Differential methylation at the 5′ and the 3′ CCGG sites flanking the X chromosomal hypervariable DXS255 locus

Summary The degree of methylation at the 5 and 3 CCGG sequences flanking the variable number of tandem repeat (VNTR) region of the DXS255 locus at Xp11.22 was analysed separately in several haematopoietic cell lineages. The 5 CCGG site on active chromosomes was found to be completely methylated in B and T lymphocytes and granulocytes. Methylation of the 5 site on inactive X chromosomes differed between females (0%–60%), but was consistent in different cell lineages obtained from individual females. In contrast, methylation at the 3 CCGG site on active chromosomes was found to vary in B lymphocytes (40%–100%), whereas complete methylation was found in T lymphocytes and granulocytes. The extent of methylation on inactive X chromosomes was found to differ significantly between B lymphocytes (17%), T lymphocytes (54%) and granulocytes (82%). Thus, methylation at the 5 CCGG site seems to be primarily related to the status of X chromosome inactivation, whereas methylation at the 3 CCGG site is mainly subject to cell-lineage-specific influences.     

Restriction enzyme banding and in situ nick-translation on different types of hetero- and euchromatin.

We studied the role of chromatin accessibility and methylation in the banding patterns produced by means of in situ nick-translation (NT) and restriction enzyme (RE) banding techniques. For these studies we used the X chromosomes of Microtus cabrerae because of their large segment with four different types of constitutive heterochromatin and because in these chromosomes we can also compare active and inactive euchromatin. The results demonstrate that constitutive heterochromatin in the X chromosomes of M. cabrerae is methylated at specific sequences in both active and inactive Xs. They also show that NT-based techniques are suitable for detecting weak differences in chromatin accessibility, such as differences between active and inactive euchromatin, and are able to distinguish methylation only at the accessible sites. Thus, when methylation has to be mapped in situ, additional experiments have to be performed in order to distinguish findings due to differential accessibility. RE banding seems less sensitive to slight differences in chromatin accessibility, and might thus be more suitable than in situ NT-based techniques for methylation mapping. In harmony with these results, HpaII-based RE banding is able to distinguish between active and inactive euchromatin, possibly depending on its methylation status.     

Active X chromosome DNA is unmethylated at eight CCGG sites clustered in a guanine-plus-cytosine-rich island at the 5'' end of the gene for phosphoglycerate kinase.

The 5' control region and first exon for human X-chromosome-linked phosphoglycerate kinase is contained in a G + C-rich island. We measured methylation at all HpaII sites in this 5' region of leukocyte DNA. By use of a blotting procedure that allows analysis of small DNA fragments, we found that the HpaII sites are entirely methylated when from an inactive X chromosome and entirely unmethylated when from an active one. In contrast, methylation of HpaII sites in more downstream regions of the gene is essentially the same in active and inactive X chromosomes.     

Analysis of DNase 1 sensitivity and methylation of active and inactive X chromosomes of kangaroos (Macropus robustus) by in situ nick translation

The overall nuclease sensitivity and methylation of active and inactive X chromosomes of kangaroos were examined by in situ nick translation. Cultured fibroblasts of subspecies wallaroo-euro (Macropus robustus robustus; Macropus robustus erubescens) hybrids were used, enabling the paternally and maternally derived X chromosomes to be distinguished. No difference was found between the active and inactive X chromosomes with DNase I or MspI digestion. When chromosomes were digested with the methylation sensitive restriction enzymes HpaII and HhaI, the inactive X chromosome was labelled to a greater extent. These results indicate no overall difference in chromatin condensation between the active and inactive X chromosomes and greater overall methylation of the active X chromosome. This relative undermethylation of the inactive X chromosome may be important in X chromosome inactivation, but its function, if any, remains to be determined.by A. Bird     

Restriction enzyme banding and in situ nick-translation on different types of hetero- and euchromatin

We studied the role of chromatin accessibility and methylation in the banding patterns produced by means of in situ nick-translation (NT) and restriction enzyme (RE) banding techniques. For these studies we used the X chromosomes of Microtus cabrerae because of their large segment with four different types of constitutive heterochromatin and because in these chromosomes we can also compare active and inactive euchromatin. The results demonstrate that constitutive heterochromatin in the X chromosomes of M. cabrerae is methylated at specific sequences in both active and inactive Xs. They also show that NT-based techniques are suitable for detecting weak differences in chromatin accessibility, such as differences between active and inactive euchromatin, and are able to distinguish methylation only at the accessible sites. Thus, when methylation has to be mapped in situ, additional experiments have to be performed in order to distinguish findings due to differential accessibility. RE banding seems less sensitive to slight differences in chromatin accessibility, and might thus be more suitable than in situ NT-based techniques for methylation mapping. In harmony with these results, HpaII-based RE banding is able to distinguish between active and inactive euchromatin, possibly depending on its methylation status.     

Methylation of the mouse hprt gene differs on the active and inactive X chromosomes.

It has been proposed that DNA methylation is involved in the mechanism of X inactivation, the process by which equivalence of levels of X-linked gene products is achieved in female (XX) and male (XY) mammals. In this study, Southern blots of female and male DNA digested with methylation-sensitive restriction endonucleases and hybridized to various portions of the cloned mouse hprt gene were compared, and sites within the mouse hprt gene were identified that are differentially methylated in female and male cells. The extent to which these sites are methylated when carried on the active and inactive X chromosomes was directly determined in a similar analysis of DNA from clonal cell lines established from a female embryo derived from a mating of two species of mouse, Mus musculus and Mus caroli. The results revealed two regions of differential methylation in the mouse hprt gene. One region, in the first intron of the gene, includes four sites that are completely unmethylated when carried on the active X and extensively methylated when carried on the inactive X. These same sites are extensively demethylated in hprt genes reactivated either spontaneously or after 5-azacytidine treatment. The second region includes several sites in the 3' 20kilobases of the gene extending from exon 3 to exon 9 that show the converse pattern; i.e., they are completely methylated when carried on the active X and completely unmethylated when carried on the inactive X. At least one of these sites does not become methylated after reactivation of the gene. The results of this study, together with the results of previous studies by others of the human hprt gene, indicate that these regions of differential methylation on the active and inactive X are conserved between mammalian species. Furthermore, the data described here are consistent with the idea that at least the sites in the 5' region of the gene play a role in the X inactivation phenomenon and regulation of expression of the mouse hprt gene.     

The hypervariable DXS255 locus contains a LINE-1 repetitive element with a CpG island that is extensively methylated only on the active X chromosome.

The DXS255 locus at Xp11.22 is highly polymorphic due to a 26-bp variable number of tandem repeats (VNTR) motif. In previous studies, one of the MspI sites flanking the VNTR manifested a correlation between methylation and X chromosome inactivation. Here we show, by DNA sequence analysis, that this MspI site is located within the CpG island at the 5' end of a LINE-1 element, which is 2.5 kb from the VNTR. The methylation status of the CpG island was assessed in Southern blotting experiments using the methylation-sensitive enzymes HpaII, HhaI, and BssHII. All these sites were completely methylated on active X chromosomes, consistent with previously reported findings of full methylation of LINE-1 elements throughout the genome. However, on inactive X chromosomes these sites were predominantly unmethylated, although patterns were found to be heterogeneous. The results suggest that LINE-1 elements on the inactive X chromosome are not suppressed by full methylation of their CpG islands. The differential methylation of the DXS255 CpG island provides the basis for a highly informative X inactivation analysis system.     

Analysis of methylation of a human X located gene which escapes X inactivation.

The gene MIC2 is located in the pseudoautosomal region at the ends of the short arms of the X and Y chromosomes. In females MIC2 escapes X inactivation. We have analyzed the methylation pattern of MIC2 on the active X, the inactive X chromosomes, and the Y chromosome. The 5' end of the gene contains a GC rich region which is unmethylated on the active X, the inactive X and on the Y. The body of the gene is characterized by variable methylation.     

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.     

Correlation between the size of the intergenic regulatory region, the status of cytosine methylation of rRNA genes and nucleolar expression in wheat

Summary A large number of wheat rRNA genes are methylated at all the CCGG sites that are present in the intergenic regions. A smaller number of rRNA genes are not methylated at one or more CCGG sites. A subset of genes was found unmethylated at a specific CCGG site just downstream of the array of 135 by A repeats in the intergenic region. In all the genotypes studied, the rDNA loci with larger intergenic regions between their genes also possess a greater number of rRNA genes that are unmethylated at one or more CCGG sites in the intergenic regions than do the loci with shorter intergenic regions. In four genotypes (for which data were available), rDNA loci with longer intergenic regions had larger secondary constrictions on metaphase chromosomes, a measure of relative locus activity, than the loci with shorter intergenic regions. The results have been integrated into a model for the control of rDNA expression based on correlations between cytosine methylation patterns and the number of upstream 135 by repeats in intergenic regions. According to this model the 135 by repeats play a part in the control of gene activity by binding a protein(s) that is in limiting supply, thereby predisposing the neighbouring gene to become active preferentially.     

The distribution of genes on human chromosomes as studied by in situ nick translation.

We have studied the distribution of potentially active genes on human chromosomes, using two methods: DNAse I hypersensitivity and restriction enzyme--nick translation with enzymes sensitive to methylation of CpG doublets. DNAse hypersensitivity is known to be associated with potentially active genes, and, when the reaction is detected by "in situ" nick translation, produces an R-banding pattern. Digestion of chromosomes with HpaII or CfoI, both of which should preferentially cut unmethylated sequences in the CpG islands associated with the majority of genes, also produces R-banding patterns. Deviations are attributable to overdigestion of the chromosomes, leading to extraction of DNA and loss of the specific sites that were to be detected. Contrary to the results of a number of previous workers, we have failed to demonstrate any differences between the DNAse I hypersensitivity or the degree of methylation of the active and inactive X chromosomes in metaphases from females.     

Evidence for a relationship between DNA methylation and DNA replication from studies of the 5-azacytidine-reactivated allocyclic X chromosome

We examined the sequence of DNA synthesis of the human active, inactive and reactivated X chromosomes in mouse-human hybrid cells. The two independent reactivants, induced by 5-azacytidine (5-azaC), expressed human hypoxanthinephosphoribosyl transferase (HPRT), and one also expressed human glucose-6-phosphate dehydrogenase (G6PD) and phosphoglycerate kinase (PGK). Restriction enzyme analysis of DNA methylation at the re-expressed loci revealed hypomethylation of CpG clusters, that characterizes the relevant genes on the active X. The transfer of active and inactive X chromosomes from the native environment of the human fibroblast to the foreign environment of the hybrid cell did not affect the specific replication sequence of either human X chromosome. The silent X chromosome when reactivated, remained allocyclic, and the first bands to replicate were the same as prior to reactivation. In one reactivant, however, further progression of replication was significantly altered with respect to the order in which bands were synthesized. This alteration in the replication of the silent X following 5-azaC-induced reactivation suggests that DNA methylation may modulate the replication kinetics of chromosomal DNA.     

Methylation patterns at the hypervariable X-chromosome locus DXS255 (M27 beta): correlation with X-inactivation status.

Methylation patterns surrounding a hypervariable X-chromosome locus, DXS255, have been analyzed with the restriction enzyme MspI and its methylation-sensitive isoschizomer HpaII. HpaII sites flanking the hypervariable region were found to be methylated on 41 active X chromosomes and unmethylated on 11 inactive X chromosomes present in a range of male, female, and hybrid cells and tissues. This differential methylation pattern coupled with the previously described high level (greater than 90%) of heterozygosity at the DXS255 locus can therefore be applied to determine the inactivation status of X chromosomes in females heterozygous for X-linked disease and in tumor clonality studies.     

A deletion at the mouse Xist gene exposes trans-effects that alter the heterochromatin of the inactive X chromosome and the replication time and DNA stability of both X chromosomes

The inactive X chromosome of female mammals displays several properties of heterochromatin including late replication, histone H4 hypoacetylation, histone H3 hypomethylation at lysine-4, and methylated CpG islands. We show that cre-Lox-mediated excision of 21 kb from both Xist alleles in female mouse fibroblasts led to the appearance of two histone modifications throughout the inactive X chromosome usually associated with euchromatin: histone H4 acetylation and histone H3 lysine-4 methylation. Despite these euchromatic properties, the inactive X chromosome was replicated even later in S phase than in wild-type female cells. Homozygosity for the deletion also caused regions of the active X chromosome that are associated with very high concentrations of LINE-1 elements to be replicated very late in S phase. Extreme late replication is a property of fragile sites and the 21-kb deletions destabilized the DNA of both X chromosomes, leading to deletions and translocations. This was accompanied by the phosphorylation of p53 at serine-15, an event that occurs in response to DNA damage, and the accumulation of gamma-H2AX, a histone involved in DNA repair, on the X chromosome. The Xist locus therefore maintains the DNA stability of both X chromosomes.     

Differential methylation of the hypervariable locus DXS255 on active and inactive X chromosomes correlates with the expression of a human X-linked gene

Consistent differences in methylation of particular cytosine residues in the DNA of active and inactive X chromosomes can be used for rapid, direct analysis of X-inactivation patterns in different female tissues. We have studied methylation of the highly polymorphic DXS255 locus in tissues from patients with deficiency of the E1 alpha subunit of the pyruvate dehydrogenase complex in whom the results can be correlated directly with total enzyme activity, levels of immunoreactive protein, and patterns of cell mosaicism. The results confirm that methylation of the DXS255 locus correlates with X-chromosome expression. In patients and normal controls, the pattern of X inactivation varied widely from tissue to tissue and often deviated markedly from a 50:50 proportion. These deviations are likely to reflect small numbers of tissue-specific stem cells at the time of random X inactivation and cannot be taken alone as evidence for selection or "nonrandom" inactivation.     

DNA methylation of the X chromosomes of the human female: an in situ semi-quantitative analysis

We present an in situ semi-quantitative analysis of the global DNA methylation of the X chromosomes of the human female using antibodies raised against 5-methylcytosine. The antibodies were revealed by immunofluorescence. Images were recorded by a CCD camera and the difference in intensity of fluorescence between active (early replicating) and inactive (late-replicating) X chromosomes was measured. Global hypomethylation of the late-replicating X chromosomal DNA was observed in three cases of fibroblast primary cultures that were characterized by numerical and structural aberrations of the X chromosomes [46,X,ter rea(X;X), 48,XXXX and 46,X,t(X;15)]. In these cases, the difference between early and late-replicating X chromosomes was significantly greater than the intrametaphasic variations, measured for a pair of autosomes, that result from experimental procedures. In cells with normal karyotypes, the differneces between the two X chromosomes were in the range of experimental variation. These results demonstrated that late replication and facultative heterochromatinization of the inactive X are two processes that are not related to global hypermethylation of the DNA     

Methylation profile of genes on the human X chromosome

X chromosome inactivation occurs in female mammals for the purpose of equalisation of dosage of X linked genes between the two sexes. In eutherian mammals, one of the two copies of the X chromosome present in female individuals is silenced. Epigenetic modifications of both DNA and histones have been implicated to play a crucial role in this inactivation phenomenon. In this work, we have employed a novel method published earlier by us, to assess the DNA methylation levels of genes on the inactive X chromosome in the human system. We have used genomic DNA from cells with the following karyotype namely, 47,XXX and 45,X to compare methylation levels from the active and inactive X. We report differential methylation of genes from the active and the inactive X chromosome with higher number of methylated genes being present on the inactive X chromosome. Our work has also led to identification of motifs that show a significant similarity to microRNA sequences which are enriched in methylated regions specific to the inactive X.