DNA methylation increases throughout Arabidopsis development

We used amplified fragment length polymorphisms (AFLP) to analyze the stability of DNA methylation throughout Arabidopsis development. AFLP can detect genome-wide changes in cytosine methylation produced by DNA demethylation agents, such as 5-azacytidine, or specific mutations at the DDM1 locus. In both cases, cytosine demethylation is associated with a general increase in the presence of amplified fragments. Using this approach, we followed DNA methylation at methylation sensitive restriction sites throughout Arabidopsis development. The results show a progressive DNA methylation trend from cotyledons to vegetative organs to reproductive organs.     

Methylation analysis revealed salicylic acid affects pearl millet defense through external cytosine DNA demethylation

The cytosine DNA methylation and demethylation have a role in regulating plant responses to the environment by affecting the promoter regions of most plant defense-related genes through the CpG islands or the CCGG motifs. Salicylic acid, a defense and signaling plant hormone, is seen playing crucial role in the variation of the methylome. In this study, the effects of salicylic acid and feeding of the millet headminer (Heliocheilus albipunctella de Joannis) on pearl millet DNA methylome changes were evaluated through MSAP epigenotyping during panicle development. The results showed that millet headminer feeding increased the level of genomic methylation while application of salicylic acid caused DNA demethylation occurring mostly at external cytosine and accompanied by a decrease of the number of larvae per panicle. This suggests that hemimethylation (external cytosine methylation) has key role in regulating defense responses and conferring tolerance to pearl millet through salicylic acid application.     

Absence of global genomic cytosine methylation pattern erasure during medaka (Oryzias latipes) early embryo development

Two techniques were used to analyze global genomic 5-methyl cytosine methylation at CCGG sites of medaka embryo DNA. DNA was labeled by incorporation of microinjected radiolabeled deoxynucleotide into one-cell embryos. After Hpa II or Msp I digestion the radiolabeled DNA was fractionated in agarose gels and the distribution of label quantified throughout each sample lane to detect differences in fragment distribution. Alternately isolated DNA was digested with Hpa II or Msp I and the resulting generated termini end-labeled. The end-labeled digestion products were then analyzed for fragment distribution after gel fractionation. These techniques proved to be extremely sensitive, allowing comparison of genomic DNA methylation values from as few as 640 fish cells. The data suggest that in medaka embryos the vast majority (>90%) of genomic DNA is methylated at CCGG sites. Furthermore, these data support the conclusion that the extent of methylation at these sites does not change or changes very little during embryogenesis (from 16 cells to the hatchling). These data argue against active demethylation, or loss of methylation patterns by dilution, during the developmental stages between the one cell zygote and gastrulation. From a comparative viewpoint, these data may indicate that mammals and fishes methylate and demethylate their genomes in very different manners during development.     

Varied patterns of DNA methylation change between different satellite regions in bovine preimplantation development

Global reduction of DNA methylation, a part of genome reprogramming processes, occurs in a gradual manner until before implantation and is recognized as a conserved process in mammals. Here, we reported that in bovine, satellite regions exhibited varied patterns of methylation changes when one-cell egg advanced to the blastocyst; a maintenance methylation was observed in satellite I sequences, a decrease in alpha satellites, and an increase in satellite II regions. Cloned embryos exhibited similar changes for DNA methylation in the satellite I and alpha. We also observed that the satellite I and alpha sequences were methylated more in inner cell mass region of the blastocyst whereas the satellite II showed selective demethylation in this region. Together, these findings point that individual satellite sequences carry their own methylation patterns under the pressure of global demethylation, suggesting that local methylation control system acts on the satellite regions in early bovine embryos.     

Differential DNA methylation reprogramming of various repetitive sequences in mouse preimplantation embryos

Genome-wide changes of DNA methylation by active and passive demethylation processes are typical features during preimplantation development. Here we provide an insight that epigenetic reprogramming of DNA methylation is regulated in a region-specific manner, not a genome-wide fashion. To address this hypothesis, methylation states of three repetitive genomic regions were monitored at various developmental stages in the mouse embryos. Active demethylation was not observed in the IAP sequences whereas methylation reprogramming of the satellite sequences was regulated only by the active mechanism. Etn elements were actively demethylated after fertilization, passively demethylated by the 8-cell stage, and de novo methylated at the morular and blastocyst stages, showing dynamic epigenetic changes. Thus, our findings suggest that the specific genomic regions or sequences may spatially/temporally have their unique characteristics in the reprogramming of the DNA methylation during preimplantation development.     

Dynamic link of DNA demethylation,DNA strand breaks and repair in mouse zygotes

In mammalian zygotes, the 5‐methyl‐cytosine (5mC) content of paternal chromosomes is rapidly changed by a yet unknown but presumably active enzymatic mechanism. Here, we describe the developmental dynamics and parental asymmetries of DNA methylation in relation to the presence of DNA strand breaks, DNA repair markers and a precise timing of zygotic DNA replication. The analysis shows that distinct pre‐replicative (active) and replicative (active and passive) phases of DNA demethylation can be observed. These phases of DNA demethylation are concomitant with the appearance of DNA strand breaks and DNA repair markers such as γH2A.X and PARP‐1, respectively. The same correlations are found in cloned embryos obtained after somatic cell nuclear transfer. Together, the data suggest that (1) DNA‐methylation reprogramming is more complex and extended as anticipated earlier and (2) the DNA demethylation, particularly the rapid loss of 5mC in paternal DNA, is likely to be linked to DNA repair mechanisms.     

The CHH motif in sugar beet satellite DNA: a modulator for cytosine methylation

Methylation of DNA is important for the epigenetic silencing of repetitive DNA in plant genomes. Knowledge about the cytosine methylation status of satellite DNAs, a major class of repetitive DNA, is scarce. One reason for this is that arrays of tandemly arranged sequences are usually collapsed in next‐generation sequencing assemblies. We applied strategies to overcome this limitation and quantified the level of cytosine methylation and its pattern in three satellite families of sugar beet (Beta vulgaris) which differ in their abundance, chromosomal localization and monomer size. We visualized methylation levels along pachytene chromosomes with respect to small satellite loci at maximum resolution using chromosome‐wide fluorescent in situ hybridization complemented with immunostaining and super‐resolution microscopy. Only reduced methylation of many satellite arrays was obtained. To investigate methylation at the nucleotide level we performed bisulfite sequencing of 1569 satellite sequences. We found that the level of methylation of cytosine strongly depends on the sequence context: cytosines in the CHH motif show lower methylation (44–52%), while CG and CHG motifs are more strongly methylated. This affects the overall methylation of satellite sequences because CHH occurs frequently while CG and CHG are rare or even absent in the satellite arrays investigated. Evidently, CHH is the major target for modulation of the cytosine methylation level of adjacent monomers within individual arrays and contributes to their epigenetic function. This strongly indicates that asymmetric cytosine methylation plays a role in the epigenetic modification of satellite repeats in plant genomes.     

Analysis of DNA methylation during the germination of wheat seeds

DNA methylation is known to play a crucial role in regulating plant development and organ or tissue differentiation. Here, we focused on the DNA methylation dynamics during the germination of wheat seeds using the adapted AFLP technique so called methylation-sensitive amplified polymorphism (MSAP). The MSAP profiles of genomic DNA in embryo and endosperm tissues of germinating seeds, as well as dry seeds were characterized and notable changes of cytosine methylation were detected. Comparisons of MSAP profiles in different tissues tested showed that the methylation level in dry seeds is the highest. The alteration analysis of cytosine methylation displayed that the number of demethylation events were three times higher than that of de novo methylation, which indicated that the demethylation was predominant in germinating wheat seeds, though the methylation events occurred as well. Sixteen differentially displayed DNA fragments in MSAP profiles were cloned and the sequencing analysis confirmed that nine of them contained CCGG sites. The further BLAST search showed that four of the cloned sequences were located in coding regions. Interestingly, three of the sixteen candidates were homologous to retrotransposons, which indicated that switches between DNA methylation and demethylation occurred in retrotransposon elements along with the germination of wheat seeds.     

Differentiation of metaxylem cell line in the root ofAllium cepa L.

Summary The differentiation processes of the metaxylem cell line in the root ofAllium cepa are characterized by amplification phenomena of repetitive DNA sequences mainly localized in heterochromatic regions of metaphase chromosomes. Moreover, these sequences are heavily methylated. This paper presents additional results on variation in endogenous DNA methylation in different developing root segments. The results show that methylation is higher in apical meristematic cells than the differentiating segments; contrastingly, total RNA synthesis seems to be correlated with undermethylation. Addition of labelled methyl groups to DNA by eukaryotic methylase, DNA digestions with different restriction enzymes specific for methylated sites and HPLC analysis confirmed the above results. Moreover, variation in methylation levels during differentiation occur not only at the internal cytosine of the-CCG-sites, but also at external cytosine. Furthermore, methylation affects other sites containing the trinucleotides-CXG-. In conclusion, root differentiation inAllium cepa seems to be correlated with gene activation modulated by the methylation/demethylation of particular DNA sequences.     

Active demethylation of individual genes in intracytoplasmic sperm injection rabbit embryos

Intracytoplasmic sperm injection (ICSI), as an assisted reproduction technique, has been widely used in animal and human. However, its possible effect on epigenetic changes has not been well studied. To investigate whether ICSI can induce aberrant DNA methylation changes in rabbit preimplantation embryos, we examined the methylation status of the SP-A promoter region and the satellite sequence Rsat IIE by bisulfite-sequencing technology. The SP-A promoter region was extensively demethylated before the first round of DNA replication commences, and the unmethylated status was maintained until morula when dynamic remethylation occurred. A similar but more moderate demethylation process was observed in satellite sequence Rsat IIE. These results are in contrast with the previous reports of no active demethylation in normal rabbit embryos, suggesting that the active demethylation we observed may be induced by ICSI.     

Active DNA demethylation and DNA repair

DNA methylation on cytosine is an epigenetic modification and is essential for gene regulation and genome stability in vertebrates. Traditionally DNA methylation was considered as the most stable of all heritable epigenetic marks. However, it has become clear that DNA methylation is reversible by enzymatic “active” DNA demethylation, with examples in plant cells, animal development and immune cells. It emerges that “pruning” of methylated cytosines by active DNA demethylation is an important determinant for the DNA methylation signature of a cell. Work in plants and animals shows that demethylation occurs by base excision and nucleotide excision repair. Far from merely protecting genomic integrity from environmental insult, DNA repair is therefore at the heart of an epigenetic activation process.     

Mammalian ChlR1 has a role in heterochromatin organization

The ChlR1 DNA helicase, encoded by DDX11 gene, which is responsible for Warsaw breakage syndrome (WABS), has a role in sister-chromatid cohesion. In this study, we show that human ChlR1 deficient cells exhibit abnormal heterochromatin organization. While constitutive heterochromatin is discretely localized at perinuclear and perinucleolar regions in control HeLa cells, ChlR1-depleted cells showed dispersed localization of constitutive heterochromatin accompanied by disrupted centromere clustering. Cells isolated from Ddx11^−/− embryos also exhibited diffuse localization of centromeres and heterochromatin foci. Similar abnormalities were found in HeLa cells depleted of combinations of HP1α and HP1β. Immunofluorescence and chromatin immunoprecipitation showed a decreased level of HP1α at pericentric regions in ChlR1-depleted cells. Trimethyl-histone H3 at lysine 9 (H3K9-me3) was also modestly decreased at pericentric sequences. The abnormality in pericentric heterochromatin was further supported by decreased DNA methylation within major satellite repeats of Ddx11^−/− embryos. Furthermore, micrococcal nuclease (MNase) assay revealed a decreased chromatin density at the telomeres. These data suggest that in addition to a role in sister-chromatid cohesion, ChlR1 is also involved in the proper formation of heterochromatin, which in turn contributes to global nuclear organization and pleiotropic effects.     

Influence of DNA methylation on positioning and DNA flexibility of nucleosomes with pericentric satellite DNA

DNA methylation occurs on CpG sites and is important to form pericentric heterochromatin domains. The satellite 2 sequence, containing seven CpG sites, is located in the pericentric region of human chromosome 1 and is highly methylated in normal cells. In contrast, the satellite 2 region is reportedly hypomethylated in cancer cells, suggesting that the methylation status may affect the chromatin structure around the pericentric regions in tumours. In this study, we mapped the nucleosome positioning on the satellite 2 sequence in vitro and found that DNA methylation modestly affects the distribution of the nucleosome positioning. The micrococcal nuclease assay revealed that the DNA end flexibility of the nucleosomes changes, depending on the DNA methylation status. However, the structures and thermal stabilities of the nucleosomes are unaffected by DNA methylation. These findings provide new information to understand how DNA methylation functions in regulating pericentric heterochromatin formation and maintenance in normal and malignant cells.     

Mammalian DNA demethylation

DNA cytosine methylation is a reversible epigenetic mark regulating gene expression. Aberrant methylation profiles are concomitant with developmental defects and cancer. Numerous studies in the past decade have identified enzymes and pathways responsible for active DNA demethylation both on a genome-wide as well as gene-specific scale. Recent findings have strengthened the idea that 5-methylcytosine oxidation catalyzed by members of the ten-eleven translocation (Tet1–3) oxygenases in conjunction with replication-coupled dilution of the conversion products causes the majority of genome-wide erasure of methylation marks during early development. In contrast, short and long patch DNA excision repair seems to be implicated mainly in gene-specific demethylation. Growth arrest and DNA damage-inducible protein 45 a (Gadd45a) regulates gene-specific demethylation within regulatory sequences of limited lengths raising the question of how such site specificity is achieved. A new study identified the protein inhibitor of growth 1 (Ing1) as a reader of the active chromatin mark histone H3 lysine 4 trimethylation (H3K4me3). Ing1 binds and directs Gadd45a to target sites, thus linking the histone code with DNA demethylation.     

Tissue-specific differences in cytosine methylation and their association with differential gene expression in sorghum

It has been well established that DNA cytosine methylation plays essential regulatory roles in imprinting gene expression in endosperm, and hence normal embryonic development, in the model plant Arabidopsis (Arabidopsis thaliana). Nonetheless, the developmental role of this epigenetic marker in cereal crops remains largely unexplored. Here, we report for sorghum (Sorghum bicolor) differences in relative cytosine methylation levels and patterns at 5'-CCGG sites in seven tissues (endosperm, embryo, leaf, root, young inflorescence, anther, and ovary), and characterize a set of tissue-specific differentially methylated regions (TDMRs). We found that the most enriched TDMRs in sorghum are specific for the endosperm and are generated concomitantly but imbalanced by decrease versus increase in cytosine methylation at multiple 5'-CCGG sites across the genome. This leads to more extensive demethylation in the endosperm than in other tissues, where TDMRs are mainly tissue nonspecific rather than specific to a particular tissue. Accordingly, relative to endosperm, the other six tissues showed grossly similar levels though distinct patterns of cytosine methylation, presumably as a result of a similar extent of concomitant decrease versus increase in cytosine methylation that occurred at variable genomic loci. All four tested TDMRs were validated by bisulfite genomic sequencing. Diverse sequences were found to underlie the TDMRs, including those encoding various known-function or predicted proteins, transposable elements, and those bearing homology to putative imprinted genes in maize (Zea mays). We further found that the expression pattern of at least some genic TDMRs was correlated with its tissue-specific methylation state, implicating a developmental role of DNA methylation in regulating tissue-specific or -preferential gene expression in sorghum.     

Differential DNA methylation between two wing phenotypes adults of Sogatella furcifera

Sogatella furcifera is a major rice pest with wing dimorphism . DNA methylation is an important epigenetic modification that plays a role in gene regulation and phenotype variation in most organisms. The objective of the current research was to survey the frequencies and variation of cytosine methylation at CCGG sequences in macropterous female adults (MFA) and brachypterous female adults (BFA) of S. furcifera, and to determine the occurrence of methylation changes associated with wing phenotypes by using methylation‐sensitive amplification polymorphism (MSAP). No differences were found in the average proportions of methylated CCGG sites between MFA and BFA, but there were significant differences for methylation patterns between MFA and BFA. The fully methylated ratio was 5.81% in BFA, much higher than 2.40% in MFA; while the hemi‐methylated ratio was 4.35% in BFA, much lower than 8.35% in MFA. These results provide circumstantial evidence that DNA methylation might be related to wing phenotype variation in S. furcifera. We also cloned and got 14 satisfactory sequences, which displayed variable cytosine methylation patterns between MFA and BFA. All these data will facilitate the researches on the epigenetic mechanisms of insect wing polymorphism. genesis 51:819–826. © 2013 Wiley Periodicals, Inc.