivocally identify genes with imprinted expression.     

Differential loss of histone H3 isoforms mono-, di- and tri-methylated at lysine 4 during X-inactivation in female embryonic stem cells

Silencing of genes on one of the two female X chromosomes early in development helps balance expression of X-linked genes between XX females and XY males and involves chromosome-wide changes in histone variants and modifications. Mouse female embryonic stem (ES) cells have two active Xs, one of which is silenced on differentiation, and provide a powerful model for studying the dynamics of X inactivation. Here, we use immunofluorescence microscopy of metaphase chromosomes to study changes in H3 mono-, di- or tri-methylated at lysine 4 (H3K4mel, -2 or -3) on the inactivating X (Xi) in female ES cells. H3K4me3 is absent from Xi in approximately 25% of chromosome spreads by day 2 of differentiation and in 40-50% of spreads by days 4-6, making it one of the earliest detectable changes on Xi. In contrast, loss of H3K4me2 occurs 1-2 days later, when histone acetylation also diminishes. Remarkably, H3K4mel is depleted on both (active) X chromosomes in undifferentiated female ES cells, and on the single X in males, and remains depleted on Xi. Consistent with this, chromatin immunoprecipitation reveals differentiation-related reductions in H3K4me2 and H3K4me3 at the promoter regions of genes undergoing X-inactivation in female ES cells, but no comparable change in H3K4me1.     

M33 condenses chromatin through nuclear body formation and methylation of both histone H3 lysine 9 and lysine 27

Heterochromatin, a type of condensed DNA in eukaryotic cells, has two main categories: Constitutive heterochromatin, which contains H3K9 methylation, and facultative heterochromatin, which contains H3K27 methylation. Methylated H3K9 and H3K27 serve as docking sites for chromodomain-containing proteins that compact chromatin. M33 (also known as CBX2) is a chromodomain-containing protein that binds H3K27me3 and compacts chromatin in vitro. However, whether M33 mediates chromatin compaction in cellulo remains unknown. Here we show that M33 compacts chromatin into DAPI-intense heterochromatin domains in cells. The formation of these heterochromatin domains requires H3K27me3, which recruits M33 to form nuclear bodies. G9a and SUV39H1 are sequentially recruited into M33 nuclear bodies to create H3K9 methylated chromatin in a process that is independent of HP1α. Finally, M33 decreases progerin-induced nuclear envelope disruption caused by loss of heterochromatin. Our findings demonstrate that M33 mediates the formation of condensed chromatin by forming nuclear bodies containing both H3K27me3 and H3K9me3. Our model of M33-dependent chromatin condensation suggests H3K27 methylation corroborates with H3K9 methylation during the formation of facultative heterochromatin and provides the theoretical basis for developing novel therapies to treat heterochromatin-related diseases.