Molecular and phenotypic analysis of patients with deletions within the deletion-rich region of the Duchenne muscular dystrophy (DMD) gene

Eighty unrelated individuals with Duchenne muscular dystrophy (DMD) or Becker muscular dystrophy (BMD) were found to have deletions in the major deletion-rich region of the DMD locus. This region includes the last five exons detected by cDNA5b-7, all exons detected by cDNA8, and the first two exons detected by cDNA9. These 80 individuals account for approximately 75% of 109 deletions of the gene, detected among 181 patients analyzed with the entire dystrophin cDNA. Endpoints for many of these deletions were further characterized using two genomic probes, p20 (DXS269; Wapenaar et al.) and GMGX11 (DXS239; present paper). Clinical findings are presented for all 80 patients allowing a correlation of phenotypic severity with the genotype. Thirty-eight independent patients were old enough to be classified as DMD, BMD, or intermediate phenotype and had deletions of exons with sequenced intron/exon boundaries. Of these, eight BMD patients and one intermediate patient had gene deletions predicted to leave the reading frame intact, while 21 DMD patients, 7 intermediate patients, and 1 BMD patient had gene deletions predicted to disrupt the reading frame. Thus, with two exceptions, frameshift deletions of the gene resulted in more severe phenotype than did in-frame deletions. This is in agreement with recent findings by Baumbach et al. and Koenig et al. but is in contrast to findings, by Malhotra et al., at the 5' end of the gene.     

A deletion hot spot in the Duchenne muscular dystrophy gene

We have made a detailed study of a deletion hot spot in the distal half of the Duchenne muscular dystrophy (DMD) gene, using intragenic probe P20 (DXS269), isolated by a hybrid cell-mediated cloning procedure. P20 detects 16% deletions in patients suffering from either DMD or Becker muscular dystrophy (BMD), in sharp contrast to the adjacent intragenic markers JBir (7%) and J66 (less than 1%), mapping respectively 200-320 kb proximal and 380-500 kb distal to P20. Of the P20 deletions, 30% start within a region of 25-40 kb, the majority extending distally. P20 was confirmed to map internal to a distal intron of the DMD gene. This region was recently shown by both cDNA analysis (M. Koenig et al., 1987; Cell 50: 509-517), and field inversion electrophoresis studies (J.T. Den Dunnen et al., 1987, Nature (London) 329: 640-642) to be specifically prone to deletions. In addition, P20 detects MspI and EcoRV RFLPs, informative in 48% of the carrier females. Together, these properties make P20 useful for carrier detection, prenatal diagnosis, and the study of deletion induction in both DMD and BMD.     

Gene deletions in X-linked muscular dystrophy

Of the approximately 170 families with X-linked muscular dystrophy of the Duchenne (DMD) and Becker (BMD) type in Finland, we have studied 90 unrelated patients for intragenic deletions by using the cDNA probes described by Koenig et al. Forty-five patients (50%) had molecular deletions of one or several of the 65 exon-containing HindIII fragments. In six deletion cases junction fragments of altered size were seen. Thirty-eight (84%) of the 45 deletions were detected using only two (1–2a and 8) of the six cDNA subclones. Using a wheelchair age of 12 years to distinguish between DMD and BMD, we found that the proportions of patients with deletions were similar. Deletions were equally common in familial and sporadic disease. BMD was more commonly caused by deletions in the 5' end of the gene than was DMD. In at least three instances deletions of similar type resulted in diseases of similar severity. Of 14 patients with mental retardation seven had deletions; six of these comprised exons contained in probe 8. We conclude that cDNA hybridization studies provide a powerful diagnostic tool in DMD and BMD and that they promise to produce better insights into molecular-clinical correlations.     

Molecular deletion patterns in families from southern France with Duchenne/Becker muscular dystrophies

Summary We studied 38 unrelated patients from southern France with Duchenne (DMD) or Decker (BMD) muscular dystrophy for intragenic deletions of the DMD/ BMD gene. We used both multiplex amplification of selected exons and cDNA probes. Of the 26 (68%) unrelated individuals found to have deletions, 24 (92%) were detected by multiplex polymerase chain reaction. All these deletions have been delineated with regard to the exon-containing HindIII fragments revealed by cDNA probes, and in two cases, junction fragments of altered size were seen. The correlation between phenotype and type of deletion agreed with the reading frame theory, except for two BMD and two DMD cases.     

Duchenne and Becker muscular dystrophy mutations: analysis using 2.6 kb of muscle cDNA from the 5'' end of the gene.

We have isolated overlapping human fetal muscle cDNAs encompassing 2.6kb which are localised very close to the 5' end of the Duchenne muscular dystrophy (DMD) gene. Using DNA from patients with deletions of previously reported genomic probes, we have mapped the exons across the region. Investigation of deletions in both DMD and Becker muscular dystrophy (BMD) patients shows the deletions to be present in 10% of cases and heterogeneous.     

Detection of gene deletions in Chinese patients with Duchenne/Becker muscular dystrophy using CDNA probes and the polymerase chain reaction method.

One hundred thirty-eight patients with Duchenne/Becker muscular dystrophy (DMD/BMD) were screened with complete cDNA probes and the multiplex polymerase chain reaction (mPCR) amplification of 18 pairs of oligonucleotide primers. Eighty-six deletions and 4 duplications were detected, the deletion frequency being 62.3%. Eighty-two deletions were detected with the two sets of primers described by Chamberlain et al. and Beggs et al, which was 95.4% of deletions detected by complete cDNA probes. Consistent with the deletion locations described previously, the deletions of dystrophin gene in Chinese individuals are clustered mainly in two high-frequency deletion regions of exons 44-52 (68.6%) of 3' side of the gene central regions and exons 1-19 (26.7%) in the 5' side. The distribution of deletions in dystrophin gene is associated with the phenotype of DMD/BMD. In the 25 cases with in-frame deletions, 15 deletions located in the region of exons 2-47 were milder BMD and intermediate patients, as the location of deletions was not the important region of the dystrophin gene.     

Strategy for comprehensive molecular testing for Duchenne and Becker muscular dystrophies

Comprehensive molecular testing for mutations in the DMD gene causing Duchenne and Becker muscular dystrophy (DMD/BMD) is challenging because of the large size of the gene and the variety of mutation types. There is an increasing demand for comprehensive DMD gene molecular testing, including deletion/duplication testing of 79 exons and direct sequencing of the 14-kb coding region from genomic DNA, to provide confirmation of clinical diagnoses in affected patients and to determine carrier risk for family members. To determine an efficient strategy to prioritize patients for comprehensive molecular testing of the DMD gene, we tested a consecutive cohort of 165 males referred over a 4-year period because of a suspicion of DMD or BMD using: (1) a new quantitative multiplex polymerase chain reaction (PCR) assay designed to detect deletions or duplications in all exons of the gene and the brain promoter and (2) direct sequencing of the coding region and intron/exon boundaries. For the patients being tested because of a suspicion of DMD, deletion/duplication testing followed by direct sequencing detected pathogenic mutations in 98% (106/108 total patients). However, of the patients tested because of a suspicion of BMD, only 60% (34/57 total patients) had causative mutations identified, all of which were deletions or duplications. Our results suggest that direct genomic sequence analysis of the DMD gene is a useful addition to deletion/duplication testing for diagnosis of DMD, but does not provide an improved sensitivity compared to deletion/duplication analysis alone for the diagnosis of BMD. In addition, due to the relatively common finding of single exon deletions and duplications (22%, 27 of 125 total patients with deletions/duplications), methods to examine all exons of the gene for deletions/duplications should be used as the initial molecular quantitative test for DMD and BMD.     

Localisation of the endpoints of deletions in the 5'' region of the Duchenne gene using a sequence isolated by chromosome jumping.

We have used chromosome jumping technology to move from within a large intron sequence in the Duchenne muscular dystrophy (DMD) gene to a region adjacent to exons of the gene. The single copy jump clone, HH1, was used to characterise deletions in patients previously shown to be deleted for DNA markers in the 5' end of the gene. 12 out of 15 such patients have breakpoints which lie between HH1 and the genomic locus J-47. Thus the vast majority of the deletions in these patients have proximal breakpoints in a similar region distal to the 5' end of the gene. HH1 was mapped with respect to the X;1 translocation in a DMD female and was shown to lie at least 80 kb from the starting point of the chromosome jump, HIP25.     

Molecular deletion patterns in Duchenne and Becker type muscular dystrophy

Summary DNA from 80 Duchenne (DMD) and 15 Becker (BMD) index patients was analyzed with 12 genomic probes and the total cDNA. Deletions were detected in 24 DMD (30%) and 10 BMD patients (67%) by genomic probes alone, mostly p20, pXJ, and/or pERT87. All deletions were confirmed by cDNA probes, and an additional 29 DMD deletions were detected, resulting in a total of 63/95 deletions (66%). The majority of the deletions are localized between kb 6.7 and 9.7 of the cDNA; a smaller group, between kb 0.5 and 3.5. Of the deletions, 90% are detected by the three cDNA probes 1–2a, 7, and 8. This can be applied to strategies for carrier detection and prenatal diagnosis. The order of 13 exon-containing HindIII fragments in the region between probes 7 and 9–10, where most of the deletions are found, could be defined. The deletion patterns in DMD and BMD patients are different and well in accordance with the “reading frame theory” of Monaco and coworkers. Thus our findings indicate that a DMD or BMD phenotype may be predicted according to the breakpoint position and the number of deleted exons.     

Topography of the Duchenne muscular dystrophy (DMD) gene: FIGE and cDNA analysis of 194 cases reveals 115 deletions and 13 duplications.

We have studied 34 Becker and 160 Duchenne muscular dystrophy (DMD) patients with the dystrophin cDNA, using conventional blots and FIGE analysis. One hundred twenty-eight mutations (65%) were found, 115 deletions and 13 duplications, of which 106 deletions and 11 duplications could be precisely mapped in relation to both the mRNA and the major and minor mutation hot spots. Junction fragments, ideal markers for carrier detection, were found in 23 (17%) of the 128 cases. We identified eight new cDNA RFLPs within the DMD gene. With the use of cDNA probes we have completed the long-range map of the DMD gene, by the identification of a 680-kb SfiI fragment containing the gene's 3' end. The size of the DMD gene is now determined to be about 2.3 million basepairs. The combination of cDNA hybridizations with long-range analysis of deletion and duplication patients yields a global picture of the exon spacing within the dystrophin gene. The gene shows a large variability of intron size, ranging from only a few kilobases to 160-180 kb for the P20 intron.     

Patterns of exon deletions in Duchenne and Becker muscular dystrophy

Summary A panel of patients with Duchenne and Becker muscular dystrophy (DMD and BMD) has been screened with the cDNA probes Cf56a and Cf23a, which detect exons in the central part of the DMD gene. One or more exons were deleted in 60% of patients. The deletions were mapped and prove to be heterogeneous in size and extent, particularly in DMD. Deletions specific to DMD and to BMD are described. Half of all BMD patients have a deletion of one particular small group of exons; smaller deletions within this same group produce the more severe DMD.     

Mapping of four translocation breakpoints within the Duchenne muscular dystrophy gene

There are over 20 females with Duchenne or Becker muscular dystrophy (DMD or BMD) who have X-autosome translocations that break the X chromosome within band Xp21. Several of these translocations have been mapped with genomic probes to regions throughout the large (approximately 2000 kb) DMD gene. In this report, a cDNA clone from the 5' end of the gene was used to further map the breakpoints in four X-autosome translocations. A t(X;21) translocation in a patient with BMD and a t(X;1) translocation in a patient with DMD were found to break within a large 110-kb intron between exons 7 and 8. Two other DMD translocations, t(X;5) and t(X;11), were found to break between the first and the second exon of the gene within a presumably large intron (greater than 100 kb). These results demonstrate that all four translocations have disrupted the DMD gene and make it possible to clone and sequence the breakpoints. This will in turn determine whether these translocations occur by chance in these large introns or whether there are sequences that predispose to translocations.     

A small deletion in the Duchenne/Becker muscular dystrophy locus —a functionally important region?

Summary A DNA deletion in a patient with Becker muscular dystrophy (BMD) has been delineated by restriction endonuclease mapping. The deletion is unusually small, removing six kilobases (kb) of DNA distal to pERT 87-1 (DXS164). This region has previously been shown to contain an exon of a candidate gene which, when defective, causes Duchenne muscular dystrophy (DMD) or Becker muscular dystrophy. Removal of this exon and surrounding DNA is apparently sufficient, in this case, to cause a BMD phenotype. The occurrence of this deletion in DXS164 would appear to confirm that this region is part of the BMD locus. Many DMD patients have deletions in and around this region, adding further evidence for the allelic nature of the two disorders. This fortuitous deletion may identify a functionally important domain of the protein product in terms of the severity of phenotype manifested.     

RFLPs for Duchenne muscular dystrophy cDNA clones 9 and 10.

The complete 14-kb cDNA for the gene causing the X-linked recessive muscular dystrophy (MD) type Duchenne (DMD) and Becker (BMD) has recently been cloned and made available for deletion/duplication screening in patients. It detects 65 exon-containing nonpolymorphic HindIII fragments spread over a gene locus of about 2,000 kb. When the entire DMD cDNA is used, deletions/duplications can be found in about 65%-70% of affected patients, permitting direct carrier detection by densitometric scanning. But in cases where no deletion/duplication is detectable, RFLP analysis, specially favored within the gene, will be the method for carrier-status determination. Clones 9 and 10-1.2-kb and 0.7-kb fragments, respectively, of the 14-kb DMD cDNA--have been hybridized with human genomic DNA digested by nine different restriction enzymes. Five RFLPs, involving Asp700, PvuII, XbaI, and EcoRV sites, were detected, and Mendelian inheritance could be demonstrated. Since clones 9 and 10 are localized telomeric to the mutation-hot-spot region, their polymorphisms are thought to be very helpful as flanking markers for indirect carrier detection in families with a family history of DMD/BMD. Moreover, these RFLPs can be used for direct carrier detection or exclusion in families with patients showing a deletion/duplication in the region of p9 or p10.     

The molecular basis for Duchenne versus Becker muscular dystrophy: Correlation of severity with type of deletion

About 60% of both Duchenne muscular dystrophy (DMD) and Becker muscular dystrophy (BMD) is due to deletions of the dystrophin gene. For cases with a deletion mutation, the "reading frame" hypothesis predicts that BMD patients produce a semifunctional, internally deleted dystrophin protein, whereas DMD patients produce a severely truncated protein that would be unstable. To test the validity of this theory, we analyzed 258 independent deletions at the DMD/BMD locus. The correlation between phenotype and type of deletion mutation is in agreement with the "reading frame" theory in 92% of cases and is of diagnostic and prognostic significance. The distribution and frequency of deletions spanning the entire locus suggests that many "in-frame" deletions of the dystrophin gene are not detected because the individuals bearing them are either asymptomatic or exhibit non-DMD/non-BMD clinical features.     

两个DMD cDNA片段在进行性肌营养不良症基因诊断中的应用

本文使用了缺失热点区的两个DMD cDNA片段1b-2a及8为探针检测Duc-henne型及Becker型肌营养不良(DMD/BMD)患者的基因缺失。在34例不相关患者中分别检测到5例及8例基因片段缺失,缺失检测率分别为14.7％及23.5％,总检出率为38.2％。结果表明,中国肌营养不良患者的基因缺失也不是随机分布的,主要集中于基因中心附近,其次在基因5′侧。     

Analysis of molecular deletions with cDNA probes in patients with Duchenne and Becker muscular dystrophies

In the course of a systematic survey of DMD and BMD patients with intronic probes and with cDNA probes covering three-fourths of the coding sequence, 45 molecular deletions within the DMD gene were investigated. Forty-two percent of the breakpoints were located in the intronic sequence containing probe P20, whereas the other deletions were widespread around the more proximal part of the gene. Most of the BMD deletions were in the P20 region. Pulsed field gel electrophoresis was used to determine the size of some deletions and allowed us to estimate the physical distance between the intronic probes JBir and P20. The reading frame was checked in 11 cases with proximal deletions and found to be disrupted in 6 of 7 DMD patients, in 1 intermediate case, and, unexpectedly, in 3 BMD patients.     

DNA deletions in mild and severe Becker muscular dystrophy

Summary The DNA of 33 patients diagnosed as suffering from Becker muscular dystrophy (BMD) has been probed with cloned DNA sequences from Xp21, known to reveal DNA deletions in patients suffering from the more severe Duchenne muscular dystrophy (DMD). Two BMD cases showed clear deletions. A third case gave aberrant band sizes, which further analysis showed to be caused by a small deletion. This suggests that deletions in DXS164 occur approximately as frequently in BMD as they do in DMD. Of the two cases showing large deletions, one is at the severe end of the Becker clinical spectrum, whilst the other is a classical Becker-type dystrophy. The fact that loci defined by probes commonly deleted in classical DMD patients are also deleted in BMD patients of varying severity is strong additional evidence that these disorders are allelic, and further justifies the use of probes with defined linkage relationships to DMD also being used for counselling in BMD families.     

An explanation for the phenotypic differences between patients bearing partial deletions of the DMD locus

Deletions giving rise to Duchenne muscular dystrophy (DMD) and the less severe Becker muscular dystrophy (BMD) occur in the same large gene on the short arm of the human X chromosome. We present a molecular mechanism to explain the clinical difference in severity between DMD and BMD patients who bear partial deletions of the same gene locus. The model is based on the breakpoints of intragenic deletions and their effect on the translation of triplet codons into amino acids of the protein product. Deletions identified in three DMD patients are shown to shift the translational open reading frame (ORF) of triplet codons for amino acids, and each deletion is predicted to result in a truncated, abnormal protein product. Deletions identified in three BMD patients are shown to maintain the translational ORF for amino acids and predict a shorter, lower molecular weight protein. The smaller protein product is presumed to be semifunctional and to result in a milder clinical phenotype. The same ORF mechanism is also applicable to potential 5' and 3' intron splice mutations and their effect on protein production and clinical phenotype.