Ccp1 modulates epigenetic stability at centromeres and affects heterochromatin distribution in Schizosaccharomyces pombe.

Distinct chromatin organization features, such as centromeres and heterochromatin domains, are inherited epigenetically. However, the mechanisms that modulate the accuracy of epigenetic inheritance, especially at the individual nucleosome level, are not well-understood. Here, using ChIP and next-generation sequencing (ChIP-Seq), we characterized Ccp1, a homolog of the histone chaperone Vps75 in budding yeast that functions in centromere chromatin duplication and heterochromatin maintenance in fission yeast (Schizosaccharomyces pombe). We show that Ccp1 is enriched at the central core regions of the centromeres. Of note, among all histone chaperones characterized, deletion of the ccp1 gene uniquely reduced the rate of epigenetic switching, manifested as position effect variegation within the centromeric core region (CEN-PEV). In contrast, gene deletion of other histone chaperones either elevated the PEV switching rates or did not affect centromeric PEV. Ccp1 and the kinetochore components Mis6 and Sim4 were mutually dependent for centromere or kinetochore association at the proper levels. Moreover, Ccp1 influenced heterochromatin distribution at multiple loci in the genome, including the subtelomeric and the pericentromeric regions. We also found that Gar2, a protein predominantly enriched in the nucleolus, functions similarly to Ccp1 in modulating the epigenetic stability of centromeric regions, although its mechanism remained unclear. Together, our results identify Ccp1 as an important player in modulating epigenetic stability and maintaining proper organization of multiple chromatin domains throughout the fission yeast genome.

Intricate regulation on epigenetic stability of the subtelomeric heterochromatin and the centromeric chromatin in fission yeast.

In eukaryotes, the integrity of chromatin structure and organization is crucial to diverse key cellular processes from development to disease avoidance. To maintain the cell identity through mitotic cell generations, the genome (the genomic DNA sequence) as well as the epigenome (pertaining various forms of epigenetic information carriers, such as histone modifications, nucleosome positioning and the chromatin organization) is inherited with high fidelity. In comparison to the wealth of knowledge on genetic stability, we know much less on what may control the accuracy of epigenetic inheritance. In our recent work in the fission yeast Schizosaccharomyces pombe, by quantifying the epigenetic fidelity of CENP-A/Cnp1 or H3K9me2 nucleosome inheritance through cell divisions, we demonstrated that Ccp1, a homolog of histone chaperone Vps75 in budding yeast, participates in the modulation of centromeric nucleosomal epigenetic stability as well as proper heterochromatin organization. In this essay, we focus on discussing the uniquely high dynamicity of the subtelomeric heterochromatin regions and the complex mechanisms regulating epigenetic stability of centromeric chromatin.

A Susceptibility Locus on Chromosome 13 Profoundly Impacts the Stability of Genomic Imprinting in Mouse Pluripotent Stem Cells.

Cultured pluripotent cells accumulate detrimental chromatin alterations, including DNA methylation changes at imprinted genes known as loss of imprinting (LOI). Although the occurrence of LOI is considered a stochastic phenomenon, here we document a genetic determinant that segregates mouse pluripotent cells into stable and unstable cell lines. Unstable lines exhibit hypermethylation at Dlk1-Dio3 and other imprinted loci, in addition to impaired developmental potential. Stimulation of demethylases by ascorbic acid prevents LOI and loss of developmental potential. Susceptibility to LOI greatly differs between commonly used mouse strains, which we use to map a causal region on chromosome 13 with quantitative trait locus (QTL) analysis. Our observations identify a strong genetic determinant of locus-specific chromatin abnormalities in pluripotent cells and provide a non-invasive way to suppress them. This highlights the importance of considering genetics in conjunction with culture conditions for assuring the quality of pluripotent cells for biomedical applications.

Epigenetic stability in Saffron (Crocus sativus L.) accessions during four consecutive years of cultivation and vegetative propagation under open field conditions.

Saffron (Crocus sativus L.) is a sterile species that is vegetatively propagated in the field, year by year, via the production of new corms. While Saffron's genetic variability is extremely low, phenotypic variation is frequently observed in the field and epigenetics could be a possible origin of these alternative phenotypes. Present day knowledge on Saffron epigenetics is very low or absent. In the present paper, to deepen existing knowledge, we focused on the epigenetic differences and stability among 17 Saffron accessions, of different geographic origin, during four consecutive years of vegetative propagation under open field conditions. Before the analysis, the selected accessions have been cultivated in the same field for at least three consecutive years. Despite the low genetic variability and the prolonged co-cultivation in the same environment, Methylation-Sensitive Amplified Fragment Length Polymorphism (MS-AFLP) analysis revealed a very high epigenetic difference among accessions, making it possible to discriminate them based on the epigenetic profiles. During the four years of the study, a little variation has been observed within accessions following different patterns, slightly modifying the accession epigenotypes but not enough to even them to a more uniform profile. These results confirm that, under natural conditions, Saffron epigenotypes are highly stable, supporting a role for epigenetics in phenotypic variability.

Sirt1 Regulates DNA Methylation and Differentiation Potential of Embryonic Stem Cells by Antagonizing Dnmt3l.

Embryonic stem cell (ESC) abnormalities in genome methylation hamper the utility of their therapeutic derivatives; however, the underlying mechanisms are unknown. Here, we show that the nicotinamide adenine dinucleotide (NAD)-dependent deacetylase, Sirt1, selectively prevents abnormal DNA methylation of some developmental genes in murine ESCs by antagonizing Dnmt3l. Transcriptome and DNA methylome analyses demonstrated that Sirt1-null (Sirt1-/-) ESCs repress expression of a subset of imprinted and germline genes concomitant with increased DNA methylation of regulatory elements. Dnmt3l was highly expressed in Sirt1-/- ESCs, and knockdown partially rescued abnormal DNA methylation of the Sirt1 target genes. The Sirt1 protein suppressed transcription of Dnmt3l and physically interacted with the Dnmt3l protein, deacetylating and destabilizing Dnmt3l protein. Sirt1 deficiency delayed neurogenesis and spermatogenesis. These differentiation delays were significantly or partially abolished by reintroduction of Sirt1 cDNA or Dnmt3l knockdown. This study sheds light on mechanisms that restrain DNA methylation of developmentally vital genes operating in ESCs.

Stability of single copy transgene expression in CHOK1 cells is affected by histone modifications but not by DNA methylation.

Intraclonal heterogeneity of genetically modified mammalian cells has been observed as a phenomenon that has a strong impact on overall transgene expression levels and that limits the predictability of transgene expression in genetically modified cells, thereby hampering single cell based screening approaches. The underlying mechanism(s) leading to this variance are poorly understood. To study the dynamics and mechanisms of heterogeneity of early stage silencing we analyzed the expression in more than 100 independent clones of CHOK1 cells that harbour genetically stable integrates of single copy reporter cassettes driven by EF1α and CMV promoters. Single cell analysis showed intraclonal variability with heterogeneity in expression in genetically uniform populations. DNA methylation is a well known mechanism responsible for silencing of gene expression. Interestingly, loss of expression was not associated with DNA methylation of the CMV promoter. However, in most of the clonal populations expression could be increased by inhibitors of the histone deacetylases (HDACi) suggesting that heterogeneity of transgene expression is crucially governed by histone modifications. Further, to determine if the epigenetic status of transgene expression is governed by the chromosomal integration locus we targeted heterologous expression cassettes into two chromosomal sites using recombinase mediated cassette exchange (RMCE). The expression status of a particular clone was faithfully re-established when the same promoter used. In this way the problem of early stage cell clone instability can be bypassed. However, upon introduction of an unrelated promoter methylation-independent silencing was observed. Together, these results suggest that histone modifications are the relevant mechanisms by which epigenetic modulation of transgene expression cassettes is governed in the early phase of clone generation.

Replication of Structured DNA and its implication in epigenetic stability.

DNA replication is an extremely risky process that cells have to endure in order to correctly duplicate and segregate their genome. This task is particularly sensitive to DNA damage and multiple mechanisms have evolved to protect DNA replication as a block to the replication fork could lead to genomic instability and possibly cell death. The DNA in the genome folds, for the most part, into the canonical B-form but in some instances can form complex secondary structures such as G-quadruplexes (G4). These G rich regions are thermodynamically stable and can constitute an obstacle to DNA and RNA metabolism. The human genome contains more than 350,000 sequences potentially capable to form G-quadruplexes and these structures are involved in a variety of cellular processes such as initiation of DNA replication, telomere maintenance and control of gene expression. Only recently, we started to understand how G4 DNA poses a problem to DNA replication and how its successful bypass requires the coordinated activity of ssDNA binding proteins, helicases and specialized DNA polymerases. Their role in the resolution and replication of structured DNA crucially prevents both genetic and epigenetic instability across the genome.