应用多重PCR和MLPA技术检测DMD患者和携带者的基因突变及产前诊断

目的 应用多重PCR和多重连接依赖探针扩增(multiplex ligation-dependent probe amplification,MLPA)技术检测Duchenne/Becker肌营养不良症(Duchenne/Becker muscular dystrophy,DMD/BMD)患者、携带者并应用于产前诊断.方法 首先采用多重PCR对临床诊断为DMD/BMD的患者检测DMD基因的26个外显子,未查到缺失突变者和可能的携带者采用MLPA检测全部79个外显子是否有缺失或重复突变.对产前诊断病例,用PCR法检测缺失突变,用MLPA法检测重复突变.结果 多重PCR对22例患者的DMD基因的26个外显子检测.13例有缺失突变.未查到常见缺失突变的9例患者经MLPA检测DMD基因的全部79个外显子,3例为重复突变、1例为单个第18外显子缺失、其他5例未查到缺失和重复突变.16例携带者中,3例有家族史,其中2例检出突变;13例为检测到突变的散发病例患儿的母亲,有8例检测到突变.产前诊断9个胎儿(其中双胎1例),2例胎儿有突变,引产后核实无误;7例胎儿未检测到突变,现均已分娩.结论 多重PCR可检出92.86%的缺失突变并可用于缺失突变的产前诊断,因其简便、可靠、价廉可作为临床上DMD/BMD基因诊断的初选.MLPA可用于多重PCR未检测到缺失突变的患者及携带者的检查.     

应用多重PCR和MLPA技术检测DMD患者和携带者的基因突变及产前诊断

目的 应用多重PCR和多重连接依赖探针扩增(multiplex ligation-dependent probe amplification,MLPA)技术检测Duchenne/Becker肌营养不良症(Duchenne/Becker muscular dystrophy,DMD/BMD)患者、携带者并应用于产前诊断.方法 首先采用多重PCR对临床诊断为DMD/BMD的患者检测DMD基因的26个外显子,未查到缺失突变者和可能的携带者采用MLPA检测全部79个外显子是否有缺失或重复突变.对产前诊断病例,用PCR法检测缺失突变,用MLPA法检测重复突变.结果 多重PCR对22例患者的DMD基因的26个外显子检测.13例有缺失突变.未查到常见缺失突变的9例患者经MLPA检测DMD基因的全部79个外显子,3例为重复突变、1例为单个第18外显子缺失、其他5例未查到缺失和重复突变.16例携带者中,3例有家族史,其中2例检出突变;13例为检测到突变的散发病例患儿的母亲,有8例检测到突变.产前诊断9个胎儿(其中双胎1例),2例胎儿有突变,引产后核实无误;7例胎儿未检测到突变,现均已分娩.结论 多重PCR可检出92.86%的缺失突变并可用于缺失突变的产前诊断,因其简便、可靠、价廉可作为临床上DMD/BMD基因诊断的初选.MLPA可用于多重PCR未检测到缺失突变的患者及携带者的检查.     

应用多重PCR和MLPA技术检测DMD患者和携带者的基因突变及产前诊断

目的 应用多重PCR和多重连接依赖探针扩增(multiplex ligation-dependent probe amplification,MLPA)技术检测Duchenne/Becker肌营养不良症(Duchenne/Becker muscular dystrophy,DMD/BMD)患者、携带者并应用于产前诊断.方法 首先采用多重PCR对临床诊断为DMD/BMD的患者检测DMD基因的26个外显子,未查到缺失突变者和可能的携带者采用MLPA检测全部79个外显子是否有缺失或重复突变.对产前诊断病例,用PCR法检测缺失突变,用MLPA法检测重复突变.结果 多重PCR对22例患者的DMD基因的26个外显子检测.13例有缺失突变.未查到常见缺失突变的9例患者经MLPA检测DMD基因的全部79个外显子,3例为重复突变、1例为单个第18外显子缺失、其他5例未查到缺失和重复突变.16例携带者中,3例有家族史,其中2例检出突变;13例为检测到突变的散发病例患儿的母亲,有8例检测到突变.产前诊断9个胎儿(其中双胎1例),2例胎儿有突变,引产后核实无误;7例胎儿未检测到突变,现均已分娩.结论 多重PCR可检出92.86%的缺失突变并可用于缺失突变的产前诊断,因其简便、可靠、价廉可作为临床上DMD/BMD基因诊断的初选.MLPA可用于多重PCR未检测到缺失突变的患者及携带者的检查.     

应用多重PCR和MLPA技术检测DMD患者和携带者的基因突变及产前诊断

目的 应用多重PCR和多重连接依赖探针扩增(multiplex ligation-dependent probe amplification,MLPA)技术检测Duchenne/Becker肌营养不良症(Duchenne/Becker muscular dystrophy,DMD/BMD)患者、携带者并应用于产前诊断.方法 首先采用多重PCR对临床诊断为DMD/BMD的患者检测DMD基因的26个外显子,未查到缺失突变者和可能的携带者采用MLPA检测全部79个外显子是否有缺失或重复突变.对产前诊断病例,用PCR法检测缺失突变,用MLPA法检测重复突变.结果 多重PCR对22例患者的DMD基因的26个外显子检测.13例有缺失突变.未查到常见缺失突变的9例患者经MLPA检测DMD基因的全部79个外显子,3例为重复突变、1例为单个第18外显子缺失、其他5例未查到缺失和重复突变.16例携带者中,3例有家族史,其中2例检出突变;13例为检测到突变的散发病例患儿的母亲,有8例检测到突变.产前诊断9个胎儿(其中双胎1例),2例胎儿有突变,引产后核实无误;7例胎儿未检测到突变,现均已分娩.结论 多重PCR可检出92.86%的缺失突变并可用于缺失突变的产前诊断,因其简便、可靠、价廉可作为临床上DMD/BMD基因诊断的初选.MLPA可用于多重PCR未检测到缺失突变的患者及携带者的检查.     

应用多重PCR和MLPA技术检测DMD患者和携带者的基因突变及产前诊断

目的 应用多重PCR和多重连接依赖探针扩增(multiplex ligation-dependent probe amplification,MLPA)技术检测Duchenne/Becker肌营养不良症(Duchenne/Becker muscular dystrophy,DMD/BMD)患者、携带者并应用于产前诊断.方法 首先采用多重PCR对临床诊断为DMD/BMD的患者检测DMD基因的26个外显子,未查到缺失突变者和可能的携带者采用MLPA检测全部79个外显子是否有缺失或重复突变.对产前诊断病例,用PCR法检测缺失突变,用MLPA法检测重复突变.结果 多重PCR对22例患者的DMD基因的26个外显子检测.13例有缺失突变.未查到常见缺失突变的9例患者经MLPA检测DMD基因的全部79个外显子,3例为重复突变、1例为单个第18外显子缺失、其他5例未查到缺失和重复突变.16例携带者中,3例有家族史,其中2例检出突变;13例为检测到突变的散发病例患儿的母亲,有8例检测到突变.产前诊断9个胎儿(其中双胎1例),2例胎儿有突变,引产后核实无误;7例胎儿未检测到突变,现均已分娩.结论 多重PCR可检出92.86%的缺失突变并可用于缺失突变的产前诊断,因其简便、可靠、价廉可作为临床上DMD/BMD基因诊断的初选.MLPA可用于多重PCR未检测到缺失突变的患者及携带者的检查.     

应用多重PCR和MLPA技术检测DMD患者和携带者的基因突变及产前诊断

目的 应用多重PCR和多重连接依赖探针扩增(multiplex ligation-dependent probe amplification,MLPA)技术检测Duchenne/Becker肌营养不良症(Duchenne/Becker muscular dystrophy,DMD/BMD)患者、携带者并应用于产前诊断.方法 首先采用多重PCR对临床诊断为DMD/BMD的患者检测DMD基因的26个外显子,未查到缺失突变者和可能的携带者采用MLPA检测全部79个外显子是否有缺失或重复突变.对产前诊断病例,用PCR法检测缺失突变,用MLPA法检测重复突变.结果 多重PCR对22例患者的DMD基因的26个外显子检测.13例有缺失突变.未查到常见缺失突变的9例患者经MLPA检测DMD基因的全部79个外显子,3例为重复突变、1例为单个第18外显子缺失、其他5例未查到缺失和重复突变.16例携带者中,3例有家族史,其中2例检出突变;13例为检测到突变的散发病例患儿的母亲,有8例检测到突变.产前诊断9个胎儿(其中双胎1例),2例胎儿有突变,引产后核实无误;7例胎儿未检测到突变,现均已分娩.结论 多重PCR可检出92.86%的缺失突变并可用于缺失突变的产前诊断,因其简便、可靠、价廉可作为临床上DMD/BMD基因诊断的初选.MLPA可用于多重PCR未检测到缺失突变的患者及携带者的检查.     

应用多重PCR和MLPA技术检测DMD患者和携带者的基因突变及产前诊断

目的 应用多重PCR和多重连接依赖探针扩增(multiplex ligation-dependent probe amplification,MLPA)技术检测Duchenne/Becker肌营养不良症(Duchenne/Becker muscular dystrophy,DMD/BMD)患者、携带者并应用于产前诊断.方法 首先采用多重PCR对临床诊断为DMD/BMD的患者检测DMD基因的26个外显子,未查到缺失突变者和可能的携带者采用MLPA检测全部79个外显子是否有缺失或重复突变.对产前诊断病例,用PCR法检测缺失突变,用MLPA法检测重复突变.结果 多重PCR对22例患者的DMD基因的26个外显子检测.13例有缺失突变.未查到常见缺失突变的9例患者经MLPA检测DMD基因的全部79个外显子,3例为重复突变、1例为单个第18外显子缺失、其他5例未查到缺失和重复突变.16例携带者中,3例有家族史,其中2例检出突变;13例为检测到突变的散发病例患儿的母亲,有8例检测到突变.产前诊断9个胎儿(其中双胎1例),2例胎儿有突变,引产后核实无误;7例胎儿未检测到突变,现均已分娩.结论 多重PCR可检出92.86%的缺失突变并可用于缺失突变的产前诊断,因其简便、可靠、价廉可作为临床上DMD/BMD基因诊断的初选.MLPA可用于多重PCR未检测到缺失突变的患者及携带者的检查.     

应用多重PCR和MLPA技术检测DMD患者和携带者的基因突变及产前诊断

目的 应用多重PCR和多重连接依赖探针扩增(multiplex ligation-dependent probe amplification,MLPA)技术检测Duchenne/Becker肌营养不良症(Duchenne/Becker muscular dystrophy,DMD/BMD)患者、携带者并应用于产前诊断.方法 首先采用多重PCR对临床诊断为DMD/BMD的患者检测DMD基因的26个外显子,未查到缺失突变者和可能的携带者采用MLPA检测全部79个外显子是否有缺失或重复突变.对产前诊断病例,用PCR法检测缺失突变,用MLPA法检测重复突变.结果 多重PCR对22例患者的DMD基因的26个外显子检测.13例有缺失突变.未查到常见缺失突变的9例患者经MLPA检测DMD基因的全部79个外显子,3例为重复突变、1例为单个第18外显子缺失、其他5例未查到缺失和重复突变.16例携带者中,3例有家族史,其中2例检出突变;13例为检测到突变的散发病例患儿的母亲,有8例检测到突变.产前诊断9个胎儿(其中双胎1例),2例胎儿有突变,引产后核实无误;7例胎儿未检测到突变,现均已分娩.结论 多重PCR可检出92.86%的缺失突变并可用于缺失突变的产前诊断,因其简便、可靠、价廉可作为临床上DMD/BMD基因诊断的初选.MLPA可用于多重PCR未检测到缺失突变的患者及携带者的检查.     

应用多重PCR和MLPA技术检测DMD患者和携带者的基因突变及产前诊断

目的 应用多重PCR和多重连接依赖探针扩增(multiplex ligation-dependent probe amplification,MLPA)技术检测Duchenne/Becker肌营养不良症(Duchenne/Becker muscular dystrophy,DMD/BMD)患者、携带者并应用于产前诊断.方法 首先采用多重PCR对临床诊断为DMD/BMD的患者检测DMD基因的26个外显子,未查到缺失突变者和可能的携带者采用MLPA检测全部79个外显子是否有缺失或重复突变.对产前诊断病例,用PCR法检测缺失突变,用MLPA法检测重复突变.结果 多重PCR对22例患者的DMD基因的26个外显子检测.13例有缺失突变.未查到常见缺失突变的9例患者经MLPA检测DMD基因的全部79个外显子,3例为重复突变、1例为单个第18外显子缺失、其他5例未查到缺失和重复突变.16例携带者中,3例有家族史,其中2例检出突变;13例为检测到突变的散发病例患儿的母亲,有8例检测到突变.产前诊断9个胎儿(其中双胎1例),2例胎儿有突变,引产后核实无误;7例胎儿未检测到突变,现均已分娩.结论 多重PCR可检出92.86%的缺失突变并可用于缺失突变的产前诊断,因其简便、可靠、价廉可作为临床上DMD/BMD基因诊断的初选.MLPA可用于多重PCR未检测到缺失突变的患者及携带者的检查.     

应用多重PCR和MLPA技术检测DMD患者和携带者的基因突变及产前诊断

目的 应用多重PCR和多重连接依赖探针扩增(multiplex ligation-dependent probe amplification,MLPA)技术检测Duchenne/Becker肌营养不良症(Duchenne/Becker muscular dystrophy,DMD/BMD)患者、携带者并应用于产前诊断.方法 首先采用多重PCR对临床诊断为DMD/BMD的患者检测DMD基因的26个外显子,未查到缺失突变者和可能的携带者采用MLPA检测全部79个外显子是否有缺失或重复突变.对产前诊断病例,用PCR法检测缺失突变,用MLPA法检测重复突变.结果 多重PCR对22例患者的DMD基因的26个外显子检测.13例有缺失突变.未查到常见缺失突变的9例患者经MLPA检测DMD基因的全部79个外显子,3例为重复突变、1例为单个第18外显子缺失、其他5例未查到缺失和重复突变.16例携带者中,3例有家族史,其中2例检出突变;13例为检测到突变的散发病例患儿的母亲,有8例检测到突变.产前诊断9个胎儿(其中双胎1例),2例胎儿有突变,引产后核实无误;7例胎儿未检测到突变,现均已分娩.结论 多重PCR可检出92.86%的缺失突变并可用于缺失突变的产前诊断,因其简便、可靠、价廉可作为临床上DMD/BMD基因诊断的初选.MLPA可用于多重PCR未检测到缺失突变的患者及携带者的检查.     

应用多重PCR和MLPA技术检测DMD患者和携带者的基因突变及产前诊断

目的 应用多重PCR和多重连接依赖探针扩增(multiplex ligation-dependent probe amplification,MLPA)技术检测Duchenne/Becker肌营养不良症(Duchenne/Becker muscular dystrophy,DMD/BMD)患者、携带者并应用于产前诊断.方法 首先采用多重PCR对临床诊断为DMD/BMD的患者检测DMD基因的26个外显子,未查到缺失突变者和可能的携带者采用MLPA检测全部79个外显子是否有缺失或重复突变.对产前诊断病例,用PCR法检测缺失突变,用MLPA法检测重复突变.结果 多重PCR对22例患者的DMD基因的26个外显子检测.13例有缺失突变.未查到常见缺失突变的9例患者经MLPA检测DMD基因的全部79个外显子,3例为重复突变、1例为单个第18外显子缺失、其他5例未查到缺失和重复突变.16例携带者中,3例有家族史,其中2例检出突变;13例为检测到突变的散发病例患儿的母亲,有8例检测到突变.产前诊断9个胎儿(其中双胎1例),2例胎儿有突变,引产后核实无误;7例胎儿未检测到突变,现均已分娩.结论 多重PCR可检出92.86%的缺失突变并可用于缺失突变的产前诊断,因其简便、可靠、价廉可作为临床上DMD/BMD基因诊断的初选.MLPA可用于多重PCR未检测到缺失突变的患者及携带者的检查.     

Possibilities and limitation of prenatal diagnosis and carrier determination for Duchenne and Becker muscular dystrophy using cDNA probes.

Two cDNA probes, cf23a and cf56a, identify deletions of selected exons in about 50% of our DMD/BMD patients. We have estimated the most likely order of the 11 exons detectable with both probes with respect to the different extensions of the deletions. In one of our BMD pedigrees, the observed deletion could be traced in the affected males through three generations. This result shows that with the use of cDNA probes detecting deletions, the only risk of error in genomic prenatal diagnosis is the general high frequency of new mutations for DMD/BMD. This is important progress in diagnosis compared to the 2 to 5% risk of misdiagnosis because of crossing over events using conventional linkage analysis with bridging or intragenic probes. The first prenatal diagnosis of an unaffected fetus of a woman who is a DMD carrier according to ultrasound examination is described. In one of our DMD males, the cDNA probe cf56a detects a deletion breakpoint. His sister also shows the altered band and is therefore a DMD carrier, while his mother has a totally normal band pattern. The interpretation of this observation could be either germline mosaicism or two identical new mutations. The identification of deletion breakpoints is a new diagnostic strategy, especially for carrier determination, which excludes misdiagnosis owing to crossing over events and the problems of dosage estimation. It is, however, limited by the low frequency of breakpoints detectable with cDNA probes. Therefore, the generation of new intron probes in this region is an important goal.     

Direct method for prenatal diagnosis and carrier detection in Duchenne/Becker muscular dystrophy using the entire dystrophin cDNA

DNA sequence polymorphisms (RFLPs) have been widely used as genetic markers for identification of the X chromosome that carries the mutation for Duchenne muscular dystrophy (DMD) in affected families, but serious limitations and pitfalls are associated with this approach [Darras et al., 1987]. The complementary DNA (cDNA) of the DMD gene has recently been isolated and shown to detect partial gene deletions in a large proportion of patients [Koenig et al., 1987]. Two prenatal studies are presented to illustrate how the unambiguous identification of deletion mutations by cDNA probes permits direct DNA-based diagnoses with high accuracy and in otherwise uninformative families. In a single proband family, DNA marker analysis had determined that the Xp21 chromosomal region present in the affected male was also carried by a male fetus in a subsequent pregnancy. Analysis of this family's DNA with probes covering the entire 14 kb cDNA revealed a small deletion in the affected male that was not present in the fetus nor in the mother. In the second family the fetus was a female deletion carrier identified by comparing intensities of restriction fragments. Since 1/3 of all DMD patients are thought to result from new mutations and most families have only single affected males, the cloned cDNA probes now available are likely to revolutionize DNA-based diagnostic studies in this disorder. More reliable, more rapid and less expensive than linkage studies with DNA polymorphisms, this method will be informative in the more than 50% of DMD/BMD cases that have deletion mutations.     

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。     

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.     

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.     

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 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.     

Exon Deletion Patterns of the Dystrophin Gene in 82 Vietnamese Duchenne/Becker Muscular Dystrophy Patients

Abstract

Duchenne and Becker muscular dystrophies (DMD/BMD) are the most common inherited muscle diseases caused by mutations in the dystrophin gene. The reading frame rule explains the genotype-phenotype relationship in DMD/BMD. In Vietnam, extensive mutation analysis has never been conducted in DMD/BMD. Here, 152 Vietnamese muscular dystrophy patients were examined for dystrophin exon deletion by amplifying 19 deletion-prone exons and deletion ends were confirmed by dystrophin cDNA analysis if necessary. The result was that 82 (54%) patients were found to have exon deletions, thus confirming exact deletion ends. A further result was that 37 patterns of deletion were classified. Deletions of exons 45–50 and 49–52 were the most common patterns identified, numbering six cases each (7.3%). The reading frame rule explained the genotype-phenotype relationship, but not five (6.1%) DMD cases. Each of five patients had deletions of exons 11–27 in common. The applicability of the therapy producing semifunctional in frame mRNA in DMD by inducing skipping of a single exon was examined. Induction of exon 51 skipping was ranked at top priority, since 16 (27%) patients were predicted to have semifunctional mRNA skipping. Exons 45 and 53 were the next ranked, with 12 (20%) and 11 (18%) patients, respectively. The largest deletion database of the dystrophin gene, established in Vietnamese DMD/BMD patients, disclosed a strong indication for exon-skipping therapy.     

ERG phenotype of a dystrophin mutation in heterozygous female carriers of Duchenne muscular dystrophy

PURPOSE: Mutations in the dystrophin gene result in Duchenne muscular dystrophy (DMD). DMD is associated with an abnormal electroretinogram (ERG) if the mutation disrupts the translation of retinal dystrophin (Dp260). Our aim was to determine if incomplete ERG abnormalities would be associated with heterozygous carriers of dystrophin gene mutations. METHODS: Ganzfeld ERGs were obtained under scotopic and photopic testing conditions from a family which includes the heterozygous maternal grandmother, the heterozygous mother, and her children, two affected boys and dizygotic twin sibs, an unaffected male and heterozygous female. Southern blot analyses were done to characterise the dystrophin mutation. RESULTS: The dystrophin gene was found to contain a deletion encompassing exon 50. The ERGs in the two affected boys were abnormal, consistent with the DMD ERG phenotype. Serial ERGs of the heterozygous females were abnormal; however, they were less severely affected than the DMD boys. The ERG of the female sib showed a greater abnormality than her mother and maternal grandmother. The unaffected twin had a normal ERG. CONCLUSIONS: The ERG shows abnormalities associated with carrier status in this family with a single exon deletion. A large study of confirmed obligate carriers is planned to clarify further the value of the ERG in detecting female heterozygous carriers of dystrophin gene mutations.