Simultaneous mutation scanning for gross deletions, duplications and point mutations in the DMD gene

We have developed a technique to screen for gross deletions/duplications and point mutations using one streamlined approach. Fluorescent multiplex quantitative PCR is used to determine the copy number of each exon, followed by conformation sensitive capillary electrophoresis (CSCE) of the same PCR products on a multi-capillary genetic analyser. We have developed this technique to screen all 79 exons of one of the largest human genes currently known (dystrophin) using 12 multiplex PCR assays. A blind trial of 50 male and 50 female samples, in which 84 mutations had previously been found and characterized by other techniques, showed 100% sensitivity and specificity. We then applied this method to screen over 100 patient samples previously screened for deletions and duplications of 28 exons from the two hotspot regions. Our data show that combining a full deletion/duplication screen with CSCE will detect a mutation in 98% of Duchenne muscular dystrophy patients and 93% of Becker muscular dystrophy patients where the clinical diagnosis is certain. This technique is applicable to any gene and is particularly suited to mutation screening of large genes, decreasing the time taken for a complete gene screen for nearly all mutation types.     

Novel point mutations in the dystrophin gene

Duchenne (DMD) and Becker (BMD) type muscular dystrophies are allelic X-linked recessive disorders caused by mutations in the gene encoding dystrophin. About 65% of the cases are caused by deletions, while 5–10% are duplications. The remaining 30% of affected individuals may have smaller mutations (point mutations or small deletions/insertions) which cannot be identified by current diagnostic screening strategies. In order to look for pathogenic small mutations in the dystrophin gene, we have screened the 18 exons located in the hot spot region of this gene through two different single strand conformation polymorphism (SSCP) conditions. Five different pathogenic mutations were identified in 6 out of 192 DMD/BMD patients without detectable deletions: 2 nonsense, 1 bp insertion, 1 bp deletion and 1 intronic. Except for the intronic change, which alters a splice site, all the others cause a premature stop codon. In addition, 8 apparently neutral changes were identified. However, interestingly, one of them was not identified in 195 normal chromosomes, although it was previously described in a DMD patient from a different population. The possibility that this mutation may be pathogenic is discussed. Except for two neutral changes, all the others are apparently here described for the first time. Hum Mutat 10:217–222, 1997. © 1997 Wiley-Liss, Inc.     

Duchenne肌营养不良症患者及携带者的基因缺失和重复突变检测

目的利用多重连接依赖探针PCR扩增技术检测Duchenne肌营养不良症（Duchenne muscular dystrophy，DMD）患者及其可能的女性携带者的dystrophin基因的缺失、重复突变。方法利用多重连接依赖探针PCR扩增对32例DMD患者及其27个可能的女性携带者的dystrophin基因缺失、重复进行检测。结果32个先证者中，共检测出了24例DMI）患者具有一个或多个外显子的缺失，l例DMD患者具有重复突变，l例患者为第19外显子的无义突变（R768X），6例没有检测出缺失、重复突变的先证者可能是点突变所致。17个先证者的18位女性亲属具有和先证者相同的缺失、重复突变。结论多重连接依赖探针PCR扩增技术可用于检测DMD基因的缺失、重复突变，可以检测DMD基因女性携带者的基因杂合情况，在检测DMD基因缺失和重复方面，具有一定的应用价值。     

非缺失/重复型Duchenne肌营养不良症患者的致病点突变分析

目的检测非缺失／重复突变型Duchenne肌营养不良症（Duchenne muscular dystrophy，DMD）的致病点突变。方法对6个家系的6个无关DMD男性患者的DMD基因的79个外显子及5′-3′-非翻译序列进行PER扩增，产物通过变性高效液相色谱（denaturing high performance liquid chromatography，DHPLC）技术进行突变筛查。结果6例非缺失／重复突变型Duchenne肌营养不良症患者，检测出了5例患者的致病点突变，即697-698insGT，C616T，G1255T，C4279T和C2302T。第1个点突变引起移码突变，后4个致病点突变引起翻译的提前终止，最终导致Duchenne肌营养不良症。患者3除致病点突变外，在第39内含子还发现1个T5586＋61A点突变；患者5还检测出了一个位于第8外显子的错义突变；而没有检出致病点突变的患者6，发现了2个外显子突变及2个内含子序列点突变，即C2168＋13T、G5234A、C5280T和5740-13dupG。所有检出的突变有7个点突变未见报道。结论变性高效液相色谱技术结合测序，可用于检测DMD患者的点突变．该方法具有准确，灵敏的特点。     

POLG mutations in sporadic mitochondrial disorders with multiple mtDNA deletions

The accumulation of multiple mitochondrial DNA (mtDNA) deletions in stable tissues is a distinctive feature of several autosomal disorders, characterized by Progressive External Ophthalmoplegia (PEO), ptosis, and proximal myopathy. At least three nuclear genes are responsible for these disorders: ANT1 and C10orf2 cause autosomal dominant PEO, while mutations of DNA polymerase gammaA (POLG1 or POLG) gene on chromosome 15q25 causes both autosomal dominant and recessive forms of PEO. To investigate the contribution of these genes to the sporadic cases of PEO with multiple mtDNA deletions, we studied 31 mitochondrial myopathy patients without any family history for the disorder: 23 had PEO with myopathy, with or without the additional features of pigmentary retinopathy, ataxia, neurosensorial hypoacusia and diabetes mellitus, 7 presented isolated myopathy and one a peripheral neuropathy with ptosis. In all patients Southern blot of muscle DNA showed multiple mtDNA deletions; screening for ANT1 and C10ORF2 genes was negative. POLG analysis revealed mutations in eight patients; in six of them the mutations were allelic, while two patients were heterozygous. Five mutations were new, namely one stop codon (c.2407C>T/p.R709X) and four missense mutations (c.1085G>C/p.G268A; c.1967G>A/p.R562Q; c.2702G>C/p.R807P; c.3076C>T/p.H932W). A high degree of conservation was observed for all the new missense mutations. Only patients presenting PEO as part of their clinical phenotype had POLG mutations, in seven of them together with myopathic signs and in one with a sensori-motor peripheral neuropathy.     

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.     

Expanding the spectrum of TBX5 mutations in Holt-Oram syndrome: detection of two intragenic deletions by quantitative real time PCR, and report of eight novel point mutations

Mutations in the gene TBX5 cause Holt-Oram syndrome (HOS), an autosomal dominant disorder characterized by anterior (i.e., radial ray) upper limb malformations and congenital heart defects and/or cardiac conduction anomalies. The detection rate for TBX5 mutations in HOS patients has been given as 30-35% in most reports. However, a detection rate of 74% was reported when strict clinical inclusion criteria for HOS were applied prior to TBX5 analysis. Still, in a significant proportion of typical HOS cases no mutation can be found within the TBX5 coding region and flanking intronic sequences. One explanation could be that large but submicroscopic deletions of TBX5 could cause HOS, yet only one such TBX5 deletion has been reported to date. We developed a quantitative Real Time PCR strategy to detect large, submicroscopic deletions in TBX5. Using this assay, we screened a total of 102 TBX5 mutation negative patients and discovered two novel intragenic deletions. One deletion of 7756 bp removes exon 6 and a considerable part of the neighboring intronic sequences, and the other of 3695 bp removes exon 9 with the stop codon and the 3'UTR completely as well as a part of the preceding intron 8. We conclude that quantitative Real Time PCR is a reliable method to detect submicroscopic deletions within TBX5. However, such deletions explain only approximately 2% of the TBX5 mutational spectrum in HOS cases. In addition, we also present eight novel TBX5 mutations (three nonsense, one splice mutation, four short deletions) as detected by direct sequencing in 21 families not previously analyzed for mutations.     

Protein- and mRNA-based phenotype-genotype correlations in DMD/BMD with point mutations and molecular basis for BMD with nonsense and frameshift mutations in the DMD gene

Straightforward detectable Duchenne muscular dystrophy (DMD) gene rearrangements, such as deletions or duplications involving an entire exon or more, are involved in about 70% of dystrophinopathies. In the remaining 30% a variety of point mutations or "small" mutations are suspected. Due to their diversity and to the large size and complexity of the DMD gene, these point mutations are difficult to detect. To overcome this diagnostic issue, we developed and optimized a routine muscle biopsy-based diagnostic strategy. The mutation detection rate is almost as high as 100% and mutations were identified in all patients for whom the diagnosis of DMD and Becker muscular dystrophy (BMD) was clinically suspected and further supported by the detection on Western blot of quantitative and/or qualitative dystrophin protein abnormalities. Here we report a total of 124 small mutations including 11 nonsense and frameshift mutations detected in BMD patients. In addition to a comprehensive assessment of muscular phenotypes that takes into account consequences of mutations on the expression of the dystrophin mRNA and protein, we provide and discuss genomic, mRNA, and protein data that pinpoint molecular mechanisms underlying BMD phenotypes associated with nonsense and frameshift mutations.     

Genetic analysis of dystrophin gene for affected male and female carriers with Duchenne/Becker muscular dystrophy in Korea

Duchenne and Becker muscular dystrophy (DMD/BMD) are X-linked recessive disorders caused by mutation in dystrophin gene. We analyzed the results of a genetic test in 29 DMD/BMD patients, their six female relatives, and two myopathic female patients in Korea. As the methods developed, we applied different procedures for dystrophin gene analysis; initially, multiplex polymerase chain reaction was used, followed by multiplex ligation-dependent probe amplification (MLPA). Additionally, we used direct DNA sequencing for some patients who had negative results using the above methods. The overall mutation detection rate was 72.4% (21/29) in DMD/BMD patients, identifying deletions in 58.6% (17/29). Most of the deletions were confined to the central hot spot region between exons 44 and 55 (52.9%, 7/19). The percentage of deletions and duplications revealed by MLPA was 45.5% (5/11) and 27.2% (3/11), respectively. Using the MLPA method, we detected mutations confirming their carrier status in all female relatives and symptomatic female patients. In one patient in whom MLPA revealed a single exon deletion of the dystrophin gene, subsequent DNA sequencing analysis identified a novel nonsense mutation (c.4558G > T; Gln1520X). The MLPA assay is a useful quantitative method for detecting mutation in asymptomatic or symptomatic carriers as well as DMD/BMD patients.     

Novel POLG mutations in progressive external ophthalmoplegia mimicking mitochondrial neurogastrointestinal encephalomyopathy

Autosomal recessive progressive external ophthalmoplegia (PEO) is one clinical disorder associated with multiple mitochondrial DNA deletions and can be caused by missense mutations in POLG, the gene encoding the mitochondrial DNA polymerase gamma. Mitochondrial neurogastrointestinal encephalomyopathy (MNGIE) is another autosomal recessive disorder associated with PEO and multiple deletions of mitochondrial DNA in skeletal muscle. In several patients this disorder is caused by loss of function mutations in the gene encoding thymidine phosphorylase (TP). We report a recessive family with features of MNGIE but no leukoencephalopathy in which two patients carry three missense mutations in POLG, of which two are novel mutations (N846S and P587L). The third mutation was previously reported as a recessive POLG mutation (T251I). This finding indicates the need for POLG sequencing in patients with features of MNGIE without TP mutations.     

STR-PCR联合SRY-PCR方法在DMD点突变家系产前基因诊断中的应用

目的对点突变型假肥大型肌营养不良症（Duchenne＇s muscular dystrophy,DMD）患者的家系采用STR-PCR联合SRY-PCR分析方法进行产前基因诊断。方法采用STR-PCR连锁分析方法和SRY-PCR方法对20个点突变型DMD家系进行产前基因诊断。结果男性胎儿40%（8/20）,其中患胎62.5%（5/8）;女性胎儿60%（12/20）,其中携带者58.3%（7/12）。结论 STR-PCR连锁分析方法结合SRY-PCR方法用于点突变型DMD家系的产前诊断,是目前一种快速、简便、准确和可行的方法。     

The rate of germline mutations and large deletions of SMAD4 and BMPR1A in juvenile polyposis

Juvenile polyposis (JPS) is an autosomal dominant syndrome that predisposes individuals to develop gastrointestinal polyps and cancer. Germline point mutations in SMAD4 and BMPR1A have been identified as causing JPS in approximately 40–60% of patients, but few studies have looked at the rate of large deletions. In this study, we determined the overall prevalence of genetic changes of SMAD4 and BMPR1A by sequencing and by screening for larger deletions. DNA was extracted from 102 JPS probands, and each exon and intron–exon boundary of SMAD4 and BMPR1A were sequenced. Coding and non-coding exons of SMAD4 and BMPR1A were screened for deletions with multiplex ligation-dependent probe amplification (MLPA). By sequencing, 20 probands had point mutations of SMAD4 and 22 of BMPR1A . By MLPA, one proband had deletion of most of SMAD4 , one of both BMPR1A and PTEN , one of the 5' end of BMPR1A , and another of the 5' end of SMAD4 . The overall prevalence of SMAD4 and BMPR1A point mutations and deletions in JPS was 45% in the largest series of patients to date. Large deletions are less frequent in JPS patients, but represent other heritable causes of JPS, which should be screened for in pre-symptomatic genetic testing.     

Identification of two novel SMN1 point mutations associated with a very severe SMA-I phenotype

Spinal muscular atrophy (SMA) is a common autosomal recessive genetic disorder characterized by degeneration of motor neurons and weakness and muscle atrophy. Approximately 95% of SMA patients are caused by homozygous deletions of the SMN1 gene, whereas the remaining 5% of patients harbor compound heterozygous mutations such as an SMN1 deletion allele and an intragenic mutation (insertions, deletions, or point mutations) in the other SMN1 allele. Although analysis for the SMN1/SMN2 copy number is relatively easy, molecular genetic testing for patients with subtle mutations is still compromised due to the presence of a highly homologous SMN2 gene. Herein, we analyzed the SMN1/SMN2 copy number by multiplex ligation-dependent probe amplification (MLPA) and subtle mutations by long-range PCR (LR-PCR) for two “nondeletion” SMA patients. We identified a missense mutation (c.280G > T, p. (Val94Phe)) and a splicing mutation c.*3+3A > T in SMN1 gene not previously described in the scientific literature. Giving the severe phenotype of the two patients, we speculated that these two point mutations could significantly affect the function of SMN proteins. Our results provide important information for genetic counseling and prenatal diagnosis in these families and enrich the SMN1 mutation database.     

The prevalence of intragenic deletions in patients with idiopathic hypogonadotropic hypogonadism and Kallmann syndrome

Idiopathic hypogonadotropic hypogonadism (IHH) and Kallmann syndrome (KS) are clinically and genetically heterogeneous disorders caused by a deficiency of gonadotrophin-releasing hormone (GnRH). Mutations in three genes--KAL1, GNRHR and FGFR1--account for 15-20% of all causes of IHH/KS. Nearly all mutations are point mutations identified by traditional PCR-based DNA sequencing. The relatively new method of multiplex ligation-dependent probe amplification (MLPA) has been successful for detecting intragenic deletions in other genetic diseases. We hypothesized that MLPA would detect intragenic deletions in approximately 15-20% of our cohort of IHH/KS patients. Fifty-four IHH/KS patients were studied for KAL1 deletions and 100 were studied for an autosomal panel of FGFR1, GNRH1, GNRHR, GPR54 and NELF gene deletions. Of all male and female subjects screened, 4/54 (7.4%) had KAL1 deletions. If only anosmic males were considered, 4/33 (12.1%) had KAL1 deletions. No deletions were identified in any of the autosomal genes in 100 IHH/KS patients. We believe this to be the first study to use MLPA to identify intragenic deletions in IHH/KS patients. Our results indicate approximately 12% of KS males have KAL1 deletions, but intragenic deletions of the FGFR1, GNRH1, GNRHR, GPR54 and NELF genes are uncommon in IHH/KS.     

Theoretic applicability of antisense‐mediated exon skipping for Duchenne muscular dystrophy mutations

Antisense‐mediated exon skipping aiming for reading frame restoration is currently a promising therapeutic application for Duchenne muscular dystrophy (DMD). This approach is mutation specific, but as the majority of DMD patients have deletions that cluster in hotspot regions, the skipping of a small number of exons is applicable to relatively large numbers of patients. To assess the actual applicability of the exon skipping approach, we here determined for deletions, duplications and point mutations reported in the Leiden DMD mutation database, which exon(s) should be skipped to restore the open reading frame. In theory, single and double exon skipping would be applicable to 79% of deletions, 91% of small mutations, and 73% of duplications, amounting to 83% of all DMD mutations. Exon 51 skipping, which is being tested in clinical trials, would be applicable to the largest group (13%) of all DMD patients. Further research is needed to determine the functionality of different in‐frame dystrophins and a number of hurdles has to be overcome before this approach can be applied clinically. Hum Mutat 0, 1–7, 2009. © 2009 Wiley‐Liss, Inc.     

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.     

Screening of male patients with autosomal recessive Duchenne dystrophy through dystrophin and DNA studies

Previously we estimated that about 2.5-4% of isolated male patients diagnosed as Duchenne dystrophy (DMD) may have the autosomal recessive form (AR-DMD). Such cases can be distinguished from X-linked DMD through the analysis of dystrophin. Fifty DMD patients from 47 families were investigated for dystrophin and DNA deletions. Based on our results, we estimate that the frequency of AR-DMD may be about 8-12% among male patients diagnosed as DMD in whom X-linked inheritance could not be confirmed through pedigree data, serum enzymes in female relatives or DNA studies. Such an estimate must be confirmed in a larger sample; however, it shows the importance of assessing dystrophin in all patients diagnosed as DMD in whom X-linked inheritance cannot be proved, since the distinction between these 2 forms has implications for genetic counseling.     

Germinal mosaicism increases the recurrence risk for ''new'' Duchenne muscular dystrophy mutations.

In 288 Dutch and Belgian Duchenne and Becker muscular dystrophy families, the parental origin of 41 new deletion or duplication mutations was determined. Twenty seven of the new mutations occurred in the maternal X chromosome and nine in the grandmaternal and five in the grandpaternal X chromosome. The grandparental data are compatible with equal mutation rates for DMD in male and female X chromosomes. New mutations were defined by their presence in one or more progeny and absence in the lymphocytes of the mother or the grandparents. In one family a fraction of the maternal lymphocytes was found to carry the mutation, suggesting somatic mosaicism. In six cases out of 41, the mutation was transmitted more than once by a parent in whom the mutation was absent in lymphocytes, suggesting gonadal mosaicism as the explanation for the multiple transmission. Using our data for the recurrence of the mutations among the total of at risk haplotypes transmitted, we arrive at a recurrence risk of 14% for the at risk haplotype. The observation of this high risk of germinal mosaicism is crucially important for all physicians counselling females in DMD families. Recently, germinal mosaicism has been observed also in a number of other X linked and autosomal disorders. The implications and appropriate diagnostic precautions are discussed.     

Exon-level array CGH in a large clinical cohort demonstrates increased sensitivity of diagnostic testing for Mendelian disorders

PurposeMendelian disorders are most commonly caused by mutations identifiable by DNA sequencing. Exonic deletions and duplications can go undetected by sequencing, and their frequency in most Mendelian disorders is unknown.MethodsWe designed an array comparative genomic hybridization (CGH) test with probes in exonic regions of 589 genes. Targeted testing was performed for 219 genes in 3,018 patients. We demonstrate for the first time the utility of exon-level array CGH in a large clinical cohort by testing for 136 autosomal dominant, 53 autosomal recessive, and 30 X-linked disorders.ResultsOverall, 98 deletions and two duplications were identified in 53 genes, corresponding to a detection rate of 3.3%. Approximately 40% of positive findings were deletions of only one or two exons. A high frequency of deletions was observed for several autosomal dominant disorders, with a detection rate of 2.9%. For autosomal recessive disorders, array CGH was usually performed after a single mutation was identified by sequencing. Among 138 individuals tested for recessive disorders, 10.1% had intragenic deletions. For X-linked disorders, 3.5% of 313 patients carried a deletion or duplication.ConclusionOur results demonstrate that exon-level array CGH provides a robust option for intragenic copy number analysis and should routinely supplement sequence analysis for Mendelian disorders.Genet Med 2012:14(6):594–603