Your search keyword '"Wieskamp, Nienke"' showing total 4 results

1. Additional file 2 of Reanalysis of exome negative patients with rare disease: a pragmatic workflow for diagnostic applications

Author

Schobers, Gaby, Schieving, Jolanda H., Yntema, Helger G., Pennings, Maartje, Pfundt, Rolph, Derks, Ronny, Hofste, Tom, de Wijs, Ilse, Wieskamp, Nienke, van den Heuvel, Simone, Galbany, Jordi Corominas, Gilissen, Christian, Nelen, Marcel, Brunner, Han G., Kleefstra, Tjitske, Kamsteeg, Erik-Jan, Willemsen, Michèl A. A. P., and Vissers, Lisenka E. L. M.

Abstract

Additional file 2: Fig. S1. Timeline from first analysis, VUS discovery, publication, and diagnosis.

Published

2022

2. Molecular diagnosis of usher syndrome: application of two different next generation sequencing-based procedures

Author

Emmanouil Athanasakis, Ivana Peluso, Angela D'Eustacchio, Vincenzo Nigro, Antonella Fabretto, Carmela Ziviello, Nienke Wieskamp, Danilo Licastro, Margherita Mutarelli, Francesca Simonelli, Paolo Gasparini, Rossella Rispoli, F. d’Amico, Kornelia Neveling, Diego Vozzi, Mariateresa Pizzo, Hans Scheffer, Sandro Banfi, Licastro, Danilo, Mutarelli, Margherita, Peluso, Ivana, Neveling, Kornelia, Wieskamp, Nienke, Rispoli, Rossella, Vozzi, Diego, Athanasakis, Emmanouil, D'Eustacchio, Angela, Pizzo, Mariateresa, D'Amico, Francesca, Ziviello, Carmela, Simonelli, Francesca, Fabretto, Antonella, Scheffer, Han, Gasparini, Paolo, Banfi, Sandro, Nigro, Vincenzo, Licastro, D, Mutarelli, M, Peluso, I, Neveling, K, Wieskamp, N, Rispoli, R, Vozzi, D, Athanasakis, E, D'Eustacchio, A, Pizzo, M, D'Amico, F, Ziviello, C, Fabretto, A, Scheffer, H, and Gasparini, P

Subjects

Genetics and Molecular Biology (all), Genetic Screens, Gene Identification and Analysis, lcsh:Medicine, Pilot Projects, Biochemistry, Genome Databases, Exome, Genome Sequencing, lcsh:Science, Child, Exome sequencing, Genetics, 0303 health sciences, Multidisciplinary, Massive parallel sequencing, Genome, Medicine (all), 030305 genetics & heredity, High-Throughput Nucleotide Sequencing, Genomics, 3. Good health, Molecular Diagnostic Techniques, Child, Preschool, Medicine, Usher Syndrome, Genome, Human, Humans, Sequence Analysis, DNA, Usher Syndromes, Agricultural and Biological Sciences (all), Biochemistry, Genetics and Molecular Biology (all), Sequence Analysis, Research Article, Human, Molecular Diagnostic Technique, Sequence Databases, Genetic Counseling, Biology, DNA sequencing, Genomic disorders and inherited multi-system disorders DCN MP - Plasticity and memory [IGMD 3], Genomic disorders and inherited multi-system disorders [IGMD 3], Molecular Genetics, 03 medical and health sciences, Pilot Project, Genetic Testing, Preschool, Genotyping, 030304 developmental biology, Clinical Genetics, lcsh:R, Personalized Medicine, Human Genetics, DNA, Molecular diagnostics, Otorhinolaryngology, Genetics of Disease, Mutation Databases, Human genome, lcsh:Q

Abstract

Contains fulltext : 108716.pdf (Publisher’s version ) (Open Access) Usher syndrome (USH) is a clinically and genetically heterogeneous disorder characterized by visual and hearing impairments. Clinically, it is subdivided into three subclasses with nine genes identified so far. In the present study, we investigated whether the currently available Next Generation Sequencing (NGS) technologies are already suitable for molecular diagnostics of USH. We analyzed a total of 12 patients, most of which were negative for previously described mutations in known USH genes upon primer extension-based microarray genotyping. We enriched the NGS template either by whole exome capture or by Long-PCR of the known USH genes. The main NGS sequencing platforms were used: SOLiD for whole exome sequencing, Illumina (Genome Analyzer II) and Roche 454 (GS FLX) for the Long-PCR sequencing. Long-PCR targeting was more efficient with up to 94% of USH gene regions displaying an overall coverage higher than 25x, whereas whole exome sequencing yielded a similar coverage for only 50% of those regions. Overall this integrated analysis led to the identification of 11 novel sequence variations in USH genes (2 homozygous and 9 heterozygous) out of 18 detected. However, at least two cases were not genetically solved. Our result highlights the current limitations in the diagnostic use of NGS for USH patients. The limit for whole exome sequencing is linked to the need of a strong coverage and to the correct interpretation of sequence variations with a non obvious, pathogenic role, whereas the targeted approach suffers from the high genetic heterogeneity of USH that may be also caused by the presence of additional causative genes yet to be identified.

Published

2012

3. Massively parallel sequencing of ataxia genes after array-based enrichment

Author

Marloes Steehouwer, Rowdy Meijer, Peer Arts, Nine V A M Knoers, Nienke Wieskamp, Christian Gilissen, Hans Scheffer, Sascha Vermeer, Alexander Hoischen, Jorge Seiqueros, Joris A. Veltman, Walter van der Vliet, Michael F. Buckley, Petra de Vries, Hoischen, Alexander, Gilissen, Christian, Arts, Peer, Wieskamp, Nienke, Van Vliet, Walter Der, Vermeer, Sascha, Steehouwer, Marloes, De Vries, Petra, Meijer, Rowdy, Seiqueros, Jorge, Knoers, Nine VAM, Buckley, Michael F, Scheffer, Hans, and Veltman, Joris A

Subjects

Mutation/genetics, Genotype, DNA Mutational Analysis, Molecular Sequence Data, Oligonucleotide Array Sequence Analysis/methods, Biology, Polymorphism, Single Nucleotide, Deep sequencing, Massively parallel signature sequencing, Genetics, Humans, Polymorphism, Gene, Genetics (clinical), Exome sequencing, Oligonucleotide Array Sequence Analysis, resequencing, Massive parallel sequencing, Base Sequence, Genetic heterogeneity, massively parallel sequencing, Point mutation, ataxia, Sequence Analysis, DNA, Polymorphism, Single Nucleotide/genetics, DNA/methods, Sequence Analysis, DNA/methods, NGS, Ataxia/genetics, Mutation, Ataxia, sequence enrichment, Single Nucleotide/genetics, Sequence Analysis

Abstract

Massively parallel sequencing has tremendous diagnostic potential but requires enriched templates for sequencing. Here we report the validation of an arraybased sequence capture method in genetically heterogeneous disorders. The model disorder selected was AR ataxia, using five subjects with known mutations and two unaffected controls. The genomic sequences of seven disease genes, together with two control loci were targeted on a 2-Mb sequence-capture array. After enrichment, the patients' DNA samples were analyzed using one-quarter Roche GS FLX Titanium sequencing run, resulting in an average of 65Mb of sequence data per patient. This was sufficient for an average 25-fold coverage/base in all targeted regions. Enrichment showed high specificity; on average, 80% of uniquely mapped reads were on target. Importantly, this approach enabled automated detection of deletions and hetero- and homozygous point mutations for 6/7 mutant alleles, and greater than 99% accuracy for known SNP variants. Our results also clearly show reduced coverage for sequences in repeat-rich regions, which significantly impacts the reliable detection of genomic variants. Based on these findings we recommend a minimal coverage of 15-fold for diagnostic implementation of this technology. We conclude that massive parallel sequencing of enriched samples enables personalized diagnosis of heterogeneous genetic disorders and qualifies for rapid diagnostic implementation. Refereed/Peer-reviewed

Published

2010

4. Next-generation sequencing of a 40 Mb linkage interval reveals TSPAN12 mutations in patients with familial exudative vitreoretinopathy

Author

Christian Gilissen, F. Nienke Boonstra, Joris A. Veltman, Ellen A.W. Blokland, Nienke Wieskamp, Carmen Ayuso, Frans P.M. Cremers, Konstantinos Nikopoulos, Rob W.J. Collin, C. Erik van Nouhuys, Hans Scheffer, Peer Arts, Arijit Mukhopadhyay, Tim M. Strom, Lies H. Hoefsloot, Sanne Bouwhuis, Mauk A. D. Tilanus, Alexander Hoischen, Nikopoulos, Konstantinos, Gilissen, Christian, Hoischen, Alexander, Erik van Nouhuys, C, Boonstra, F Nienke, Blokland, Ellen AW, Arts, Peer, Wieskamp, Nienke, Strom, Tim M, Ayuso, Carmen, Tilanus, Mauk AD, Bouwhuis, Sanne, Mukhopadhyay, Arijit, Scheffer, Hans, Hoefsloot, Lies H, Veltman, Joris A, Cremers, Frans PM, and Collin, Rob WJ

Subjects

Male, FZD4, Genetics and epigenetic pathways of disease [NCMLS 6], Sequence analysis, Fundus Oculi, Genetic Linkage, Tetraspanins, DNA Mutational Analysis, Molecular Sequence Data, Mutation, Missense, Genome-wide association study, Locus (genetics), Biology, Polymorphism, Single Nucleotide, Genomic disorders and inherited multi-system disorders [IGMD 3], TSPAN12, Retinal Diseases, Genetic linkage, Report, medicine, Genetics, Humans, Genetics(clinical), Family, Amino Acid Sequence, Base Pairing, Genetics (clinical), Base Sequence, Haplotype, familial exudative vitreoretinopathy, Membrane Proteins, Sequence Analysis, DNA, medicine.disease, Pedigree, Evaluation of complex medical interventions [NCEBP 2], Mutation, Familial exudative vitreoretinopathy, Female, mutation, Functional Neurogenomics [DCN 2], SNP array, Genome-Wide Association Study

Abstract

Contains fulltext : 89704.pdf (Publisher’s version ) (Closed access) Familial exudative vitreoretinopathy (FEVR) is a genetically heterogeneous retinal disorder characterized by abnormal vascularisation of the peripheral retina, often accompanied by retinal detachment. To date, mutations in three genes (FZD4, LRP5, and NDP) have been shown to be causative for FEVR. In two large Dutch pedigrees segregating autosomal-dominant FEVR, genome-wide SNP analysis identified an FEVR locus of approximately 40 Mb on chromosome 7. Microsatellite marker analysis suggested similar at risk haplotypes in patients of both families. To identify the causative gene, we applied next-generation sequencing in the proband of one of the families, by analyzing all exons and intron-exon boundaries of 338 genes, in addition to microRNAs, noncoding RNAs, and other highly conserved genomic regions in the 40 Mb linkage interval. After detailed bioinformatic analysis of the sequence data, prioritization of all detected sequence variants led to three candidates to be considered as the causative genetic defect in this family. One of these variants was an alanine-to-proline substitution in the transmembrane 4 superfamily member 12 protein, encoded by TSPAN12. This protein has very recently been implicated in regulating the development of retinal vasculature, together with the proteins encoded by FZD4, LRP5, and NDP. Sequence analysis of TSPAN12 revealed two mutations segregating in five of 11 FEVR families, indicating that mutations in TSPAN12 are a relatively frequent cause of FEVR. Furthermore, we demonstrate the power of targeted next-generation sequencing technology to identify disease genes in linkage intervals.

Published

2009