Mechanism and timing of mitotic rearrangements in the subtelomeric D4Z4 repeat involved in facioscapulohumeral muscular dystrophy

Autosomal dominant facioscapulohumeral muscular dystrophy (FSHD1A) is associated with contractions of the polymorphic D4Z4 repeat on chromosome 4qter. Almost half of new FSHD mutations occur postfertilization, resulting in somatic mosaicism for D4Z4. Detailed D4Z4 analysis of 11 mosaic individuals with FSHD revealed a mosaic mixture of a contracted FSHD-sized allele and the unchanged ancestral allele in 8 cases, which is suggestive of a mitotic gene conversion without crossover. However, in 3 cases, the D4Z4 rearrangement resulted in two different-sized D4Z4 repeats, indicative of a gene conversion with crossover. In all cases, DNA markers proximal and distal to D4Z4 showed no allelic exchanges, suggesting that all rearrangements were intrachromosomal. We propose that D4Z4 rearrangements occur via a synthesis-dependent strand annealing model that relatively frequently allows for crossovers. Furthermore, the distribution of different cell populations in mosaic patients with FSHD suggests that mosaicism here results from D4Z4 rearrangements occurring during the first few zygotic cell divisions after fertilization.     

Genetic confirmation of facioscapulohumeral muscular dystrophy in a case with complex D4Z4 rearrangments

Facioscapulohumeral muscular dystrophy (FSHD) is caused by contraction of the D4Z4 repeat on chromosome 4q. Genetic confirmation of the clinical diagnosis of FSHD is complicated by the presence of a homologous repeat on chromosome 10q and the frequent repeat exchanges between both chromosomes. Here, we describe the genetic evaluation of an FSHD patient with a complex D4Z4 allele constitution in which the potentially pathogenic allele seemingly resides on chromosome 10, despite FSHD being exclusively linked to chromosome 4. Complementary allele typing and segregation analysis confirmed the clinical diagnosis of FSHD by revealing the chromosome 4 origin of the pathogenic allele in the presence of two exchanged repeat arrays, one on chromosome 4 and one on chromosome 10, an allele constitution that cannot be identified by conventional DNA diagnosis.     

Contractions of D4Z4 on 4qB subtelomeres do not cause facioscapulohumeral muscular dystrophy

Facioscapulohumeral muscular dystrophy (FSHD) is associated with contractions of the D4Z4 repeat in the subtelomere of chromosome 4q. Two allelic variants of chromosome 4q (4qA and 4qB) exist in the region distal to D4Z4. Although both variants are almost equally frequent in the population, FSHD is associated exclusively with the 4qA allele. We identified three families with FSHD in which each proband carries two FSHD-sized alleles and is heterozygous for the 4qA/4qB polymorphism. Segregation analysis demonstrated that FSHD-sized 4qB alleles are not associated with disease, since these were present in unaffected family members. Thus, in addition to a contraction of D4Z4, additional cis-acting elements on 4qA may be required for the development of FSHD. Alternatively, 4qB subtelomeres may contain elements that prevent FSHD pathogenesis.     

DNA replication timing is maintained genome-wide in primary human myoblasts independent of D4Z4 contraction in FSH muscular dystrophy

Facioscapulohumeral muscular dystrophy (FSHD) is linked to contraction of an array of tandem 3.3-kb repeats (D4Z4) at 4q35.2 from 11-100 copies to 1-10 copies. The extent to which D4Z4 contraction at 4q35.2 affects overall 4q35.2 chromatin organization remains unclear. Because DNA replication timing is highly predictive of long-range chromatin interactions, we generated genome-wide replication-timing profiles for FSHD and control myogenic precursor cells. We compared non-immortalized myoblasts from four FSHD patients and three control individuals to each other and to a variety of other human cell types. This study also represents the first genome-wide comparison of replication timing profiles in non-immortalized human cell cultures. Myoblasts from both control and FSHD individuals all shared a myoblast-specific replication profile. In contrast, male and female individuals were readily distinguished by monoallelic differences in replication timing at DXZ4 and other regions across the X chromosome affected by X inactivation. We conclude that replication timing is a robust cell-type specific feature that is unaffected by FSHD-related D4Z4 contraction.     

Sequence homology between 4qter and 10qter loci facilitates the instability of subtelomeric KpnI repeat units implicated in facioscapulohumeral muscular dystrophy.

Physical mapping and in situ hybridization experiments have shown that a duplicated locus with a structural organization similar to that of the 4q35 locus implicated in facioscapulohumeral muscular dystrophy is present in the subtelomeric portion of 10q. We performed sequence analysis of the p13E-11 probe and of the adjacent KpnI tandem-repeat unit derived from a 10qter cosmid clone and compared our results with those published, by other laboratories, for the 4q35 region. We found that the sequence homology range is 98%-100% and confirmed that the only difference that can be exploited for differentiation of the 10qter from the 4q35 alleles is the presence of an additional BlnI site within the 10qter KpnI repeat unit. In addition, we observed that the high degree of sequence homology does facilitate interchromosomal exchanges resulting in displacement of the whole set of BlnI-resistant or BlnI-sensitive KpnI repeats from one chromosome to the other. However, partial translocations escape detection if the latter simply relies on the hybridization pattern from double digestion with EcoRI/BlnI and with p13E-11 as a probe. We discovered that the restriction enzyme Tru9I cuts at both ends of the array of KpnI repeats of different chromosomal origins and allows the use of cloned KpnI sequences as a probe by eliminating other spurious fragments. This approach coupled with BlnI digestion permitted us to investigate the structural organization of BlnI-resistant and BlnI-sensitive units within translocated chromosomes of 4q35 and 10q26 origin. A priori, the possibility that partial translocations could play a role in the molecular mechanism of the disease cannot be excluded.     

Linkage localization of facioscapulohumeral muscular dystrophy (FSHD) in 4q35.

Fasioscapulohumeral muscular dystrophy (FSHD) has recently been localized to 4q35. We have studied four families with FSHD. Linkage to the 4q35 probes D4S163, D4S139, and D4S171 was confirmed. We found no recombinants helpful in detailed localization of the FSHD gene. Two of our families include males with a rapidly progressive muscle disease that had been diagnosed, on the basis of clinical features, as Duchenne muscular dystrophy. One of these males is available for linkage study and shares the haplotype of his FSHD-affected aunt and cousin.     

De novo facioscapulohumeral muscular dystrophy: frequent somatic mosaicism, sex-dependent phenotype, and the role of mitotic transchromosomal repeat interaction between chromosomes 4 and 10

Autosomal dominant facioscapulohumeral muscular dystrophy (FSHD) is caused by deletion of most copies of the 3.3-kb subtelomeric D4Z4 repeat array on chromosome 4q. The molecular mechanisms behind the deletion and the high proportion of new mutations have remained elusive. We surveyed 35 de novo FSHD families and found somatic mosaicism in 40% of cases, in either the patient or an asymptomatic parent. Mosaic males were typically affected; mosaic females were more often the unaffected parent of a nonmosaic de novo patient. A genotypic-severity score, composed of the residual repeat size and the degree of somatic mosaicism, yields a consistent relationship with severity and age at onset of disease. Mosaic females had a higher proportion of somatic mosaicism than did mosaic males. The repeat deletion is significantly enhanced by supernumerary homologous repeat arrays. In 10% of normal chromosomes, 4-type repeat arrays are present on chromosome 10. In mosaic individuals, 4-type repeats on chromosome 10 are almost five times more frequent. The reverse configuration, also 10% in normal chromosomes, was not found, indicating that mutations may arise from transchromosomal interaction, to which the increase in 4-type repeat clusters is a predisposing factor. The somatic mosaicism suggests a mainly mitotic origin; mitotic interchromosomal gene conversion or translocation between fully homologous 4-type repeat arrays may be a major mechanism for FSHD mutations.     

Cytogenetic and immuno-FISH analysis of the 4q subtelomeric region,which is associated with facioscapulohumeral muscular dystrophy

Facioscapulohumeral muscular dystrophy (FSHD) is caused by the shortening of a copy-number polymorphic array of 3.3 kb repeats (D4Z4) at one allelic 4q35.2 region. How this contraction of a subtelomeric tandem array causes FSHD is unknown but indirect evidence suggests that a short array has a cis effect on a distant gene or genes. It was hypothesized that the length of the D4Z4 array determines whether or not the array and a large proximal region are heterochromatic and thereby controls gene expression in cis. To test this, we used fluorescence in situ hybridization probes with FSHD and control myoblasts to characterize the distal portion of 4q35.2 with respect to the following: intense staining with the chromatin dye 4,6-diamidino-2-phenylindole; association with constitutively heterochromatic foci; extent of binding of heterochromatin protein 1; histone H3 methylation at lysine 9 and lysine 4; histone H4 lysine 8 acetylation; and replication timing within S-phase. Our results indicate that 4q35.2 does not resemble constitutive heterochromatin in FSHD or control myoblasts. Furthermore, in these analyses, the allelic 4q35.2 regions of FSHD myoblasts did not behave differently than those of control myoblasts. Other models for how D4Z4 array contraction causes long-distance regulation of gene expression in cis need to be tested.Communicated by S. Gerbi     

The mapping of chromosome 4q markers in relation to facioscapulohumeral muscular dystrophy (FSHD).

The Basque population is one of the oldest populations of Europe. It has been suggested that the Basques arose from a population established in western Europe during the late Paleolithic Age. The Basque language (Euskera) is a supposedly pre-Indo-European language that originates from the first settlers of Europe. The variable distribution of the major cystic fibrosis (CF) mutation (delta F508 deletion) in Europe, with higher frequencies of the mutation in northern Europe and lower frequencies in southern Europe, has suggested that the delta F508 mutation was spread by early farmers migrating from the Middle East during the Neolithic period. We have studied 45 CF families from the Basque Country, where the incidence of CF is approximately 1/4,500. The birthplaces of the parents and grandparents have been traced and are distributed according to their origin as Basque or Mixed Basque. The frequency of the delta F508 mutation in the chromosomes of Basque origin is 87%, compared with 58% in those of Mixed Basque origin. The analysis of haplotypes, both with markers closely linked to the CF gene and with intragenic markers, suggests that the delta F508 mutation was not spread by the Indo-European invasions but was already present in Europe more than 10,000 years ago, during the Paleolithic period.     

Developmental expression of myotilin, a gene mutated in limb-girdle muscular dystrophy type 1A

We analyzed developmental expression of myotilin, a novel sarcomeric component mutated in limb-girdle muscular dystrophy 1A (LGMD1A). In situ hybridization and immunostaining of embryonic mouse tissues revealed expression of myotilin initially (E9-10) in heart, somites and neuroepithelium. At E13 myotilin was expressed in a variety of tissues, including the nervous system, lung, liver and kidney, but upon organ differentiation expression became more restricted. The level of expression during early development is comparable between mouse and human, indicating that the mouse may provide a model for further studying the functions of myotilin and the pathogenesis of LGMD1A.     

Genetic and physical mapping on chromosome 4 narrows the localization of the gene for facioscapulohumeral muscular dystrophy (FSHD).

We have used a combination of classical RFLPs and PCR-based polymorphisms including CA repeats and single-strand conformation polymorphisms to generate a fine-structure genetic map of the distal long arm of chromosome 4q. This map is now genetically linked to the pre-existing anchor map of 4pter-4q31 and generates, for the first time, a complete linkage map of this chromosome. The map consists of 32 anchor loci placed with odds of greater than 1,000:1. The high-resolution map in the cytogenetic region surrounding 4q35 provides the order 4cen-D4S171-F11-D4S187-D4S163-D4S139-4q ter. When we used somatic cell hybrids from a t(X;4)(p21;q35) translocation, these five markers fell into three groups consistent with the genetic map-D4S171 and F11 in 4pter-4q35, D4S163 and D4S139 in 4q35-4qter, and D4S187 as a junction fragment between these two regions. These markers are in tight linkage to the gene for facioscapulo-humeral muscular dystrophy (FSHD) mapped to this region by several collaborating investigators and provide a framework for further detailed analysis of this region.     

Linkage analyses of five chromosome 4 markers localizes the facioscapulohumeral muscular dystrophy (FSHD) gene to distal 4q35

The genetic locus for facioscapulohumeral muscular dystrophy (FSHD) has been mapped to chromosome 4. We have examined linkage to five chromosome 4q DNA markers in 22 multigenerational FSHD families. Multipoint linkage analyses of the segregation of four markers in the FSHD families and in 40 multigenerational mapping families from the Centre d'Etude du Polymorphisme Humaine enabled these loci and FSHD to be placed in the following order: cen-D4S171-factor XI-D4S163-D4S139-FSHD-qter. One interval, D4S171-FSHD, showed significant sex-specific differences in recombination. Homogeneity tests supported linkage of FSHD to these 4q DNA markers in all of the families we studied. The position of FSHD is consistent with that generated by other groups as members of an international FSHD consortium.     

Equal proportions of affected cells in muscle and blood of a mosaic carrier of facioscapulohumeral muscular dystrophy

Autosomal dominant facioscapulohumeral muscular dystrophy (FSHD) is associated with contractions of D4Z4 repeat on 4q35. It displays a remarkable inter- and intra-familial clinical variability ranging from severe phenotype to asymptomatic carriers. Mosaicism for the contracted FSHD-sized allele is a recurrent finding, but only DNA from lymphocytes had been studied. It is currently not known if mosaicism is unequally distributed between different tissues and if muscle is relatively spared for the presence of the disease allele in mosaic asymptomatic carriers of a disease allele. Here we compare DNA extracted from peripheral blood lymphocytes (PBL), fibroblasts and muscle from a mosaic asymptomatic female carrier and mother of a FSHD patient. PFGE analysis showed a complex allelic segregation: two independent mitotic rearrangement episodes occurred, resulting in mosaicism for a contracted D4Z4 repeat on 4q35 in the mother and mosaicism for an expanded D4Z4 repeat on 10q26 in the affected daughter. The results show that the proportion of mosaicism in PBL and muscle were comparable, while in fibroblasts there was some variation in the mosaicism, which might be caused by culturing artefacts. This finding supports the hypothesis that a mitotic contraction of D4Z4 is an early embryonic event and indicates that the degree of mosaicism in PBL is representative for that of muscle.     

Prediction of tandem repeat polymorphisms in the coding region of dog genome

After the dog genome was sequenced, an increasing number of studies involving genetic research of dogs have been conducted to understand gene functions and mammalian evolution. To study the genetic diversity in dogs and other mammals, genetic markers linked to function and conserved in wide lineages are necessary. Thus far, few polymorphic markers have been used in dogs. In this study, we surveyed the entire dog genome and predicted a total of 109 tandem repeats (TRs) located on the protein coding region that may be polymorphic by our prediction model. We selected 10 TRs that may be related to neurophysiology and neural developments, and tested them in 167 individuals of 8 dog breeds: 5 European dog breeds (Beagle, Golden Retriever, Labrador Retriever, German Shepherd, and Toy Poodle) and 3 Japanese dog breeds (Japanese Spitz, Shiba, and Shikoku). Among the tested TRs, nine were polymorphic indicating that 90% of the TRs were successfully predicted to be polymorphic. PCR fragments of the TRs were amplified from dog brain cDNA, showing their expression in the dog brain. Our results provide abundant opportunities for the study of phenotypic variations in dogs, and our prediction method for variable number of tandem repeats (VNTRs) can be applied to any other animal genome sequences for the survey of functional and polymorphic markers.     

Mapping of facioscapulohumeral muscular dystrophy gene to chromosome 4q35-qter by multipoint linkage analysis and in situ hybridization

We have recently assigned the facioscapulohumeral muscular dystrophy (FSHD) gene to chromome 4 by linkage to the microsatellite marker Mfd 22 (locus D4S171). We now report that D4S139, a VNTR locus, is much more closely linked to FSHD. Two-point linkage analysis between FSHD and D4S139 in nine informative families showed a maximum combined lod score (Zmax) of 17.28 at a recombination fraction theta of 0.027. Multipoint linkage analysis between FSHD and the loci D4S139 and D4S171 resulted in a peak lod score of 20.21 at 2.7 cM from D4S139. Due to the small number of recombinants found with D4S139, the position of the FSHD gene relative to that of D4S139 could not be established with certainty. D4S139 was mapped to chromosome 4q35-qter by in situ hybridization, thus firmly establishing the location of the FSHD gene in the subtelomeric region of chromosome 4q. One small family yielded a negative lod score for D4S139. In the other families no significant evidence for genetic heterogeneity was obtained. Studies of additional markers and new families will improve the map of the FSHD region, reveal possible genetic heterogeneity, and allow better diagnostic reliability.     

Structural analysis of emerin, an inner nuclear membrane protein mutated in X-linked Emery-Dreifuss muscular dystrophy

Like Duchenne and Becker muscular dystrophies, Emery-Dreifuss muscular dystrophy (EDMD) is characterized by myopathic and cardiomyopathic abnormalities. EDMD has the particularity of being linked to mutations in nuclear proteins. The X-linked form of EDMD is caused by mutations in the emerin gene, whereas autosomal dominant EDMD is caused by mutations in the lamin A/C gene. Emerin colocalizes with lamin A/C in interphase cells, and binds in vitro to lamin A/C. Recent work suggests that lamin A/C might serve as a receptor for emerin. We have undertaken a structural analysis of emerin, and in particular of its N-terminal domain, which is comprised in the emerin segment critical for binding to lamin A/C. We show that region 2-54 of emerin adopts the LEM fold. This fold was originally described in the two N-terminal domains of another inner nuclear membrane protein called lamina-associated protein 2 (LAP2). The existence of a conserved solvent-exposed surface on the LEM domains of LAP2 and emerin is discussed, as well as the nature of a possible common target.     

The human skeletal muscle adenine nucleotide translocator gene maps to chromosome 4q35 in the region of the facioscapulohumeral muscular dystrophy locus

Facioscapulohumeral muscular dystrophy (FSHD) is a relatively common autosomal dominant neuromuscular disorder. The gene for FSHD has recently been assigned to chromosome 4q35. Although abnormal mitochondrial and biochemical changes have been observed in FSHD, the molecular defect is unknown. In addition to the FSHD gene, the human muscle adenine nucleotide translocator gene (ANT1) is located on chromosome 4. Interestingly, biochemical studies recently showed a possible defect of ANT1. In order to evaluate the potential role of ANT1 in the etiology of FSHD, the human ANT1 gene was isolated by cosmid cloning and localized to 4q35, in the region containing the FSHD gene. However, in situ hybridization and physical mapping of somatic cell hybrids localized the ANT1 gene proximal to the FSHD gene. In addition, a polymorphic CA-repeat 5 kb upsstream of the ANT1 gene was used as a marker in FSHD and Centre d'Etude du Polymorphisme Humain families to perform linkage analysis. These data together exclude ANT1 as the primary candidate gene for FSHD. The most likely order of the loci on chromosome 4q35 is cen-ANT1-D4S171-F11-D4S187-D4S163-D4S139-FSHD-tel.