Identification of consensus motifs associated with mitotic recombination and clinical characteristics in patients with paternal uniparental isodisomy of chromosome 11.

Uniparental disomy (UPD) is defined as the inheritance of both homologs of a given genomic region from only one parent. The majority of UPD includes an entire chromosome. However, the extent of UPD is sometimes limited to a subchromosomal region (segmental UPD). Mosaic paternal UPD (pUPD) of chromosome 11 is found in approximately 20% of patients with Beckwith-Wiedemann syndrome (BWS) and almost all pUPDs are segmental isodisomic pUPDs resulting from mitotic recombination at an early embryonic stage. A mechanism initiating a DNA double strand break (DSB) within 11p has been predicted to lead to segmental pUPD. However, no consensus motif has yet been found. Here, we analyzed 32 BWS patients with pUPD by SNP array and searched for consensus motifs. We identified four consensus motifs frequently appearing within breakpoint regions of segmental pUPD. These motifs were found in another nine BWS patients with pUPD. In addition, the seven motifs found in meiotic recombination hot spots could not be found within pUPD breakpoint regions. Histone H3 lysine 4 trimethylation, a marker of DSB initiation, could not be found either. These findings suggest that the mechanism(s) of mitotic recombination leading to segmental pUPD are different from that of meiotic recombination. Furthermore, we found seven patients with paternal uniparental diploidy (PUD) mosaicism. Comparison of clinical features between segmental pUPDs and PUDs showed that developmental disability and cardiac abnormalities were additional characteristic features of PUD mosaicism, along with high risk of tumor development. We also found that macroglossia was characteristic of segmental pUPD mosaicism.

Comprehensive and quantitative multilocus methylation analysis reveals the susceptibility of specific imprinted differentially methylated regions to aberrant methylation in Beckwith-Wiedemann syndrome with epimutations.

PURPOSE: Expression of imprinted genes is regulated by DNA methylation of differentially methylated regions (DMRs). Beckwith-Wiedemann syndrome is an imprinting disorder caused by epimutations of DMRs at 11p15.5. To date, multiple methylation defects have been reported in Beckwith-Wiedemann syndrome patients with epimutations; however, limited numbers of DMRs have been analyzed. The susceptibility of DMRs to aberrant methylation, alteration of gene expression due to aberrant methylation, and causative factors for multiple methylation defects remain undetermined. METHODS: Comprehensive methylation analysis with two quantitative methods, matrix-assisted laser desorption/ionization mass spectrometry and bisulfite pyrosequencing, was conducted across 29 DMRs in 54 Beckwith-Wiedemann syndrome patients with epimutations. Allelic expressions of three genes with aberrant methylation were analyzed. All DMRs with aberrant methylation were sequenced. RESULTS: Thirty-four percent of KvDMR1-loss of methylation patients and 30% of H19DMR-gain of methylation patients showed multiple methylation defects. Maternally methylated DMRs were susceptible to aberrant hypomethylation in KvDMR1-loss of methylation patients. Biallelic expression of the genes was associated with aberrant methylation. Cis-acting pathological variations were not found in any aberrantly methylated DMR. CONCLUSION: Maternally methylated DMRs may be vulnerable to DNA demethylation during the preimplantation stage, when hypomethylation of KvDMR1 occurs, and aberrant methylation of DMRs affects imprinted gene expression. Cis-acting variations of the DMRs are not involved in the multiple methylation defects.

Aberrant methylation of H19-DMR acquired after implantation was dissimilar in soma versus placenta of patients with Beckwith-Wiedemann syndrome.

Gain of methylation (GOM) at the H19-differentially methylated region (H19-DMR) is one of several causative alterations in Beckwith-Wiedemann syndrome (BWS), an imprinting-related disorder. In most patients with epigenetic changes at H19-DMR, the timing of and mechanism mediating GOM is unknown. To clarify this, we analyzed methylation at the imprinting control regions of somatic tissues and the placenta from two unrelated, naturally conceived patients with sporadic BWS. Maternal H19-DMR was abnormally and variably hypermethylated in both patients, indicating epigenetic mosaicism. Aberrant methylation levels were consistently lower in placenta than in blood and skin. Mosaic and discordant methylation strongly suggested that aberrant hypermethylation occurred after implantation, when genome-wide de novo methylation normally occurs. We expect aberrant de novo hypermethylation of H19-DMR happens to a greater extent in embryos than in placentas, as this is normally the case for de novo methylation. In addition, of 16 primary imprinted DMRs analyzed, only H19-DMR was aberrantly methylated, except for NNAT DMR in the placental chorangioma of Patient 2. To our knowledge, these are the first data suggesting when GOM of H19-DMR occurs.

Role of DNA methylation and histone H3 lysine 27 methylation in tissue-specific imprinting of mouse Grb10.

Mouse Grb10 is a tissue-specific imprinted gene with promoter-specific expression. In most tissues, Grb10 is expressed exclusively from the major-type promoter of the maternal allele, whereas in the brain, it is expressed predominantly from the brain type promoter of the paternal allele. Such reciprocally imprinted expression in the brain and other tissues is thought to be regulated by DNA methylation and the Polycomb group (PcG) protein Eed. To investigate how DNA methylation and chromatin remodeling by PcG proteins coordinate tissue-specific imprinting of Grb10, we analyzed epigenetic modifications associated with Grb10 expression in cultured brain cells. Reverse transcriptase PCR analysis revealed that the imprinted paternal expression of Grb10 in the brain implied neuron-specific and developmental stage-specific expression from the paternal brain type promoter, whereas in glial cells and fibroblasts, Grb10 was reciprocally expressed from the maternal major-type promoter. The cell-specific imprinted expression was not directly related to allele-specific DNA methylation in the promoters because the major-type promoter remained biallelically hypomethylated regardless of its activity, whereas gametic DNA methylation in the brain type promoter was maintained during differentiation. Histone modification analysis showed that allelic methylation of histone H3 lysine 4 and H3 lysine 9 were associated with gametic DNA methylation in the brain type promoter, whereas that of H3 lysine 27 regulated by the Eed PcG complex was detected in the paternal major-type promoter, corresponding to its allele-specific silencing. Here, we propose a molecular model that gametic DNA methylation and chromatin remodeling by PcG proteins during cell differentiation cause tissue-specific imprinting in embryonic tissues.

MeCP2 knockdown reveals DNA methylation-independent gene repression of target genes in living cells and a bias in the cellular location of target gene products.

MeCP2, a methyl-CpG binding domain (MBD) protein, is known to bind to methylated CpG sites via a conserved MBD, leading to transcriptional repression. However, studies in cell-free system for gene repression and MeCP2 binding have suggested that DNA methylation-independent repression also occurs in living cells. It has been difficult to characterize the target genes of MeCP2 because a limited number have been identified to date. In this context, we screened for MeCP2 target genes using knockdown (KD) experiments combined with microarray gene expression analyses. Of the 49 genes that showed a more than three-fold increase in expression in two independent KD experiments conducted with different siRNA sets, unexpectedly, half (24 genes) did not contain promoter CpG islands (CGIs). Of seven selected genes that did contain CGIs, only two were methylated at the CGI, bound MeCP2 before KD, and reduced MeCP2 after KD. For three, MeCP2 was observed to bind to the unmethylated CGI before KD, and for one MeCP2 was reduced after KD. Another two genes neither had DNA methylation nor bound MeCP2 before KD. Gene ontology analysis suggested that MeCP2 represses a certain group of genes. These results suggest that in addition to the canonical gene repression function, MeCP2 can repress gene expression by binding to unmethylated DNA in particular genes in living cells.

Japanese and North American/European patients with Beckwith-Wiedemann syndrome have different frequencies of some epigenetic and genetic alterations.

Beckwith-Wiedemann syndrome (BWS) is an imprinting-related human disease. The frequencies of causative alterations such as loss of methylation (LOM) of KvDMR1, hypermethylation of H19-DMR, paternal uniparental disomy, CDKN1C gene mutation, and chromosome abnormality have been described for North American and European patients, but the corresponding frequencies in Japanese patients have not been measured to date. Analysis of 47 Japanese cases of BWS revealed a significantly lower frequency of H19-DMR hypermethylation and a higher frequency of chromosome abnormality than in North American and European patients. These results suggest that susceptibility to epigenetic and genetic alterations differs between the two groups.

Retinoic acid receptor beta2 is epigenetically silenced either by DNA methylation or repressive histone modifications at the promoter in cervical cancer cells.

To elucidate the silencing mechanism of retinoic acid receptor beta2 (RAR beta2) in cervical carcinogenesis, we investigated RAR beta2 expression and the status of both DNA methylation and histone modifications at the promoter in cervical cancer cell lines. RAR beta2 was frequently repressed in cancer cell lines and in primary cancers of the cervix. Although the majority of RAR beta2-negative cancers had methylated promoter, RAR beta2 was repressed with hypomethylated promoter in a substantial fraction of the cancers. The RAR beta2-negative cells with hypomethylated promoters showed a repressive histone modification pattern at the promoter. RAR beta2 was reactivated by a histone deacetylase inhibitor, accompanied by formation of active histone modifications. The repressive modification was also observed in cells repressed with hypermethylated promoter, but RAR beta2 was reactivated only by DNA demethylating agent and not by histone deacetylase inhibitor. Our results suggest that RAR beta2 is silenced by either of the two key epigenetic pathways, DNA methylation or repressive histone modifications, depending on the individual cancer cells.

The mouse Murr1 gene is imprinted in the adult brain, presumably due to transcriptional interference by the antisense-oriented U2af1-rs1 gene.

The mouse Murr1 gene contains an imprinted gene, U2af1-rs1, in its first intron. U2af1-rs1 shows paternal allele-specific expression and is transcribed in the direction opposite to that of the Murr1 gene. In contrast to a previous report of biallelic expression of Murr1 in neonatal mice, we have found that the maternal allele is expressed predominantly in the adult brain and also preferentially in other adult tissues. This maternal-predominant expression is not observed in embryonic and neonatal brains. In situ hybridization experiments that used the adult brain indicated that Murr1 gene was maternally expressed in neuronal cells in all regions of the brain. We analyzed the developmental change in the expression levels of both Murr1 and U2af1-rs1 in the brain and liver, and we propose that the maternal-predominant expression of Murr1 results from transcriptional interference of the gene by U2af1-rs1 through the Murr1 promoter region.

Comparative analyses of genomic imprinting and CpG island-methylation in mouse Murr1 and human MURR1 loci revealed a putative imprinting control region in mice.

Human MURR1 is an orthologue of mouse Murr1 gene, which was previously reported to be imprinted only in adult brain with a maternal allele-predominant expression and to contain another imprinted gene, U2af1-rs1, in the first intron. Human MURR1 was found not to harbor the U2af1-rs1 orthologue and to be expressed biallelically in tissues, including adult brain. Three genes identified around Murr1 and their orthologues around MURR1 were expressed biallelically. These findings suggest that the mouse imprinting locus is limited to a small region and the introduction of U2af1-rs1 in mouse causes the imprinting of this locus. The CpG island (CGI) at U2af1-rs1 with maternal methylation was the only differentially methylated region among CGIs found in these loci. Detailed methylation analyses of the U2af1-rs1 CGI in germ cells led to identification of a region with oocyte-specific methylation. These results suggest that this region is the imprinting control region of the Murr1/U2af1-rs1 locus in mouse.

A comprehensive analysis of allelic methylation status of CpG islands on human chromosome 11q: comparison with chromosome 21q.

It was generally believed that autosomal CpG islands (CGIs) escape methylation. However, our comprehensive analysis of allelic methylation status of 149 CGIs on human chromosome 21q revealed that a sizable fraction of them are methylated on both alleles even in normal blood cells. Here, we performed a similar analysis of 656 CGIs on chromosome 11q, which is gene-rich in contrast with 21q. The results indicate that 11q contains less methylated CGIs, especially those with tandem repeats and those in the coding or 3'-untranslated regions (UTRs), than 21q. Thus, methylation status of CGIs may substantially differ from one chromosome to another.

Gene silencing in phenomena related to DNA repair.

DNA methylation is essential for embryonic development and important for transcriptional repression, as observed in several biological phenomena. These include genomic imprinting, X-inactivation and carcinogenesis. The basic mechanism by which DNA methylation silences transcription is generally understood, but there is still much to be learned about how DNA methyltransferase is targeted to a specific region of the gene. Silencing by DNA methylation occurs at an early stage of carcinogenesis, when the DNA repair genes, MGMT and hMLH1, are frequently inactivated, resulting in mutations in key cancer-related genes in cells. Mice defective in Mgmt and/or Mlh1 gave clear evidence of the significant roles of these proteins in carcinogenesis. Recently, it has been demonstrated that DNA methylation is linked to histone methylation in fungi and plants, although it remains unknown whether this mechanism occurs in mammalian systems.

Silencing of imprinted CDKN1C gene expression is associated with loss of CpG and histone H3 lysine 9 methylation at DMR-LIT1 in esophageal cancer.

The putative tumor suppressor CDKN1C is an imprinted gene at 11p15.5, a well-known imprinted region often deleted in tumors. The absence of somatic mutations and the frequent diminished expression in tumors would suggest that CDKN1C expression is regulated epigenetically. It has been, however, controversial whether the diminution is caused by imprinting disruption of the CDKN1C/LIT1 domain or by promoter hypermethylation of CDKN1C itself. To clarify this, we investigated the CpG methylation index of the CDKN1C promoter and the differentially methylated region of the LIT1 CpG island (differentially methylated region (DMR)-LIT1), an imprinting control region of the domain, and CDKN1C expression in esophageal cancer cell lines. CDKN1C expression was diminished in 10 of 17 lines and statistically correlated with the loss of methylation at DMR-LIT1 in all but three. However, there was no statistical correlation between CDKN1C promoter MI and CDKN1C expression. Furthermore, loss of CpG methylation was associated with loss of histone H3 lysine 9 (H3K9) methylation at DMR-LIT1. Histone modifications at CDKN1C promoter were not correlated with CDKN1C expression. The data suggested that the diminished CDKN1C expression is associated with the loss of methylation of CpG and H3K9 at DMR-LIT1, not by its own promoter CpG methylation, and is involved in esophageal cancer, implying that DMR-LIT1 epigenetically regulates CDKN1C expression not through histone modifications at CDKN1C promoter, but through that of DMR-LIT1.

Silencing effect of CpG island hypermethylation and histone modifications on O6-methylguanine-DNA methyltransferase (MGMT) gene expression in human cancer.

O6-methylguanine-DNA methyltransferase (MGMT) repairs the cytotoxic and mutagenic O6-alkylguanine produced by alkylating agents such as chemotherapeutic agents and mutagens. Recent studies have shown that in a subset of tumors, MGMT expression is inversely linked to hypermethylation of the CpG island in the promoter region; however, how the epigenetic silencing mechanism works, as it relates to hypermethylation, was still unclear. To understand the mechanism, we examined the detailed methylation status of the whole island with bisulfite-sequencing in 19 MGMT non-expressed cancer cell lines. We found two highly methylated regions in the island. One was upstream of exon 1, including minimal promoter, and the other was downstream, including enhancer. Reporter gene assay showed that methylation of both the upstream and downstream regions suppressed luciferase activity drastically. Chromatin immunoprecipitation assay revealed that histone H3 lysine 9 was hypermethylated throughout the island in the MGMT negative line, whereas acetylation on H3 and H4 and methylation on H3 lysine 4 were at significantly high levels outside the minimal promoter in the MGMT-expressed line. Furthermore, MeCP2 preferentially bound to the CpG-methylated island in the MGMT negative line. Given these results, we propose a model for gene silencing of MGMT that is dependent on the epigenetic state in cancer.

The essential role of histone H3 Lys9 di-methylation and MeCP2 binding in MGMT silencing with poor DNA methylation of the promoter CpG island.

Silencing of the O (6)-methylguanine-DNA methyltransferase (MGMT) gene, a key to DNA repair, is involved in carcinogenesis. Recent studies have focused on DNA hypermethylation of the promoter CpG island. However, cases showing silencing with DNA hypomethylation certainly exist, and the mechanism involved is not elucidated. To clarify this mechanism, we examined the dynamics of DNA methylation, histone acetylation, histone methylation, and binding of methyl-CpG binding proteins at the MGMT promoter region using four MGMT negative cell lines with various extents of DNA methylation. Histone H3K9 di-methylation (H3me2K9), not tri-methylation, and MeCP2 binding were commonly seen in all MGMT negative cell lines regardless of DNA methylation status. 5Aza-dC, but not TSA, restored gene expression, accompanied by a decrease in H3me2K9 and MeCP2 binding. In SaOS2 cells with the most hypomethylated CpG island, 5Aza-dC decreased H3me2K9 and MeCP2 binding with no effect on DNA methylation or histone acetylation. H3me2K9 and DNA methylation were restricted to in and around the island, indicating that epigenetic modification at the promoter CpG island is critical. We conclude that H3me2K9 and MeCP2 binding are common and more essential for MGMT silencing than DNA hypermethylation or histone deacetylation. The epigenetic mechanism leading to silent heterochromatin at the promoter CpG island may be the same in different types of cancer irrespective of the extent of DNA methylation.

A 210-kb segment of tandem repeats and retroelements located between imprinted subdomains of mouse distal chromosome 7.

Mammalian genes subject to genomic imprinting often form clusters and are regulated by long-range mechanisms. The distal imprinted domain of mouse chromosome 7 is orthologous to the Beckwith-Wiedemann syndrome domain in human chromosome 11p15.5 and contains at least 13 imprinted genes. This domain consists of two subdomains, which are respectively regulated by an imprinting center. We here report the finished-quality sequence of a 0.6-Mb region encompassing the more centromeric subdomain. The sequence contains four imprinted genes (Ascl2/Mash2, Ins2, Igf2 and H19) and reveals previously unidentified CpG islands and tandem repeats, which may be features of imprinted genes. Most interestingly, a unique 210-kb segment consisting almost exclusively of tandem repeats and retroelements is identified. This segment, located between Th and Ins2, has features of heterochromatin-forming DNA and is highly methylated at CpG sites. The segment exhibits asynchronous replication on the parental chromosomes, a feature of the imprinted domains. We propose that this repeat segment could serve either as a boundary between the two subdomains or as a target for epigenetic chromatin modifications that regulate imprinting.

Significant reduction of WT1 gene expression, possibly due to epigenetic alteration in Wilms' tumor.

WT1 at 11p13 is a tumor suppressor gene, an aberration of which causes Wilms' tumor (WT). Since WT1 expression is reduced in a certain proportion of WTs and its mutation is found only in 10-20% of WTs, we examined WT1 gene silencing due to epigenetic alteration in a total of 22 WTs. WT1 expression was significantly reduced in half of WTs without any mutation in the WT1 gene itself, suggesting that the reduction of expression was possibly epigenetic. We found promoter hypermethylation in one WT with loss of heterozygosity (LOH) and showed that promoter methylation reduced reporter gene activity by a reporter assay. These data suggested that methylation was an epigenetic mechanism leading to WT1 silencing and that the expression-reduced allele by hypermethylation combined with LOH was consistent with the revised two-hit model. In addition, as the beta-catenin mutation is frequently associated with the WT1 mutation, the association of WT1 silencing with the beta-catenin mutation was also investigated. beta-catenin mutated in only one WT without WT1 silencing, suggesting that the beta-catenin mutation was not associated with the reduction of WT1 expression.

Identification of a novel isoform of Murr1 transcript, U2mu, which is transcribed from the portions of two closely located but oppositely oriented genes.

Here we identified a novel transcript in mouse that is transcribed from the portions of two independent genes, U2af1-rs1 and Murr1, and we designated it U2mu. The U2af1-rs1 gene is located in the intron and transcribed in the opposite direction from the Murr1 gene on the proximal region of mouse chromosome 11. The U2mu cDNA sequence is derived from three genomic regions--an intron of the Murr1 gene, an antisense sequence of U2af1-rs1 gene, and the last exon of Murr1 gene--in the order of 5' to 3'. The U2mu transcript of 2.8 kb is expressed ubiquitously in adult mice. It is transcribed biallelically, and is not imprinted, in neonatal and adult mice.

Antisense transcription occurs at the promoter of a mouse imprinted gene, commd1, on the repressed paternal allele.

The Commd1 gene is imprinted in the adult mouse brain and is predominantly expressed from the maternal allele. A paternally expressing imprinted gene, U2af1-rs1, resides in the first intron of Commd1 in an antisense orientation. We found that RNA polymerase II phosphorylated at serine 2 of the carboxyl-terminal domain repeats, a marker of transcription elongation, is enriched on the paternal allele than on the maternal allele in the Commd1 promoter. The Commd1 promoter harbours no allelic differences in DNA methylation and histone modifications. These results strongly suggested that imprinting of Commd1 is generated by interference with paternal Commd1 transcription by the oppositely directed U2af1-rs1 transcription.

Expression profile of LIT1/KCNQ1OT1 and epigenetic status at the KvDMR1 in colorectal cancers.

The human chromosome region 11p15.5 contains a number of maternally and paternally imprinted genes, and the LIT1/KCNQ1OT1 locus acts as an imprinting center in the proximal domain of 11p15.5. Loss of imprinting (LOI) of LIT1 and its correlation with methylation status at a differentially methylated region, the KvDMR1, were investigated in 69 colorectal cancer tissue specimens. LIT1 expression profiles were also examined by RNA-fluorescence in situ hybridization in 13 colorectal cancer cell lines. In 69 colorectal cancer tissue specimens, LOI of LIT1 was observed in nine of the 17 (53%) informative cases. Moreover, LOI of LIT1 was only observed in tumor samples. In the cell lines, methylation status at the KvDMR1 correlated well with LIT1 expression profiles. Loss of expression of LIT1 also correlated with enrichment of H3 lysine 9 (H3-K9) dimethylation and reduction of H3 lysine 4 (H3-K4) dimethylation. Thus, LIT1 expression appears to be controlled by epigenetic modifications at the KvDMR1, although CDKN1C expression, which is considered to be controlled by LIT1, was not associated with epigenetic status at the KvDMR1 in some colorectal cancer cell lines. Therefore, these findings suggest that LOI of LIT1 via epigenetic disruption plays an important role in colorectal carcinogenesis, but it is not necessarily associated with CDKN1C expression.

Primary palmar hyperhidrosis locus maps to 14q11.2-q13.

Primary palmar hyperhidrosis (PPH) is a unique disorder of unknown cause. It is characterized by excessive perspiration of the eccrine sweat gland in the palm, sole, and the axilla. It is presumed that PPH results from overactivation of the cholinergic sympathetic nerve or dysfunction of the autonomic nervous system. There have been no genetic studies on the disease. We performed a linkage analysis of 11 families including 42 affected and 40 unaffected members using genome-wide DNA polymorphic markers to identify the disease locus. Diagnosis of their PPH was made by direct inspection, interviewing and measurement of the sweating rate with perspirometer. Consequently, from data of three of the 11 families examined, the combined maximum two-point LOD scores of 3.08 and 3.16 (recombination fraction = 0) were obtained at the D14S283 and D14S264 loci, respectively, on chromosome 14q11.2-q13, under an assumption that two liability conditions depend on age. These regions were ruled out in eight other families. Haplotype analysis of the three families supported that one of the PPH locus is assigned at minimum to about a 6-cM interval between D14S1070 and D14S990 and at maximum to about a 30-cM interval between D14S1070 and D14S70. This is the first report of systemic mapping of the PPH locus.