Epimutation of the telomeric imprinting center region on chromosome 11p15 in Silver-Russell syndrome.

Silver-Russell syndrome (SRS, OMIM 180860) is a congenital disorder characterized by severe intrauterine and postnatal growth retardation, dysmorphic facial features and body asymmetry. SRS is genetically heterogenous with maternal uniparental disomy with respect to chromosome 7 occurring in approximately 10% of affected individuals. Given the crucial role of the 11p15 imprinted region in the control of fetal growth, we hypothesized that dysregulation of genes at 11p15 might be involved in syndromic intrauterine growth retardation. We identified an epimutation (demethylation) in the telomeric imprinting center region ICR1 of the 11p15 region in several individuals with clinically typical SRS. This epigenetic defect is associated with, and probably responsible for, relaxation of imprinting and biallelic expression of H19 and downregulation of IGF2. These findings provide new insight into the pathogenesis of SRS and strongly suggest that the 11p15 imprinted region, in addition to those of 7p11.2-p13 and 7q31-qter, is involved in SRS.

Allele-specific methylated multiplex real-time quantitative PCR (ASMM RTQ-PCR), a powerful method for diagnosing loss of imprinting of the 11p15 region in Russell Silver and Beckwith Wiedemann syndromes.

Many human syndromes involve a loss of imprinting (LOI) due to a loss (LOM) or a gain of DNA methylation (GOM). Most LOI occur as mosaics and can therefore be difficult to detect with conventional methods. The human imprinted 11p15 region is crucial for the control of fetal growth, and LOI at this locus is associated with two clinical disorders with opposite phenotypes: Beckwith-Wiedemann syndrome (BWS), characterized by fetal overgrowth and a high risk of tumors, and Russell-Silver syndrome (RSS), characterized by intrauterine and postnatal growth restriction. Until recently, we have been using Southern blotting for the diagnosis of RSS and BWS. We describe here a powerful quantitative technique, allele-specific methylated multiplex real-time quantitative PCR (ASMM RTQ-PCR), for the diagnosis of these two complex disorders. We first checked the specificity of the probes and primers used for ASMM RTQ-PCR. We then carried out statistical validation for this method, on both retrospective and prospective populations of patients. This analysis demonstrated that ASMM RTQ-PCR is more sensitive than Southern blotting for detecting low degree of LOI. Moreover, ASMM RTQ-PCR is a very rapid, reliable, simple, safe, and cost effective method.

Multilocus methylation analysis in a large cohort of 11p15-related foetal growth disorders (Russell Silver and Beckwith Wiedemann syndromes) reveals simultaneous loss of methylation at paternal and maternal imprinted loci.

Genomic imprinting plays an important role in mammalian development. Loss of imprinting (LOI) through loss (LOM) or gain (GOM) of methylation is involved in many human disorders and cancers. The imprinted 11p15 region is crucial for the control of foetal growth and LOI at this locus is implicated in two clinically opposite disorders: Beckwith Wiedemann syndrome (BWS) with foetal overgrowth associated with an enhanced tumour risk and Russell-Silver syndrome (RSS) with intrauterine and postnatal growth restriction. So far, only a few studies have assessed multilocus LOM in human imprinting diseases. To investigate multilocus LOI syndrome, we studied the methylation status of five maternally and two paternally methylated loci in a large series (n = 167) of patients with 11p15-related foetal growth disorders. We found that 9.5% of RSS and 24% of BWS patients showed multilocus LOM at regions other than ICR1 and ICR2 11p15, respectively. Moreover, over two third of multilocus LOM RSS patients also had LOM at a second paternally methylated locus, DLK1/GTL2 IG-DMR. No additional clinical features due to LOM of other loci were found suggesting an (epi)dominant effect of the 11p15 LOM on the clinical phenotype for this series of patients. Surprisingly, four patients displayed LOM at both ICR1 and ICR2 11p15. Three of them had a RSS and one a BWS phenotype. Our results show for the first time that multilocus LOM can also concern RSS patients. Moreover, LOM can involve both paternally and maternally methylated loci in the same patient.

11p15 imprinting center region 1 loss of methylation is a common and specific cause of typical Russell-Silver syndrome: clinical scoring system and epigenetic-phenotypic correlations.

CONTEXT: Russell-Silver syndrome (RSS), characterized by intrauterine and postnatal growth retardation, dysmorphic features, and frequent body asymmetry, spares cranial growth. Maternal uniparental disomy for chromosome 7 (mUPD7) is found in 5-10% of cases. We identified loss of methylation (LOM) of 11p15 Imprinting Center Region 1 (ICR1) domain (including IGF-II) as a mechanism leading to RSS. OBJECTIVE: The aim was to screen for 11p15 epimutation and mUPD7 in RSS and non-RSS small-for-gestational-age (SGA) patients and identify epigenetic-phenotypic correlations. STUDIED POPULATION AND METHODS: A total of 127 SGA patients were analyzed. Clinical diagnosis of RSS was established when the criterion of being SGA was associated with at least three of five criteria: postnatal growth retardation, relative macrocephaly, prominent forehead, body asymmetry, and feeding difficulties. Serum IGF-II was evaluated for 82 patients. RESULTS: Of the 127 SGA patients, 58 were diagnosed with RSS; 37 of these (63.8%) displayed partial LOM of the 11p15 ICR1 domain, and three (5.2%) had mUPD7. No molecular abnormalities were found in the non-RSS SGA group (n = 69). Birth weight, birth length, and postnatal body mass index (BMI) were lower in the abnormal 11p15 RSS group (ab-ICR1-RSS) than in the normal 11p15 RSS group [-3.4 vs.-2.6 SD score (SDS), -4.4 vs.-3.4 SDS, and -2.5 vs.-1.6 SDS, respectively; P < 0.05]. Among RSS patients, prominent forehead, relative macrocephaly, body asymmetry, and low BMI were significantly associated with ICR1 LOM. All ab-ICR1-RSS patients had at least four of five criteria of the scoring system. Postnatal IGF-II levels were within normal values. CONCLUSION: The 11p15 ICR1 epimutation is a major, specific cause of RSS exhibiting failure to thrive. We propose a clinical scoring system (including a BMI < -2 SDS), highly predictive of 11p15 ICR1 LOM, for the diagnosis of RSS.

Implementation of a Reliable Next-Generation Sequencing Strategy for Molecular Diagnosis of Dystrophinopathies.

Diagnosis of dystrophinopathies needs to combine several techniques for detecting copy number variations (CNVs; two-thirds of mutations) and single nucleotide variations (SNVs). We participated in the design of an amplicon-based PCR kit (Multiplicom) for sequencing with a GS-Junior instrument (Roche) and later with a MiSeq instrument (Illumina). We compared two different software programs, MiSeq Reporter (Illumina) and SeqNext (JSI Medical Systems) for data analyses. Testing of six patient DNA samples carrying 72 SNVs in the DMD gene showed an experimental sensitivity of 91.7% with MiSeq Reporter, 98.6% with SeqNext, and >99.9% with both, demonstrating the need to use two different software programs. Analytical specificity was >98%. Fifty-eight additional patient DNAs were analyzed, and 25 deleterious mutations were identified, without false-negative results. We also tested the possibility for our protocol to identify CNVs. We performed additional next-generation sequencing experiments on 50 DNAs and identified 28 CNVs, all confirmed by multiple ligation probe amplification. Statistical analyses on amplicons without CNV (n = 3797), amplicons with heterozygous deletions (n = 51) or duplications (n = 191), and with hemizygous duplications (n = 63) showed a sensitivity and specificity of >99.9%. We implemented a strategy to simultaneously detect SNVs and CNVs in the DMD gene with one comprehensive technique, allowing considerable reduction of time and cost burden for diagnosis of dystrophinopathies.