Veronica Ferreiro

Asymptomatic Becker muscular dystrophy in a family with a multiexon deletion

We report a Becker muscular dystrophy (BMD) family with one 5‐year‐old affected patient and a 69‐year‐old asymptomatic grandfather. Dystrophin gene multiplex polymerase chain reaction and multiplex ligation‐dependant probe amplification analysis showed that both males carried an in‐frame deletion of exons 45–55. Segregation analysis revealed two additional asymptomatic boys in this family. Our finding supports previous predictions that exons 45–55 are the optimal multiexon skipping target in antisense gene therapy to transform the severe Duchenne muscular dystrophy into the milder BMD, or even asymptomatic, phenotype. Muscle Nerve, 2008

Detection of germline mosaicism in two duchenne muscular dystrophy families using polymorphic dinucleotide (CA)n repeat loci within the dystrophin gene

AbstractBackground: Approximately one-third of new cases of Duchenne muscular dystrophy (DMD) can be attributed to sporadically arising new mutations, however in the majority of cases the DMD mutation has been inherited from the mother. These female carriers can have either a constitutive or mosaic mutation. Aim: The aim of this study was to determine the segregation of the at-risk haplotype and to find a deletion in the dystrophin gene of patients. Method: We analyzed individuals from two families with a history of DMD in order to predict the carrier status of related females. In one of these cases the mother had two affected sons, while in the other one son and two grandchildren were affected; therefore we predict that the mother would be an obligatory carrier. Results: Haplotype analysis of the DMD loci revealed that in the two families both the healthy and affected brothers had inherited the same X maternal chromosome. However, the affected brother carried a deletion, which was absent in the unaffected sibling. Conclusion: These findings suggested that the mothers in the two families were germline mosaics for the DMD gene. The results of this study demonstrate the usefulness of the methodology that combine the haplotype analysis with the identification of the mutation in order to detect hidden germline mosaicisms and, thus, improve genetic counseling.

NF2 tumor suppressor gene : a comprehensive and efficient detection of somatic mutations by denaturing HPLC and microarray-CGH

The NF2 tumor suppressor gene, located in chromosome 22q12, is involved in the development of multiple tumors of the nervous system, either associated with neurofibromatosis 2 or sporadic ones, mainly schwannomas and meningiomas. In order to evaluate the role of the NF2 gene in sporadic central nervous system (CNS) tumors, we analyzed NF2 mutations in 26 specimens: 14 meningiomas, 4 schwannomas, 4 metastases, and 4 other histopathological types of neoplasms. Denaturing high performance liquid chromatography (denaturing HPLC) and comparative genomic hybridization on a DNA microarray (microarray- CGH) were used as scanning methods for small mutations and gross rearrangements respectively. Small mutations were identified in six out of seventeen meningiomas and schwannomas, one mutation was novel. Large deletions were detected in six meningiomas. All mutations were predicted to result in truncated protein or in the absence of a large protein domain. No NF2 mutations were found in other histopathological types of CNS tumors. These results provide additional evidence that mutations in the NF2 gene play an important role in the development of sporadic meningiomas and schwannomas. Denaturing HPLC analysis of small mutations and microarray-CGH of large deletions are complementary, fast, and efficient methods for the detection of mutations in tumor tissues.

Symptomatic female carriers of Duchenne muscular dystrophy (DMD): Genetic and clinical characterization

Duchenne muscular dystrophy (DMD) is an X-linked recessive disease caused by mutations in the dystrophin gene and is characterized by muscle degeneration and death. DMD affects males; females being asymptomatic carriers of mutations. However, some of them manifest symptoms due to a translocation between X chromosome and an autosome or to a heterozygous mutation leading to inactivation of most of their normal X chromosome. Six symptomatic female carriers and two asymptomatic were analyzed by: I) Segregation of STRs-(CA)n and MLPA assays to detect a hemizygous alteration, and II) X chromosome inactivation pattern to uncover the reason for symptoms in these females. The symptomatic females shared mild but progressive muscular weakness and increased serum creatin kinase (CK) levels. Levels of dystrophin protein were below normal or absent in many fibers. Segregation of STRs-(CA)n revealed hemizygous patterns in three patients, which were confirmed by MLPA. In addition, this analysis showed a duplication in another patient. X chromosome inactivation assay revealed a skewed X inactivation pattern in the symptomatic females and a random inactivation pattern in the asymptomatic ones. Our results support the hypothesis that the DMD phenotype in female carriers of a dystrophin mutation has a direct correlation with a skewed X-chromosome inactivation pattern.

RB1 Germ-Line Deletions in Argentine Retinoblastoma Patients

AbstractBackground: Retinoblastoma (RB) is a malignant tumor originating in the retinal cell precursors and can be presented as a unilateral or bilateral form in childhood (one or both eyes affected). Development of this tumor is caused by mutations in the RB1 gene on chromosome 13ql4; the first mutation may occur in the germ line (hereditary RB) or in somatic cells (non-hereditary RB). The hereditary form of RB is transmitted with a high penetrance to offspring (90%). Because early diagnosis is necessary for implementing effective treatment and preserving vision, it is important to identify the mutations in the affected family. Aim: The aim of this study was to identify large and small RB1 germ-line mutations and to correlate them with the RB phenotype. Methods: Constitutional RB1 gene gross deletions were studied in 40 patients with bilateral or unilateral familial RB by a segregation assay of four intragenic polymorphisms located in introns 1,4, 17, and 20 of the RB1 gene, along with fluorescence in situ hibridization (FISH) analysis. Small mutations were ascertained in a subgroup of ten patients by heteroduplex/sequence analysis of RB1-exons. Results: In the course of our study, we have found three large deletions, which probably represent whole gene deletions, and two small deletions of 1bp in length. One large deletion was found in a family with several members affected. This represents a rare case of familial RB, which is usually caused by small mutations. Phenotype analysis of the family revealed a low penetrance inheritance, with an ‘affected eyes: number of mutation-carriers’ ratio of ≈1.0, whereas this ratio in families with small loss-of-function mutations is 1.5–2.0. Conclusions: Our results emphasize the usefulness of a combined methodology that includes segregation of polymorphisms, FISH, and heteroduplex/sequence analyses for detection of gross and small DNA rearrangements in familial and sporadic RB. Identification of mutations in sporadic cases is important for risk-assessment in patients’ relatives. The degree of penetrance in the inheritance of RB not only depends on the occurrence of the second mutation in the RB1 gene but also on the extent of inactivation of the first mutation.

The Role of Polymorphic Short Tandem (CA)n Repeat Loci Segregation Analysis in the Detection of Duchenne Muscular Dystrophy Carriers and Prenatal Diagnosis

AbstractBackground: Duchenne and Becker muscular dystrophies (DMD/BMD) are X-linked diseases caused by mutations in the dystrophin gene at Xp21.2; they include gross deletions (60%), duplications (10%), and small mutations (30%). Since there is no cure or effective treatment for progressive muscular dystrophy, prevention of the disease is important and strongly depends on carrier-status information. Two-thirds of DMD/BMD cases are familial; thus, female relatives are candidates for carrier-risk assessment. Aim: Segregation analysis of polymorphic short tandem (CA)n repeats [STR-(CA)n] was used to establish and compare the haplotypes of female relatives of patients with DMD/BMD with those of the patient in order to identify the mutant dystrophin gene and thus determine each female relative’s carrier status. Methods: 248 individuals from 52 families were studied through segregation of up to 11 STR-(CA)n loci. The assay was performed on leukocyte DNA by PCR amplification, polyacrylamide-gel electrophoresis and autoradiography. Haplotypes were established by determination of alleles on the autoradiography. Results: 38 of 51 (75%) female relatives from familial cases were diagnosed as carriers or non-carriers with a 95–100% likelihood, and 18 out of 56 (32%) female relatives from sporadic cases could be excluded from the risk of being a DMD carrier with the same probability. In addition, STR studies detected gross deletions in 13 of the 52 (25%) families in both male and female individuals, four of which were de novo deletions. STR assays were also informative in families without an available DNA sample of an affected male and in two of seven symptomatic females. Determination of carrier status was particularly significant for prediction of DMD risk in prenatal analysis of five male chorionic villi. Other genetic events revealed by STR analysis were: (i) 11 recombinations identified in 6.6% of meiosis in the DMD families; (ii) germinal mosaicism detected in two female carriers; and (iii) changes in STR-(CA)n length during transmission from father to daughters, including three retractions and one elongation at an estimated rate of 0.004. Conclusion: The STR assay is an excellent molecular tool for carrier-status identification and the detection of deletions and other genetic changes in families affected by DMD/BMD. Thus, it is useful in genetic counseling for the prevention of this disease.

Prenatal diagnosis of duchenne/becker muscular dystrophy by short tandem repeat segregation analysis in argentine families

Introduction: Duchenne/Becker muscular dystrophies (DMD/BMD) are X‐linked recessive diseases caused by mutations in the dystrophin gene. Methods: We used multiplex polymerase chain reaction (PCR) and short tandem repeat (STR) segregation analysis for DMD/BMD‐carrier detection and prenatal diagnosis. Results: Twenty‐four at‐risk pregnancies were evaluated: 17 were excluded from carrying dystrophin gene mutations with 95–100% certainty. Of the remaining cases, 2 were determined to carry a dystrophin gene mutation with 95–100% certainty. Three cases had a 67% probability of carrying the mutation, and 2 others were not informative. The certainty of the test increased to ∽100% in some cases due to the identification of several genetic events: 4 recombinations; 4 de novo mutations; and 8 deletions encompassing some of the STRs evaluated. Discussion: Overall, 19 of 24 (79%) molecular prenatal diagnoses were informative, indicating that multiplex PCR/STR segregation analysis is a reliable method for carrier detection and prenatal diagnosis when other more sophisticated techniques are unavailable. Muscle Nerve, 2011