Methylation of CpG dinucleotides in the open reading frame of a testicular germ cell-specific intronless gene,Tact1/Actl7b,represses its expression in somatic cells

Methylation of CpG islands spanning promoter regions is associated with control of gene expression. However, it is considered that methylation of exonic CpG islands without promoter is not related to gene expression, because such exonic CpG islands are usually distant from the promoter. Whether methylation of exonic CpG islands near the promoter, as in the case of a CpG-rich intronless gene, causes repression of the promoter remains unknown. To gain insight into this issue, we investigated the distribution and methylation status of CpG dinucleotides in the mouse Tact1/Actl7b gene, which is intronless and expressed exclusively in testicular germ cells. The region upstream to the gene was poor in CpG, with CpG dinucleotides absent from the core promoter. However, a CpG island was found inside the open reading frame (ORF). Analysis of the methylation status of the Tact1/Actl7b gene including the 5′-flanking area demonstrated that all CpG sites were methylated in somatic cells, whereas these sites were unmethylated in the Tact1/Actl7b-positive testis. Trans fection experiments with in vitro-methylated constructs indicated that methylation of the ORF but not 5′ upstream repressed Tact1/Actl7b promoter activity in somatic cells. Similar effects of ORF methylation on the promoter activity were observed in testicular germ cells. These are the first results indicating that methylation of the CpG island in the ORF represses its promoter in somatic cells and demethylation is necessary for gene expression in spermatogenic cells.     

Gene-associated CpG islands in plants as revealed by analyses of genomic sequences

We screened plant genome sequences, primarily from rice and Arabidopsis thaliana, for CpG islands, and identified DNA segments rich in CpG dinucleotides within these sequences. These CpG-rich clusters appeared in the analysed sequences as discrete peaks and occurred at the frequencies of one per 4.7 kb in rice and one per 4.0 kb in A. thaliana. In rice and A. thaliana, most of the CpG-rich clusters were associated with genes, which suggests that these clusters are useful landmarks in genome sequences for identifying genes in plants with small genomes. In contrast, in plants with larger genomes, only a few of the clusters were associated with genes. These plant CpG-rich clusters satisfied the criteria used for identifying human CpG islands, which suggests that these CpG clusters may be regarded as plant CpG islands. The position of each island relative to the 5'-end of its associated gene varied considerably. Genes in the analysed sequences were grouped into five classes according to the position of the CpG islands within their associated genes. A large proportion of the genes belonged to one of two classes, in which a CpG island occurred near the 5'-end of the gene or covered the whole gene region. The position of a plant CpG island within its associated gene appeared to be related to the extent of tissue-specific expression of the gene; the CpG islands of most of the widely expressed rice genes occurred near the 5'-end of the genes.     

Unmethylated CpG islands associated with genes in higher plant DNA

The genomes of many higher plant species are the most highly methylated among eukaryotes. We report here that in spite of their heavy methylation, genomic DNAs from four plant species contain a fraction that is very rich in non-methylated sites. The fraction was characterized in maize where it represents about 2.5% of the total nuclear genome. In order to establish the genomic origin of the fraction, three maize genes containing clustered CpG were tested for methylation and were found to be non-methylated in the CpG-rich regions. By contrast, tested CpGs were methylated in a gene whose sequence showed no clustering of CpG. These observations suggest that the CpG-rich fraction of plants is at least partially derived from non-methylated regions that are associated with genes. A similar phenomenon has been described in vertebrate genomes. We discuss the evolution of CpG islands in both groups of organisms, and their possible uses in mapping and gene isolation in plants.     

Genome-wide profiling of DNA methylation reveals a class of normally methylated CpG island promoters

The role of CpG island methylation in normal development and cell differentiation is of keen interest, but remains poorly understood. We performed comprehensive DNA methylation profiling of promoter regions in normal peripheral blood by methylated CpG island amplification in combination with microarrays. This technique allowed us to simultaneously determine the methylation status of 6,177 genes, 92% of which include dense CpG islands. Among these 5,549 autosomal genes with dense CpG island promoters, we have identified 4.0% genes that are nearly completely methylated in normal blood, providing another exception to the general rule that CpG island methylation in normal tissue is limited to X inactivation and imprinted genes. We examined seven genes in detail, including ANKRD30A, FLJ40201, INSL6, SOHLH2, FTMT, C12orf12, and DPPA5. Dense promoter CpG island methylation and gene silencing were found in normal tissues studied except testis and sperm. In both tissues, bisulfite cloning and sequencing identified cells carrying unmethylated alleles. Interestingly, hypomethylation of several genes was associated with gene activation in cancer. Furthermore, reactivation of silenced genes could be induced after treatment with a DNA demethylating agent or in a cell line lacking DNMT1 and/or DNMT3b. Sequence analysis identified five motifs significantly enriched in this class of genes, suggesting that cis-regulatory elements may facilitate preferential methylation at these promoter CpG islands. We have identified a group of non-X-linked bona fide promoter CpG islands that are densely methylated in normal somatic tissues, escape methylation in germline cells, and for which DNA methylation is a primary mechanism of tissue-specific gene silencing.     

Heterologous CpG island becomes extensively methylated in the genome of transgenic mice

It is demonstrated that a heterologous (chicken) CpG island containing five Sp1 canonical recognition sequences becomes highly methylated in the genome of transgenic mice bearing one or several copies of the transgene. Similar levels of methylation of the chicken CpG island were observed in different tissues of transgenic mice except the brain where the level of methylation of this chicken CpG-rich fragment was significantly lower than in other tissues. Analysis of susceptibility of the "transgenic" CpG island to Hpa II and Msp I restriction nucleases revealed an unusual methylation pattern interfering with the action of both of these enzymes. A conclusion has been drawn that heterologous CpG island per se does not contain all necessary signals permitting to maintain its own non-methylated status in the genome of transgenic animals.     

Evaluation of single CpG sites as proxies of CpG island methylation states at the genome scale

Methylation of a CpG island is a faithful marker of silencing of its associated gene. Different approaches report the methylation status of a CpG island based on the determination of one or a few CpG sites by assuming the homogeneity of methylation along the element. This strategy is frequently applied in both locus-specific and genome-wide studies, but often without a validation of the representativeness of the interrogated CpG site compared with the whole element. We have evaluated the predictive informativeness of the HpaII sites located in CpG islands using data from high-resolution methylome maps, which offer the possibility to assess the methylation homogeneity of each CpG island and to determine the reporter accuracy of single sites as surrogate markers. An excellent correlation was observed between the HpaII and CpG island methylation levels (r > 0.93). At the qualitative level, the predictive sensitivity of HpaII was >95% with >92% specificity for methylated CpG islands and >90% sensitivity with >95% specificity for unmethylated CpG islands. This analysis provides a global validation framework for strategies based on the use of the methylation-sensitive HpaII restriction enzyme.     

Abnormal methylation of p16/CDKN2A AND p14/ARF genes GpG Islands in non-small cell lung cancer and in acute lymphoblastic leukemia

Multiplex methylation-sensitive PCR and methylation-specific PCR were employed in studying the methylation of CpG islands in the p16/CDKN2A and p14/ARF promoter and the first exon regions in non-small cell lung cancer (54 samples) and acute B-cell lymphoblastic leukemia (61 samples). Differences in methylation were detected between types of neoplasia as well as between CpG islands studied within the same types of tumors. High level of the p16/CDKN2A first exon CpC island methylation was revealed in non-small cell lung cancer (68%) and in acute B-cell lymphoblastic leukemia (55%) and the CpG island of p14/ARF first exon was nonmethylated in these types of tumors. The methylation of CpG-rich fragments of genes p16/CDKN2A and p14/ARF promoters was analysed. As was found out, CpG islands located in 5' areas of one and the same gene can differ in methylation frequencies. The comparison of sensitivity between methylation-specific PCR and methylation-sensitive PCR used in the methylations studies was carried out.     

Methylation-mediated silencing of TMS1/ASC is accompanied by histone hypoacetylation and CpG island-localized changes in chromatin architecture.

Aberrant methylation of CpG-dense islands in the promoter regions of genes is an acquired epigenetic alteration associated with the silencing of tumor suppressor genes in human cancers. In a screen for endogenous targets of methylation-mediated gene silencing, we identified a novel CpG island-associated gene, TMS1, which is aberrantly methylated and silenced in response to the ectopic expression of DNA methyltransferase-1. TMS1 functions in the regulation of apoptosis and is frequently methylated and silenced in human breast cancers. In this study, we characterized the methylation pattern and chromatin architecture of the TMS1 locus in normal fibroblasts and determined the changes associated with its progressive methylation. In normal fibroblasts expressing TMS1, the CpG island is defined by an unmethylated domain that is separated from densely methylated flanking DNA by distinct 5' and 3' boundaries. Analysis of the nucleoprotein architecture of the locus in intact nuclei revealed three DNase I-hypersensitive sites that map within the CpG island. Strikingly, two of these sites coincided with the 5'- and 3'-methylation boundaries. Methylation of the TMS1 CpG island was accompanied by loss of hypersensitive site formation, hypoacetylation of histones H3 and H4, and gene silencing. This altered chromatin structure was confined to the CpG island and occurred without significant changes in methylation, histone acetylation, or hypersensitive site formation at a fourth DNase I-hypersensitive site 2 kb downstream of the TMS1 CpG island. The data indicate that there are sites of protein binding and/or structural transitions that define the boundaries of the unmethylated CpG island in normal cells and that aberrant methylation overcomes these boundaries to direct a local change in chromatin structure, resulting in gene silencing.     

Comparison of Aberrant Methylation of CpG Islands in the p16/CDKN2A and p14/ARF Promoters in Non-Small Cell Lung Cancer and Acute Lymphoblastic Leukemia

Multiplex methylation-sensitive (MSe-PCR) and methylation-specific (MSp-PCR) PCRs were used to detect aberrant methylation of CpG islands in the promoter regions and first exons of p16/CDKN2A and p14/ARF in non-small cell lung cancer (NSCLC, 54 specimens) and B-cell acute lymphoblastic leukemia (B-ALL, 61 specimens). A difference in CpG methylation was observed for individual specimens and for the two malignancies. A high methylation frequency of the first exon of p16/CDKN2A was detected both in NSCLC (68%) and in B-ALL (55%). The CpG island of the p14/ARF first exon proved to be nonmethylated in both malignancies. Particular CpG-rich fragments were examined in the p16/CDKN2A and p14/ARF promoters. It was shown that methylation frequency can differ between the 5 regions of one promoter. The sensitivity was compared for MSe-PCR and MSp-PCR, which are commonly employed in methylation analysis.     

Tissue-specific methylation of a CpG island in transgenic mice.

Clustering of CpG dinucleotides in CpG-rich islands is a characteristic feature of mammalian genomes. Such CpG islands are frequently associated with genes and usually hypomethylated, regardless of the gene activity. This is the case for the CpG island of the murine Thy-1 gene. A transgenic line containing multiple copies of a truncated, concatemeric CpG island from the Thy-1.1 allele (Thy-1.2 background) showed that a stable fraction (approx. 0.20) became fully methylated in somatic tissues of homozygous mice with respect to testable restriction sites, while the remaining copies were methylation-free, i.e., this methylation appears to be an 'all-or-none' phenomenon. DNA from extraembryonic tissues (placenta and yolk sac) and epididymal sperm showed, however, an even higher degree of methylation in two distinct patterns. In the extraembryonic tissue, partial methylation of each copy was seen, whereas in sperm a high degree of 'all-or-none' methylation (greater than 0.35) was observed.     

A novel imprinted transgene located near a repetitive element that exhibits allelic imbalance in DNA methylation during early development

A mouse line carrying a lacZ transgene driven by the human EEF1A1/EF1alpha promoter was established. Although the promoter is known to show ubiquitous activity, only paternal transgene alleles were expressed, resulting in a transgene imprinting. At mid‐gestation, the promoter sequence was differentially methylated, hypomethylated for paternal and hypermethylated for maternal alleles. In germline, the promoter was a typical differentially methylated region. After fertilization, however, both alleles were hypermethylated. Thus, the differential methylation of the promoter required for transgene imprinting was re‐established during later embryonic development independently of the germline differential methylation. Furthermore, also a retroelement promoter closely‐flanking imprinted transgene and its wild type counterpart displayed similar differential methylation during early development. The retroelement promoter was methylated differentially also in germline, but in an opposite pattern to the embryonic differential methylation. These results suggest that there might be an unknown epigenetic regulation inducing transgene imprinting independently of DNA methylation in the transgene insertion site. Then, besides CpG dinucleotides, non‐CpG cytosines of the retroelement promoter were highly methylated especially in the transgene‐active mid‐gestational embryos, suggesting that an unusual epigenetic regulation might protect the active transgene against de novo methylation occurring generally in mid‐gestational embryo.     

Factors to preserve CpG-rich sequences in methylated CpG islands

Background

Mammalian CpG islands (CGIs) normally escape DNA methylation in all adult tissues and developmental stages. However, in our previous study we unexpectedly identified many methylated CGIs in human peripheral blood leukocytes. Methylated CpG dinucleotides convert to TpG dinucleotides through deaminization of their cytosine bases more frequently than hypomethylated CpG dinucleotides. Therefore, we wondered how methylated CGIs in germline or non-germline cells maintain their CpG-rich sequences. It is known that events such as germline hypomethylation, CpG selection, biased gene conversion (BGC), and frequent CpG fixation can contribute to the maintenance of CpG-rich sequences in methylated CGIs in germline or non-germline cells. However, it has not been investigated which of the processes maintain CpG-rich sequences of methylated CGIs in each genomic position.

Results

In this study, we comprehensively examined the contribution of the processes described above to the maintenance of CpG-rich sequences in methylated CGIs in germline and non-germline cells which were classified by genomic positions. Approximately 60–80% of CGIs with high methylation in H1 cell line (H1-HM) in all the genomic positions showed a low average CpG → TpG/CpA substitution rate. In contrast, fewer than half the numbers of CGIs with H1-HM in all the genomic positions showed a low average CpG → TpG/CpA substitution rate and low levels of methylation in sperm cells (SPM-LM). Furthermore, a small fraction of CGIs with a low average CpG → TpG/CpA substitution rate and high levels of methylation in sperm cells (SPM-HM) showed CpG selection.On the other hand, independent of the positions in genes, most CGIs with SPM-HM showed a slightly higher average TpG/CpA → CpG substitution rate compared with those with SPM-LM.

Conclusions

Relatively high numbers (approximately 60–80%) of CGIs with H1-HM in all the genomic positions preserve their CpG-rich sequences by a low CpG → TpG/CpA substitution rate caused mainly by their SPM-LM, and for those with SPM-HM partly by CpG selection and TpG/CpA → CpG fixation. BGC has little contribution to the maintenance of CpG-rich sequences of CGIs with SPM-HM which were classified by genomic positions.

Electronic supplementary material

The online version of this article (doi:10.1186/s12864-015-1286-x) contains supplementary material, which is available to authorized users.     

Methylation status of CpG-rich islands on active and inactive mouse X chromosomes

Single copy probes derived from CpG-rich island clones fromEag I andNot I linking libraries and nine rare-cutter restriction endonucleases were used to investigate the methylation status of CpG-rich islands on the inactive and active X chromosomes (Chr) of the mouse. Thirteen of the 14 probes used detected CpG-rich islands in genomic DNA. The majority of island CpGs detected by rare-cutter restriction endonucleases were methylated on the inactive X Chr and unmethylated on the active X Chr, but some heterogeneity within the cell population used to make genomic DNA was detected. The CpG-rich islands detected by two putative pseudoautosomal probes remained unmethylated on both the active and inactive X Chrs. Otherwise, distance from the X Chr inactivation center did not affect the methylation profile of CpG-rich islands. We conclude that methylation of CpG-rich islands is a general feature of X Chr inactivation.     

A non-methylated CpG-rich island associated with the human muscle-specific carbonic anhydrase III gene

A cluster of CpG dinucleotides immediately upstream from exon 1 in the muscle-specific carbonic anhydrase III gene (CAIII) resembles the 'HpaII tiny fragment' (HTF) islands characteristic of mammalian 'housekeeping' genes. Since this CAIII gene shows tissue-specific expression we have carried out a detailed examination of methylation status within the CpG cluster using a polyacrylamide gel/electroblot procedure to extend the range of conventional Southern blotting. None of the clustered CpGs are methylated in DNA from muscle or other somatic tissues or in DNA from spermatozoa although flanking CpGs are methylated. Comparison with a candidate HTF island from the more ubiquitously expressed carbonic anhydrase II gene (CAII) shows that the CAII CpG cluster is markedly more CpG-rich than that from the strictly tissue-specific CAIII gene.