Your search keyword '"optical genome mapping"' showing total 343 results

1. Genomic structural variants analysis in leukemia by a novel cytogenetic technique: Optical genome mapping.

Author

Lu, Song, Liu, Kefu, Wang, Di, Ye, Yuan, Jiang, Zhiping, and Gao, Yunhua

Abstract

Genomic structural variants (SVs) play a pivotal role in driving the evolution of hematologic malignancies, particularly in leukemia, in which genetic abnormalities are crucial features. Detecting SVs is essential for achieving precise diagnosis and prognosis in these cases. Karyotyping, often complemented by fluorescence in situ hybridization and/or chromosomal microarray analysis, provides standard diagnostic outcomes for various types of SVs in front‐line testing for leukemia. Recently, optical genome mapping (OGM) has emerged as a promising technique due to its ability to detect all SVs identified by other cytogenetic methods within one single assay. Furthermore, OGM has revealed additional clinically significant SVs in various clinical laboratories, underscoring its considerable potential for enhancing front‐line testing in cases of leukemia. This review aims to elucidate the principles of conventional cytogenetic techniques and OGM, with a focus on the technical performance of OGM and its applications in diagnosing and prognosticating myelodysplastic syndromes, acute myeloid leukemia, acute lymphoblastic leukemia, and chronic lymphocytic leukemia. [ABSTRACT FROM AUTHOR]

Published

2024

2. Utility of Optical Genome Mapping in Repeat Disorders.

Author

Mutlu, Mehmet Burak, Karakaya, Taner, Çelebi, Hamide Betül Gerik, Duymuş, Fahrettin, Seyhan, Serhat, Yılmaz, Sanem, Yiş, Uluç, Atik, Tahir, Yetkin, Mehmet Fatih, and Gümüş, Hakan

Subjects

*FRAGILE X syndrome, *FRIEDREICH'S ataxia, *GENE mapping, *TANDEM repeats, *NUCLEIC acids, *FACIOSCAPULOHUMERAL muscular dystrophy

Abstract

ABSTRACT Genomic repeat sequences are patterns of nucleic acids that exist in multiple copies throughout the genome. More than 60 Mendelian disorders are caused by the expansion or contraction of these repeats. Various specific methods for determining tandem repeat variations have been developed. However, these methods are highly specific to the genomic region being studied and sometimes require specialized tools. In this study, we have investigated the use of Optical Genome Mapping (OGM) as a diagnostic tool for detecting repeat disorders. We evaluated 19 patients with a prediagnosis of repeat disorders and explained the molecular etiology of 9 of them with OGM (5 patients with Facioscapulohumeral Muscular Dystrophy (FSHD), 2 patients with Friedreich's Ataxia (FA), 1 patient with Fragile X Syndrome (FXS), and 1 patient with Progressive Myoclonic Epilepsy 1A (EPM1A)). We confirmed OGM results with more widely used fragment analysis techniques. This study highlights the utility of OGM as a diagnostic tool for repeat expansion and contraction diseases such as FA, FXS, EPM1A, and FSHD. [ABSTRACT FROM AUTHOR]

Published

2024

3. Optical genome mapping of structural variants in Parkinson's disease-related induced pluripotent stem cells.

Author

Trinh, Joanne, Schaake, Susen, Gabbert, Carolin, Lüth, Theresa, Cowley, Sally A., Fienemann, André, Ullrich, Kristian K., Klein, Christine, and Seibler, Philip

Subjects

*INDUCED pluripotent stem cells, *SINGLE nucleotide polymorphisms, *GENETIC testing, *PARKINSON'S disease, *GENE mapping

Abstract

Background: Certain structural variants (SVs) including large-scale genetic copy number variants, as well as copy number-neutral inversions and translocations may not all be resolved by chromosome karyotype studies. The identification of genetic risk factors for Parkinson's disease (PD) has been primarily focused on the gene-disruptive single nucleotide variants. In contrast, larger SVs, which may significantly influence human phenotypes, have been largely underexplored. Optical genomic mapping (OGM) represents a novel approach that offers greater sensitivity and resolution for detecting SVs. In this study, we used induced pluripotent stem cell (iPSC) lines of patients with PD-linked SNCA and PRKN variants as a proof of concept to (i) show the detection of pathogenic SVs in PD with OGM and (ii) provide a comprehensive screening of genetic abnormalities in iPSCs. Results: OGM detected SNCA gene triplication and duplication in patient-derived iPSC lines, which were not identified by long-read sequencing. Additionally, various exon deletions were confirmed by OGM in the PRKN gene of iPSCs, of which exon 3–5 and exon 2 deletions were unable to phase with conventional multiplex-ligation-dependent probe amplification. In terms of chromosomal abnormalities in iPSCs, no gene fusions, no aneuploidy but two balanced inter-chromosomal translocations were detected in one line that were absent in the parental fibroblasts and not identified by routine single nucleotide variant karyotyping. Conclusions: In summary, OGM can detect pathogenic SVs in PD-linked genes as well as reveal genomic abnormalities for iPSCs that were not identified by other techniques, which is supportive for OGM's future use in gene discovery and iPSC line screening. [ABSTRACT FROM AUTHOR]

Published

2024

4. Combining optical genome mapping and RNA-seq for structural variants detection and interpretation in unsolved neurodevelopmental disorders.

Author

Xiao, Bing, Luo, Xiaomei, Liu, Yi, Ye, Hui, Liu, Huili, Fan, Yanjie, and Yu, Yongguo

Subjects

*GENE mapping, *GENETIC testing, *SYNCRIP protein, *CHROMOSOMAL rearrangement, *RNA sequencing, *RECESSIVE genes

Abstract

Background: Structural variations (SVs) are key genetic contributors to neurodevelopmental disorders (NDDs). Exome sequencing (ES), the current first-line tool for genetic testing of NDDs, falls short in SVs detection. This diagnostic gap is being actively addressed by new methods such as optical genome mapping (OGM). Methods: This study evaluated the utility of combining OGM and RNA-seq in the detection and interpretation of SVs in ES-negative NDDs. OGM was performed in 43 patients with NDDs with inconclusive ES results. Candidate SVs were selected based on disease association and pathogenicity evaluation, and further validated or reconstructed by alternative methods, including long-read sequencing for a complex rearrangement event. RNA-Seq was performed on blood samples from patients with candidate SVs to facilitate interpretation of pathogenicity. Results: OGM detected four candidate SVs, and RNA-seq confirmed the pathogenicity of three SVs in the patient cohort. This combined approach solved three cases—two cases with de novo SVs in genes associated with autosomal dominant NDDs, including a deletion encompassing the promoter and 5′UTR of MBD5 and an intragenic duplication of PAFAH1B1, and a third case possessing an intragenic duplication in trans with a pathogenic single-nucleotide variant of PLA2G6, associated with autosomal recessive NDDs. The expression alteration of the affected genes and the tandem positioning of two intragenic duplications were confirmed by RNA-seq. In the fourth case, OGM detected a complex rearrangement involving chromosomes 2 and 6, much more complex than the de novo t(2:6)(q13;q15) indicated by conventional cytogenetic analysis. Reconstruction showed that 17 segments of 6q15 spanning 9.3 Mb were disarranged and joined 2q11.2, with four breakpoints detected in the 5′ and 3′ non-coding region of the NDD-associated gene SYNCRIP. RNA-seq revealed largely preserved SYNCRIP expression, leaving the pathogenicity of this complex rearrangement event uncertain. Conclusions: SVs in ES-negative NDDs can be identified by OGM, which is particularly useful for SVs in non-coding regions not covered by ES. OGM helps to construct complex SVs and provides information on the location and orientation of duplications, which is crucial for pathogenicity interpretation. The integration of RNA-seq facilitates the interpretation of the functional consequences of SVs at the transcriptional level. These findings demonstrate the utility and feasibility of combining OGM and RNA-seq in ES-negative cases with NDDs. [ABSTRACT FROM AUTHOR]

Published

2024

5. The cryptic complex rearrangements involving the DMD gene: etiologic clues about phenotypical differences revealed by optical genome mapping.

Author

Ma, Yunting, Gui, Chunrong, Shi, Meizhen, Wei, Lilin, He, Junfang, Xie, Bobo, Zheng, Haiyang, Lei, Xiaoyun, Wei, Xianda, Cheng, Zifeng, Zhou, Xu, Chen, Shaoke, Luo, Jiefeng, Huang, Yan, and Gui, Baoheng

Abstract

Background: Deletion or duplication in the DMD gene is one of the most common causes of Duchenne and Becker muscular dystrophy (DMD/BMD). However, the pathogenicity of complex rearrangements involving DMD, especially segmental duplications with unknown breakpoints, is not well understood. This study aimed to evaluate the structure, pattern, and potential impact of rearrangements involving DMD duplication. Methods: Two families with DMD segmental duplications exhibiting phenotypical differences were recruited. Optical genome mapping (OGM) was used to explore the cryptic pattern of the rearrangements. Breakpoints were validated using long-range polymerase chain reaction combined with next-generation sequencing and Sanger sequencing. Results: A multi-copy duplication involving exons 64–79 of DMD was identified in Family A without obvious clinical symptoms. Family B exhibited typical DMD neuromuscular manifestations and presented a duplication involving exons 10–13 of DMD. The rearrangement in Family A involved complex in-cis tandem repeats shown by OGM but retained a complete copy (reading frame) of DMD inferred from breakpoint validation. A reversed insertion with a segmental repeat was identified in Family B by OGM, which was predicted to disrupt the normal structure and reading frame of DMD after confirming the breakpoints. Conclusions: Validating breakpoint and rearrangement pattern is crucial for the functional annotation and pathogenic classification of genomic structural variations. OGM provides valuable insights into etiological analysis of DMD/BMD and enhances our understanding for cryptic effects of complex rearrangements. [ABSTRACT FROM AUTHOR]

Published

2024

6. Optical Genome Mapping Identifies a Second Xq27.1 Rearrangement Associated With Charcot–Marie–Tooth Neuropathy CMTX3.

Author

Rahikkala, Elisa, Komulainen‐Ebrahim, Jonna, Tolonen, Jussi‐Pekka, Vorimo, Sandra, Suo‐Palosaari, Maria, Vieira, Päivi, Piispala, Johanna, Uusimaa, Johanna, Pylkäs, Katri, and Mantere, Tuomo

Subjects

*GENE mapping, *GENETIC testing, *GENOMICS, *CHROMOSOMES, *MOLECULAR diagnosis

Abstract

Background: X‐linked recessive type 3 Charcot–Marie–Tooth (CMTX3) is a rare subtype of childhood‐onset CMT. To date, all reported CMTX3 patients share a common founder 78 kb insertion from chromosome 8 into the Xq27.1 palindrome region. Methods: We conducted patient–parent trio optical genome mapping (OGM) on a male patient presenting with clinically diagnosed Dejerine–Sottas disease for whom initial standard diagnostic genetic tests, including whole‐genome sequencing (WGS), yielded negative results. Results: OGM analysis revealed a maternally inherited interchromosomal insertion from chromosome region 7q31.1 into Xq27.1. Coupled with manual reassessment of WGS data, this confirmed the molecular diagnosis of atypical CMTX3 and showed that the 122.4 kb inserted fragment contained DLD and partially LAMB1. Subsequent analyses confirmed that the rearrangement had arisen de novo in the proband's mother. Conclusion: We report the second Xq27.1 rearrangement associated with CMTX3, providing novel clinical insights into its phenotypic and genotypic spectrum. Our findings highlight the importance of including genomic rearrangement analysis of Xq27.1 in standard diagnostic pipelines for childhood‐onset CMT. Given the overlap in polyneuropathy phenotypes resulting from insertions from chromosomes 7 and 8 into the same Xq27.1 palindrome region, the pathogenic mechanism underlying peripheral neuropathy in CMTX3 likely involves dysregulation of genes within this region. [ABSTRACT FROM AUTHOR]

Published

2024

7. Optical genome mapping of structural variants in Parkinson’s disease-related induced pluripotent stem cells

Author

Joanne Trinh, Susen Schaake, Carolin Gabbert, Theresa Lüth, Sally A. Cowley, André Fienemann, Kristian K. Ullrich, Christine Klein, and Philip Seibler

Subjects

Optical genome mapping, iPSCs, Parkinson’s disease, Structural variants, Biotechnology, TP248.13-248.65, Genetics, QH426-470

Abstract

Abstract Background Certain structural variants (SVs) including large-scale genetic copy number variants, as well as copy number-neutral inversions and translocations may not all be resolved by chromosome karyotype studies. The identification of genetic risk factors for Parkinson’s disease (PD) has been primarily focused on the gene-disruptive single nucleotide variants. In contrast, larger SVs, which may significantly influence human phenotypes, have been largely underexplored. Optical genomic mapping (OGM) represents a novel approach that offers greater sensitivity and resolution for detecting SVs. In this study, we used induced pluripotent stem cell (iPSC) lines of patients with PD-linked SNCA and PRKN variants as a proof of concept to (i) show the detection of pathogenic SVs in PD with OGM and (ii) provide a comprehensive screening of genetic abnormalities in iPSCs. Results OGM detected SNCA gene triplication and duplication in patient-derived iPSC lines, which were not identified by long-read sequencing. Additionally, various exon deletions were confirmed by OGM in the PRKN gene of iPSCs, of which exon 3–5 and exon 2 deletions were unable to phase with conventional multiplex-ligation-dependent probe amplification. In terms of chromosomal abnormalities in iPSCs, no gene fusions, no aneuploidy but two balanced inter-chromosomal translocations were detected in one line that were absent in the parental fibroblasts and not identified by routine single nucleotide variant karyotyping. Conclusions In summary, OGM can detect pathogenic SVs in PD-linked genes as well as reveal genomic abnormalities for iPSCs that were not identified by other techniques, which is supportive for OGM’s future use in gene discovery and iPSC line screening.

Published

2024

8. The cryptic complex rearrangements involving the DMD gene: etiologic clues about phenotypical differences revealed by optical genome mapping

Author

Yunting Ma, Chunrong Gui, Meizhen Shi, Lilin Wei, Junfang He, Bobo Xie, Haiyang Zheng, Xiaoyun Lei, Xianda Wei, Zifeng Cheng, Xu Zhou, Shaoke Chen, Jiefeng Luo, Yan Huang, and Baoheng Gui

Subjects

DMD, Complex rearrangement, Breakpoints, Phenotypical differences, Optical genome mapping, Medicine, Genetics, QH426-470

Abstract

Abstract Background Deletion or duplication in the DMD gene is one of the most common causes of Duchenne and Becker muscular dystrophy (DMD/BMD). However, the pathogenicity of complex rearrangements involving DMD, especially segmental duplications with unknown breakpoints, is not well understood. This study aimed to evaluate the structure, pattern, and potential impact of rearrangements involving DMD duplication. Methods Two families with DMD segmental duplications exhibiting phenotypical differences were recruited. Optical genome mapping (OGM) was used to explore the cryptic pattern of the rearrangements. Breakpoints were validated using long-range polymerase chain reaction combined with next-generation sequencing and Sanger sequencing. Results A multi-copy duplication involving exons 64–79 of DMD was identified in Family A without obvious clinical symptoms. Family B exhibited typical DMD neuromuscular manifestations and presented a duplication involving exons 10–13 of DMD. The rearrangement in Family A involved complex in-cis tandem repeats shown by OGM but retained a complete copy (reading frame) of DMD inferred from breakpoint validation. A reversed insertion with a segmental repeat was identified in Family B by OGM, which was predicted to disrupt the normal structure and reading frame of DMD after confirming the breakpoints. Conclusions Validating breakpoint and rearrangement pattern is crucial for the functional annotation and pathogenic classification of genomic structural variations. OGM provides valuable insights into etiological analysis of DMD/BMD and enhances our understanding for cryptic effects of complex rearrangements.

Published

2024

9. Combining optical genome mapping and RNA-seq for structural variants detection and interpretation in unsolved neurodevelopmental disorders

Author

Bing Xiao, Xiaomei Luo, Yi Liu, Hui Ye, Huili Liu, Yanjie Fan, and Yongguo Yu

Subjects

Optical genome mapping, RNA-seq, Structural variants, Neurodevelopmental disorders, Medicine, Genetics, QH426-470

Abstract

Abstract Background Structural variations (SVs) are key genetic contributors to neurodevelopmental disorders (NDDs). Exome sequencing (ES), the current first-line tool for genetic testing of NDDs, falls short in SVs detection. This diagnostic gap is being actively addressed by new methods such as optical genome mapping (OGM). Methods This study evaluated the utility of combining OGM and RNA-seq in the detection and interpretation of SVs in ES-negative NDDs. OGM was performed in 43 patients with NDDs with inconclusive ES results. Candidate SVs were selected based on disease association and pathogenicity evaluation, and further validated or reconstructed by alternative methods, including long-read sequencing for a complex rearrangement event. RNA-Seq was performed on blood samples from patients with candidate SVs to facilitate interpretation of pathogenicity. Results OGM detected four candidate SVs, and RNA-seq confirmed the pathogenicity of three SVs in the patient cohort. This combined approach solved three cases—two cases with de novo SVs in genes associated with autosomal dominant NDDs, including a deletion encompassing the promoter and 5′UTR of MBD5 and an intragenic duplication of PAFAH1B1, and a third case possessing an intragenic duplication in trans with a pathogenic single-nucleotide variant of PLA2G6, associated with autosomal recessive NDDs. The expression alteration of the affected genes and the tandem positioning of two intragenic duplications were confirmed by RNA-seq. In the fourth case, OGM detected a complex rearrangement involving chromosomes 2 and 6, much more complex than the de novo t(2:6)(q13;q15) indicated by conventional cytogenetic analysis. Reconstruction showed that 17 segments of 6q15 spanning 9.3 Mb were disarranged and joined 2q11.2, with four breakpoints detected in the 5′ and 3′ non-coding region of the NDD-associated gene SYNCRIP. RNA-seq revealed largely preserved SYNCRIP expression, leaving the pathogenicity of this complex rearrangement event uncertain. Conclusions SVs in ES-negative NDDs can be identified by OGM, which is particularly useful for SVs in non-coding regions not covered by ES. OGM helps to construct complex SVs and provides information on the location and orientation of duplications, which is crucial for pathogenicity interpretation. The integration of RNA-seq facilitates the interpretation of the functional consequences of SVs at the transcriptional level. These findings demonstrate the utility and feasibility of combining OGM and RNA-seq in ES-negative cases with NDDs.

Published

2024

10. Long‐read sequencing and optical genome mapping identify causative gene disruptions in noncoding sequence in two patients with neurologic disease and known chromosome abnormalities.

Author

Sund, Kristen L., Liu, Jie, Lee, Joyce, Garbe, John, Abdelhamed, Zakia, Maag, Chelsey, Hallinan, Barbara, Wu, Steven W., Sperry, Ethan, Deshpande, Archana, Stottmann, Rolf, Smolarek, Teresa A., Dyer, Lisa M., and Hestand, Matthew S.

Abstract

Despite advances in next generation sequencing (NGS), genetic diagnoses remain elusive for many patients with neurologic syndromes. Long‐read sequencing (LRS) and optical genome mapping (OGM) technologies improve upon existing capabilities in the detection and interpretation of structural variation in repetitive DNA, on a single haplotype, while also providing enhanced breakpoint resolution. We performed LRS and OGM on two patients with known chromosomal rearrangements and inconclusive Sanger or NGS. The first patient, who had epilepsy and developmental delay, had a complex translocation between two chromosomes that included insertion and inversion events. The second patient, who had a movement disorder, had an inversion on a single chromosome disrupted by multiple smaller inversions and insertions. Sequence level resolution of the rearrangements identified pathogenic breaks in noncoding sequence in or near known disease‐causing genes with relevant neurologic phenotypes (MBD5, NKX2‐1). These specific variants have not been reported previously, but expected molecular consequences are consistent with previously reported cases. As the use of LRS and OGM technologies for clinical testing increases and data analyses become more standardized, these methods along with multiomic data to validate noncoding variation effects will improve diagnostic yield and increase the proportion of probands with detectable pathogenic variants for known genes implicated in neurogenetic disease. [ABSTRACT FROM AUTHOR]

Published

2024

11. Optical genome mapping with genome sequencing identifies subtelomeric Xq28 deletion and inserted 7p22.3 duplication in a male with multisystem developmental disorder.

Author

Rodriguez‐Gil, Jorge L., Nagy, Peter L., and Francke, Uta

Abstract

We report a 17‐year‐old male with supravalvular stenosis, initial failure to thrive and delayed early development, short stature, acromelia, dysmorphic facial features, hypertelorism, macrocephaly, syringomyelia, hypertension, and anxiety disorder. Fluorescent in situ hybridization (FISH), chromosomal microarray analysis (CMA), and exome sequencing (ES) were nondiagnostic. Combined optical genome mapping (OGM) and genome sequencing (GS) showed a complex rearrangement including an X chromosome with a 22.5 kb deletion in band Xq28 replaced by a 61.4 kb insertion of duplicated chromosome 7p22.3 material. The deletion removes the distal 3′ untranslated region (UTR) of FUNDC2, the entire CMC4 and MTCP1, and the first five exons of BRCC3. Transcriptome analysis revealed absent expression of CMC4 and MTCP1 and BRCC3 with normal transcript level of FUNDC2. The inserted duplication includes only one known gene: UNCX. Similar overlapping Xq28 deletions have been reported to be associated with Moyamoya disease (MMD), short stature, hypergonadotropic hypogonadism (HH), and facial dysmorphism. Although he has short stature, our patient does not have signs of Moyamoya arteriopathy or hypogonadism. The structurally abnormal X chromosome was present in his mother, but not in his unaffected brother, maternal uncle, or maternal grandparents. We propose that the combination of his absent Xq28 and duplicated 7p22.3 genomic material is responsible for his phenotype. This case highlights the potential of combined OGM and GS for detecting complex structural variants compared with standard of care genetic testing such as CMA and ES. [ABSTRACT FROM AUTHOR]

Published

2024

12. Uncovering hidden genetic variations: long-read sequencing reveals new insights into tuberous sclerosis complex.

Author

Jing Duan, Shirang Pan, Yuanzhen Ye, Zhanqi Hu, Li Chen, Dachao Liang, Tao Fu, Lintao Zhan, Zhuo Li, Jianxiang Liao, and Xia Zhao

Subjects

TUBEROUS sclerosis, GENETIC variation, MOSAICISM

Abstract

Background: Tuberous sclerosis is a multi-system disorder caused by mutations in either TSC1 or TSC2. The majority of affected patients (85%--90%) have heterozygous variants, and a smaller number (around 5%) have mosaic variants. Despite using various techniques, some patients still have "no mutation identified" (NMI). Methods: We hypothesized that the causal variants of patients with NMI may be structural variants or deep intronic variants. To investigate this, we sequenced the DNA of 26 tuberous sclerosis patients with NMI using targeted long-read sequencing. Results: We identified likely pathogenic/pathogenic variants in 13 of the cases, of which 6 were large deletions, four were InDels, two were deep intronic variants, one had retrotransposon insertion in either TSC1 or TSC2, and one was complex rearrangement. Furthermore, there was a de novo Alu element insertion with a high suspicion of pathogenicity that was classified as a variant of unknown significance. Conclusion: Our findings expand the current knowledge of known pathogenic variants related to tuberous sclerosis, particularly uncovering mosaic complex structural variations and retrotransposon insertions that have not been previously reported in tuberous sclerosis. Our findings suggest a higher prevalence of mosaicism among tuberous sclerosis patients than previously recognized. Our results indicate that long-read sequencing is a valuable approach for tuberous sclerosis cases with no mutation identified (NMI). [ABSTRACT FROM AUTHOR]

Published

2024

13. Optical genome mapping identifies a homozygous deletion in the non-coding region of the SCN9A gene in individuals from the same family with congenital insensitivity to pain.

Author

Boughalem, Aïcha, Ciorna-Monferrato, Viorica, Sloboda, Natacha, Guegan, Amélie, Page, François, Zimmer, Sophie, Benazra, Marion, Kleinfinger, Pascale, Lohmann, Laurence, Valduga, Mylène, Receveur, Aline, Martin, Fernando, and Trost, Detlef

Subjects

GENE mapping, WHOLE genome sequencing, GENETIC testing, JOINT hypermobility, GENETIC variation

Abstract

We report an index patient with complete insensitivity to pain and a history of painless fractures, joint hypermobility, and behavioral problems. The index patient descends froma familywith notable cases among hismaternal relatives, including his aunt and his mother's first cousin, both of whom suffer from congenital insensitivity to pain. The patient had normal results for prior genetic testing: fragile-X syndrome testing, chromosomal microarray analysis, and exome sequencing. Optical genome mapping detected a homozygous deletion affecting the noncoding 5' untranslated region (UTR) and the first non-coding exon of the SCN9A gene in all affected family members, compatiblewith recessive disease transmission. Pathogenic homozygous loss-of-function variants in the SCN9A gene are associated with impaired pain sensation in humans. Optical genome mapping can thus detect pathogenic structural variants in patients without molecular etiology by standard diagnostic procedures and is a more accessible diagnostic tool than short-read or long-read whole-genome sequencing. [ABSTRACT FROM AUTHOR]

Published

2024

14. Clinical Utility of Optical Genome Mapping for Improved Cytogenomic Analysis of Gliomas.

Author

Singh, Harmanpreet, Sahajpal, Nikhil S., Mondal, Ashis K., Burke, Stephanie L., Farmaha, Jaspreet, Alptekin, Ahmet, Vashisht, Ashutosh, Jones, Kimya, Vashisht, Vishakha, and Kolhe, Ravindra

Subjects

FLUORESCENCE in situ hybridization, GENE mapping, BRAIN stem, TURNAROUND time, GLIOMAS

Abstract

A glioma is a solid brain tumor which originates in the brain or brain stem area. The diagnosis of gliomas based on standard-of-care (SOC) techniques includes karyotyping, fluorescence in situ hybridization (FISH), and chromosomal microarray (CMA), for detecting the pathogenic variants and chromosomal abnormalities. But these techniques do not reveal the complete picture of genetic complexity, thus requiring an alternative technology for better characterization of these tumors. The present study aimed to evaluate the clinical performance and feasibility of using optical genome mapping (OGM) for chromosomal characterization of gliomas. Herein, we evaluated 10 cases of gliomas that were previously characterized by CMA. OGM analysis showed concordance with the results of CMA in identifying the characterized Structural Variants (SVs) in these cases. More notably, it also revealed additional clinically relevant aberrations, demonstrating a higher resolution and sensitivity. These clinically relevant SVs included cryptic translocation, and SVs which are beyond the detection capabilities of CMA. Our analysis highlights the unique capability of OGM to detect all classes of SVs within a single assay, thereby unveiling clinically significant data with a shorter turnaround time. Adopting this diagnostic tool as a standard of care for solid tumors like gliomas shows potential for improving therapeutic management, potentially leading to more personalized and timely interventions for patients. [ABSTRACT FROM AUTHOR]

Published

2024

15. Comparison of Optical Genome Mapping With Conventional Diagnostic Methods for Structural Variant Detection in Hematologic Malignancies.

Author

Yeeun Shim, Yu-Kyung Koo, Saeam Shin, Seung-Tae Lee, Kyung-A Lee, and Jong Rak Choi

Subjects

GENE mapping, HEMATOLOGIC malignancies, TECHNOLOGICAL innovations, GENETIC markers, BONE marrow, CHROMOSOME duplication, OPTOELECTRONICS

Abstract

Background: Structural variants (SVs) are currently analyzed using a combination of conventional methods; however, this approach has limitations. Optical genome mapping (OGM), an emerging technology for detecting SVs using a single-molecule strategy, has the potential to replace conventional methods. We compared OGM with conventional diagnostic methods for detecting SVs in various hematologic malignancies. Methods: Residual bone marrow aspirates from 27 patients with hematologic malignancies in whom SVs were observed using conventional methods (chromosomal banding analysis, FISH, an RNA fusion panel, and reverse transcription PCR) were analyzed using OGM. The concordance between the OGM and conventional method results was evaluated. Results: OGM showed concordance in 63% (17/27) and partial concordance in 37% (10/27) of samples. OGM detected 76% (52/68) of the total SVs correctly (concordance rate for each type of SVs: aneuploidies, 83% [15/18]; balanced translocation, 80% [12/15] unbalanced translocation, 54% [7/13] deletions, 81% [13/16]; duplications, 100% [2/2] inversion 100% [1/1]; insertion, 100% [1/1]; marker chromosome, 0% [0/1]; isochromosome, 100% [1/1]). Sixteen discordant results were attributed to the involvement of centromeric/telomeric regions, detection sensitivity, and a low mapping rate and coverage. OGM identified additional SVs, including submicroscopic SVs and novel fusions, in five cases. Conclusions: OGM shows a high level of concordance with conventional diagnostic methods for the detection of SVs and can identify novel variants, suggesting its potential utility in enabling more comprehensive SV analysis in routine diagnostics of hematologic malignancies, although further studies and improvements are required. [ABSTRACT FROM AUTHOR]

Published

2024

16. Optical Genome Mapping Reveals Disruption of the RASGRF2 Gene in a Patient with Developmental Delay Carrying a De Novo Balanced Reciprocal Translocation.

Author

Lederbogen, Rosa Catalina, Hoffjan, Sabine, Thiels, Charlotte, Mau-Holzmann, Ulrike Angelika, Singer, Sylke, Yusenko, Maria Viktorovna, Nguyen, Hoa Huu Phuc, and Gerding, Wanda Maria

Subjects

*CHROMOSOMAL translocation, *GUANINE nucleotide exchange factors, *DEVELOPMENTAL delay, *GENE mapping, *NEUROPLASTICITY, *INTELLECTUAL disabilities

Abstract

While balanced reciprocal translocations are relatively common, they often remain clinically silent unless they lead to the disruption of functional genes. In this study, we present the case of a boy exhibiting developmental delay and mild intellectual disability. Initial karyotyping revealed a translocation t(5;6)(q13;q23) between chromosomes 5 and 6 with limited resolution. Optical genome mapping (OGM) enabled a more precise depiction of the breakpoint regions involved in the reciprocal translocation. While the breakpoint region on chromosome 6 did not encompass any known gene, OGM revealed the disruption of the RASGRF2 (Ras protein-specific guanine nucleotide releasing factor 2) gene on chromosome 5, implicating RASGRF2 as a potential candidate gene contributing to the observed developmental delay in the patient. Variations in RASGRF2 have so far not been reported in developmental delay, but research on the RASGRF2 gene underscores its significance in various aspects of neurodevelopment, including synaptic plasticity, signaling pathways, and behavioral responses. This study highlights the utility of OGM in identifying breakpoint regions, providing possible insights into the understanding of neurodevelopmental disorders. It also helps affected individuals in gaining more knowledge about potential causes of their conditions. [ABSTRACT FROM AUTHOR]

Published

2024

17. Tissue-specific TCF4 triplet repeat instability revealed by optical genome mappingResearch in context

Author

Christina Zarouchlioti, Stephanie Efthymiou, Stefano Facchini, Natalia Dominik, Nihar Bhattacharyya, Siyin Liu, Marcos Abreu Costa, Anita Szabo, Amanda N. Sadan, Albert S. Jun, Enrico Bugiardini, Henry Houlden, Andrea Cortese, Pavlina Skalicka, Lubica Dudakova, Kirithika Muthusamy, Michael E. Cheetham, Alison J. Hardcastle, Petra Liskova, Stephen J. Tuft, and Alice E. Davidson

Subjects

Fuchs endothelial corneal dystrophy, Trinucleotide repeat expansion disease, Triplet repeat expansion-mediated disease, Somatic mosaicism, Tissue-specific repeat instability, Optical genome mapping, Medicine, Medicine (General), R5-920

Abstract

Summary: Background: Fuchs endothelial corneal dystrophy (FECD) is the most common repeat-mediated disease in humans. It exclusively affects corneal endothelial cells (CECs), with ≤81% of cases associated with an intronic TCF4 triplet repeat (CTG18.1). Here, we utilise optical genome mapping (OGM) to investigate CTG18.1 tissue-specific instability to gain mechanistic insights. Methods: We applied OGM to a diverse range of genomic DNAs (gDNAs) from patients with FECD and controls (n = 43); CECs, leukocytes and fibroblasts. A bioinformatics pipeline was developed to robustly interrogate CTG18.1-spanning DNA molecules. All results were compared with conventional polymerase chain reaction-based fragment analysis. Findings: Analysis of bio-samples revealed that expanded CTG18.1 alleles behave dynamically, regardless of cell-type origin. However, clusters of CTG18.1 molecules, encompassing ∼1800–11,900 repeats, were exclusively detected in diseased CECs from expansion-positive cases. Additionally, both progenitor allele size and age were found to influence the level of leukocyte-specific CTG18.1 instability. Interpretation: OGM is a powerful tool for analysing somatic instability of repeat loci and reveals here the extreme levels of CTG18.1 instability occurring within diseased CECs underpinning FECD pathophysiology, opening up new therapeutic avenues for FECD. Furthermore, these findings highlight the broader translational utility of FECD as a model for developing therapeutic strategies for rarer diseases similarly attributed to somatically unstable repeats. Funding: UK Research and Innovation, Moorfields Eye Charity, Fight for Sight, Medical Research Council, NIHR BRC at Moorfields Eye Hospital and UCL Institute of Ophthalmology, Grantová Agentura České Republiky, Univerzita Karlova v Praze, the National Brain Appeal’s Innovation Fund and Rosetrees Trust.

Published

2024

18. Optical Genome Mapping Identifies a Second Xq27.1 Rearrangement Associated With Charcot–Marie–Tooth Neuropathy CMTX3

Author

Elisa Rahikkala, Jonna Komulainen‐Ebrahim, Jussi‐Pekka Tolonen, Sandra Vorimo, Maria Suo‐Palosaari, Päivi Vieira, Johanna Piispala, Johanna Uusimaa, Katri Pylkäs, and Tuomo Mantere

Subjects

Charcot–Marie–Tooth disease, CMTX3, genome sequencing, genomic rearrangement, optical genome mapping, Genetics, QH426-470

Abstract

ABSTRACT Background X‐linked recessive type 3 Charcot–Marie–Tooth (CMTX3) is a rare subtype of childhood‐onset CMT. To date, all reported CMTX3 patients share a common founder 78 kb insertion from chromosome 8 into the Xq27.1 palindrome region. Methods We conducted patient–parent trio optical genome mapping (OGM) on a male patient presenting with clinically diagnosed Dejerine–Sottas disease for whom initial standard diagnostic genetic tests, including whole‐genome sequencing (WGS), yielded negative results. Results OGM analysis revealed a maternally inherited interchromosomal insertion from chromosome region 7q31.1 into Xq27.1. Coupled with manual reassessment of WGS data, this confirmed the molecular diagnosis of atypical CMTX3 and showed that the 122.4 kb inserted fragment contained DLD and partially LAMB1. Subsequent analyses confirmed that the rearrangement had arisen de novo in the proband's mother. Conclusion We report the second Xq27.1 rearrangement associated with CMTX3, providing novel clinical insights into its phenotypic and genotypic spectrum. Our findings highlight the importance of including genomic rearrangement analysis of Xq27.1 in standard diagnostic pipelines for childhood‐onset CMT. Given the overlap in polyneuropathy phenotypes resulting from insertions from chromosomes 7 and 8 into the same Xq27.1 palindrome region, the pathogenic mechanism underlying peripheral neuropathy in CMTX3 likely involves dysregulation of genes within this region.

Published

2024

19. Unravelling a KMT2A::ARHGEF12 fusion within chromoanagenesis in acute myeloid leukemia using Optical Genome Mapping.

Author

Klos, Corentine, Roynard, Pauline, Berthon, Céline, Soenen, Valérie, Marceau, Alice, Fournier, Elise, Fenwarth, Laurene, Daudignon, Agnès, Roche, Catherine, and Guermouche, Hélène

Published

2024

20. Optical Genome Mapping Identifies a Novel Unbalanced Translocation Between Chromosomes 4q and 6q Leading to Feeding Difficulties and Hypotonia in a Neonate: A Case Report

Author

Wang Y, Bi S, Shi X, and Dai L

Subjects

optical genome mapping, unbalanced translocation, copy number variations, neonatal diseases, Medicine (General), R5-920, Genetics, QH426-470

Abstract

Ying Wang, Shaohua Bi, Xiaoqing Shi, Liying Dai Division of Neonatology, Anhui Provincial Children’s Hospital, Hefei, Anhui, 230051, People’s Republic of ChinaCorrespondence: Liying Dai, Division of Neonatology, Anhui Province Children’s Hospital, No. 39, Wangjiang East Road, Baohe District, Hefei, Anhui, 230051, People’s Republic of China, Email dailiying1101@163.comAbstract: Optical Genome Mapping (OGM) technology has garnered growing interest for the identification of chromosomal structural variations (SVs), particularly complex ones that are implicated in genetic diseases in humans. In this study, we performed genetic diagnostics on a neonatal patient who presented with feeding difficulties, hypotonia, and an atrial septal defect. We utilized a combination of trio-whole exome sequencing and OGM for our analysis. The results revealed an unbalanced translocation between maternal chromosomes 4 and 6 in the proband, ogm[GRch38]t(4:6)(q35.2;q25.3), resulting in a 2.8 Mb deletion at the 4q35 terminal and a 10.2 Mb duplication at the 6q25 terminal. In summary, this study highlights how OGM, in conjunction with other genetic approaches, can unveil the genetic etiology of complex clinical syndromes. Neonatal patients often exhibit low specific phenotypes, underlining the significance of SV detection.Keywords: optical genome mapping, unbalanced translocation, copy number variations, neonatal diseases

Published

2024

21. Optical genome mapping unveils hidden structural variants in neurodevelopmental disorders

Author

Isabelle Schrauwen, Yasmin Rajendran, Anushree Acharya, Susanna Öhman, Maria Arvio, Ritva Paetau, Auli Siren, Kristiina Avela, Johanna Granvik, Suzanne M. Leal, Tuomo Määttä, Hannaleena Kokkonen, and Irma Järvelä

Subjects

Optical genome mapping, Neurodevelopmental disorders, Structural variants, Copy number variants, Unsolved cases, Medicine, Science

Abstract

Abstract While short-read sequencing currently dominates genetic research and diagnostics, it frequently falls short of capturing certain structural variants (SVs), which are often implicated in the etiology of neurodevelopmental disorders (NDDs). Optical genome mapping (OGM) is an innovative technique capable of capturing SVs that are undetectable or challenging-to-detect via short-read methods. This study aimed to investigate NDDs using OGM, specifically focusing on cases that remained unsolved after standard exome sequencing. OGM was performed in 47 families using ultra-high molecular weight DNA. Single-molecule maps were assembled de novo, followed by SV and copy number variant calling. We identified 7 variants of interest, of which 5 (10.6%) were classified as likely pathogenic or pathogenic, located in BCL11A, OPHN1, PHF8, SON, and NFIA. We also identified an inversion disrupting NAALADL2, a gene which previously was found to harbor complex rearrangements in two NDD cases. Variants in known NDD genes or candidate variants of interest missed by exome sequencing mainly consisted of larger insertions (> 1kbp), inversions, and deletions/duplications of a low number of exons (1–4 exons). In conclusion, in addition to improving molecular diagnosis in NDDs, this technique may also reveal novel NDD genes which may harbor complex SVs often missed by standard sequencing techniques.

Published

2024

22. Structural rearrangements as a recurrent pathogenic mechanism for SETBP1 haploinsufficiency

Author

V. Alesi, S. Genovese, M. C. Roberti, E. Sallicandro, S. Di Tommaso, S. Loddo, V. Orlando, D. Pompili, C. Calacci, V. Mei, E. Pisaneschi, M. V. Faggiano, A. Morgia, C. Mammì, G. Astrea, R. Battini, M. Priolo, M. L. Dentici, R. Milone, and A. Novelli

Subjects

SETBP1, Optical genome mapping, OGM, Complex rearrangement, Translocation, RASopathy, Medicine, Genetics, QH426-470

Abstract

Abstract Chromosomal structural rearrangements consist of anomalies in genomic architecture that may or may not be associated with genetic material gain and loss. Evaluating the precise breakpoint is crucial from a diagnostic point of view, highlighting possible gene disruption and addressing to appropriate genotype–phenotype association. Structural rearrangements can either occur randomly within the genome or present with a recurrence, mainly due to peculiar genomic features of the surrounding regions. We report about three non-related individuals, harboring chromosomal structural rearrangements interrupting SETBP1, leading to gene haploinsufficiency. Two out of them resulted negative to Chromosomal Microarray Analysis (CMA), being the rearrangement balanced at a microarray resolution. The third one, presenting with a complex three-chromosome rearrangement, had been previously diagnosed with SETBP1 haploinsufficiency due to a partial gene deletion at one of the chromosomal breakpoints. We thoroughly characterized the rearrangements by means of Optical Genome Mapping (OGM) and Whole Genome Sequencing (WGS), providing details about the involved sequences and the underlying mechanisms. We propose structural variants as a recurrent event in SETBP1 haploinsufficiency, which may be overlooked by laboratory routine genomic analyses (CMA and Whole Exome Sequencing) or only partially determined when associated with genomic losses at breakpoints. We finally introduce a possible role of SETBP1 in a Noonan-like phenotype.

Published

2024

23. Optical genome mapping unveils hidden structural variants in neurodevelopmental disorders.

Author

Schrauwen, Isabelle, Rajendran, Yasmin, Acharya, Anushree, Öhman, Susanna, Arvio, Maria, Paetau, Ritva, Siren, Auli, Avela, Kristiina, Granvik, Johanna, Leal, Suzanne M., Määttä, Tuomo, Kokkonen, Hannaleena, and Järvelä, Irma

Subjects

*GENE mapping, *DNA copy number variations, *NEURAL development, *GENETIC variation, *MOLECULAR diagnosis, *EXOMES, *GENOMES

Abstract

While short-read sequencing currently dominates genetic research and diagnostics, it frequently falls short of capturing certain structural variants (SVs), which are often implicated in the etiology of neurodevelopmental disorders (NDDs). Optical genome mapping (OGM) is an innovative technique capable of capturing SVs that are undetectable or challenging-to-detect via short-read methods. This study aimed to investigate NDDs using OGM, specifically focusing on cases that remained unsolved after standard exome sequencing. OGM was performed in 47 families using ultra-high molecular weight DNA. Single-molecule maps were assembled de novo, followed by SV and copy number variant calling. We identified 7 variants of interest, of which 5 (10.6%) were classified as likely pathogenic or pathogenic, located in BCL11A, OPHN1, PHF8, SON, and NFIA. We also identified an inversion disrupting NAALADL2, a gene which previously was found to harbor complex rearrangements in two NDD cases. Variants in known NDD genes or candidate variants of interest missed by exome sequencing mainly consisted of larger insertions (> 1kbp), inversions, and deletions/duplications of a low number of exons (1–4 exons). In conclusion, in addition to improving molecular diagnosis in NDDs, this technique may also reveal novel NDD genes which may harbor complex SVs often missed by standard sequencing techniques. [ABSTRACT FROM AUTHOR]

Published

2024

24. An Inversion Affecting the GCH1 Gene as a Novel Finding in Dopa‐Responsive Dystonia.

Author

El‐Wahsh, Shadi, Fellner, Avi, Hobbs, Matthew, Copty, Joe, Deveson, Ira, Stevanovski, Igor, Stoll, Marion, Zhu, Danqing, Narayanan, Ramesh K., Grosz, Bianca, Worgan, Lisa, Cheong, Pak Leng, Yeow, Dennis, Rudaks, Laura, Hasan, Md Mehedi, Hayes, Vanessa M., Kennerson, Marina, Kumar, Kishore R., and Hayes, Michael

Subjects

*DYSTONIA, *HEREDITY, *MOVEMENT disorders, *GENETIC testing, *WHOLE genome sequencing, *GENETIC variation, *TREMOR

Abstract

This article discusses a case study of a 57-year-old Han Chinese male with dopa-responsive dystonia (DRD) caused by a large inversion affecting the GCH1 gene. The patient experienced abnormal head posturing and gait disturbance following a head injury at age 10. Despite not having an identifiable disease-causing variant through conventional gene sequencing, the patient responded well to low-dose levodopa treatment. The study highlights the importance of using whole genome sequencing, nanopore long-read sequencing, and optical genome mapping to detect and confirm complex structural variants in patients with DRD. [Extracted from the article]

Published

2024

25. Optical Genome Mapping as a New Tool to Overcome Conventional Cytogenetics Limitations in Patients with Bone Marrow Failure.

Author

Iriondo, June, Gómez, Ana, Zubicaray, Josune, Garcia-Martinez, Jorge, Abad, Lorea, Matesanz, Carmen, Giménez, Reyes, Galán, Almudena, Sanz, Alejandro, Sebastián, Elena, González de Pablo, Jesús, de la Cruz, Ana, Ramírez, Manuel, and Sevilla, Julián

Subjects

*GENE mapping, *BONE marrow, *CYTOGENETICS, *FLUORESCENCE in situ hybridization, *HEMATOLOGIC malignancies, *DETECTION limit

Abstract

Cytogenetic studies are essential in the diagnosis and follow up of patients with bone marrow failure syndromes (BMFSs), but obtaining good quality results is often challenging due to hypocellularity. Optical Genome Mapping (OGM), a novel technology capable of detecting most types chromosomal structural variants (SVs) at high resolution, is being increasingly used in many settings, including hematologic malignancies. Herein, we compared conventional cytogenetic techniques to OGM in 20 patients with diverse BMFSs. Twenty metaphases for the karyotype were only obtained in three subjects (15%), and no SVs were found in any of the samples. One patient with culture failure showed a gain in chromosome 1q by fluorescence in situ hybridization, which was confirmed by OGM. In contrast, OGM provided good quality results in all subjects, and SVs were detected in 14 of them (70%), mostly corresponding to cryptic submicroscopic alterations not observed by standard techniques. Therefore, OGM emerges as a powerful tool that provides complete and evaluable results in hypocellular BMFSs, reducing multiple tests into a single assay and overcoming some of the main limitations of conventional techniques. Furthermore, in addition to confirming the abnormalities detected by conventional techniques, OGM found new alterations beyond their detection limits. [ABSTRACT FROM AUTHOR]

Published

2024

26. Appraisal of current technologies for the study of genetic alterations in hematologic malignancies with a focus on chromosome analysis and structural variants.

Author

Mrózek MD, PhD 4, Krzysztof, Salaverria PhD 1,2, Itziar, and Siebert 3, Reiner

Subjects

*HEMATOLOGIC malignancies, *CHROMOSOME analysis, *CYTOGENETICS, *REVERSE transcriptase polymerase chain reaction, *GENE mapping

Abstract

During the last five decades, chromosome analysis identified recurring translocations and inversions in leukemias and lymphomas, which led to cloning of genes at the breakpoints that contribute to oncogenesis. Such molecular cytogenetic methods as fluorescence in situ hybridization (FISH), copy number (CN) arrays or optical genome mapping (OGM) have augmented standard chromosome analysis. The use of both cytogenetic and molecular methods, such as reverse transcription-polymerase chain reaction (RT-PCR) and next generation sequencing (NGS), including whole-genome sequencing (WGS), discloses alterations that not only delineate separate WHO disease entities but also constitute independent prognostic factors, whose use in the clinic improves management of patients with hematologic neoplasms. [ABSTRACT FROM AUTHOR]

Published

2024

27. The clinical value of optical genome mapping in the rapid characterization of RB1 duplication and 15q23q24.2 triplication, for more appropriate prenatal genetic counselling.

Author

Bouassida, Malek, Molina‐Gomes, Denise, Koraichi, Fairouz, Hervé, Bérénice, Lhuilier, Morgane, Duvillier, Clémence, Le Gall, Jessica, Gauthier‐Villars, Marion, Serazin, Valérie, Quibel, Thibaud, Dard, Rodolphe, and Vialard, François

Subjects

*GENE mapping, *GENETIC counseling, *CHROMOSOMAL rearrangement, *CHROMOSOME abnormalities, *PRENATAL diagnosis, *CYTOGENETICS, *NUCLEOTIDE sequencing

Abstract

Background: Despite recent advances in prenatal genetic diagnosis, medical geneticists still face considerable difficulty in interpreting the clinical outcome of copy‐number‐variant duplications and defining the mechanisms underlying the formation of certain chromosomal rearrangements. Optical genome mapping (OGM) is an emerging cytogenomic tool with proved ability to identify the full spectrum of cytogenetic aberrations. Methods: Here, we report on the use of OGM in a prenatal diagnosis setting. Detailed breakpoint mapping was used to determine the relative orientations of triplicated and duplicated segments in two unrelated foetuses harbouring chromosomal aberrations: a de novo 15q23q24.2 triplication and a paternally inherited 13q14.2 duplication that overlapped partially with the RB1 gene. Results: OGM enabled us to suggest a plausible mechanism for the triplication and confirmed that the RB1 duplication was direct oriented and in tandem. This enabled us to predict the pathogenic consequences, refine the prognosis and adapt the follow‐up and familial screening appropriately. Conclusion: Along with an increase in diagnostic rates, OGM can rapidly highlight genotype–phenotype correlations, improve genetic counselling and significantly influence prenatal management. [ABSTRACT FROM AUTHOR]

Published

2024

28. Structural rearrangements as a recurrent pathogenic mechanism for SETBP1 haploinsufficiency.

Author

Alesi, V., Genovese, S., Roberti, M. C., Sallicandro, E., Di Tommaso, S., Loddo, S., Orlando, V., Pompili, D., Calacci, C., Mei, V., Pisaneschi, E., Faggiano, M. V., Morgia, A., Mammì, C., Astrea, G., Battini, R., Priolo, M., Dentici, M. L., Milone, R., and Novelli, A.

Abstract

Chromosomal structural rearrangements consist of anomalies in genomic architecture that may or may not be associated with genetic material gain and loss. Evaluating the precise breakpoint is crucial from a diagnostic point of view, highlighting possible gene disruption and addressing to appropriate genotype–phenotype association. Structural rearrangements can either occur randomly within the genome or present with a recurrence, mainly due to peculiar genomic features of the surrounding regions. We report about three non-related individuals, harboring chromosomal structural rearrangements interrupting SETBP1, leading to gene haploinsufficiency. Two out of them resulted negative to Chromosomal Microarray Analysis (CMA), being the rearrangement balanced at a microarray resolution. The third one, presenting with a complex three-chromosome rearrangement, had been previously diagnosed with SETBP1 haploinsufficiency due to a partial gene deletion at one of the chromosomal breakpoints. We thoroughly characterized the rearrangements by means of Optical Genome Mapping (OGM) and Whole Genome Sequencing (WGS), providing details about the involved sequences and the underlying mechanisms. We propose structural variants as a recurrent event in SETBP1 haploinsufficiency, which may be overlooked by laboratory routine genomic analyses (CMA and Whole Exome Sequencing) or only partially determined when associated with genomic losses at breakpoints. We finally introduce a possible role of SETBP1 in a Noonan-like phenotype. [ABSTRACT FROM AUTHOR]

Published

2024

29. Optical Genome Mapping Reveals Genomic Alterations upon Gene Editing in hiPSCs: Implications for Neural Tissue Differentiation and Brain Organoid Research.

Author

Gallego Villarejo, Lucia, Gerding, Wanda M., Bachmann, Lisa, Hardt, Luzie H. I., Bormann, Stefan, Nguyen, Huu Phuc, and Müller, Thorsten

Subjects

*GENOME editing, *GENE mapping, *TISSUE differentiation, *NERVE tissue, *INDUCED pluripotent stem cells, *BRAIN research

Abstract

Genome editing, notably CRISPR (cluster regularly interspaced short palindromic repeats)/Cas9 (CRISPR-associated protein 9), has revolutionized genetic engineering allowing for precise targeted modifications. This technique's combination with human induced pluripotent stem cells (hiPSCs) is a particularly valuable tool in cerebral organoid (CO) research. In this study, CRISPR/Cas9-generated fluorescently labeled hiPSCs exhibited no significant morphological or growth rate differences compared with unedited controls. However, genomic aberrations during gene editing necessitate efficient genome integrity assessment methods. Optical genome mapping, a high-resolution genome-wide technique, revealed genomic alterations, including chromosomal copy number gain and losses affecting numerous genes. Despite these genomic alterations, hiPSCs retain their pluripotency and capacity to generate COs without major phenotypic changes but one edited cell line showed potential neuroectodermal differentiation impairment. Thus, this study highlights optical genome mapping in assessing genome integrity in CRISPR/Cas9-edited hiPSCs emphasizing the need for comprehensive integration of genomic and morphological analysis to ensure the robustness of hiPSC-based models in cerebral organoid research. [ABSTRACT FROM AUTHOR]

Published

2024

30. Integrating Optical Genome Mapping and Whole Genome Sequencing in Somatic Structural Variant Detection.

Author

Budurlean, Laura, Tukaramrao, Diwakar Bastihalli, Zhang, Lijun, Dovat, Sinisa, and Broach, James

Subjects

*WHOLE genome sequencing, *GENE mapping, *GENE expression, *GENETIC variation, *NUCLEOTIDE sequencing, *OPTOELECTRONICS, *CHROMOSOME duplication

Abstract

Structural variants drive tumorigenesis by disrupting normal gene function through insertions, inversions, translocations, and copy number changes, including deletions and duplications. Detecting structural variants is crucial for revealing their roles in tumor development, clinical outcomes, and personalized therapy. Presently, most studies rely on short-read data from next-generation sequencing that aligns back to a reference genome to determine if and, if so, where a structural variant occurs. However, structural variant discovery by short-read sequencing is challenging, primarily because of the difficulty in mapping regions of repetitive sequences. Optical genome mapping (OGM) is a recent technology used for imaging and assembling long DNA strands to detect structural variations. To capture the structural variant landscape more thoroughly in the human genome, we developed an integrated pipeline that combines Bionano OGM and Illumina whole-genome sequencing and applied it to samples from 29 pediatric B-ALL patients. The addition of OGM allowed us to identify 511 deletions, 506 insertions, 93 duplications/gains, and 145 translocations that were otherwise missed in the short-read data. Moreover, we identified several novel gene fusions, the expression of which was confirmed by RNA sequencing. Our results highlight the benefit of integrating OGM and short-read detection methods to obtain a comprehensive analysis of genetic variation that can aid in clinical diagnosis, provide new therapeutic targets, and improve personalized medicine in cancers driven by structural variation. [ABSTRACT FROM AUTHOR]

Published

2024

31. Optical Genome Mapping as a Potential Routine Clinical Diagnostic Method.

Author

Barseghyan, Hayk, Eisenreich, Doris, Lindt, Evgenia, Wendlandt, Martin, Scharf, Florentine, Benet-Pages, Anna, Sendelbach, Kai, Neuhann, Teresa, Abicht, Angela, Holinski-Feder, Elke, and Koehler, Udo

Subjects

*GENE mapping, *CHROMOSOME analysis, *CHROMOSOMAL translocation, *SOUTHERN blot, *GENETIC markers, *DNA copy number variations

Abstract

Chromosome analysis (CA) and chromosomal microarray analysis (CMA) have been successfully used to diagnose genetic disorders. However, many conditions remain undiagnosed due to limitations in resolution (CA) and detection of only unbalanced events (CMA). Optical genome mapping (OGM) has the potential to address these limitations by capturing both structural variants (SVs) resulting in copy number changes and balanced rearrangements with high resolution. In this study, we investigated OGM's concordance using 87 SVs previously identified by CA, CMA, or Southern blot. Overall, OGM was 98% concordant with only three discordant cases: (1) uncalled translocation with one breakpoint in a centromere; (2) uncalled duplication with breakpoints in the pseudoautosomal region 1; and (3) uncalled mosaic triplication originating from a marker chromosome. OGM provided diagnosis for three previously unsolved cases: (1) disruption of the SON gene due to a balanced reciprocal translocation; (2) disruption of the NBEA gene due to an inverted insertion; (3) disruption of the TSC2 gene due to a mosaic deletion. We show that OGM is a valid method for the detection of many types of SVs in a single assay and is highly concordant with legacy cytogenomic methods; however, it has limited SV detection capabilities in centromeric and pseudoautosomal regions. [ABSTRACT FROM AUTHOR]

Published

2024

32. Hematolojik Neoplazilerin Karmaşık Genetik Yapısını Aydınlatmada Yeni Nesil Bir Sitogenetik Yaklaşım: Optik Genom Haritalama.

Author

Tokaç, Ayşe Gül Bayrak

Abstract

Copyright of Osmangazi Journal of Medicine / Osmangazi Tip Dergisi is the property of Eskisehir Osmangazi University and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

33. Optical genome mapping identifies a homozygous deletion in the non-coding region of the SCN9A gene in individuals from the same family with congenital insensitivity to pain

Author

Aïcha Boughalem, Viorica Ciorna-Monferrato, Natacha Sloboda, Amélie Guegan, François Page, Sophie Zimmer, Marion Benazra, Pascale Kleinfinger, Laurence Lohmann, Mylène Valduga, Aline Receveur, Fernando Martin, and Detlef Trost

Subjects

optical genome mapping, SCN9A gene, insensitivity to pain, non-coding structural variant, structural variant detection, Genetics, QH426-470

Abstract

We report an index patient with complete insensitivity to pain and a history of painless fractures, joint hypermobility, and behavioral problems. The index patient descends from a family with notable cases among his maternal relatives, including his aunt and his mother’s first cousin, both of whom suffer from congenital insensitivity to pain. The patient had normal results for prior genetic testing: fragile-X syndrome testing, chromosomal microarray analysis, and exome sequencing. Optical genome mapping detected a homozygous deletion affecting the noncoding 5′ untranslated region (UTR) and the first non-coding exon of the SCN9A gene in all affected family members, compatible with recessive disease transmission. Pathogenic homozygous loss-of-function variants in the SCN9A gene are associated with impaired pain sensation in humans. Optical genome mapping can thus detect pathogenic structural variants in patients without molecular etiology by standard diagnostic procedures and is a more accessible diagnostic tool than short-read or long-read whole-genome sequencing.

Published

2024

34. Optical genome mapping identifies structural variants in potentially new cancer predisposition candidate genes in pediatric cancer patients.

Author

Wagener, Rabea, Brandes, Danielle, Jung, Marie, Huetzen, Maxim A., Bergmann, Anke K., Panier, Stephanie, Picard, Daniel, Fischer, Ute, Jachimowicz, Ron D., Borkhardt, Arndt, and Brozou, Triantafyllia

Subjects

GENE mapping, CHILDHOOD cancer, CANCER genes, CANCER patients, SINGLE nucleotide polymorphisms, DELETION mutation, CHROMOSOME duplication

Abstract

Genetic predisposition is one of the major risk factors for pediatric cancer, with ~10% of children being carriers of a predisposing germline alteration. It is likely that this is the tip of the iceberg and many children are underdiagnosed, as most of the analysis focuses on single or short nucleotide variants, not considering the full spectrum of DNA alterations. Hence, we applied optical genome mapping (OGM) to our cohort of 34 pediatric cancer patients to perform an unbiased germline screening and analyze the frequency of structural variants (SVs) and their impact on cancer predisposition. All children were clinically highly suspicious for germline alterations (concomitant conditions or congenital anomalies, positive family cancer history, particular cancer type, synchronous or metachronous tumors), but whole exome sequencing (WES) had failed to detect pathogenic variants in cancer predisposing genes. OGM detected a median of 49 rare SVs (range 27‐149) per patient. By analysis of 18 patient‐parent trios, we identified three de novo SVs. Moreover, we discovered a likely pathogenic deletion of exon 3 in the known cancer predisposition gene BRCA2, and identified a duplication in RPA1, which might represent a new cancer predisposition gene. We conclude that optical genome mapping is a suitable tool for detecting potentially predisposing SVs in addition to WES in pediatric cancer patients. [ABSTRACT FROM AUTHOR]

Published

2024

35. Case report: Identification of facioscapulohumeral muscular dystrophy 1 in two siblings with normal phenotypic parents using optical genome mapping.

Author

Jieni Jiang, Xiaotang Cai, Haibo Qu, Qiang Yao, Tiantian He, Mei Yang, Hui Zhou, and Xuemei Zhang

Subjects

FACIOSCAPULOHUMERAL muscular dystrophy, GENE mapping, PHENOTYPES, SIBLINGS, MUSCULAR dystrophy, SOUTHERN blot

Abstract

Objective: Facioscapulohumeral muscular dystrophy type 1 (FSHD1) is one of the most common forms of autosomal-dominant muscular dystrophies characterized by variable disease penetrance due to shortened D4Z4 repeat units on 4q35. Themolecular diagnosis of FSHD1 is usuallymade by Southern blotting, which is complex, time-consuming, and lacks clinical practicality. Therefore, in this study, optical genome mapping (OGM) is employed for the genetic diagnosis of FSHD1. Furthermore, epigenetic heterogeneity is determined from methylation analysis. Methods: Genomic DNA samples from four members of the same family were subjected to whole-exome sequencing. OGM was used to identify structural variations in D4Z4, while sodium bisulfite sequencing helped identify the methylation levels of CpG sites in a region located distally to the D4Z4 array. A multidisciplinary team collected the clinical data, and comprehensive family analyses aided in the assessment of phenotypes and genotypes. Results: Whole-exome sequencing did not reveal variants related to clinical phenotypes in the patients. OGM showed that the proband was a compound heterozygote for the 4qA allele with four and eight D4Z4 repeat units, whereas the affected younger brother had only one 4qA allele with four D4Z4 repeat units. Both the proband and her younger brother were found to display asymmetric weakness predominantly involving the facial, shoulder girdle, and upper arm muscles, whereas the younger brother had more severe clinical symptoms. The proband's father, who was found to be normal after a neurological examination, also carried the 4qA allele with eight D4Z4 repeat units. The unaffected mother exhibited 49 D4Z4 repeat units of the 4qA allele and a minor mosaic pattern with four D4Z4 repeat units of the 4qA allele. Consequently, the presence of the 4qA allele in the four D4Z4 repeat units strongly pointed to the occurrence of maternal germline mosaicism. The CpG6 methylation levels were lower in symptomatic patients compared to those in the asymptomatic parents. The older sister had lower clinical scores and ACSS and higher CpG6 methylation levels than that of her younger brother. Conclusions: In this study, two siblings with FSHD1 with phenotypically normal parents were identified by OGM. Our findings suggest that the 4qA allele of four D4Z4 repeats was inherited through maternal germline mosaicism. The clinical phenotype heterogeneity is influenced by the CpG6 methylation levels. The results of this study greatly aid in the molecular diagnosis of FSHD1 and in also understanding the clinical phenotypic variability underlying the disease. [ABSTRACT FROM AUTHOR]

Published

2024

36. A novel de novo intragenic duplication in FBN1 associated with early‐onset Marfan syndrome in a 16‐month‐old: A case report and review of the literature.

Author

Piscopo, Anthony, Warner, Taylor, Nagy, Jaime, Nagrale, Vidya, Stence, Aaron, Guseva, Natalya, Bernat, John A., and Calhoun, Amy

Abstract

Marfan syndrome (MFS) is an autosomal dominant connective tissue disorder due to pathogenic variants in Fibrillin‐1 (FBN1) affecting nearly one in every 10,000 individuals. We report a 16‐month‐old female with early‐onset MFS heterozygous for an 11.2 kb de novo duplication within the FBN1 gene. Tandem location of the duplication was further confirmed by optical genome mapping in addition to genetic sequencing and chromosomal microarray. This is the third reported case of a large multi‐exon duplication in FBN1, and the only one confirmed to be in tandem. As the vast majority of pathogenic variants associated with MFS are point mutations, this expands the landscape of known FBN1 pathogenic variants and supports consistent use of genetic testing strategies that can detect large, indel‐type variants. [ABSTRACT FROM AUTHOR]

Published

2024

37. Detection of Genomic Structural Variations Associated with Drug Sensitivity and Resistance in Acute Leukemia.

Author

Finlay, Darren, Murad, Rabi, Hong, Karl, Lee, Joyce, Pang, Andy Wing Chun, Lai, Chi-Yu, Clifford, Benjamin, Burian, Carol, Mason, James, Hastie, Alex R., Yin, Jun, and Vuori, Kristiina

Subjects

*GENETIC mutation, *LEUKEMIA, *ANTINEOPLASTIC agents, *GENETIC testing, *COMPARATIVE studies, *IDARUBICIN, *GENOMICS, *DRUG monitoring, *DESCRIPTIVE statistics, *RESEARCH funding, *GENE mapping, *GENETIC techniques, *DRUG resistance in cancer cells

Abstract

Simple Summary: Whilst association of genetic mutations with targeted therapies is common in leukemia, to our knowledge, no one has associated genomic structural variants with drug sensitivities. Here we use optical genome mapping as an unbiased, genome-wide detection method for structural variants and show that some of these events are associated with sensitivity or resistance to clinically relevant anti-cancer drugs. Acute leukemia is a particularly problematic collection of hematological cancers, and, while somewhat rare, the survival rate of patients is typically abysmal without bone marrow transplantation. Furthermore, traditional chemotherapies used as standard-of-care for patients cause significant side effects. Understanding the evolution of leukemia to identify novel targets and, therefore, drug treatment regimens is a significant medical need. Genomic rearrangements and other structural variations (SVs) have long been known to be causative and pathogenic in multiple types of cancer, including leukemia. These SVs may be involved in cancer initiation, progression, clonal evolution, and drug resistance, and a better understanding of SVs from individual patients may help guide therapeutic options. Here, we show the utilization of optical genome mapping (OGM) to detect known and novel SVs in the samples of patients with leukemia. Importantly, this technology provides an unprecedented level of granularity and quantitation unavailable to other current techniques and allows for the unbiased detection of novel SVs, which may be relevant to disease pathogenesis and/or drug resistance. Coupled with the chemosensitivities of these samples to FDA-approved oncology drugs, we show how an impartial integrative analysis of these diverse datasets can be used to associate the detected genomic rearrangements with multiple drug sensitivity profiles. Indeed, an insertion in the gene MUSK is shown to be associated with increased sensitivity to the clinically relevant agent Idarubicin, while partial tandem duplication events in the KMT2A gene are related to the efficacy of another frontline treatment, Cytarabine. [ABSTRACT FROM AUTHOR]

Published

2024

38. Optical Genome Mapping for Chromosomal Aberrations Detection—False-Negative Results and Contributing Factors.

Author

Xu, Yiyun, Zhang, Qinxin, Wang, Yan, Zhou, Ran, Ji, Xiuqing, Meng, Lulu, Luo, Chunyu, Liu, An, Jiao, Jiao, Chen, Hao, Zeng, Huasha, Hu, Ping, and Xu, Zhengfeng

Subjects

*GENE mapping, *CHROMOSOME abnormalities, *MOSAICISM, *QUALITY control, *GENOMES

Abstract

Optical genome mapping (OGM) has been known as an all-in-one technology for chromosomal aberration detection. However, there are also aberrations beyond the detection range of OGM. This study aimed to report the aberrations missed by OGM and analyze the contributing factors. OGM was performed by taking both GRCh37 and GRCh38 as reference genomes. The OGM results were analyzed in blinded fashion and compared to standard assays. Quality control (QC) metrics, sample types, reference genome, effective coverage and classes and locations of aberrations were then analyzed. In total, 154 clinically reported variations from 123 samples were investigated. OGM failed to detect 10 (6.5%, 10/154) aberrations with GRCh37 assembly, including five copy number variations (CNVs), two submicroscopic balanced translocations, two pericentric inversion and one isochromosome (mosaicism). All the samples passed pre-analytical and analytical QC. With GRCh38 assembly, the false-negative rate of OGM fell to 4.5% (7/154). The breakpoints of the CNVs, balanced translocations and inversions undetected by OGM were located in segmental duplication (SD) regions or regions with no DLE-1 label. In conclusion, besides variations with centromeric breakpoints, structural variations (SVs) with breakpoints located in large repetitive sequences may also be missed by OGM. GRCh38 is recommended as the reference genome when OGM is performed. Our results highlight the necessity of fully understanding the detection range and limitation of OGM in clinical practice. [ABSTRACT FROM AUTHOR]

Published

2024

39. Optical genome mapping reveals balanced and unbalanced genetic changes associated with tumor‐forming potential in an early‐stage prostate cancer epithelial subline (M2205).

Author

Paulraj, Prabakaran, Barrie, Elizabeth, and Jackson‐Cook, Colleen

Subjects

*GENE mapping, *PROSTATE cancer, *BLACK men, *CYTOGENETICS, *PROGNOSIS, *DISEASE management

Abstract

Background: Identifying cytogenetic changes in tumors can aid in diagnosis/prognosis and disease management. Complete cytogenetic characterization has historically required a multimethod/time‐consuming approach. Optical genome mapping (OGM) offers a potential solution to this challenge by detecting both balanced and unbalanced abnormalities in a single assay. Methods: Genetic changes acquired with tumor‐forming potential in a prostate xenograft subline [M2205] (derived from a Black male) that were detected using cytogenetic versus OGM analyses were compared to assess the utility of OGM for analyzing solid tumors. Results: Cytogenetic/OGM concordance was noted for (a) copy number gains (16, 1p, 3q, 5q, 7p, 8q, 9q, 11p, 11q, 15q, 20q), (b) copy number losses (Y, 3p, 4p, 6p, 7p, 9p, 11q), and (c) structural changes, including multibreak rearrangements. Discordance was noted for two structural findings, both of which had breakpoints localized to repetitive sequences. The OGM studies identified new findings and confirmed/further characterized 8q24 structural abnormalities. It also detected genes gained/disrupted in the 8q24 region (e.g., MYC, DEPTOR, and EXT1); but recognizing a jumping translocation required cytogenetic analyses. Conclusion: These results support using OGM as a tool to analyze solid tumors in clinical/research settings. Moreover, this OGM analysis expanded the characterization of cytogenetic changes present in the M2205 subline, including alterations associated with tumors from Black males diagnosed with prostate cancer. [ABSTRACT FROM AUTHOR]

Published

2024

40. Feasibility of Optical Genome Mapping from Placental and Umbilical Cord Sampled after Spontaneous or Therapeutic Pregnancy Termination.

Author

Goumy, Carole, Ouedraogo, Zangbéwendé Guy, Bellemonte, Elodie, Eymard-Pierre, Eleonore, Soler, Gwendoline, Perthus, Isabelle, Pebrel-Richard, Céline, Gouas, Laetitia, Salaun, Gaëlle, Véronèse, Lauren, Laurichesse, Hélène, Darcha, Claude, and Tchirkov, Andrei

Subjects

*UMBILICAL cord, *GENE mapping, *ABORTION, *DNA analysis, *CHORIONIC villi

Abstract

Optical genome mapping (OGM) is an alternative to classical cytogenetic techniques to improve the detection rate of clinically significant genomic abnormalities. The isolation of high-molecular-weight (HMW) DNA is critical for a successful OGM analysis. HMW DNA quality depends on tissue type, sample size, and storage conditions. We assessed the feasibility of OGM analysis of DNA from nine umbilical cord (UC) and six chorionic villus (CV) samples collected after the spontaneous or therapeutic termination of pregnancy. We analyzed quality control metrics provided by the Saphyr system (Bionano Genomics) and assessed the length of extracted DNA molecules using pulsed-field capillary electrophoresis. OMG data were successfully analyzed for all six CV samples. Five of the UC samples did not meet the Saphyr quality criteria, mainly due to poor DNA quality. In this regard, we found that DNA quality assessment with pulsed-field capillary electrophoresis can predict a successful OGM analysis. OGM data were fully concordant with the results of standard cytogenetic methods. Moreover, OGM detected an average of 14 additional structural variants involving OMIM genes per sample. On the basis of our results, we established the optimal conditions for sample storage and preparation required for a successful OGM analysis. We recommend checking DNA quality before analysis with pulsed-field capillary electrophoresis if the storage conditions were not ideal or if the quality of the sample is poor. OGM can therefore be performed on fetal tissue harvested after the termination of pregnancy, which opens up the perspective for improved diagnostic yield. [ABSTRACT FROM AUTHOR]

Published

2023

41. Optical Genome Mapping as a Tool to Unveil New Molecular Findings in Hematological Patients with Complex Chromosomal Rearrangements.

Author

Coccaro, Nicoletta, Zagaria, Antonella, Anelli, Luisa, Tarantini, Francesco, Tota, Giuseppina, Conserva, Maria Rosa, Cumbo, Cosimo, Parciante, Elisa, Redavid, Immacolata, Ingravallo, Giuseppe, Minervini, Crescenzio Francesco, Minervini, Angela, Specchia, Giorgina, Musto, Pellegrino, and Albano, Francesco

Subjects

*CHROMOSOMAL rearrangement, *GENE mapping, *CYTOGENETICS, *FLUORESCENCE in situ hybridization, *ACUTE myeloid leukemia, *BLOOD diseases

Abstract

Standard cytogenetic techniques (chromosomal banding analysis—CBA, and fluorescence in situ hybridization—FISH) show limits in characterizing complex chromosomal rearrangements and structural variants arising from two or more chromosomal breaks. In this study, we applied optical genome mapping (OGM) to fully characterize two cases of complex chromosomal rearrangements at high resolution. In case 1, an acute myeloid leukemia (AML) patient showing chromothripsis, OGM analysis was fully concordant with classic cytogenetic techniques and helped to better refine chromosomal breakpoints. The OGM results of case 2, a patient with non-Hodgkin lymphoma, were only partially in agreement with previous cytogenetic analyses and helped to better define clonal heterogeneity, overcoming the bias related to clonal selection due to cell culture of cytogenetic techniques. In both cases, OGM analysis led to the identification of molecular markers, helping to define the pathogenesis, classification, and prognosis of the analyzed patients. Despite extensive efforts to study hematologic diseases, standard cytogenetic methods display unsurmountable limits, while OGM is a tool that has the power to overcome these limitations and provide a cytogenetic analysis at higher resolution. As OGM also shows limits in defining regions of a repetitive nature, combining OGM with CBA to obtain a complete cytogenetic characterization would be desirable. [ABSTRACT FROM AUTHOR]

Published

2023

42. Evaluation of Optical Genome Mapping in Clinical Genetic Testing of Facioscapulohumeral Muscular Dystrophy.

Author

Kovanda, Anja, Lovrečić, Luca, Rudolf, Gorazd, Babic Bozovic, Ivana, Jaklič, Helena, Leonardis, Lea, and Peterlin, Borut

Subjects

*FACIOSCAPULOHUMERAL muscular dystrophy, *GENETIC testing, *GENE mapping, *SOUTHERN blot, *SINGLE nucleotide polymorphisms, *DNA copy number variations, *EXOMES

Abstract

Facioscapulohumeral muscular dystrophy (FSHD) is the third most common hereditary muscular dystrophy, caused by the contraction of the D4Z4 repeats on the permissive 4qA haplotype on chromosome 4, resulting in the faulty expression of the DUX4 gene. Traditional diagnostics are based on Southern blotting, a time- and effort-intensive method that can be affected by single nucleotide variants (SNV) and copy number variants (CNV), as well as by the similarity of the D4Z4 repeats located on chromosome 10. We aimed to evaluate optical genome mapping (OGM) as an alternative molecular diagnostic method for the detection of FSHD. We first performed optical genome mapping with EnFocus™ FSHD analysis using DLE-1 labeling and the Saphyr instrument in patients with inconclusive diagnostic Southern blot results, negative FSHD2 results, and clinically evident FSHD. Second, we performed OGM in parallel with the classical Southern blot analysis for our prospectively collected new FSHD cases. Finally, panel exome sequencing was performed to confirm the presence of FSHD2. In two patients with diagnostically inconclusive Southern blot results, OGM was able to identify shortened D4Z4 repeats on the permissive 4qA alleles, consistent with the clinical presentation. The results of the prospectively collected patients tested in parallel using Southern blotting and OGM showed full concordance, indicating that OGM is a useful alternative to the classical Southern blotting method for detecting FSHD1. In a patient showing clinical FSHD but no shortened D4Z4 repeats in the 4qA allele using OGM or Southern blotting, a likely pathogenic variant in SMCHD1 was detected using exome sequencing, confirming FSHD2. OGM and panel exome sequencing can be used consecutively to detect FSHD2. [ABSTRACT FROM AUTHOR]

Published

2023

43. Experimental and Computational Approaches to Measure Telomere Length: Recent Advances and Future Directions.

Author

Ferrer, Alejandro, Stephens, Zachary D., and Kocher, Jean-Pierre A.

Abstract

Purpose of Review: The length of telomeres, protective structures at the chromosome ends, is a well-established biomarker for pathological conditions including multisystemic syndromes called telomere biology disorders. Approaches to measure telomere length (TL) differ on whether they estimate average, distribution, or chromosome-specific TL, and each presents their own advantages and limitations. Recent Findings: The development of long-read sequencing and publication of the telomere-to-telomere human genome reference has allowed for scalable and high-resolution TL estimation in pre-existing sequencing datasets but is still impractical as a dedicated TL test. As sequencing costs continue to fall and strategies for selectively enriching telomere regions prior to sequencing improve, these approaches may become a promising alternative to classic methods. Summary: Measurement methods rely on probe hybridization, qPCR or more recently, computational methods using sequencing data. Refinements of existing techniques and new approaches have been recently developed but a test that is accurate, simple, and scalable is still lacking. [ABSTRACT FROM AUTHOR]

Published

2023

44. The clinical value of optical genome mapping in the rapid characterization of RB1 duplication and 15q23q24.2 triplication, for more appropriate prenatal genetic counselling

Author

Malek Bouassida, Denise Molina‐Gomes, Fairouz Koraichi, Bérénice Hervé, Morgane Lhuilier, Clémence Duvillier, Jessica Le Gall, Marion Gauthier‐Villars, Valérie Serazin, Thibaud Quibel, Rodolphe Dard, and François Vialard

Subjects

15q23q24.2 triplication, optical genome mapping, prenatal diagnosis, RB1 gene, Genetics, QH426-470

Abstract

Abstract Background Despite recent advances in prenatal genetic diagnosis, medical geneticists still face considerable difficulty in interpreting the clinical outcome of copy‐number‐variant duplications and defining the mechanisms underlying the formation of certain chromosomal rearrangements. Optical genome mapping (OGM) is an emerging cytogenomic tool with proved ability to identify the full spectrum of cytogenetic aberrations. Methods Here, we report on the use of OGM in a prenatal diagnosis setting. Detailed breakpoint mapping was used to determine the relative orientations of triplicated and duplicated segments in two unrelated foetuses harbouring chromosomal aberrations: a de novo 15q23q24.2 triplication and a paternally inherited 13q14.2 duplication that overlapped partially with the RB1 gene. Results OGM enabled us to suggest a plausible mechanism for the triplication and confirmed that the RB1 duplication was direct oriented and in tandem. This enabled us to predict the pathogenic consequences, refine the prognosis and adapt the follow‐up and familial screening appropriately. Conclusion Along with an increase in diagnostic rates, OGM can rapidly highlight genotype–phenotype correlations, improve genetic counselling and significantly influence prenatal management.

Published

2024

45. Clinical Utility of Optical Genome Mapping for Improved Cytogenomic Analysis of Gliomas

Author

Harmanpreet Singh, Nikhil S. Sahajpal, Ashis K. Mondal, Stephanie L. Burke, Jaspreet Farmaha, Ahmet Alptekin, Ashutosh Vashisht, Kimya Jones, Vishakha Vashisht, and Ravindra Kolhe

Subjects

optical genome mapping, structural variants, solid tumor, glioma, chromosomal microarray, Biology (General), QH301-705.5

Abstract

A glioma is a solid brain tumor which originates in the brain or brain stem area. The diagnosis of gliomas based on standard-of-care (SOC) techniques includes karyotyping, fluorescence in situ hybridization (FISH), and chromosomal microarray (CMA), for detecting the pathogenic variants and chromosomal abnormalities. But these techniques do not reveal the complete picture of genetic complexity, thus requiring an alternative technology for better characterization of these tumors. The present study aimed to evaluate the clinical performance and feasibility of using optical genome mapping (OGM) for chromosomal characterization of gliomas. Herein, we evaluated 10 cases of gliomas that were previously characterized by CMA. OGM analysis showed concordance with the results of CMA in identifying the characterized Structural Variants (SVs) in these cases. More notably, it also revealed additional clinically relevant aberrations, demonstrating a higher resolution and sensitivity. These clinically relevant SVs included cryptic translocation, and SVs which are beyond the detection capabilities of CMA. Our analysis highlights the unique capability of OGM to detect all classes of SVs within a single assay, thereby unveiling clinically significant data with a shorter turnaround time. Adopting this diagnostic tool as a standard of care for solid tumors like gliomas shows potential for improving therapeutic management, potentially leading to more personalized and timely interventions for patients.

Published

2024

46. A Case of CDKL5 Deficiency Due to an X Chromosome Pericentric Inversion: Delineation of Structural Rearrangements as an Overlooked Recurrent Pathological Mechanism

Author

Antonietta Lombardo, Lorenzo Sinibaldi, Silvia Genovese, Giorgia Catino, Valerio Mei, Daniele Pompili, Ester Sallicandro, Roberto Falasca, Maria Teresa Liambo, Maria Vittoria Faggiano, Maria Cristina Roberti, Maddalena Di Donato, Anna Vitelli, Serena Russo, Rosalinda Giannini, Alessia Micalizzi, Nicola Pietrafusa, Maria Cristina Digilio, Antonio Novelli, Lucia Fusco, and Viola Alesi

Subjects

CDKL5 deficiency disorder (CDD), structural rearrangements, Xp22.13, CDKL5, epileptic encephalopathy, optical genome mapping, Biology (General), QH301-705.5, Chemistry, QD1-999

Abstract

CDKL5 deficiency disorder (CDD) is an X-linked dominant epileptic encephalopathy, characterized by early-onset and drug-resistant seizures, psychomotor delay, and slight facial features. Genomic variants inactivating CDKL5 or impairing its protein product kinase activity have been reported, making next-generation sequencing (NGS) and chromosomal microarray analysis (CMA) the standard diagnostic tests. We report a suspicious case of CDD in a female child who tested negative upon NGS and CMA and harbored an X chromosome de novo pericentric inversion. The use of recently developed genomic techniques (optical genome mapping and whole-genome sequencing) allowed us to finely characterize the breakpoints, with one of them interrupting CDKL5 at intron 1. This is the fifth case of CDD reported in the scientific literature harboring a structural rearrangement on the X chromosome, providing evidence for the hypothesis that this type of anomaly can represent a recurrent pathogenic mechanism, whose frequency is likely underestimated, with it being overlooked by standard techniques. The identification of the molecular etiology of the disorder is extremely important in evaluating the pathological outcome and to better investigate the mechanisms associated with drug resistance, paving the way for the development of specific therapies. Karyotype and genomic techniques should be considered in all cases presenting with CDD without molecular confirmation.

Published

2024

47. Analysis of genomic copy number variations in human hepatocellular carcinoma cell lines HepG2 and Huh7

Author

JI Mengdie, YUAN Zan, BIAN Xiaocui, YANG Yurong, GUO Xin, WANG Qi, CHEN Yang

Subjects

hepatocellular carcinoma, copy number variation, optical genome mapping, gene expression, Medicine

Abstract

Objective To explore the effect of copy number variation on the occurrence and development of hepatocellular carcinoma by using copy number variation and transcriptome experiment of hepatocellular carcinoma combined with public clinical data. Methods The copy number variation found in hepatoma cell lines HepG2 and Huh7 was identified by optical genome mapping. The function of the copy number variant genes in the two cell lines was analyzed, and the protein interaction network was mapped according to the enrichment pathway. Key genes in the core network of two cell lines were selected to analyze the relationship between copy number variation and gene expression in hepatocellular carcinoma. The relationship between gene expression and clinical survival was analyzed by GEPIA database. RNA-seq assay and public data were used to verify gene expression levels. Results HepG2 cells mainly showed increased copy number, and related genes were enriched in estrogen signaling pathway and Staphylococcus aureus infection pathway. Huh7 cells showed both increased and decreased copy number, and related genes mainly concentrated in olfactory conduction and cytokine-cytokine receptor interaction pathways. The copy number of key genes SRC, MAPK3 and MAP3K7 was proportional to gene expression, and survival was significantly reduced in patients with high expression of these genes (P＜0.05). Compared with HEK293T cell line, the expression of SRC and MAP3K7 genes in the two hepatocellular carcinoma lines was significantly increased(P＜0.001), suggesting the specific variation of hepatocellular carcinoma. MAPK3 had no difference. Conclusions The expression of copy number variant genes SRC and MAP3K7 in hepatocellular carcinoma is significantly correlated with the prognosis of patients, and may significantly affect the development and heterogeneity of hepatocellular carcinoma.

Published

2023

48. A novel FAME1 repeat configuration in a European family identified using a combined genomics approach

Author

Tatiana Maroilley, Meng‐Han Tsai, Rumika Mascarenhas, Catherine Diao, Maryam Khanbabaei, Sabine Kaya, Christel Depienne, Maja Tarailo‐Graovac, and Karl Martin Klein

Subjects

FAME, long‐read sequencing, optical genome mapping, repeat expansion, SAMD12, short‐read sequencing, Neurology. Diseases of the nervous system, RC346-429

Abstract

Abstract Familial adult myoclonic epilepsy (FAME) is an adult‐onset neurological disease characterized by cortical tremor, myoclonus, and seizures due to a pentanucleotide repeat expansion: a combination of pathogenic TTTCA expansion associated with a TTTTA repeat in introns of six different genes. Repeat‐primed PCR (RP‐PCR) is an inexpensive test for expansions at known loci. The analysis of the SAMD12 locus revealed that the repeats have different size, configuration, and composition. The TTTCA repeats can be very long (>1000 repeats) but also very short (14 being the shortest identified). Here, we report siblings of European descent with the clinical diagnosis of FAME yet a negative RP‐PCR test. Using short‐read genome sequencing, we identified the pentanucleotide expansion in intron 4 of SAMD12, which was confirmed by CRIPSR‐Cas9‐mediated enrichment and long‐read sequencing to be of (TTTTA)~879(TTTCA)3(TTTTA)7(TTTCA)7 configuration. Our finding is the first to associate the SAMD12 locus in European patients with FAME and currently represents the shortest identified TTTCA expansion. Our results suggest that the SAMD12 locus should be tested in patients with suspected FAME independent of ethnicity. Furthermore, RP‐PCR may miss the underlying mutation, and genome sequencing may be needed to confirm the pathogenic repeat.

Published

2023

49. A combination of long- and short-read genomics reveals frequent p-arm breakpoints within chromosome 21 complex genomic rearrangements

Author

Jakob Schuy, Kristine Bilgrav Sæther, Jasmin Lisfeld, Marlene Ek, Christopher M. Grochowski, Ming Yin Lun, Alex Hastie, Susanne Rudolph, Sigrid Fuchs, Kornelia Neveling, Maja Hempel, Alexander Hoischen, Maria Pettersson, Claudia M.B. Carvalho, Jesper Eisfeldt, and Anna Lindstrand

Subjects

Chromosome 21, Complex genomic rearrangement, Down syndrome critical region, Long-read genome sequencing, Optical genome mapping, Genetics, QH426-470, Medicine

Abstract

Purpose: Although chromosome 21 is the smallest human chromosome, it is highly relevant in the pathogenicity of both cancer and congenital diseases, including Alzheimer disease and trisomy 21 (Down syndrome). In addition, cases with rare structural variants (SVs) of chromosome 21 have been reported. These events vary in size and include large chromosomal events, such as ring chromosomes and small partial aneuploidies. The p-arm of the acrocentric chromosome 21 was devoid of reference genomic sequence in GRCh37 and GRCh38, which hampered our ability to solve genomic rearrangements and find the mechanism of formation of disease-causing SVs. We hypothesize that conserved satellite structures and segmental duplications located on the p-arm play an important role in the formation of complex SVs involving chromosome 21. Methods: Three cases with complex chromosome 21 rearrangements were studied with a combination of short-read and long-read genome sequencing, as well as optical genome mapping. The data were aligned to the T2T-CHM13 assembly. Results: We were able to resolve all 3 complex chromosome 21 rearrangements in which 15, 8, and 26 breakpoints were identified, respectively. By comparing the identified SV breakpoints, we were able to pinpoint a region between 21p13 and 21p12 that appears to be frequently involved in chromosome 21 rearrangements. Importantly, we observed acrocentric satellite DNA at several breakpoint junctions suggesting an important role for those elements in the formation of complex SVs. Conclusion: Taken together, our results provide further insights into the architecture and underlying mechanisms of complex rearrangements on acrocentric chromosomes.

Published

2024

50. Optical Genome Mapping for the Molecular Diagnosis of Facioscapulohumeral Muscular Dystrophy: Advancement and Challenges.

Author

Efthymiou, Stephanie, Lemmers, Richard J. L. F., Vishnu, Venugopalan Y., Dominik, Natalia, Perrone, Benedetta, Facchini, Stefano, Vegezzi, Elisa, Ravaglia, Sabrina, Wilson, Lindsay, van der Vliet, Patrick J., Mishra, Rinkle, Reyaz, Alisha, Ahmad, Tanveer, Bhatia, Rohit, Polke, James M., Srivastava, Mv Padma, Cortese, Andrea, Houlden, Henry, van der Maarel, Silvère M., and Hanna, Michael G.

Subjects

*FACIOSCAPULOHUMERAL muscular dystrophy, *GENE mapping, *MOLECULAR diagnosis, *PULSED-field gel electrophoresis, *SOUTHERN blot, *MUSCULAR dystrophy

Abstract

Facioscapulohumeral muscular dystrophy (FSHD) is the second most common muscular dystrophy in adults, and it is associated with local D4Z4 chromatin relaxation, mostly via the contraction of the D4Z4 macrosatellite repeat array on chromosome 4q35. In this study, we aimed to investigate the use of Optical Genome Mapping (OGM) as a diagnostic tool for testing FSHD cases from the UK and India and to compare OGM performance with that of traditional techniques such as linear gel (LGE) and Pulsed-field gel electrophoresis (PFGE) Southern blotting (SB). A total of 6 confirmed and 19 suspected FSHD samples were processed with LGE and PFGE, respectively. The same samples were run using a Saphyr Genome-Imaging Instrument (1-color), and the data were analysed using custom EnFocus FSHD analysis. OGM was able to confirm the diagnosis of FSHD1 in all FSHD1 cases positive for SB (n = 17), and D4Z4 sizing highly correlated with PFGE-SB (p < 0.001). OGM correctly identified cases with mosaicism for the repeat array contraction (n = 2) and with a duplication of the D4Z4 repeat array. OGM is a promising new technology able to unravel structural variants in the genome and seems to be a valid tool for diagnosing FSHD1. [ABSTRACT FROM AUTHOR]

Published

2023