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BACKGROUND: The aim of this study was to evaluate the diagnostic yield of routine exome sequencing (ES) in fetuses with ultrasound anomalies. METHODS: We performed a retrospective analysis of the ES results of 629 fetuses with isolated or multiple anomalies referred in 2019-2022. Variants in a gene panel consisting of approximately 3400 genes associated with multiple congenital anomalies and/or intellectual disability were analyzed. We used trio analysis and filtering for de novo variants, compound heterozygous variants, homozygous variants, X-linked variants, variants in imprinted genes, and known pathogenic variants. RESULTS: Pathogenic and likely pathogenic variants (class five and four, respectively) were identified in 14.0% (88/629, 95% CI 11.5%-16.9%) of cases. In the current cohort, the probability of detecting a monogenetic disorder was â¼1:7 (88/629, 95% CI 1:8.7-1:5.9), ranging from 1:9 (49/424) in cases with one major anomaly to 1:5 (32/147) in cases with multiple system anomalies. CONCLUSIONS: Our results indicate that a notable number of fetuses (1:7) with ultrasound anomalies and a normal chromosomal microarray have a (likely) pathogenic variant that can be detected through prenatal ES. These results warrant implementation of exome sequencing in selected cases, including those with an isolated anomaly on prenatal ultrasound.
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BACKGROUND: Ataxia with oculomotor apraxia type 1 is an autosomal-recessive neurodegenerative disorder characterized by a childhood onset of slowly progressive cerebellar ataxia, followed by oculomotor apraxia and a severe primary motor peripheral axonal motor neuropathy. Ataxia with oculomotor apraxia type 1 is caused by bi-allelic mutations in APTX (chromosome 9p21.1). CASE PRESENTATION: Our patient has a clinical presentation that is typical for ataxia with oculomotor apraxia type 1 with no particularly severe phenotype. Multiplex Ligation-dependent Probe Amplification analysis resulted in the identification of a homozygous deletion of all coding APTX exons (3 to 9). SNP array analysis using the Illumina Infinium CytoSNP-850 K microarray indicated that the deletion was about 62 kb. Based on the SNP array results, the breakpoints were found using direct sequence analysis: c.-5 + 1225_*44991del67512, p.0?. Both parents were heterozygous for the deletion. Homozygous complete APTX deletions have been described in literature for two other patients. We obtained a sample from one of these two patients and characterized the deletion (156 kb) as c.-23729_*115366del155489, p.0?, including the non-coding exons 1A and 2 of APTX. The more severe phenotype reported for this patient is not observed in our patient. It remains unclear whether the larger size of the deletion (156 kb vs 62 kb) plays a role in the phenotype (no extra genes are deleted). CONCLUSION: Here we described an ataxia with oculomotor apraxia type 1 patient who has a homozygous deletion of the complete coding region of APTX. In contrast to the patient with the large deletion, our patient does not have a severe phenotype. More patients with deletions of APTX are required to investigate a genotype-phenotype effect.
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Proteínas de Ligação a DNA/deficiência , Proteínas Nucleares/deficiência , Fenótipo , Degenerações Espinocerebelares/genética , Sequência de Bases , Eletromiografia , Deleção de Genes , Humanos , Masculino , Análise em Microsséries , Dados de Sequência Molecular , Marrocos , Polimorfismo de Nucleotídeo Único/genética , Análise de Sequência de DNA , Ataxias Espinocerebelares/congênitoRESUMO
Pompe disease is a metabolic disorder caused by a deficiency of the glycogen-hydrolyzing lysosomal enzyme acid α-glucosidase (GAA), which leads to progressive muscle wasting. This autosomal-recessive disorder is the result of disease-associated variants located in the GAA gene. In the present study, we performed extended molecular diagnostic analysis to identify novel disease-associated variants in six suspected Pompe patients from four different families for which conventional diagnostic assays were insufficient. Additional assays, such as a generic-splicing assay, minigene analysis, SNP array analysis, and targeted Sanger sequencing, allowed the identification of an exonic deletion, a promoter deletion, and a novel splicing variant located in the 5' UTR. Furthermore, we describe the diagnostic process for an infantile patient with an atypical phenotype, consisting of left ventricular hypertrophy but no signs of muscle weakness or motor problems. This led to the identification of a genetic mosaicism for a very severe GAA variant caused by a segmental uniparental isodisomy (UPD). With this study, we aim to emphasize the need for additional analyses to detect new disease-associated GAA variants and non-Mendelian genotypes in Pompe disease where conventional DNA diagnostic assays are insufficient.
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Analyses in our diagnostic DNA laboratory include genes involved in autosomal recessive (AR) lysosomal storage disorders such as glycogenosis type II (Pompe disease) and mucopolysaccharidosis type I (MPSI, Hurler disease). We encountered 4 cases with apparent homozygosity for a disease-causing sequence variant that could be traced to one parent only. In addition, in a young child with cardiomyopathy, in the absence of other symptoms, a diagnosis of Pompe disease was considered. Remarkably, he presented with different enzymatic and genotypic features between leukocytes and skin fibroblasts. All cases were examined with microsatellite markers and SNP genotyping arrays. We identified one case of total uniparental disomy (UPD) of chromosome 17 leading to Pompe disease and three cases of segmental uniparental isodisomy (UPiD) causing Hurler-(4p) or Pompe disease (17q). One Pompe patient with unusual combinations of features was shown to have a mosaic segmental UPiD of chromosome 17q. The chromosome 17 UPD cases amount to 11% of our diagnostic cohort of homozygous Pompe patients (plus one case of pseudoheterozygosity) where segregation analysis was possible. We conclude that inclusion of parental DNA is mandatory for reliable DNA diagnostics. Mild or unusual phenotypes of AR diseases should alert physicians to the possibility of mosaic segmental UPiD. SNP genotyping arrays are used in diagnostic workup of patients with developmental delay. Our results show that even small Regions of Homozygosity that include telomeric areas are worth reporting, regardless of the imprinting status of the chromosome, as they might indicate segmental UPiD.
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Doença de Depósito de Glicogênio Tipo II/genética , Mucopolissacaridose I/genética , Polimorfismo de Nucleotídeo Único , Dissomia Uniparental , Adolescente , Criança , Pré-Escolar , Feminino , Humanos , Lactente , MasculinoRESUMO
Cat eye syndrome (CES) is caused by a gain of the proximal part of chromosome 22. Usually, a supernumerary marker chromosome is present, containing two extra copies of the chromosome 22q11.1q11.21 region. More sporadically, the gain is present intrachromosomally. The critical region for CES is currently estimated to be about 2.1 Mb and to contain at least 14 RefSeq genes. Gain of this region may cause ocular coloboma, preauricular, anorectal, urogenital and congenital heart malformations. We describe a family in which a 600 kb intrachromosomal triplication is present in at least three generations. The copy number alteration was detected using MLPA and further characterized with interphase and metaphase FISH and SNP-array. The amplified fragment is located in the distal part of the CES region. The family members show anal atresia and preauricular tags or pits, matching part of the phenotype of this syndrome. This finding suggests that amplification of the genes CECR2, SLC25A18 and ATP6V1E1, mapping within the critical region for CES, may be responsible for anorectal, renal and preauricular anomalies in patients with CES.
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Anormalidades Múltiplas/genética , Sistema X-AG de Transporte de Aminoácidos/genética , Transtornos Cromossômicos/genética , Cromossomos Humanos Par 22/genética , Proteínas Mitocondriais/genética , Fatores de Transcrição/genética , ATPases Vacuolares Próton-Translocadoras/genética , Adulto , Aneuploidia , Transtornos Cromossômicos/complicações , Duplicação Cromossômica , Mapeamento Cromossômico , Anormalidades do Olho , Família , Feminino , Dosagem de Genes , Marcadores Genéticos , Humanos , Hibridização in Situ Fluorescente , Recém-Nascido , Cariotipagem , Masculino , Pessoa de Meia-Idade , Análise de Sequência com Séries de Oligonucleotídeos , LinhagemRESUMO
AIMS: Most patients (98%) with Friedreich's ataxia (FRDA) are homozygous for the GAA repeat expansion in FXN. Only a few compound heterozygous patients with an expanded repeat on one allele and a point mutation or an intragenic FXN deletion on the other allele are described. In a minority of the patients only a heterozygous pattern of the repeat expansion can be detected. Using array analysis after GAA repeat expansion testing, we identified a FRDA patient who is compound heterozygous for an expanded GAA repeat and a complete FXN deletion. Since not only repeat expansions and point mutations, but also large rearrangements can be the underlying cause of FRDA, a quantitative test should also be performed in case a patient shows only one allele with an expanded GAA repeat in FXN.