Distinguishing the 4qA and 4qB variants is essential for the diagnosis of facioscapulohumeral muscular dystrophy in the Chinese population

Facioscapulohumeral muscular dystrophy (FSHD) is the third most common inherited muscular dystrophy with markedly clinical variability and complex genetic cause. Several reports pertaining to the Caucasian population have confirmed that there are 4qA and 4qB variants of the 4qter subtelomere, and FSHD is uniquely associated with the 4qA variant. However, few data relevant to the Chinese population have been published. In present paper, detailed clinical and genetic re-evaluations were performed in members of four special families who had been initially diagnosed as atypical or asymptomatic FSHD based only on the D4Z4 repeat length analysis. The FSHD-sized D4Z4 repeats in the probands from families 1, 2 and 3 were identified as 4qB variants. These patients were further confirmed as limb-girdle muscular dystrophy (LGMD2) or myotonic dystrophy (DM1) by molecular analyses. Specifically, we identified a 4qB variant on chromosome 10 in the healthy members of the fourth FSHD family with complex D4Z4 rearrangements of two exchanged repeat arrays. For the first time, we demonstrated in the Chinese population that D4Z4 contractions on the 4qB variant do not cause FSHD and 4qB variant on chromosome 10 might also represent intermediate structures in the transition from 4q to 10q. Furthermore, our results emphasize that D4Z4 repeat length analysis alone is not sufficient for the diagnosis of FSHD, especially when used as an exclusion criterion. This analysis should be accompanied by 4qA/4qB variant determination and integrated chromosome assignments, especially in patients with obscure and unclassified myopathies similar to atypical forms of FSHD.     

Common epigenetic changes of D4Z4 in contraction‐dependent and contraction‐independent FSHD

Facioscapulohumeral muscular dystrophy (FSHD), caused by partial deletion of the D4Z4 macrosatellite repeat on chromosome 4q, has a complex genetic and epigenetic etiology. To develop FSHD, D4Z4 contraction needs to occur on a specific genetic background. Only contractions associated with the 4qA161 haplotype cause FSHD. In addition, contraction of the D4Z4 repeat in FSHD patients is associated with significant D4Z4 hypomethylation. To date, however, the methylation status of contracted repeats on nonpathogenic haplotypes has not been studied. We have performed a detailed methylation study of the D4Z4 repeat on chromosome 4q and on a highly homologous repeat on chromosome 10q. We show that patients with a D4Z4 deletion (FSHD1) have D4Z4‐restricted hypomethylation. Importantly, controls with a D4Z4 contraction on a nonpathogenic chromosome 4q haplotype or on chromosome 10q also demonstrate hypomethylation. In 15 FSHD families without D4Z4 contractions but with at least one 4qA161 haplotype (FSHD2), we observed D4Z4‐restricted hypomethylation on chromosomes 4q and 10q. This finding implies that a genetic defect resulting in D4Z4 hypomethylation underlies FSHD2. In conclusion, we describe two ways to develop FSHD: (1) contraction‐dependent or (2) contraction‐independent D4Z4 hypomethylation on the 4qA161 subtelomere. Hum Mutat 30:1–11, 2009. © 2009 Wiley‐Liss, Inc.     

汉族人群4q亚端粒区等位片段4qA和4qB的结构特征

目的研究中国人4q35亚端粒区等位片段4qA和4qB的结构特征,探讨其与面肩肱型肌营养不良症（facioscapulohumeral muscular dystrophy,FSHD）的内在联系。方法研究对象包括80名无血缘关系的健康成年人。低熔点胶包埋法抽提基因组DNA。同一样品分别进行EcoRⅠ酶切、EcoRⅠ/BlnⅠ双酶切和HindⅢ酶切,脉冲电场电泳分离,p13E-11、4qA和4qB探针Southern印迹,计算4qA/4qB的频率、基因型频率及各型EcoRⅠ片段的长度,SPSS13.0统计软件分析数据。结果4q亚端粒区4qA的频率（46.9%）与4qB（53.1%）基本相等（χ2=1.250,P〉0.05）,4qA/4qB杂合型频率明显高于纯合型频率（P〈0.05）,4qA型和4qB型EcoRⅠ片段长度分别为（115.8±11.9）kb和（98.3±8.6）kb,两者差异有统计学意义（t=23.04,P〈0.001）。8.8%（7/80）的个体检测到易位构型。2名个体出现4qB型短EcoRⅠ片段。结论正常中国人4q亚端粒区4qA和4qB的频率基本相等,杂合型频率明显高于纯合型频率。4qB型D4Z4缺失不致病。4qA和4qB型EcoRⅠ片段具有动态性变化特征。     

Monosomy of distal 4q does not cause facioscapulohumeral muscular dystrophy.

Facioscapulohumeral muscular dystrophy (FSHD) is a hereditary neuromuscular disorder transmitted in an autosomal dominant fashion. FSHD has been located by linkage analysis in the most distal part of chromosome 4q. The disease is associated with deletions within a 3.2 kb tandem repeat sequence, D4Z4. We have studied a family in which an abnormal chromosome 4 segregates through three generations in phenotypically normal subjects. This chromosome is the derivative of a (4;D or G) (q35;p12) translocation. Molecular analysis of the region 4q35 showed the absence of the segment ranging from the telomere to locus D4F104S1. Probe p13E-11 (D4F104S1), which detects polymorphic EcoRI fragments containing D4Z4, in Southern blot analysis showed only one allele in the carriers of the abnormal chromosome 4. Probe p13E-11 EcoRI fragments are contained in the subtelomeric region of 4q and their rearrangements associated with FSHD suggested that the gene responsible for the muscular dystrophy could be subject to a position effect variegation (PEV) because of its proximity to subtelomeric heterochromatin. The absence of the 4q telomeric region in our phenotypically normal cases indicates that haploinsufficiency of the region containing D4Z4 does not cause FSHD.     

Methylation of the FSHD syndrome-linked subtelomeric repeat in normal and FSHD cell cultures and tissues.

Facioscapulohumeral muscular dystrophy (FSHD) has an unusual molecular etiology. In a putatively heterochromatic subtelomeric region of each chromosome 4 homologue (4q35), unaffected individuals have 11 to about 95 tandem copies of a complex 3.3-kb repeat (D4Z4). Most FSHD patients have less than 10 copies at one allelic 4q35. This has been proposed to lead to the loss of heterochromatinization and, thereby, inappropriate gene expression by position effects, explaining the dominant nature of FSHD and the role of a decreased number of copies of D4Z4 at 4q35 but not at 10q26. Consistent with the proposed heterochromatinization of this repeat, by Southern blot analysis, we found that SmaI, MluI, SacII, and EagI sites in D4Z4 are highly methylated in normal and FSHD cell lines and somatic tissues, including skeletal muscle. Like repeated DNA sequences in the juxtacentromeric heterochromatin of chromosomes 1, 9, and 16, D4Z4 was hypomethylated at numerous CpGs in sperm and in cell lines from patients with an unrelated DNA methyltransferase deficiency syndrome (ICF; immunodeficiency, centromeric region instability, facial anomalies) in contrast to its hypermethylation in non-ICF postnatal somatic tissues. Our data on FSHD samples suggest that the disease-associated 4q35 D4Z4 repeats, which constitute a small percentage of the total D4Z4 repeats, are not generally hypomethylated relative to the other repeats of this sequence. However, in individuals not affected with FSHD, the hypermethylation of tandem, high-copy-number D4Z4 repeats might help stabilize heterochromatinization at allelic 4q35 regions just as hypermethylation elsewhere in the genome has been linked to chromatin compaction.     

Inflammatory facioscapulohumeral muscular dystrophy type 2 in 18p deletion syndrome

Facioscapulohumeral muscular dystrophy (FSHD) has been shown to be related to genetic and epigenetic derepression of DUX4 (mapping to chromosome 4), a gene located within a repeat array of D4Z4 sequences of polymorphic length. FSHD type 1 (FSHD1) is associated with pathogenic D4Z4 repeat array contraction, while FSHD type 2 (FSHD2) is associated with SMCHD1 variants (a chromatin modifier gene that maps to the short arm of chromosome 18). Both FSHD types require permissive polyadenylation signal (4qA) downstream of the D4Z4 array.     

Inter- and intrachromosomal sub-telomeric rearrangements on 4q35: implications for facioscapulohumeral muscular dystrophy (FSHD) aetiology and diagnosis

The autosomal dominant myopathy facioscapulohumeral muscular dystrophy (FSHD) is causally related to a short Eco RI fragment detected by probe p13E-11. This remnant fragment is the result of a deletion of an integral number of tandemly arrayed 3.3 kb repeat units (D4Z4) on 4q35. Despite intensive efforts, no transcribed sequences have been identified within this array. Previously, we have shown that these repeats on 4q35 have been exchanged for a similar highly homologous repeat locus on 10q26 in 20% of the population and that a short chromosome 10-like array on 4q35 also results in FSHD. Here, we describe the hybrid structure of some of these repeat arrays, reflecting additional sub-telomeric instability. In three healthy individuals carrying a 4-like repeat on chromosome 10 or vice versa, one repeat array was shown to consist of hybrid clusters of 4-derived and 10-derived repeat units. Moreover, employing pulsed field gel electrophoresis analysis, we identified two unrelated individuals carrying deletions of a chromosomal segment (p13E-11) proximal to the repeat locus. These deletions were not associated with FSHD. In one of these cases, however, an expansion of the deletion into the repeat array was observed in one of his children suffering from FSHD. These data provide additional evidence for instability of this sub-telomeric region and suggests that the length of the repeat, and not its intrinsic properties, is crucial to FSHD. Moreover, they are in agreement with the hypothesis that FSHD is caused by a position effect in which the repeat structure influences the expression of genes nearby. Therefore, the region deleted proximal to the repeat locus in healthy individuals can be instrumental to refine the critical region for FSHD1.      

Molecular combing reveals complex 4q35 rearrangements in Facioscapulohumeral dystrophy

Facioscapulohumeral dystrophy (FSHD), one of the most common hereditary neuromuscular disorders, is associated with a complex combination of genetic variations at the subtelomeric 4q35 locus. As molecular diagnosis relying on Southern blot (SB) might be challenging in some cases, molecular combing (MC) was recently developed as an additional technique for FSHD diagnosis and exploration of the genomic organization of the 4q35 and 10q26 regions. In complement to the usual SB, we applied MC in a large cohort of 586 individuals with clinical FSHD. In 332 subjects, the two 4q alleles were normal in size, allowing exclusion of FSHD1 while we confirmed FSHD1 in 230 patients. In 14 patients from 10 families, we identified a recurrent complex heterozygous rearrangement at 4q35 consisting of a duplication of the D4Z4 array and a 4qA haplotype, irresolvable by the SB technique. In five families, we further identified variations in the SMCHD1 gene. Impact of the different mutations was tested using a minigene assay and we analyzed DNA methylation after sodium bisulfite modification and NGS sequencing. We discuss the involvement of this rearrangement in FSHD since all mutations in SMCHD1 are not associated with D4Z4 hypomethylation and do not always segregate with the disease.     

Somatic Pairing Between Subtelomeric Chromosome Regions: Implications for Human Genetic Disease?

Fluorescence in-situ hybridization (FISH) has been used to study the spatial orientation of subtelomeric chromosome regions in the interphase nucleus. Compared to interstitial chromosomal sites, subtelomeres showed an increased number of somatic pairings. However, pairing frequency also depended on the specific regions involved and varied both between different subtelomeres and between different interstitial regions. An increased incidence of somatic pairing may play at least some role in the frequent involvement of the subtelomeres in cytogenetically cryptic chromosome rearrangements. In patients suffering from facioscapulohumeral muscular dystrophy (FSHD), which is associated with a deletion of subtelomeric repeats, the FSHD region on 4qter showed a changed pairing behavior, which could be indicative of a position effect and/or trans-sensing effect as a cause for disease.     

The evolutionary distribution and structural organization of the homeobox-containing repeat D4Z4 indicates a functional role for the ancestral copy in the FSHD region [published erratum appears in Hum Mol Genet 1997 Mar;6(3):502]

Facioscapulohumeral muscular dystrophy (FSHD) is an autosomal dominant neuromuscular disease that has been linked to deletions within a tandem array of 3.2 kb repeats adjacent to the telomere of 4q. These repeats are also present in other locations in the human genome, including the short arms of all the acrocentric chromosomes. Here, we examine two models for the role of this repeat in FSHD. First, because of the extensive similarity between the 3.2 kb repeats on 4q and those adjacent to rDNA on the acrocentric chromosomes, we investigated whether the FSHD region on 4q is involved in sub-nuclear localization, specifically to the nucleolus. The results likely exclude any involvement of nucleolar localization in the development of FSHD. Second, we investigated a model that suggests that a functional gene may be buried within the tandem array of 3.2 kb repeats. Toward this end, we evaluated the evolutionary conservation of the repeat and a double homeodomain sequence within the repeat in a variety of primate species. The genomic organization of the 3.2 kb repeat in humans, great apes and lower primates identified the FSHD-associated repeat on chromosome 4q as the likely ancestral copy. The sequence of the rhesus monkey double homeodomain reveals significant sequence identity with the human 4q sequence. These results strongly suggest a functional role for a component of the FSHD-associated repeat.      

Double SMCHD1 variants in FSHD2: the synergistic effect of two SMCHD1 variants on D4Z4 hypomethylation and disease penetrance in FSHD2

Facioscapulohumeral muscular dystrophy (FSHD) predominantly affects the muscles in the face, trunk and upper extremities and is marked by large clinical variability in disease onset and progression. FSHD is associated with partial chromatin relaxation of the D4Z4 repeat array on chromosome 4 and the somatic expression of the D4Z4 encoded DUX4 gene. The most common form, FSHD1, is caused by a contraction of the D4Z4 repeat array on chromosome 4 to a size of 1–10 units. FSHD2, the less common form of FSHD, is most often caused by heterozygous variants in the chromatin modifier SMCHD1, which is involved in the maintenance of D4Z4 methylation. We identified three families in which the proband carries two potentially damaging SMCHD1 variants. We investigated whether these variants were located in cis or in trans and determined their functional consequences by detailed clinical information and D4Z4 methylation studies. In the first family, both variants in trans were shown to act synergistically on D4Z4 hypomethylation and disease penetrance, in the second family both SMCHD1 function-affecting variants were located in cis while in the third family one of the two variants did not affect function. This study demonstrates that having two SMCHD1 missense variants that affect function is compatible with life in males and females, which is remarkable considering its role in X inactivation in mice. The study also highlights the variability in SMCHD1 variants underlying FSHD2 and the predictive value of D4Z4 methylation analysis in determining the functional consequences of SMCHD1 variants of unknown significance.     

A new dosage test for subtelomeric 4;10 translocations improves conventional diagnosis of facioscapulohumeral muscular dystrophy (FSHD)

Facioscapulohumeral muscular dystrophy (FSHD) is caused by the size reduction of a polymorphic repeat array on 4q35. Probe p13E-11 recognises this chromosomal rearrangement and is generally used for diagnosis. However, diagnosis of FSHD is complicated by three factors. First, the probe cross hybridises to a highly homologous repeat array locus on chromosome 10q26. Second, although a BlnI polymorphism allows discrimination between the repeat units on chromosomes 4 and 10 and greatly facilitates FSHD diagnosis, the occurrence of translocations between chromosomes 4 and 10 further complicates accurate FSHD diagnosis. Third, the recent identification of deletions of p13E-11 in both control and FSHD populations is an additional complicating factor. Although pulsed field gel electrophoresis is very useful and sometimes necessary to detect these rearrangements, this technique is not operational in most FSHD diagnostic laboratories. Moreover, repeat arrays >200 kb are often difficult to detect and can falsely suggest a deletion of p13E-11. Therefore, we have developed an easy and reliable Southern blotting method to identify exchanges between 4 type and 10 type repeat arrays and deletions of p13E-11. This BglII-BlnI dosage test addresses all the above mentioned complicating factors and can be carried out in addition to the standard Southern blot analysis for FSHD diagnosis as performed in most laboratories. It will enhance the specificity and sensitivity of conventional FSHD diagnosis to the values obtained by PFGE based diagnosis of FSHD. Moreover, this study delimits the FSHD candidate gene region by mapping the 4;10 translocation breakpoint proximal to the polymorphic BlnI site in the first repeat unit.     

Interchromosomal repeat array interactions between chromosomes 4 and 10: a model for subtelomeric plasticity

Chromosomal rearrangements occur more frequently in subtelomeric domains than in other regions of the genome and are often associated with human pathology. To further elucidate the plasticity of subtelomeric domains, we examined the 3.3 kb D4Z4 repeat array on chromosome 4 and its homologue on chromosome 10 in 208 Dutch blood donors by pulsed field gel electrophoresis. These subtelomeric repeats are known to rearrange and partial deletions of this polymorphic array on chromosome 4 are associated with facioscapulohumeral muscular dystrophy (FSHD), an autosomal dominant myopathy. Our results show that mitotic rearrangements occur frequently as 3% of individuals display somatic mosaicism for a repeat expansion or contraction explaining the high variability of subtelomeric repeat array sizes. Translocated 4-type repeat arrays on chromosome 10 and the reverse configuration of 10-type repeat arrays on chromosome 4 are observed in 21% of individuals. The translocated repeat arrays on chromosome 4 tend to be more heterogeneous than 4-type repeats on chromosome 10. The repeat length on chromosome 4 is on average larger than on chromosome 10. But on both chromosomes we observe a multi-modal repeat length distribution with equidistant peaks at intervals of 65 kb, possibly reflecting a higher-order chromatin structure. Interestingly, in as many as six random blood donors (3%) we identified FSHD-sized 4-type repeat arrays. Assuming that these individuals are clinically unaffected, these results imply an incomplete penetrance in the upper range of FSHD alleles. Overall, the observed dynamic characteristics of these homologous domains may serve as a model for subtelomeric plasticity.