Targeted disruption of the human LIT1 locus defines a putative imprinting control element playing an essential role in Beckwith-Wiedemann syndrome

Human chromosome 11p15.5 harbors an intriguing imprinted gene cluster of 1 Mb. This imprinted domain is implicated in a wide variety of malignancies and Beckwith-Wiedemann syndrome (BWS). Recently, several lines of evidence have suggested that the BWS-associated imprinting cluster consists of separate chromosomal domains. We have previously identified LIT1, a paternally expressed antisense RNA within the KvLQT1 locus through a positional screening approach using human monochromosomal hybrids. KvLQT1 encompasses the translocation breakpoint cluster in BWS and patients exhibit frequent loss of maternal methylation at the LIT1 CpG island, implying a regulatory role for the LIT1 locus in coordinate control of the imprinting cluster. Here we generated modified human chromosomes carrying a targeted deletion of the LIT1 CpG island using recombination-proficient chicken DT40 cells. Consistent with the prediction, this mutation abolished LIT1 expression on the paternal chromosome, accompanied by activation of the normally silent paternal alleles of multiple imprinted loci at the centromeric domain including KvLQT1 and p57(KIP2). The deletion had no effect on imprinting of H19 located at the telomeric end of the cluster. Our findings demonstrate that the LIT1 CpG island can act as a negative regulator in cis for coordinate imprinting at the centromeric domain, thereby suggesting a role for the LIT1 locus in a BWS pathway leading to functional inactivation of p57(KIP2). Thus, the targeting and precise modification of human chromosomal alleles using the DT40 cell shuttle system can be used to define regulatory elements that confer long-range control of gene activity within chromosomal domains.     

Conservation of a maternal-specific methylation signal at the human IGF2R locus

The human 1GF2R gene has been reported to be either blallelicallyor very rarely monoallelically expressed, in contrast to thematernally expressed mouse counterpart. We describe here ananalysis of the 5' portion of the human IGF2R gene and showthat it contains a maternally methylated CpG island in the secondintron. A similar maternally methylated intronic element hasbeen proposed to be the imprinting box for the mouse gene andalthough the relevance of this element has yet to be directlydemonstrated, methylation has been reported to be essentialto maintain allele-specific expression of imprinted genes. Allelicexpression analysis of human IGF2R in 70 lymphoblastoid celllines identified only one iine showing monoallelic expression.Thus, in this tissue monoparental methylatlon of the IGF2R genedoes not correlate with allele-specific expression. We alsoconfirm here that the human IGF2R gene is located in an asynchronouslyreplicating chromosomal region, as are all other imprinted genesso far analyzed. The mouse and human IGF2R intronic CpG islandsboth contain numerous large direct repeats that are methylatedfollowing maternal, but not paternal, transmittance. Thus featuresthat attract maternal-specific methylatlon are conserved betweenthe mouse and human genes. Since these intronic CpG islandsshare organizational rather than sequence homology, this suggeststhat secondary DNA structure may play a role in attracting amaternal methylation imprint.     

Beckwith-Wiedemann-like macroglossia and 18q23 haploinsufficiency

Beckwith-Wiedemann syndrome (BWS) is an overgrowth condition with tumor proclivity linked to a genetic imbalance of a complex imprinted region in 11p15.5. A female child with features fitting in with the BWS diagnostic framework and an apparent loss of imprinting (LOI) of the IGF2 gene in 11p15.5 was also reported to have a de novo chromosome 18q segmental deletion (Patient 1), thus pointing at the location of a possible trans-activating regulator element for maintenance of IGF2 imprinting and providing one of the few examples of locus heterogeneity of BWS. A second child with de novo 18q23 deletion and features of macroglossia, naevus flammeus, bilateral inguinal hernia and transient neonatal hypoglycemia, thus also fitting in with the BWS diagnostic framework, is here fully reported (Patient 2). In this child, an analysis of the BWS1 locus precluded any paternal isodisomy and showed a normal imprinting pattern (mono-allelic expression of IGF2 and normal H19 and CDKN1OT1/LIT1 methylation index). In Patients 1 and 2, deletions were shown to overlap, defining a minimal region of haplo-insufficiency of 3.8-5.6 Mb in 18q23. We conclude that this region provides a candidate location for an original macroglossia condition with strong overlap with BWS, but without obvious upstream functional relationship with the BWS1 locus in 11p15.5. Because this minimal region of haplo-insufficiency falls into a common region of deletion in 18q- syndrome, we inferred that this macroglossia condition would follow a recessive pattern of inheritance.     

Tumor development in the Beckwith-Wiedemann syndrome is associated with a variety of constitutional molecular 11p15 alterations including imprinting defects of KCNQ1OT1.

Dysregulation of imprinted genes on human chromosome 11p15 has been implicated in Beckwith-Wiedemann syndrome (BWS), an overgrowth syndrome associated with congenital malformations and tumor predisposition. The molecular basis of BWS is complex and heterogeneous. The syndrome is associated with alterations in two distinct imprinting domains on 11p15: a telomeric domain containing the H19 and IGF2 genes and a centromeric domain including the KCNQ1OT1 and CDKNIC genes. It has been postulated that disorders of imprinting in the telomeric domain are associated with overgrowth and cancer predisposition, whereas those in the centromeric domain involve malformations but not tumor development. In this study of 125 BWS cases, we confirm the association of tumors with constitutional defects in the 11p15 telomeric domain; six of 21 BWS cases with uniparental disomy (UPD) of 11p15 developed tumors and one of three of the rare BWS subtype with hypermethylation of the H19 gene developed tumors. Most importantly, we find that five of 32 individuals with BWS and imprinting defects in the centromeric domain developed embryonal tumors. Furthermore, the type of tumors observed in BWS cases with telomeric defects are different from those seen in BWS cases with defects limited to the centromeric domain. Whereas Wilms' tumor was the most frequent tumor seen in BWS cases with UPD for 11p15 or H19 hypermethylation, none of the embryonal tumors with imprinting defects at KCNQ1OT1 was a Wilms' tumor. This suggests that distinct tumor predisposition profiles result from dysregulation of the telomeric domain versus the centromeric domain and that these imprinting defects activate distinct genetic pathways for embryonal tumorigenesis.     

Rapid detection of methylation change at H19 in human imprinting disorders using methylation-sensitive high-resolution melting

Beckwith Wiedemann syndrome (BWS) and Russell Silver syndrome (RS) are growth disorders with opposing epimutations affecting the H19/IGF2 imprinting center at 11p15.5. Overgrowth and tumor risk in BWS is caused by aberrant expression of the paternally expressed, imprinted IGF2 gene, occurring as a consequence of mosaic hypermethylation within the imprinting center, or to mosaic paternal uniparental disomy (UPD). RS is characterized by severe intrauterine growth retardation (IUGR). A subset of RS cases were recently shown to have mosaic hypomethylation within the H19/IGF2 imprinting center, predicted to silence paternally expressed IGF2 in early development. Molecular diagnosis for BWS and RS involves methylation analysis of the H19 locus, enabling discrimination of allelic methylation patterns. In this study, methylation-sensitive high-resolution melting analysis (MS-HRM) was used to analyze methylation within the intergenic region of the H19 locus. A total of 36 samples comprising normal control (11), BWS (19), and RS (six) DNA were analyzed in a blinded study and scored as hypermethylated, normal, or hypomethylated. Results were compared with those derived by methylation-sensitive Southern blotting using the restriction enzymes Rsa I and Hpa II. A total of 100% concordance was obtained for the Southern blotting and MS-HRM scores. A total of three samples with paternal duplication affecting the H19/IGF2 region were scored as equivocal by both methods; however, 33 out of 36 (92%) the samples were unambiguously scored as being hypermethylated, hypomethylated, or normally methylated using MS-HRM. We conclude that MS-HRM is a rapid, cost-effective, and sensitive method for screening mosaic methylation changes at the H19 locus in BWS and RS.     

Molecular characterization of cytogenetic alterations associated with the Beckwith -- Wiedemann syndrome (BWS) phenotype refines the localization and suggests the gene for BWS is imprinted

To define the region of 11p15 involved in Beckwlth–Wiedemannsyndrome (BWS), we have carried out a molecular genetic analysisof six patients with features of BWS and constitutional cytogeneticabnormalities involving chromosome band 11pl5. Molecular analysisconfirmed the 11p origin of the duplicated material and definedthe smallest region of overlap for such duplications, withinwhich a gene involved in BWS must be located. This region encompassesthe ß-globin gene complex (HBB) to 11pter. In bothof our informative cases, the 11p duplication was found to beof paternal origin. Two BWS associated balanced traitslocatioasof 11p15 were studied to localize the breakpoints on 11p15.Somatic cell hybrids, Southern blotting and fluorescent in situhybridization (FISH) showed that both breakpoints were betweenD11S12 and the insulin-like growth factor 2 (IGF2) gene. A non-BWStranslocation breakpoint was more proximal, between HBB andcalcitonin-A (CALCA). Pedigree analysis showed that both BWSassociated 11p15 translocations were transmitted by phenotypicallynormal mothers. The data are compatible with the hypothesisthat the BWS gene is imprinted and that the maternally inheritedBWS gene is normally suppressed whereas the paternally inheritedallele is active. Thus, duplications of paternal origin wouldlead to increased dosage of the BWS gene. Similarly increaseddosage of the BWS gene could account for the findings in maternallyinherited 11p15 translocations by altering normal imprinting,so that the translocated maternal allele remains active. Thisstudy defines one or more gene loci for BWS on 11p15.5 in thegenomic region from D11512 [GenBank] to IGF2.     

A novel human homologue of yeast nucleosome assembly protein, 65 kb centromeric to the p57KIP2 gene, is biallelically expressed in fetal and adult tissues

Three genes on 11p15.5 are known to undergo genomic imprinting. The gene for insulin-like growth factor II (IGF2) is normally expressed from the paternal allele, while H19 and p57KIP2, a cyclin-dependent kinase inhibitor, are expressed from the maternal allele. Five germline balanced chromosomal rearrangement breakpoints from patients with Beckwith-Wiedemann syndrome (BWS) have been mapped to 11p15.5 between p57KIP2 and IGF2, and all are derived from the maternal chromosome. By positional cloning from BWS breakpoints, we have isolated a gene 100 kb and 65 kb centromeric to the proximal end of this BWS breakpoint cluster and p57KIP2, respectively. This gene is homologous to yeast nucleosome assembly protein (NAP1) and to a human homologue of NAP1, and we designate it hNAP2 (human nucleosome assembly protein 2). hNAP2 diverges in its expression pattern from IGF2, H19, and p57KIP2, and it shows biallelic expression in all tissues tested. Thus, hNAP2 is functionally insulated from the imprinting domain of 11p15.      

Silencing of CDKN1C (p57KIP2) is associated with hypomethylation at KvDMR1 in Beckwith-Wiedemann syndrome

Context: Beckwith–Wiedemann syndrome (BWS) arises by several genetic and epigenetic mechanisms affecting the balance of imprinted gene expression in chromosome 11p15.5. The most frequent alteration associated with BWS is the absence of methylation at the maternal allele of KvDMR1, an intronic CpG island within the KCNQ1 gene. Targeted deletion of KvDMR1 suggests that this locus is an imprinting control region (ICR) that regulates multiple genes in 11p15.5. Cell culture based enhancer blocking assays indicate that KvDMR1 may function as a methylation modulated chromatin insulator and/or silencer.

Objective: To determine the potential consequence of loss of methylation (LOM) at KvDMR1 in the development of BWS.

Methods: The steady state levels of CDKN1C gene expression in fibroblast cells from normal individuals, and from persons with BWS who have LOM at KvDMR1, was determined by both real time quantitative polymerase chain reaction (qPCR) and ribonuclease protection assay (RPA). Methylation of the CDKN1C promoter region was assessed by Southern hybridisation using a methylation sensitive restriction endonuclease.

Results: Both qPCR and RPA clearly demonstrated a marked decrease (86–93%) in the expression level of the CDKN1C gene in cells derived from patients with BWS, who had LOM at KvDMR1. Southern analysis indicated that downregulation of CDKN1C in these patients was not associated with hypermethylation at the presumptive CDKN1C promoter.

Conclusions: An epimutation at KvDMR1, the absence of maternal methylation, causes the aberrant silencing of CDKN1C, some 180 kb away on the maternal chromosome. Similar to mutations at this locus, this silencing may give rise to BWS.

     

Loss of parental-specific methylation at the IGF2 locus in human hepatocellular carcinoma

Significant production of the growth factor IGF2 has been reported in human hepatocellular carcinomas (HCCs). Disturbances associated with changes in methylation at this locus or affecting the 11p15.5 imprinting domain as a whole can be postulated in HCCs. In the present study, the methylation status of differentially methylated regions of the imprinted genes TSSC5, LIT1, and IGF2, which span the 11p15 domain, was analysed in 71 liver tissues from virus-associated and non-virus-associated HCCs compared with six normal liver tissues. Altered methylation of TSSC5 and LIT1 was observed in only 6% and 8% of HCCs, respectively, compared with 89% at the IGF2 locus, suggesting that these loci were not concomitantly dysregulated. These observations suggest that loss of parental-specific methylation at the IGF2 locus may be specifically associated with HCC, whether virus-associated or non-virus-associated, and arising in cirrhotic or non-cirrhotic livers.     

<Emphasis Type="Italic">Calcr</Emphasis>, a brain-specific imprinted mouse calcitonin receptor gene in the imprinted cluster of the proximal region of chromosome 6

Expressed sequence tags (ESTs) in the human chromosome 7q21-q31 region were recently used to screen for allelic expression bias in monochromosomal hybrids retaining a paternal or maternal human chromosome 7. Six candidate imprinted genes were identified. In this study, we investigated parent-of-origin-specific expression profiles of their mouse homologues in the proximal region of chromosome 6. An imprinting analysis, using F1 mice from reciprocal crosses between the B6 and JF strains, demonstrated that the mouse calcitonin receptor gene (Calcr) was expressed preferentially from the maternal allele in brain, whereas no allelic bias was detected in other tissues. Our results indicate that Calcr is imprinted in a tissue-specific manner, with a predominant expression from the maternal allele in the brain. Electronic Publication