Your search keyword '"optical genome mapping"' showing total 5 results

1. Optical genome mapping as an alternative to FISH-based cytogenetic assessment in chronic lymphocytic leukemia

Author

Valkama, A. (Andriana), Vorimo, S. (Sandra), Kumpula, T. A. (Timo A.), Räsänen, H. (Hannele), Savolainen, E.-R. (Eeva-Riitta), Pylkäs, K. (Katri), Mantere, T. (Tuomo), Valkama, A. (Andriana), Vorimo, S. (Sandra), Kumpula, T. A. (Timo A.), Räsänen, H. (Hannele), Savolainen, E.-R. (Eeva-Riitta), Pylkäs, K. (Katri), and Mantere, T. (Tuomo)

Abstract

The fluorescence in situ hybridization (FISH) technique plays an important role in the risk stratification and clinical management of patients with chronic lymphocytic leukemia (CLL). For genome-wide analysis, FISH needs to be complemented with other cytogenetic methods, including karyotyping and/or chromosomal microarrays. However, this is often not feasible in a diagnostic setup. Optical genome mapping (OGM) is a novel technique for high-resolution genome-wide detection of structural variants (SVs), and previous studies have indicated that OGM could serve as a generic cytogenetic tool for hematological malignancies. Herein, we report the results from our study evaluating the concordance of OGM and standard-of-care FISH in 18 CLL samples. The results were fully concordant between these two techniques in the blinded comparison. Using in silico dilution series, the lowest limit of detection with OGM was determined to range between 3 and 9% variant allele fractions. Genome-wide analysis by OGM revealed additional (>1 Mb) aberrations in 78% of the samples, including both unbalanced and balanced SVs. Importantly, OGM also enabled the detection of clinically relevant complex karyotypes, undetectable by FISH, in three samples. Overall, this study demonstrates the potential of OGM as a first-tier cytogenetic test for CLL and as a powerful tool for genome-wide SV analysis.

Published

2023

2. A complex structural variant near SOX3 causes X-linked split-hand/foot malformation

Author

de Boer, E. (Elke), Marcelis, C. (Carlo), Neveling, K. (Kornelia), van Beusekom, E. (Ellen), Hoischen, A. (Alexander), Klein, W. M. (Willemijn M.), de Leeuw, N. (Nicole), Mantere, T. (Tuomo), Melo, U. S. (Uirá S.), van Reeuwijk, J. (Jeroen), Smeets, D. (Dominique), Spielmann, M. (Malte), Kleefstra, T. (Tjitske), van Bokhoven, H. (Hans), Vissers, L. E. (Lisenka E. L. M.), de Boer, E. (Elke), Marcelis, C. (Carlo), Neveling, K. (Kornelia), van Beusekom, E. (Ellen), Hoischen, A. (Alexander), Klein, W. M. (Willemijn M.), de Leeuw, N. (Nicole), Mantere, T. (Tuomo), Melo, U. S. (Uirá S.), van Reeuwijk, J. (Jeroen), Smeets, D. (Dominique), Spielmann, M. (Malte), Kleefstra, T. (Tjitske), van Bokhoven, H. (Hans), and Vissers, L. E. (Lisenka E. L. M.)

Abstract

Summary Split-hand/foot malformation (SHFM) is a congenital limb defect most typically presenting with median clefts in hands and/or feet, that can occur in a syndromic context as well as in isolated form. SHFM is caused by failure to maintain normal apical ectodermal ridge function during limb development. Although several genes and contiguous gene syndromes are implicated in the monogenic etiology of isolated SHFM, the disorder remains genetically unexplained for many families and associated genetic loci. We describe a family with isolated X-linked SHFM, for which the causative variant could be detected after a diagnostic journey of 20 years. We combined well-established approaches including microarray-based copy number variant analysis and fluorescence in situ hybridization coupled with optical genome mapping and whole genome sequencing. This strategy identified a complex structural variant (SV) comprising a 165-kb gain of 15q26.3 material ([GRCh37/hg19] chr15:99795320-99960362dup) inserted in inverted position at the site of a 38-kb deletion on Xq27.1 ([GRCh37/hg19] chrX:139481061-139518989del). In silico analysis suggested that the SV disrupts the regulatory framework on the X chromosome and may lead to SOX3 misexpression. We hypothesize that SOX3 dysregulation in the developing limb disturbed the fine balance between morphogens required for maintaining AER function, resulting in SHFM in this family.

Published

2023

3. Optical genome mapping:a promising new tool to assess genomic complexity in chronic lymphocytic leukemia (CLL)

Author

Puiggros, A. (Anna), Campoy, S. R. (Silvia Ramos), Kamaso, J. (Joanna), de la Rosa, M. (Mireia), Salido, M. (Marta), Melero, C. (Carme), Sandrine Bougeon, M. (María), Bougeon, S. (Sandrine), Collado, R. (Rosa), Gimeno, E. (Eva), García-Serra, R. (Rocío), Alonso, S. (Sara), Moro-García, M. A. (Marco Antonio), García-Malo, M. D. (María Dolores), Calvo, X. (Xavier), Arenillas, L. (Leonor), Ferrer, A. (Ana), Mantere, T. (Tuomo), Hoischen, A. (Alexander), Schoumans, J. (Jacqueline), Espinet, B. (Blanca), Puiggros, A. (Anna), Campoy, S. R. (Silvia Ramos), Kamaso, J. (Joanna), de la Rosa, M. (Mireia), Salido, M. (Marta), Melero, C. (Carme), Sandrine Bougeon, M. (María), Bougeon, S. (Sandrine), Collado, R. (Rosa), Gimeno, E. (Eva), García-Serra, R. (Rocío), Alonso, S. (Sara), Moro-García, M. A. (Marco Antonio), García-Malo, M. D. (María Dolores), Calvo, X. (Xavier), Arenillas, L. (Leonor), Ferrer, A. (Ana), Mantere, T. (Tuomo), Hoischen, A. (Alexander), Schoumans, J. (Jacqueline), and Espinet, B. (Blanca)

Abstract

Novel treatments in chronic lymphocytic leukemia (CLL) have generated interest regarding the clinical impact of genomic complexity, currently assessed by chromosome banding analysis (CBA) and chromosomal microarray analysis (CMA). Optical genome mapping (OGM), a novel technique based on imaging of long DNA molecules labeled at specific sites, allows the identification of multiple cytogenetic abnormalities in a single test. We aimed to determine whether OGM is a suitable alternative to cytogenomic assessment in CLL, especially focused on genomic complexity. Cytogenomic OGM aberrations from 42 patients were compared with CBA, FISH, and CMA information. Clinical–biological characteristics and time to first treatment (TTFT) were analyzed according to the complexity detected by OGM. Globally, OGM identified 90.3% of the known alterations (279/309). Discordances were mainly found in (peri-)centromeric or telomeric regions or subclonal aberrations (<15–20%). OGM underscored additional abnormalities, providing novel structural information on known aberrations in 55% of patients. Regarding genomic complexity, the number of OGM abnormalities had better accuracy in predicting TTFT than current methods (C-index: 0.696, 0.602, 0.661 by OGM, CBA, and CMA, respectively). A cut-off of ≥10 alterations defined a complex OGM group (C-OGM, n = 12), which included 11/14 patients with ≥5 abnormalities by CBA/CMA and one patient with chromothripsis (Kappa index = 0.778; p < 0.001). Moreover, C-OGM displayed enrichment of TP53 abnormalities (58.3% vs. 3.3%, p < 0.001) and a significantly shorter TTFT (median: 2 vs. 43 months, p = 0.014). OGM is a robust technology for implementation in the routine management of CLL patients, although further studies are required to define standard genomic complexity criteria.

Published

2022

4. Detection of a mosaic CDKL5 deletion and inversion by optical genome mapping ends an exhaustive diagnostic odyssey.

Author

Cope, Heidi, Cope, Heidi, Barseghyan, Hayk, Bhattacharya, Surajit, Fu, Yulong, Hoppman, Nicole, Marcou, Cherisse, Walley, Nicole, Rehder, Catherine, Deak, Kristen, Alkelai, Anna, Vilain, Eric, Shashi, Vandana, Cope, Heidi, Cope, Heidi, Barseghyan, Hayk, Bhattacharya, Surajit, Fu, Yulong, Hoppman, Nicole, Marcou, Cherisse, Walley, Nicole, Rehder, Catherine, Deak, Kristen, Alkelai, Anna, Vilain, Eric, and Shashi, Vandana

Abstract

BACKGROUND: Currently available structural variant (SV) detection methods do not span the complete spectrum of disease-causing SVs. Optical genome mapping (OGM), an emerging technology with the potential to resolve diagnostic dilemmas, was performed to investigate clinically-relevant SVs in a 4-year-old male with an epileptic encephalopathy of undiagnosed molecular origin. METHODS: OGM was utilized to image long, megabase-size DNA molecules, fluorescently labeled at specific sequence motifs throughout the genome with high sensitivity for detection of SVs greater than 500 bp in size. OGM results were confirmed in a CLIA-certified laboratory via mate-pair sequencing. RESULTS: OGM identified a mosaic, de novo 90 kb deletion and inversion on the X chromosome disrupting the CDKL5 gene. Detection of the mosaic deletion, which had been previously undetected by chromosomal microarray, an infantile epilepsy panel including exon-level microarray for CDKL5, exome sequencing as well as genome sequencing, resulted in a diagnosis of X-linked dominant early infantile epileptic encephalopathy-2. CONCLUSION: OGM affords an effective technology for the detection of SVs, especially those that are mosaic, since these remain difficult to detect with current NGS technologies and with conventional chromosomal microarrays. Further research in undiagnosed populations with OGM is warranted.

Published

2021

5. nanotatoR: a tool for enhanced annotation of genomic structural variants.

Author

Bhattacharya, Surajit, Bhattacharya, Surajit, Barseghyan, Hayk, Délot, Emmanuèle, Vilain, Eric, Bhattacharya, Surajit, Bhattacharya, Surajit, Barseghyan, Hayk, Délot, Emmanuèle, and Vilain, Eric

Abstract

BACKGROUND: Whole genome sequencing is effective at identification of small variants, but because it is based on short reads, assessment of structural variants (SVs) is limited. The advent of Optical Genome Mapping (OGM), which utilizes long fluorescently labeled DNA molecules for de novo genome assembly and SV calling, has allowed for increased sensitivity and specificity in SV detection. However, compared to small variant annotation tools, OGM-based SV annotation software has seen little development, and currently available SV annotation tools do not provide sufficient information for determination of variant pathogenicity. RESULTS: We developed an R-based package, nanotatoR, which provides comprehensive annotation as a tool for SV classification. nanotatoR uses both external (DGV; DECIPHER; Bionano Genomics BNDB) and internal (user-defined) databases to estimate SV frequency. Human genome reference GRCh37/38-based BED files are used to annotate SVs with overlapping, upstream, and downstream genes. Overlap percentages and distances for nearest genes are calculated and can be used for filtration. A primary gene list is extracted from public databases based on the patients phenotype and used to filter genes overlapping SVs, providing the analyst with an easy way to prioritize variants. If available, expression of overlapping or nearby genes of interest is extracted (e.g. from an RNA-Seq dataset, allowing the user to assess the effects of SVs on the transcriptome). Most quality-control filtration parameters are customizable by the user. The output is given in an Excel file format, subdivided into multiple sheets based on SV type and inheritance pattern (INDELs, inversions, translocations, de novo, etc.). nanotatoR passed all quality and run time criteria of Bioconductor, where it was accepted in the April 2019 release. We evaluated nanotatoRs annotation capabilities using publicly available reference datasets: the singleton sample NA12878, mapped with two types of en

Published

2021