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

Undiagnosed Diseases Network

doi:10.1002/mgg3.1665

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

Undiagnosed Diseases Network

Research output: Contribution to journal › Article › peer-review

Abstract

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

Original language	English (US)
Article number	e1665
Journal	Molecular Genetics and Genomic Medicine
Volume	9
Issue number	7
DOIs	https://doi.org/10.1002/mgg3.1665
State	Published - Jul 2021

Keywords

copy number variants
epilepsy
mosaicism
optical genome mapping
structural variants

ASJC Scopus subject areas

Molecular Biology
Genetics
Genetics(clinical)

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10.1002/mgg3.1665

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@article{82d8f17379024c94b67856cd18863670,

title = "Detection of a mosaic CDKL5 deletion and inversion by optical genome mapping ends an exhaustive diagnostic odyssey",

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

keywords = "copy number variants, epilepsy, mosaicism, optical genome mapping, structural variants",

author = "{Undiagnosed Diseases Network} and Heidi Cope and Hayk Barseghyan and Surajit Bhattacharya and Yulong Fu and Nicole Hoppman and Cherisse Marcou and Nicole Walley and Catherine Rehder and Kristen Deak and Anna Alkelai and Eric Vilain and Vandana Shashi and Acosta, {Maria T.} and Margaret Adam and Adams, {David R.} and Agrawal, {Pankaj B.} and Alejandro, {Mercedes E.} and Justin Alvey and Laura Amendola and Ashley Andrews and Ashley, {Euan A.} and Azamian, {Mahshid S.} and Bacino, {Carlos A.} and Guney Bademci and Eva Baker and Ashok Balasubramanyam and Dustin Baldridge and Jim Bale and Michael Bamshad and Deborah Barbouth and Pinar Bayrak-Toydemir and Anita Beck and Beggs, {Alan H.} and Edward Behrens and Gill Bejerano and Jimmy Bennet and Beverly Berg-Rood and Bernstein, {Jonathan A.} and Berry, {Gerard T.} and Anna Bican and Stephanie Bivona and Elizabeth Blue and John Bohnsack and Carsten Bonnenmann and Devon Bonner and Surendra Dasari and Lanpher, {Brendan C.} and Lanza, {Ian R.} and Eva Morava and Devin Oglesbee",

note = "Publisher Copyright: {\textcopyright} 2021 The Authors. Molecular Genetics & Genomic Medicine published by Wiley Periodicals LLC.",

year = "2021",

month = jul,

doi = "10.1002/mgg3.1665",

language = "English (US)",

volume = "9",

journal = "Molecular Genetics and Genomic Medicine",

issn = "2324-9269",

publisher = "John Wiley and Sons Inc.",

number = "7",

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TY - JOUR

T1 - Detection of a mosaic CDKL5 deletion and inversion by optical genome mapping ends an exhaustive diagnostic odyssey

AU - Undiagnosed Diseases Network

AU - Cope, Heidi

AU - Barseghyan, Hayk

AU - Bhattacharya, Surajit

AU - Fu, Yulong

AU - Hoppman, Nicole

AU - Marcou, Cherisse

AU - Walley, Nicole

AU - Rehder, Catherine

AU - Deak, Kristen

AU - Alkelai, Anna

AU - Vilain, Eric

AU - Shashi, Vandana

AU - Acosta, Maria T.

AU - Adam, Margaret

AU - Adams, David R.

AU - Agrawal, Pankaj B.

AU - Alejandro, Mercedes E.

AU - Alvey, Justin

AU - Amendola, Laura

AU - Andrews, Ashley

AU - Ashley, Euan A.

AU - Azamian, Mahshid S.

AU - Bacino, Carlos A.

AU - Bademci, Guney

AU - Baker, Eva

AU - Balasubramanyam, Ashok

AU - Baldridge, Dustin

AU - Bale, Jim

AU - Bamshad, Michael

AU - Barbouth, Deborah

AU - Bayrak-Toydemir, Pinar

AU - Beck, Anita

AU - Beggs, Alan H.

AU - Behrens, Edward

AU - Bejerano, Gill

AU - Bennet, Jimmy

AU - Berg-Rood, Beverly

AU - Bernstein, Jonathan A.

AU - Berry, Gerard T.

AU - Bican, Anna

AU - Bivona, Stephanie

AU - Blue, Elizabeth

AU - Bohnsack, John

AU - Bonnenmann, Carsten

AU - Bonner, Devon

AU - Dasari, Surendra

AU - Lanpher, Brendan C.

AU - Lanza, Ian R.

AU - Morava, Eva

AU - Oglesbee, Devin

PY - 2021/7

Y1 - 2021/7

N2 - Background: Currently available structural variant (SV) detection methods do not span the complete spectrum of disease-causing SVs. Optical genome mapping (OGM), an emerging technology with the potential to resolve diagnostic dilemmas, was performed to investigate clinically-relevant SVs in a 4-year-old male with an epileptic encephalopathy of undiagnosed molecular origin. Methods: OGM was utilized to image long, megabase-size DNA molecules, fluorescently labeled at specific sequence motifs throughout the genome with high sensitivity for detection of SVs greater than 500 bp in size. OGM results were confirmed in a CLIA-certified laboratory via mate-pair sequencing. Results: OGM identified a mosaic, de novo 90 kb deletion and inversion on the X chromosome disrupting the CDKL5 gene. Detection of the mosaic deletion, which had been previously undetected by chromosomal microarray, an infantile epilepsy panel including exon-level microarray for CDKL5, exome sequencing as well as genome sequencing, resulted in a diagnosis of X-linked dominant early infantile epileptic encephalopathy-2. Conclusion: OGM affords an effective technology for the detection of SVs, especially those that are mosaic, since these remain difficult to detect with current NGS technologies and with conventional chromosomal microarrays. Further research in undiagnosed populations with OGM is warranted.

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

KW - copy number variants

KW - epilepsy

KW - mosaicism

KW - optical genome mapping

KW - structural variants

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U2 - 10.1002/mgg3.1665

DO - 10.1002/mgg3.1665

M3 - Article

C2 - 33955715

AN - SCOPUS:85105141512

SN - 2324-9269

VL - 9

JO - Molecular Genetics and Genomic Medicine

JF - Molecular Genetics and Genomic Medicine

IS - 7

M1 - e1665

ER -

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

Abstract

Keywords

ASJC Scopus subject areas

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