EC:2.1.1.37 - FACTA Search

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Query: EC:2.1.1.37 (DNA methyltransferase)
4,983 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Maintaining and acquiring the pluripotent cell state in plants is critical to tissue regeneration and vegetative multiplication. Histone-based epigenetic mechanisms are important for regulating this undifferentiated state. Here we report the use of genetic and pharmacological experimental approaches to show that Arabidopsis cell suspensions and calluses specifically repress some genes as a result of promoter DNA hypermethylation. We found that promoters of the MAPK12, GSTU10 and BXL1 genes become hypermethylated in callus cells and that hypermethylation also affects the TTG1, GSTF5, SUVH8, fimbrin and CCD7 genes in cell suspensions. Promoter hypermethylation in undifferentiated cells was associated with histone hypoacetylation and primarily occurred at CpG sites. Accordingly, we found that the process specifically depends on MET1 and DRM2 methyltransferases, as demonstrated with DNA methyltransferase mutants. Our results suggest that promoter DNA methylation may be another important epigenetic mechanism for the establishment and/or maintenance of the undifferentiated state in plant cells.
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PMID:Promoter DNA hypermethylation and gene repression in undifferentiated Arabidopsis cells. 1882 94

The widespread occurrence of epigenetic alterations in allopolyploid species deserves scrutiny that DNA methylation systems may be perturbed by interspecies hybridization and polyploidization. Here we studied the genes involved in DNA methylation in Nicotiana tabacum (tobacco) allotetraploid containing S and T genomes inherited from Nicotiana sylvestris and Nicotiana tomentosiformis progenitors. To determine the inheritance of DNA methyltransferase genes and their expression patterns we examined three major DNA methyltransferase families (MET1, CMT3 and DRM) from tobacco and the progenitor species. Using Southern blot hybridization and PCR-based methods (genomic CAPS), we found that the parental loci of these gene families are retained in tobacco. Homoeologous expression was found in all tissues examined (leaf, root, flower) suggesting that DNA methyltransferase genes were probably not themselves targets of uniparental epigenetic silencing for over thousands of generations of allotetraploid evolution. The level of CG and CHG methylation of selected high-copy repeated sequences was similar and high in tobacco and its diploid progenitors. We speculate that natural selection might favor additive expression of parental DNA methyltransferase genes maintaining high levels of DNA methylation in tobacco, which has a repeat-rich heterochromatic genome.
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PMID:Faithful inheritance of cytosine methylation patterns in repeated sequences of the allotetraploid tobacco correlates with the expression of DNA methyltransferase gene families from both parental genomes. 1913 93

Although homologous recombination-promoted knock-in targeting to monitor the expression of a gene by fusing a reporter gene with its promoter is routine practice in mice, gene targeting to modify endogenous genes in flowering plants remains in its infancy. In the knock-in targeting, the junction sequence between a reporter gene and an endogenous target promoter can be designed properly, and transgenic plants carrying an identical and desired knock-in allele can be repeatedly obtained. By employing a reproducible gene-targeting procedure with positive-negative selection in rice, we were able to obtain fertile transgenic knock-in plants with the promoterless GUS reporter gene encoding beta-glucuronidase fused with the endogenous promoter of MET1a, one of two rice MET1 genes encoding a maintenance DNA methyltransferase. All of the primary (T(0)) transgenic knock-in plants obtained were found to carry only one copy of GUS, with the anticipated structure in the heterozygous condition, and no ectopic events associated with gene targeting could be detected. We showed the reproducible, dosage-dependent and spatiotemporal expression of GUS in the selfed progenies of independently isolated knock-in targeted plants. The results in knock-in targeted plants contrast sharply with the results in transgenic plants with the MET1a promoter-fused GUS reporter gene integrated randomly in the genome: clear interindividual variation of GUS expression was observed among independently obtained plants bearing the randomly integrated transgenes. As our homologous recombination-mediated gene-targeting strategy with positive-negative selection is, in principle, applicable to modify any endogenous gene, knock-in targeting would facilitate basic and applied plant research.
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PMID:Homologous recombination-mediated knock-in targeting of the MET1a gene for a maintenance DNA methyltransferase reproducibly reveals dosage-dependent spatiotemporal gene expression in rice. 1951 2

Imprinted genes are expressed primarily or exclusively from either the maternal or paternal allele, a phenomenon that occurs in flowering plants and mammals. Flowering plant imprinted gene expression has been described primarily in endosperm, a terminal nutritive tissue consumed by the embryo during seed development or after germination. Imprinted expression in Arabidopsis thaliana endosperm is orchestrated by differences in cytosine DNA methylation between the paternal and maternal genomes as well as by Polycomb group proteins. Currently, only 11 imprinted A. thaliana genes are known. Here, we use extensive sequencing of cDNA libraries to identify 9 paternally expressed and 34 maternally expressed imprinted genes in A. thaliana endosperm that are regulated by the DNA-demethylating glycosylase DEMETER, the DNA methyltransferase MET1, and/or the core Polycomb group protein FIE. These genes encode transcription factors, proteins involved in hormone signaling, components of the ubiquitin protein degradation pathway, regulators of histone and DNA methylation, and small RNA pathway proteins. We also identify maternally expressed genes that may be regulated by unknown mechanisms or deposited from maternal tissues. We did not detect any imprinted genes in the embryo. Our results show that imprinted gene expression is an extensive mechanistically complex phenomenon that likely affects multiple aspects of seed development.
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PMID:Regulation of imprinted gene expression in Arabidopsis endosperm. 2125 7

The methylation patterns of the MET1 gene in organs of Arabidopsis thaliana were studied by Southern blot hybridization of DNA samples hydrolyzed with differentially methylation-sensitive restriction endonucleases. A highly methylated on internal cytosine residue CCGG site was found 1.5 kb upstream of the gene, whereas CCGG sites located in more proximal parts of the 5'-flanking region and the gene itself are essentially unmethylated. This methylation pattern was observed in different organs of plants belonging to two different ecotypes as well as in different transgenic plant lines. The methylation level ofa CCGG site in exon 3 (2.1 kb from the gene's 5'-end) occurred to be variable between different transgenic plant lines and two ecotypes studied. Transcription levels of the MET1 gene vary slightly in organs of wild-type plants without any obvious correlation with its methylation. The transgenic antisense MET1 constructs expressed in plant genome do affect both MET1 methylation and its transcription but again without any obvious correlation. The comparative investigation of transcription levels of different genes of cytosine DNA methyltransferase family MET (MET1, MET2a, MET2b, MET3) and their methylation patterns shows that there may exist some mechanisms defending the most actively transcribed gene MET1 of this family from methylation mediated silencing. In contrast to DRM2 gene we could not find any adenine methylated GATC sites in the MET1 gene.
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PMID:[Is the cytosine DNA methyltransferase gene MET1 regulated by DNA methylation in Arabidopsis thaliana plants?]. 2154 2

A relatively high degree of nuclear DNA (nDNA) methylation is a specific feature of plant genomes. Targets for cytosine DNA methylation in plant genomes are CG, CHG and CHH (H is A, T, C) sequences. More than 30% total m(5)C in plant DNA is located in non-CG sites. DNA methylation in plants is species-, tissue-, organelle- and age-specific; it is involved in the control of all genetic functions including transcription, replication, DNA repair, gene transposition and cell differentiation. DNA methylation is engaged in gene silencing and parental imprinting, it controls expression of transgenes and foreign DNA in cell. Plants have much more complicated and sophisticated system of the multicomponent genome methylations compared to animals; DNA methylation in plant mitochondria is performed in other fashion as compared to that in nuclei. The nDNA methylation is carried out by cytosine DNA methyltransferases of, at least, three families. In contrast to animals the plants with the major maintenance methyltransferase MET1 (similar to animal Dnmt1) inactivated do survive. One and the same plant gene may be methylated at both adenine and cytosine residues; specific plant adenine DNA methyltransferase was described. Thus, two different systems of the genome modification based on methylation of cytosines and adenines seem to coexist in higher plants. This article is part of a Special Issue entitled: Epigenetic control of cellular and developmental processes in plants.
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PMID:DNA methylation in higher plants: past, present and future. 2154 30

Heterochromatin silencing is pivotal for genome stability in eukaryotes. In Arabidopsis, a plant-specific mechanism called RNA-directed DNA methylation (RdDM) is involved in heterochromatin silencing. Histone deacetylase HDA6 has been identified as a component of such machineries; however, its endogenous targets and the silencing mechanisms have not been analyzed globally. In this study, we investigated the silencing mechanism mediated by HDA6. Genome-wide transcript profiling revealed that the loci silenced by HDA6 carried sequences corresponding to the RDR2-dependent 24-nt siRNAs, however their transcript levels were mostly unaffected in the rdr2 mutant. Strikingly, we observed significant overlap of genes silenced by HDA6 to those by the CG DNA methyltransferase MET1. Furthermore, regardless of dependence on RdDM pathway, HDA6 deficiency resulted in loss of heterochromatic epigenetic marks and aberrant enrichment for euchromatic marks at HDA6 direct targets, along with ectopic expression of these loci. Acetylation levels increased significantly in the hda6 mutant at all of the lysine residues in the H3 and H4 N-tails, except H4K16. Interestingly, we observed two different CG methylation statuses in the hda6 mutant. CG methylation was sustained in the hda6 mutant at some HDA6 target loci that were surrounded by flanking DNA-methylated regions. In contrast, complete loss of CG methylation occurred in the hda6 mutant at the HDA6 target loci that were isolated from flanking DNA methylation. Regardless of CG methylation status, CHG and CHH methylation were lost and transcriptional derepression occurred in the hda6 mutant. Furthermore, we show that HDA6 binds only to its target loci, not the flanking methylated DNA, indicating the profound target specificity of HDA6. We propose that HDA6 regulates locus-directed heterochromatin silencing in cooperation with MET1, possibly recruiting MET1 to specific loci, thus forming the foundation of silent chromatin structure for subsequent non-CG methylation.
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PMID:Arabidopsis HDA6 regulates locus-directed heterochromatin silencing in cooperation with MET1. 2155 33

One of the most fundamental questions in the control of gene expression is how epigenetic patterns of DNA methylation and histone modifications are established. Our recent studies demonstrate that histone deacetylase HDA6 integrates DNA methylation and histone modifications in gene silencing by interacting with DNA methyltransferase MET1 and histone demethylase FLD, suggesting that regulatory crosstalk between histone modifications and DNA methylation could be mediated by the interaction of various epigenetic modification proteins.
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PMID:Epigenetic interplay of histone modifications and DNA methylation mediated by HDA6. 2258 Jul 2

The stability of epigenetic patterns is critical for genome integrity and gene expression. This highly coordinated process involves interrelated positive and negative regulators that impact distinct epigenetic marks, including DNA methylation and dimethylation at histone H3 lysine 9 (H3K9me2). In Arabidopsis, mutations in the DNA methyltransferase MET1, which maintains CG methylation, result in aberrant patterns of other epigenetic marks, including ectopic non-CG methylation and the relocation of H3K9me2 from heterochromatin into gene-rich chromosome regions. Here, we show that the expression of the H3K9 demethylase IBM1 (increase in BONSAI methylation 1) requires DNA methylation. Surprisingly, the regulatory methylated region is contained in an unusually large intron that is conserved in IBM1 orthologues. The re-establishment of IBM1 expression in met1 mutants restored the wild-type H3K9me2 nuclear patterns, non-CG DNA methylation and transcriptional patterns at selected loci, which included DNA demethylase genes. These results provide a mechanistic explanation for long-standing puzzling observations in met1 mutants and reveal yet another layer of control in the interplay between DNA methylation and histone modification, which stabilizes DNA methylation patterns at genes.
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PMID:DNA methylation in an intron of the IBM1 histone demethylase gene stabilizes chromatin modification patterns. 2258 Aug 22

Genomic imprinting is exclusive to mammals and seed plants and refers to parent-of-origin-dependent, differential transcription. As previously shown in mammals, studies in Arabidopsis have implicated DNA methylation as an important hallmark of imprinting. The current model suggests that maternally expressed imprinted genes, such as MEDEA (MEA), are activated by the DNA glycosylase DEMETER (DME), which removes DNA methylation established by the DNA methyltransferase MET1. We report the systematic functional dissection of the MEA cis-regulatory region, resulting in the identification of a 200-bp fragment that is necessary and sufficient to mediate MEA activation and imprinted expression, thus containing the imprinting control region (ICR). Notably, imprinted MEA expression mediated by this ICR is independent of DME and MET1, consistent with the lack of any significant DNA methylation in this region. This is the first example of an ICR without differential DNA methylation, suggesting that factors other than DME and MET1 are required for imprinting at the MEA locus.
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PMID:Identification of a DNA methylation-independent imprinting control region at the Arabidopsis MEDEA locus. 2285 91

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