Identification of deletions and duplications of the DMD gene in affected males and carrier females by multiple ligation probe amplification (MLPA)

Duchenne muscular dystrophy (DMD) and Becker muscular dystrophy (BMD) are caused in the majority of cases by deletions of the DMD gene and are readily detectable in affected males by multiplex polymerase chain reaction (PCR). However, different approaches must be used for the identification of female carriers, in which deletions are not detectable by PCR, because of the presence of a normal X chromosome. In this study, we used the multiple ligation probe amplification (MLPA) tool for the identification of female carriers of DMD deletions or duplications in 12 families with a single affected male, 10 of which were previously diagnosed as carriers of a DMD rearrangement, and the remaining two as having an unknown disease-causing mutation. In all the investigated affected males, MLPA analysis confirmed the presence of a DMD rearrangement, and in six of them allowed the refinement of the breakpoints. In 12 female relatives of the affected patients, MLPA analysis showed a DMD deletion or duplication, confirming their carrier status. Two of these were the mother and the sister of a patient whose disease-causing mutation was not known. MLPA analysis thus proved to be an useful tool for the analysis of both affected males and females carriers of DMD rearrangements in cases in which the disease-causing mutation in the affected male was not known, providing useful information for the genetic counselling of the family.Valentina Gatta and Oronzo Scarciolla contributed equally to this work.     

Direct deletion analysis in two Duchenne muscular dystrophy symptomatic females using polymorphic dinucleotide (CA)n loci within the dystrophin gene

Duchenne muscular dystrophy (DMD) is the most common hereditary neuromuscular disease. It is inherited as an X-linked recessive trait in which males show clinical manifestations. In some rare cases, the disease can also be manifested in females. The aim of the present study was to determine the molecular alteration in two cases of nonrelated DMD symptomatic carriers with no previous history of DMD. Multiplex PCR is commonly used to search for deletion in the DMD gene of affected males. This method could not be used in females because the normal X chromosome masks the deletion of the mutated one. Therefore, we used a set of seven highly polymorphic dinucleotide (CA)(n) repeat markers that lie within the human dystrophin gene. The deletions were evidenced by hemizygosity of the loci under study. We localized a deletion in the locus 7A (intron 7) on the maternal X chromosome in one case, and a deletion in the region of introns 49 and 50 on the paternal X chromosome in the other. The use of microsatellite genotyping within the DMD gene enables the detection of the mutant allele in female carriers. It is also a useful method to provide DMD families with more accurate genetic counseling.     

DNA studies in a family with Duchenne muscular dystrophy and a deletion at Xp21.

We have performed Southern blot analysis on a large, four-generation kindred with Duchenne muscular dystrophy (DMD). Probes 754 (DXS 84), pERT87-1, pERT87-8, pERT87-15 (DXS164), and pXJ-1.1 did not hybridize to digested genomic DNA of affected males. Obligate-carrier mothers and unaffected brothers showed signals of a single X-chromosome copy intensity, and suspected noncarrier sisters demonstrated either a single band of two-copy intensity or informative polymorphisms. Uniform hybridization was seen with probes C7 (DXS28) and D2 (DXS43), which map distal to the DMD locus, and with OTC, which maps proximally. This deletion was present in six affected individuals and has been transmitted through 3 generations to date. On high-resolution chromosome analysis, a deletion within band Xp21 was consistently observed in one affected male studied and in one of the two X chromosomes in obligate carriers. This large molecular and cytogenetically visible deletion in affected DMD individuals without glycerol kinase deficiency, chronic granulomatous disease, retinitis pigmentosa (RP), or ornithine transcarbamylase deficiency is a very rare finding and should prove useful in specifically cloning additional probes within and flanking the DMD locus.     

Fluorescent multiplex linkage analysis and carrier detection for Duchenne/Becker muscular dystrophy.

We have developed a fast and accurate PCR-based linkage and carrier detection protocol for families of Duchenne muscular dystrophy (DMD)/Becker muscular dystrophy (BMD) patients with or without detectable deletions of the dystrophin gene, using fluorescent PCR products analyzed on an automated sequencer. When a deletion is found in the affected male DMD/BMD patient by standard multiplex PCR, fluorescently labeled primers specific for the deleted and nondeleted exon(s) are used to amplify the DNA of at-risk female relatives by using multiplex PCR at low cycle number (20 cycles). The products are then quantitatively analyzed on an automatic sequencer to determine whether they are heterozygous for the deletion and thus are carriers. As a confirmation of the deletion data, and in cases in which a deletion is not found in the proband, fluorescent multiplex PCR linkage is done by using four previously described polymorphic dinucleotide sequences. The four (CA)n repeats are located throughout the dystrophin gene, making the analysis highly informative and accurate. We present the successful application of this protocol in families who proved refractory to more traditional analyses.     

Brother/sister pairs affected with early-onset, progressive muscular dystrophy: molecular studies reveal etiologic heterogeneity.

An autosomal recessive (AR) form of muscular dystrophy that clinically resembles Duchenne/Becker types exists, but its frequency is unknown. We have studied three unrelated affected brother/sister pairs and their families for deletions and polymorphisms with the entire dystrophin cDNA and other DNA probes from the Xp21 region to test for involvement of the DMD locus. In family 1 a large intragenic deletion was found in the affected male. The affected sister was heterozygous for this deletion, but the mother was not, implying germinal mosaicism. In family 2, no deletion was detected in the affected male. RFLP analysis revealed that the affected male and an unaffected sister shared a complete Xp21 haplotype while the affected sister had inherited a recombinant Xp21 region resulting from a crossover between pERT 87-15 and J-Bir. Only the 5' region of the dystrophin gene was shared with the affected boy. X-inactivation studies using a polymorphism in the 5'-flanking region of the HPRT gene, in conjunction with methylation-sensitive enzymes, revealed random X inactivation in the affected girl's leukocytes. In a muscle biopsy from the affected male, the dystrophin protein was present in normal amount and size. Family 3 was informative for four RFLPs detected with dystrophin cDNA probes which span the entire gene. The affected male was found to share the complete dystrophin RFLP haplotype with his unaffected brother, while his affected sister had inherited the other maternal haplotype. It is concluded that the clinical presentation of early-onset, progressive muscular dystrophy in a male and in his karyotypically normal sister can be caused by mutations at different loci. While in family 1 a deletion in the dystrophin gene is responsible, this gene does not appear to be involved in families 2 and 3.     

Molecular genetic characteristics of Duchenne-Becker muscular dystrophy in the Republic of Moldova

Solution to some problems of clinical genealogical and molecular genetic study of Duchenne muscular dystrophy (DMD) in the Republic of Moldova and prenatal diagnosis aimed at preventing the birth of infants with this disease is proposed. An integrated clinical and molecular genetic study of families with a high risk of DMD has allowed its specific characteristics in the Moldovan population to be identified. The spectrum of mutations at the gene level in DMD patients and their role in prenatal and clinical diagnosis has been determined. RFLP analysis and PCR have been used to estimate the informativeness of families with a high DMD risk; prenatal diagnosis has been performed in some of them. Population analysis of the frequencies of polymorphic restriction sites have been carried out for loci pERT87-8/Tag1, pERT87-15/BamH1, and 16intron/Tag1. The results of analysis of deletion frequencies in the dystrophin gene and the frequencies of the pERT87-8, pERT87-15, and 16intron intragenic polymorphic loci have served as a basis for a strategy of molecular diagnosis. The new strategy allows the informativeness to be evaluated and, hence, clinical, preclinical, and prenatal diagnosis to be performed in approximately 94% of cases. A modified PCR method (MPCR) using the system of primers pERT87-8/Tag1 and 16intron/Tag1 has been developed for direct search for deletions. The method makes it possible to avoid diagnostic errors and decrease both the duration and the cost of the analysis.     

Familial deletion of Xp21.2 with glycerol kinase deficiency and congenital adrenal hypoplasia

Summary Congenital adrenal hypoplasia (CAH) and glycerol kinase deficiency (GKD) were diagnosed in a male during the neonatal period. On prometaphase chromosomes there was an interstitial deletion involving Xp21.2 and possibly Xp21.3 in the propositus and his mother. Duchenne muscular dystrophy (DMD) was excluded on the basis of normal serum creatine kinase and a muscle biopsy. Molecular hybridization of DNA from the propositus with 11 probes covering Xp21, including the DMD locus, was normal. In situ hybridization with the probe pERT87.15 showed a normal signal at the expected site indicating that the DMD locus was preserved and not translocated. This suggests that the DMD locus is located at the most proximal part of the sub-band Xp21.2 or in Xp21.1, and that the DXS68 (probe L1) is far from it on the distal flanking DNA.     

FMR1 gene deletion/reversion: a pitfall of fragile X carrier testing

The Fragile X syndrome is, in the majority of cases, caused by CGG trinucleotide amplification within the FMR1 gene. The syndrome is rarely caused by point mutations or deletions. Here we describe a family with 2 sons and 1 daughter affected by Fragile X syndrome and 2 unaffected daughters whose carrier status was unknown prior to this study. Analysis of DNA from each of the 2 daughters revealed two alleles in the normal size range. However, 1 daughter carried one allele of 10 CGG repeats that was not present in either the mother or the father. No evidence for mosaicism could be detected. Haplotype analysis of flanking polymorphic markers revealed that the 10 CGG allele was derived from the mutated allele inherited from the mother. Thus, this case most likely represents an additional case of a reverse mutation from a premutation allele in a female to a normal-sized allele in the offspring. It remains unclear how frequently such reversion events occur. The observation has important consequences for genetic testing, because many laboratories prescreen for the Fragile X syndrome by determining the length of the CGG repeat using PCR. If this shows alleles in the normal size range, a diagnosis of Fragile X syndrome is considered to be excluded. Because the routine PCR and/or Southern blot analyses alone may yield false-negative results in cases of a regression of the number of CGG repeats, we strongly recommend the inclusion of fragment length or haplotype analysis when determining the carrier status within Fragile X syndrome families.     

多重连接探针扩增方法在假肥大性肌营养不良产前基因诊断中的应用

假肥大性肌营养不良(Duchenne/Becker muscular dystrophy, DMD/BMD)是一种由于DMD基因突变导致的X连锁隐性致死性遗传病。目前没有有效的治疗方法。为建立一种既可以对携带者进行检测又可以进行产前基因诊断的方法, 文章联合应用多重连接探针扩增技术(Multiplex ligation-dependent probe amplification, MLPA)和短串联重复序列(Short tandem repeats , STR)为遗传标记连锁分析的方法对26例有高风险再生育患儿的假肥大性肌营养不良家系的孕妇通过羊水穿刺进行产前基因诊断。26例进行产前基因诊断的羊水标本中有7例诊断为男性患儿, 4例诊断为女性携带者。MLPA可以作为筛查DMD基因缺失和重复突变的首选方法。联合应用MLPA和STR连锁分析, 可以提高假肥大性肌营养不良的产前基因诊断率。     

Direct carrier detection by in situ suppression hybridization with cosmid clones of the Duchenne/Becker muscular dystrophy locus

Summary A basic problem in genetic counseling of families with Duchenne/Becker muscular dystrophy (DMD/BMD) concerns the carrier status of female relatives of an affected male. In about 60% of these patients, deletions of one or more exons of the dystrophin gene can be identified. These deletions preferentially include exon 45, which can be detected by multiplex polymerase chain reaction (PCR) and Southern blot analysis of genomic cosmid clones that map to this critical region. As a new approach for definitive carrier detection, we have performed chromosomal in situ suppression (CISS) hybridization with these cosmid clones in female relatives of four unrelated patients. In normal females, most metaphases showed signals on both×chromosomes, whereas only one×chromosome was labeled in carriers. Our results demonstrate that CISS hybridization can define the carrier status in female relatives of DMD patients exhibiting a deletion in the dystrophin gene.     

Deletion screening of the Duchenne muscular dystrophy locus via multiplex DNA amplification.

The application of recombinant DNA technology to prenatal diagnosis of many recessively inherited X-linked diseases is complicated by a high frequency of heterogeneous, new mutations (1). Partial gene deletions account for more than 50% of Duchenne muscular dystrophy (DMD) lesions, and approximately one-third of all cases result from a new mutation (2-5). We report the isolation and DNA sequence of several deletion prone exons from the human DMD gene. We also describe a rapid method capable of detecting the majority of deletions in the DMD gene. This procedure utilizes simultaneous genomic DNA amplification of multiple widely separated sequences and should permit deletion scanning at any hemizygous locus. We demonstrate the application of this multiplex reaction for prenatal and postnatal diagnosis of DMD.     

Deletion proximal to DXS68 locus (L1 probe site) in a boy with Duchenne muscular dystrophy,glycerol kinase deficiency,and adrenal hypoplasia

Summary We report a case of a boy with Duchenne muscular dystrophy (DMD) associated with GK deficiency (GK), congenital adrenal hypoplasia (AHC), and mental retardation. Cytogenetic analysis of prometaphasic chromosomes revealed an interstitial chromosome deletion at Xp21.2 possibly extending to Xp21.1 or Xp21.3. His phenotypically normal mother was heterozygous for this deletion. DNA probe analysis on Southern blots showed that the deletion affected the following probe sites: 754, pERT 84, 21A, XJ2.3, pERT 87, JBir, and J66-H1, whereas L1, C7, and CX5.4 probes gave a normal signal. Pulse field gel electrophoresis after SfiI digestion did not show abnormal fragments with L1. These data are consistent with a deletion of about 4 megabases and indicate that the GK and AHC loci are proximal to L1 and distal to J66-H1.     

Familial deletion in Becker type muscular dystrophy within the pXJ region

Summary A family of an isolated patient with Becker muscular dystrophy has been investigated by DNA analysis. Southern blotting and hybridization were performed with six probes (C7, pERT87.15, pERT87.1, pXJ1.1, pXJ2.3, 754) mapping in the Xp21 region. A deletion within the pXJ region was demonstrated in the proband, his mother and all three sisters. The segregation pattern for the restriction fragment length polymorphisms (RFLPs) observed with the pXJ probes as well as with pERT87.15, pERT87.1 and 754 probes indicates that the deletion is of grandpaternal origin.     

Familial inheritance of a DXS164 deletion mutation from a heterozygous female.

Restriction-fragment-length-polymorphism analysis was used to examine a female who is segregating for Duchenne muscular dystrophy (DMD) and a deletion of the DXS164 region of the X chromosome. The segregating female has no prior family history of DMD, and she has two copies of the DXS164 region in her peripheral blood lymphocytes. The following two hypotheses are proposed to explain the coincidence of the DMD phenotype and deletion of the DXS164 region in her offspring: (1) she may be a gonadal mosaic for cells with two normal X chromosomes and cells with one normal X chromosome and an X chromosome with a deletion of the DXS164 region; and (2) she may carry a familial X;autosome translocation in which the DXS164 region is deleted from one X chromosome and translocated to an autosome. The segregation of DMD and the DXS164 deletion in this family illustrates the importance of extended pedigree analysis when DXS164 deletions are used to identify female carriers of the DMD gene.     

A very small frame-shifting deletion within exon 19 of the Duchenne muscular dystrophy gene

We report the molecular characterization of a Japanese Duchenne muscular dystrophy (DMD) patient. The analysis of genomic gene by polymerase chain reaction indicates that the individuals have a limited deletion within an amplified region, which encompasses exon 19 of DMD gene. The amplified region was sequenced. Comparison of the deletion joint sequence with the normal amplified region sequence indicates that both 5' and 3' deletion end points are present within exon 19 and the deletion removes total 52 bp out of 88 bp of exon 19. Both his mother and sister are carriers of the deletion-containing allele. The mutation introduces a termination codon at residue 791 in exon 20, and is predicted to result in the production of a severely truncated protein. This sort of deletion (designated as DMD-Kobe) might be classified as a new type of DMD gene abnormality.     

X-linked Menkes disease: first documented report of germ-line mosaicism

This work investigated a three-generation Menkes disease family, where germ-line mosaicism was suspected in the maternal grandmother of the index patient. She had given birth to 2 boys who died of suspected Menkes disease on the basis of clinical and photographic evidence. Biochemical analysis of the index patient confirmed the diagnosis of Menkes disease, and DNA analysis established a partial gene deletion (EX11_EX23del), involving exons 11-23 and the 3'-untranslated region (UTR) of ATP7A. A junction fragment was detectable by Southern blot analysis, which enabled carrier analysis. The mother was demonstrated to be a carrier, whereas analysis of lymphoblasts and skin fibroblasts from the maternal grandmother gave no indication of a partial gene deletion. No materials were available from the possibly affected maternal uncles. Further genetic analyses, including biochemical testing of the grandmother and haplotype analysis using four intragenic markers on DNA from selected members of the family, corroborated this finding. The combined results from DNA analyses showed that the grandmother had transmitted three different ATP7A haplotypes to her offspring: (1) the at-risk allele (CA(B))-1 and the deletion; (2) the at-risk allele (CA(B))-1 without deletion; and (3) the second allele (CAB)-2 without deletion. In conclusion, our study demonstrated segregation of Menkes disease within the family investigated that can best be explained by extensive germ-line mosaicism in the maternal grandmother. The finding of germ-line mosaicism has obvious implications for genetic counseling of Menkes disease families.     

Importance of genetic diagnosis of DAX-1 deficiency: example from a large, multigenerational family

BACKGROUND: Inactivating mutations of DAX-1 give rise to the X-linked form of adrenal hypoplasia congenita (AHC). Affected fetuses are at risk of early postnatal Addisonian crisis, but the variable phenotypic expression of DAX-1 insufficiency renders this diagnosis challenging. METHODS: We describe the familial transmission of AHC over several generations. The proband was diagnosed with adrenal insufficiency at age 3.5 years: molecular analysis revealed a novel, 373-bp deletion including the second exon of DAX-1. Given the familial history of several unexplained deaths in male infants related to the proband via his maternal great-grandmother, we hypothesized that all these boys had been affected with AHC. Another female member of the family being pregnant with a male fetus at the time, we performed DAX-1 analysis on the mother and the newborn. The mother was heterozygous for the deletion, and the newborn hemizygous: he presented an adrenal crisis at 10 days of life, and is now doing well on hormone replacement therapy. CONCLUSION: The unfortunate deaths of male infants at each generation of this family underlie the importance of early and precise diagnosis of this rare condition, stressing the value of genetic diagnosis in six potential female carriers of this family entering their reproductive years.     

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.     

Genotype-phenotype correlation and germline mosaicism in DMD/BMD patients with deletions of the dystrophin gene

Summary The molecular analysis of 127 DMD/BMD patients showed that 73 of them (57%) had deletions in the dystrophin gene. Two different methods were used in this study: (a) hybridization of HindIII-digested genomic DNA with nine cDNA probes corresponding to the entire 14 kb cDNA of the DMD gene; and (b) simultaneous amplification of nine exons of the DMD gene (multiplex DNA amplification) by the polymerase chain reaction (PCR). When the deletion breakpoints of the intragenic deletions were analyzed with regard to their phenotypic consequences, nine patients were found to represent exceptions to the reading-frame hypothesis. Information regarding mental development was also available for 61 of the 73 deleted patients and for 34 of the 54 non-deleted ones. The proportion of mentally retarded patients was found to be similar in the two groups (deleted, 15%; non-deleted, 18%). Finally, in one family, a junction fragment present in the patient was not found in the peripheral blood DNA of the mother but was present in the sister, thus indicating germline mosaicism in the mother.     

Uniparental disomy of the entire X chromosome in a female with Duchenne muscular dystrophy.

Duchenne muscular dystrophy (DMD) is a severe, progressive, X-linked muscle-wasting disorder with an incidence of approximately 1/3,500 male births. Females are also affected, in rare instances. The manifestation of mild to severe symptoms in female carriers of dystrophin mutations is often the result of the preferential inactivation of the X chromosome carrying the normal dystrophin gene. The severity of the symptoms is dependent on the proportion of cells that have inactivated the normal X chromosome. A skewed pattern of X inactivation is also responsible for the clinical manifestation of DMD in females carrying X;autosome translocations, which disrupt the dystrophin gene. DMD may also be observed in females with Turner syndrome (45,X), if the remaining X chromosome carries a DMD mutation. We report here the case of a karyotypically normal female affected with DMD as a result of homozygosity for a deletion of exon 50 of the dystrophin gene. PCR analysis of microsatellite markers spanning the length of the X chromosome demonstrated that homozygosity for the dystrophin gene mutation was caused by maternal isodisomy for the entire X chromosome. This finding demonstrates that uniparental isodisomy of the X chromosome is an additional mechanism for the expression of X-linked recessive disorders. The proband's clinical presentation is consistent with the absence of imprinted genes (i.e., genes that are selectively expressed based on the parent of origin) on the X chromosome.