Your search keyword '"Maria Iascone"' showing total 2 results

1. Long-read sequencing reveals chromothripsis in a molecularly unsolved case of Cornelia de Lange syndrome

Author

Ilaria Bestetti, Milena Crippa, Alessandra Sironi, Matteo Bellini, Francesca Tumiatti, Sara Ballabio, Ferruccio Ceriotti, Luigi Memo, Maria Iascone, Lidia Larizza, and Palma Finelli

Subjects

long-read sequencing, NIPBL, Cornelia de Lange syndrome, translocation, complex chromosomal rearrangement, chromothripsis, Genetics, QH426-470

Abstract

Thanks to a long-read sequencing (LRS) approach, in this study, we have reported a molecularly solved case of a proband with a clinical diagnosis of Cornelia de Lange syndrome (CDLS), which is a multisystemic disorder whose causative molecular defects involve cohesin complex genes, with NIPBL located at 5p13.2 accounting for approximately 50%–60% of CDLS cases. The first-tier tests revealed an abnormal karyotype 46,XY,t(5;15)(p13;q25)dn and a preserved NIPBL sequencing. Copy number variants (CNVs) at the translocation breakpoints, in disease genes, or in probably pathogenic loci were excluded by a-CGH analysis. Through fluorescence in situ hybridization (FISH) analysis on derivative chromosome 5, the breakpoint was relocated 3 Mb far from NIPBL 5′UTR, which seemed fully maintained as FISH-probe mapping to the gene showed no split signals. Moreover, tri-color FISH revealed an apparently balanced paracentric inversion including NIPBL on derivative 5. Based on the strong clinical suspicion, we evaluated the NIPBL transcript by RT-qPCR that revealed a normal amount of transcript till exon 22 and a halved amount of the transcript from exon 23 to 3′UTR, indicating the expression of a truncated transcript probably leading to a defective protein. Despite RT-qPCR confirmed the patient’s CDLS clinical diagnosis, the molecular mechanism underlying this event remained to be an unsolved challenge for years. The LRS approach with nanopore technologies was able to fill the gap in this complex scenario and highlighted a chromothripsis event marked out at 5p13.2 by 36 breaks clustered in a 7.3-Mb region. The NIPBL gene was disrupted by 16 breaks and the resulting fragments were relocated in different positions and orientations. LRS confirmed the previous findings, and it has been proven to be crucial to define the complex chromosomal rearrangement in this patient which escaped current diagnostic investigations. Its application in the clinical practice will contribute to solve the unsolved.

Published

2024

2. Menkes disease complicated by concurrent ACY1 deficiency: A case report

Author

Alessia Mauri, Laura Assunta Saielli, Enrico Alfei, Maria Iascone, Daniela Marchetti, Elisa Cattaneo, Anna Di Lauro, Laura Antonelli, Luisella Alberti, Eleonora Bonaventura, Pierangelo Veggiotti, Luigina Spaccini, and Cristina Cereda

Subjects

case report, Menkes disease, novel ATP7A variant, ACY deficiency, overlapping phenotype, delayed copper therapy, Genetics, QH426-470

Abstract

Introduction: Menkes disease is an X‐linked recessive condition caused by mutations in the ATP7A gene, which leads to severe copper deficiency. Aminoacylase-1 deficiency is a rare inborn error of metabolism caused by homozygous or compound heterozygous variant in the ACY1 gene, characterized by increased urinary excretion of specific N-acetyl amino acids.Case presentation: We report an infant with neurological findings such as seizures, neurodevelopmental delay and hypotonia. Metabolic screening showed low serum copper and ceruloplasmin, and increased urinary excretion of several N-acetylated amino acids. Whole-exome sequencing analysis (WES) revealed the novel de novo variant c.3642_3649dup (p.Ala1217Aspfs*2) in the ATP7A gene, leading to a diagnosis of Menkes disease, and the simultaneous presence of the homozygous ACY1 variant c.1057C>T (p.Arg353Cys) causative of Aminoacylase-1 deficiency.Conclusion: Our patient had two rare conditions with different treatment courses but overlapping clinical features. The identified novel ATP7A mutation associated with Menkes disease expands the ATP7A gene spectrum.

Published

2023