Relatively low proportion of dystrophin gene deletions in Israeli Duchenne and Becker muscular dystrophy patients

Duchenne muscular dystrophy (DMD) and Becker muscular dystrophy (BMD) are allelic disorders caused by mutations in the X-linked dystrophin gene. The most common mutations in western populations are deletions that are spread non-randomly throughout the gene. Molecular analysis of the dystrophin gene structure by hybridization of the full length cDNA to Southern blots and by PCR in 62 unrelated Israeli male DMD/BMD patients showed deletions in 23 (37%). This proportion is significantly lower than that found in European and North American populations (55–65%). Seventy-eight percent of the deletions were confined to exons 44–52, half of these to exons 44–45, and the remaining 22% to exons 1 and 19. There was no correlation between the size of the deletion and the severity of the disease. All the deletions causing frameshift resulted in the DMD phenotypes. © 1994 Wiley-Liss, Inc.     

Detection of carriers of Duchenne and Becker muscular dystrophy using the fluorescence in situ hybridization method

Duchenne and Becker muscular dystrophies (DMD/BMD) are X-linked recessive disorders caused by mutations in the dystrophin gene. A large intragenic deletion has been described in about 65% of DMD/BMD patients. Mothers of affected males are DMD/BMD carriers in two thirds of the cases. Routine deletions detection in DMD/BMD males is performed using multiplex polymerase chain reaction (mPCR), RT-PCR with a protein truncation test (PTT) or using Southern blotting. In females the deletions detection is complicated by the presence of a normal gene copy on the second X-chromosome. We are presenting the diagnostic strategy using FISH for the deletions detection in the dystrophin gene of female DMD/BMD carriers. We have used a set of six cosmid probes for the detection of the most frequently deleted areas of the dystrophin gene from the Department of Human Genetics, Leiden University Medical Center. We have examined 14 mothers of DMD/BMD males with a deletion in the dystrophin gene identified using mPCR. Four mothers of affected males have been diagnosed as carriers of a deletion in the dystrophin gene. We have revealed no deletion mutations in the exons examined in a control group of four healthy females. No discrepancy has been found between the FISH analysis results and the results of mPCR. Our results indicate that FISH is an effective and direct method for the identification of DMD/BMD carriers and we suggest this method as a method of a first choice in the identification of DMD/BMD carriers.     

Genetic epidemiology of Duchenne and Becker muscular dystrophy in Slovenia

Most population studies on Duchenne (DMD) and Becker (BMD) muscular dystrophies predated the discovery of the gene and its product dystrophin. The diagnosis of these conditions and consequent epidemiological estimates were therefore limited to clinical criteria. In our study of the Slovene population the prevalence and cumulative incidence of DMD and BMD were calculated by including additional diagnostic tests: deletion screening in the dystrophin gene as well as dystrophin immunocytochemistry. The minimal prevalence rates, 2.9/100000 for DMD, 1.2/100000 for BMD, and the minimal cumulative DMD incidence rate of 13.8/100000 are in the range of lower estimates compared to studies world-wide. However, we found a high BMD cumulative incidence rate of 5.7/100000 and a high proportion of BMD versus DMD cumulative incidence rate (41.3%). Our results imply that the epidemiological figures for BMD might have been underestimated in the past.     

Analysis of Dystrophin Gene Deletions by Multiplex PCR in Moroccan Patients

Duchenne and Becker muscular dystrophy (DMD and BMD) are X-linked diseases resulting from a defect in the dystrophin gene located on Xp21. DMD is the most frequent neuromuscular disease in humans (1/3500 male newborn). Deletions in the dystrophin gene represent 65% of mutations in DMD/BMD patients. We have analyzed DNA from 72 Moroccan patients with DMD/BMD using the multiplex polymerase chain reaction (PCR) to screen for exon deletions within the dystrophin gene, and to estimate the frequency of these abnormalities. We found dystrophin gene deletions in 37 cases. Therefore the frequency in Moroccan DMD/BMD patients is about 51.3%. All deletions were clustered in the two known hot-spots regions, and in 81% of cases deletions were detected in the region from exon 43 to exon 52. These findings are comparable to those reported in other studies. It is important to note that in our population, we can first search for deletions of DMD gene in the most frequently deleted exons determined by this study. This may facilitate the molecular diagnosis of DMD and BMD in our country.     

Integrated study of 100 patients with Xp21 linked muscular dystrophy using clinical, genetic, immunochemical, and histopathological data. Part 2. Correlations within individual patients.

This report is the second part of a trilogy from a multidisciplinary study which was undertaken to record the relationships between clinical severity and dystrophin gene and protein expression. The aim in part 2 was to correlate the effect of gene deletions on protein expression in individual patients with well defined clinical phenotypes. Among the DMD patients, most of the deletions/duplications disrupted the open reading frame, but three patients had in frame deletions. Some of the intermediate D/BMD patients had mutations which were frameshifting while others were in frame. All of the deletions/duplications in the BMD patients maintained the open reading frame and 25/26 deletions in typical BMD group 5 started with exon 45. The deletion of single exon 44 was the most common mutation in patients from groups 1 to 3. Dystrophin was detected in sections and blots from 58% of the DMD patients with a size that was compatible with synthesis from mRNA in which the reading frame had been restored. Certain deletions were particularly associated with the occurrence of limited dystrophin synthesis in DMD patients. For example, 9/11 DMD patients missing single exons had some detectable dystrophin labelling compared with 10/24 who had deletions affecting more than one exon. All patients missing single exon 44 or 45 had some dystrophin. Deletions starting or finishing with exons 3 or 51 (8/9) cases were usually associated with dystrophin synthesis whereas those starting or finishing with exons 46 or 52 (11/11) were not. Formal IQ assessments (verbal, performance, and full scores) were available for 47 patients. Mean IQ score among the DMD patients was 83 and no clear relationship was found between gene mutations and IQ. The mutations in patients with a particularly severe deficit of verbal IQ were spread throughout the gene.     

A TaqI map of the dystrophin gene useful for deletion and carrier status analysis.

We describe a partial TaqI map of the dystrophin gene, obtained mainly by analysis of 87 overlapping DMD/BMD deletions with small fragments of the dystrophin cDNA probes; exon 6 of the dystrophin gene was identified on the TaqI map using the polymerase chain reaction. The cDNA probes detect five polymorphisms with TaqI, more than with HindIII (one), BglII (four), or PstI (three). The five polymorphisms are analysed concomitant with screening for deletions on the TaqI map, and in the one-third of DMD/BMD cases with no detected deletion the polymorphism information may be used for counselling. Correlation of the TaqI map with the HindIII map in the region of probes 5b-7 and 8 has allowed the establishment of reading frame. In this region of the dystrophin gene, all of 41 DMD deletions resulted in a shift of reading frame and all of 10 BMD patients maintained reading frame, in agreement with the 'reading frame hypothesis'.     

Point mutations at the carboxy terminus of the human dystrophin gene: implications for an association with mental retardation in DMD patients

Duchenne and Becker muscular dystrophies (DMD/BMD) are causedby mutations in the human dystrophin gene. About two-thirdsof DMD/BMD patients exhibit gross rearrangements in the genewhereas the mutations in the remaining one third are thoughtto be point mutations or minor structural lesions. By meansof various progressive PCR-based techniques hitherto a numberof point mutations has been described that in most cases shouldcause premature translational termination. These data indicatea particular functional importance for the C-termlnal regionof dystrophin and consequently for its gene products Dp 71 andDp 116. To screen for mlcroheterogeneities in this gene regionwe applied PCR-SSCP analysis to exons 60 – 79 of twenty-sixDMD/BMD patients without detectable deletions. The study identifiedseven point mutations and one intron polymorphism. Six pointmutations, found in DMD patients, should cause premature translationaltermination. One point mutation, identified in a BMD patient,results in an amino acid exchange. Five of the DMD patientsbearing a point mutation are mentally retarded suggesting thata disruption of the translational reading frame in the C-terminalregion is associated with this clinical finding in DMD cases.Therefore our data raise the possibility, that Dp 71 and/orDp 116, the C-termlnal translational products of dystrophin,may be causally involved in cases of mental retardation thatare associated with DMD.     

Identification of female carriers for Duchenne and Becker muscular dystrophies using a FISH-based approach

Duchenne muscular dystrophy (DMD) and Becker muscular dystrophy (BMD) are X-linked recessive neuromuscular diseases caused by dystrophin gene mutations. Deletions, or more rarely duplications, of single or multiple exons within the dystrophin gene can be detected by current molecular methods in approximately 65% of DMD patients. Mothers of affected males have a two-thirds chance of carrying a dystrophin mutation, whilst approximately one-third of affected males have de novo mutations. Currently, Southern blot analysis and multiplex PCR directed against exons in deletion hot spots are used to determine female carrier status. However, both of these assays depend on dosage assessment to accurately identify carriers since, in females, the normal X chromosome is also present. To obviate quantitation of gene dosage, we have developed exon-specific probes from the dystrophin gene and applied them to a screen for potential carrier females using fluorescence in situ hybridization (FISH). Cosmid clones, representing 16 exons, were identified and used in FISH analysis of DMD/BMD families. Our preliminary work has identified multiple, informative probes for several families with dystrophin deletions and has shown that a FISH-based assay can be an effective and direct method for establishing the DMD/BMD carrier status of females.     

Comparative analysis of PCR-deletion detection and immunohistochemistry in Brazilian Duchenne and Becker muscular dystrophy patients

We studied 48 patients with dystrophinopathies (29 Duchenne muscular dystrophy (DMD), 13 Becker muscular dystrophy (BMD), four possible carriers, one female with DMD, and one intermediate form, using polymerase chain reaction (PCR) analysis of muscle tissue for 20 exons and compared them with immunohistochemistry studies for dystrophin. Of these, 42 (87.5%) showed at least one intragenic deletion. Most of them (47.45%) involved exons 2 to 20. All BMD patients presented deletions on the dystrophin gene. The 29 patients with DMD showed abnormal dystrophin in immunohistochemistry studies, some with total absence (17/29), others with residual (3/29), and the remaining with scattered positive fiber (9/29). The majority of the 13 patients with BMD had abnormal immunohistochemistry studies with diffuse reduction in the majority of muscle fibers (10/13), a few with patch discontinuation in the sarcolemma (2/13), and one normal (1/13). The immunohistochemistry exam for dystrophin is still the gold-standard method for DMD/BMD diagnosis. An ethnic difference, the analysis of several exons, the sample size, and the use of muscle tissue could explain this high frequency of deletions in the dystrophin gene found in our cases.     

Screening for minor changes in the distal part of the human dystrophin gene in Greek DMD/BMD patients

The distal part of the human dystrophin gene is characterised by particular features and seems to play an important functional role. Additionally in recent years several data have implicated minor mutations in this gene region in some patients with mental retardation (MR). In order to screen for pathogenic mutations at the distal part of the human dystrophin gene we have used single-strand conformation analysis of products amplified by polymerase chain reaction (PCR-SSCA) in 35 unrelated male Greek DMD/BMD patients with no detectable deletions. Seven patients also had severe mental retardation. Direct sequencing of samples demonstrating a shift of SSCA mobility revealed six different and pathogenic minor changes, five in DMD and one in a BMD patient. Four of the mutations were found in DMD patients with severe MR. Three of these mutations were localised in exon 66, which presents an interesting similarity with part of the 3' end of the genome of eastern equine encephalomyelitis virus (EEEV). The present data from Greek DMD/BMD patients give further information about the phenotypic effects consequent on mutations in exons at the distal part of the human dystrophin gene.     

Gene deletions in Japanese patients with Duchenne and Becker muscular dystrophies: deletion study and carrier detection

Fifty unrelated Japanese patients with Duchenne and Becker muscular dystrophy (DMD and BMD) have been studied through use of the dystrophin cDNA probes. The 14-kb dystrophin cDNA was subdivided into six subclones, and Hind III-digested DNAs were analyzed by Southern blotting. Of 50 unrelated patients, 20 showed a deletion of one or several of the exon-containing Hind III fragments (40.0%). These corresponded to 50% (11/22) of BMD patients and 32.1% (9/28) of DMD patients, and the position and extent of deletions were mapped and proven to be more heterogeneous in DMD than in BMD. Both ends of deletions detected by probe 1-2a were common to all six BMD patients, and the 5' ends of deletions in probe 5b-7 were also common to four BMD patients. The phenotypic-specific deletion in Japanese BMD patients existed in the 5' end of the DMD gene, although an apparently similar deletion produced a wide range of clinical courses (BMD phenotype). Three out of eight females in DMD/BMD families were diagnosed as carriers through use of the junctional fragment and dosage analyses of dystrophin cDNA.     

Identification of point mutations in Turkish DMD/BMD families using multiplex-single stranded conformation analysis (SSCA)

Small mutations are the cause of the disease in one third of cases of Duchenne and Becker muscular dystrophy (DMD/BMD). The identification of point mutations in the dystrophin gene is considered to be very important, because it may provide new insights into the function of dystrophin and direct information for genetic counselling. In this study, we have screened 18 deletion-prone exons (25.5% of the coding region) of the dystrophin gene by using a modified non-isotopic multiplex single-stranded conformation analysis (SSCA). Mutations responsible for the disease phenotype could be identified in five out of 56 unrelated DMD/BMD patients without detectable deletions. Two of these mutations, 980-981delCC and 719G > C, are novel mutations which have not been described previously. Four of the five mutations, including 980-981delCC detected in this study are found to be nonsense or frameshift mutations leading to the synthesis of a truncated dystrophin protein. The missense mutation, 719G > C, causing the substitution of highly conserved alanine residue at 171 with proline in the actin binding domain of the dystrophin, is associated with a BMD phenotype. This study also revealed the presence of six polymorphisms in Turkish DMD/BMD patients.     

PGD for dystrophin gene deletions using fluorescence in situ hybridization

Duchenne muscular dystrophy and Becker muscular dystrophy (DMD and BMD) are caused by mutations in the dystrophin gene (Xp21). In two-thirds of DMD/BMD cases, the mutation is a large deletion of one or several exons. We have established PGD for DMD/BMD using interphase fluorescence in situ hybridization (FISH) analysis on single nuclei from blastomeres for the detection of deletions of specific exons in the dystrophin gene. We performed PGD for two carrier females; one had a deletion of exons 45-50 (DMD), and the other had a deletion of exons 45-48 (BMD). An exon 45-specific probe was used in combination with probes for the X and Y centromeres. Using this straightforward approach, we can distinguish affected and unaffected male embryos as well as carrier female and normal female embryos. Three cycles were performed for each patient, which resulted in a pregnancy and the birth of a healthy girl. To the best of our knowledge, this approach for PGD has not been previously reported. The use of interphase FISH is an attractive alternative to sexing or PCR-based mutation detection for PGD patients with known deletions of the dystrophin gene.     

Microarray-based mutation detection in the dystrophin gene

Duchenne and Becker muscular dystrophies (DMD and BMD) are X-linked recessive neuromuscular disorders caused by mutations in the dystrophin gene affecting approximately 1 in 3,500 males. The human dystrophin gene spans>2,200 kb, or roughly 0.1% of the genome, and is composed of 79 exons. The mutational spectrum of disease-causing alleles, including exonic copy number variations (CNVs), is complex. Deletions account for approximately 65% of DMD mutations and 85% of BMD mutations. Duplications occur in approximately 6 to 10% of males with either DMD or BMD. The remaining 30 to 35% of mutations consist of small deletions, insertions, point mutations, or splicing mutations, most of which introduce a premature stop codon. Laboratory analysis of dystrophin can be used to confirm a clinical diagnosis of DMD, characterize the type of dystrophin mutation, and perform prenatal testing and carrier testing for females. Current dystrophin diagnostic assays involve a variety of methodologies, including multiplex PCR, Southern blot analysis, multiplex ligation-dependent probe amplification (MLPA), detection of virtually all mutations-SSCP (DOVAM-S), and single condition amplification/internal primer sequencing (SCAIP); however, these methods are time-consuming, laborious, and do not accurately detect duplication mutations in the dystrophin gene. Furthermore, carrier testing in females is often difficult when a related affected male is unavailable. Here we describe the development, design, validation, and implementation of a high-resolution comparative genomic hybridization (CGH) microarray-based approach capable of accurately detecting both deletions and duplications in the dystrophin gene. This assay can be readily adopted by clinical molecular testing laboratories and represents a rapid, cost-effective approach for screening a large gene, such as dystrophin.