Two Non-Contiguous Duplications in the DMD Gene in a Spanish Family

DMD and BMD are X-linked myopathy diseases in most cases caused by intragenic deletions, but duplications also appear in a significant number of cases. We present a complex duplication pattern detected by MLPA, a recently formulated method applied here to amplify the 79 exons of the DMD gene. We found a double-duplication in two DMD-affected brothers and in their carrier mother, which consist of two non-contiguous duplications encompassing exons 2 to 7 and exons 50 to 55. Different models are presented to explain formation of this genetic variant.     

Partial gene duplication in Duchenne and Becker muscular dystrophies.

Duchenne and Becker muscular dystrophies (DMD and BMD) are progressive muscle wasting disorders with an X linked recessive mode of inheritance. We have surveyed 120 unrelated patients with DMD or BMD for gene duplications using a series of genomic probes from within the DMD/BMD gene locus. In three patients, two with DMD and one with BMD, a duplicated region within the DMD/BMD locus has been shown by Southern blot analysis and transmission densitometry. In two cases a new restriction fragment spanning the duplication junction has been visualised, indicating that the duplications are tandemly arranged. Mendelian inheritance of the duplication has been shown in two families by following the segregation of the duplication junction fragment. The three duplication cases have been analysed with a cDNA probe isolated from the DXS206 region of the DMD/BMD locus and the duplication of a specific set of exons has been found in two cases. This study shows that all three duplications are internal to the gene and confirms that such a duplication can result in a genetic disorder through the disruption of exon organisation.     

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.     

Rapid identification of female carriers of DMD/BMD by quantitative real-time PCR

Recently developed PCR systems offer online-monitoring of amplification and allow simple and reliable DNA quantification. We have used the LightCycler system to develop a simple and rapid method for direct identification of female carriers of deletions and duplications in the dystrophin gene. The challenge resides in the ability to identify the presence of a deleted or duplicated allele over the background contributed by the normal allele. Quantification is based on the determination of the ratio between potentially deleted/duplicated dystrophin exons and non-deleted/-duplicated reference exons using the unspecific dsDNA-dye SYBRgreen I. In a retrospective study, we evaluated our method in female relatives of DMD/BMD patients with known carrier status by comparative analysis of deleted or duplicated versus non-deleted/-duplicated exons. Carrier status was accurately attributed in 100% of cases, the mean ratios being 0.52+/-0.12 for deletion carriers (expected value: 0.5) and 1.56+/-0.18 for duplication carriers (expected value: 1.5) vs. 1.022+/-0.17 for non-carriers (expected value: 1.0). The method proved to be simple, rapid, reliable, and cost-effective. It may be used for direct determination of deletions/duplications in potential DMD/BMD carriers and may easily be adapted for other genetic conditions involving deletions and duplications.     

Deletion and duplication screening in the DMD gene using MLPA

We have designed a multiplex ligation-dependent probe amplification (MLPA) assay to simultaneously screen all 79 DMD gene exons for deletions and duplications in Duchenne and Becker muscular dystrophy (DMD/BMD) patients. We validated the assay by screening 123 unrelated patients from Serbia and Montenegro already screened using multiplex PCR. MLPA screening confirmed the presence of all previously detected deletions. In addition, we detected seven new deletions, nine duplications, one point mutation, and we were able to precisely determine the extent of all rearrangements. To facilitate MLPA-based screening in laboratories lacking specific equipment, we designed the assay such that it can also be performed using agarose gel analysis and ethidium bromide staining. The MLPA assay as described provides a simple and cheap method for deletion and duplication screening in DMD/BMD patients. The assay outperforms the Beggs and Chamberlain multiplex-PCR test, and should be considered as the method of choice for an initial DNA analysis of DMD/BMD patients.     

Identification of two point mutations and a one base deletion in exon 19 of the dystrophin gene by heteroduplex formation

Two thirds of the Duchenne muscular dystrophy population haveeither gene deletions or duplications. The nondeletion/duplicationcases are most likely the result of point mutations or smalldeletions and duplications that cannot be easily identifiedby current strategies. The major obstacle in identifying smallmutations is due to the large size of the dystrophin gene. Weselectively screened 5 DMD exons containing CpG dinucleotidesin 110 DMD patients without detectable deletions or duplications.Nonsenses mutations are frequently due to a C- to -T transitionwithin a CG dinucleotide pair. To screen for the nonsense mutations,we used the heteroduplex method. Utilizing this approach, weidentified 2 different nonsense mutations and a single basedeletion all occurring in exon 19. This is the first reportof a clustering of small mutations in the the dystrophin gene.