Targeted Next-Generation Sequencing Analysis of 1,000 Individuals with Intellectual Disability.

Detelina Grozeva; Keren Carss; Olivera Spasic-Boskovic; Maria-Isabel Tejada; Jozef Gecz; Marie Shaw; Mark Corbett; Eric Haan; Elizabeth Thompson; Kathryn Friend; Zaamin Hussain; Anna Hackett; Michael Field; Alessandra Renieri; Roger Stevenson; Charles Schwartz; James A B Floyd; Jamie Bentham; Catherine Cosgrove; Bernard Keavney; Shoumo Bhattacharya; Matthew Hurles; F Lucy Raymond

doi:10.1002/humu.22901

Targeted Next-Generation Sequencing Analysis of 1,000 Individuals with Intellectual Disability.

Detelina Grozeva, Keren Carss, Olivera Spasic-Boskovic, Maria-Isabel Tejada, Jozef Gecz, Marie Shaw, Mark Corbett, Eric Haan, Elizabeth Thompson, Kathryn Friend, Zaamin Hussain, Anna Hackett, Michael Field, Alessandra Renieri, Roger Stevenson, Charles Schwartz, James A B Floyd, Jamie Bentham, Catherine Cosgrove, Bernard KeavneyShoumo Bhattacharya, Matthew Hurles, F Lucy Raymond

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

Abstract

To identify genetic causes of intellectual disability (ID), we screened a cohort of 986 individuals with moderate to severe ID for variants in 565 known or candidate ID-associated genes using targeted next-generation sequencing. Likely pathogenic rare variants were found in ∼11% of the cases (113 variants in 107/986 individuals: ∼8% of the individuals had a likely pathogenic loss-of-function [LoF] variant, whereas ∼3% had a known pathogenic missense variant). Variants in SETD5, ATRX, CUL4B, MECP2, and ARID1B were the most common causes of ID. This study assessed the value of sequencing a cohort of probands to provide a molecular diagnosis of ID, without the availability of DNA from both parents for de novo sequence analysis. This modeling is clinically relevant as 28% of all UK families with dependent children are single parent households. In conclusion, to diagnose patients with ID in the absence of parental DNA, we recommend investigation of all LoF variants in known genes that cause ID and assessment of a limited list of proven pathogenic missense variants in these genes. This will provide 11% additional diagnostic yield beyond the 10%-15% yield from array CGH alone.

Original language	English
Journal	Human Mutation
Volume	36
Issue number	12
DOIs	https://doi.org/10.1002/humu.22901
Publication status	Published - Dec 2015

Keywords

Mendelian disease
developmental delay
intellectual disability
next-generation sequencing

Access to Document

10.1002/humu.22901

Cite this

Grozeva, D., Carss, K., Spasic-Boskovic, O., Tejada, M.-I., Gecz, J., Shaw, M., Corbett, M., Haan, E., Thompson, E., Friend, K., Hussain, Z., Hackett, A., Field, M., Renieri, A., Stevenson, R., Schwartz, C., Floyd, J. A. B., Bentham, J., Cosgrove, C., ... Raymond, F. L. (2015). Targeted Next-Generation Sequencing Analysis of 1,000 Individuals with Intellectual Disability. Human Mutation, 36(12). https://doi.org/10.1002/humu.22901

@article{78033b1bc6614477b087218ed93e80a0,

title = "Targeted Next-Generation Sequencing Analysis of 1,000 Individuals with Intellectual Disability.",

abstract = "To identify genetic causes of intellectual disability (ID), we screened a cohort of 986 individuals with moderate to severe ID for variants in 565 known or candidate ID-associated genes using targeted next-generation sequencing. Likely pathogenic rare variants were found in ∼11% of the cases (113 variants in 107/986 individuals: ∼8% of the individuals had a likely pathogenic loss-of-function [LoF] variant, whereas ∼3% had a known pathogenic missense variant). Variants in SETD5, ATRX, CUL4B, MECP2, and ARID1B were the most common causes of ID. This study assessed the value of sequencing a cohort of probands to provide a molecular diagnosis of ID, without the availability of DNA from both parents for de novo sequence analysis. This modeling is clinically relevant as 28% of all UK families with dependent children are single parent households. In conclusion, to diagnose patients with ID in the absence of parental DNA, we recommend investigation of all LoF variants in known genes that cause ID and assessment of a limited list of proven pathogenic missense variants in these genes. This will provide 11% additional diagnostic yield beyond the 10%-15% yield from array CGH alone.",

keywords = "Mendelian disease, developmental delay, intellectual disability, next-generation sequencing",

author = "Detelina Grozeva and Keren Carss and Olivera Spasic-Boskovic and Maria-Isabel Tejada and Jozef Gecz and Marie Shaw and Mark Corbett and Eric Haan and Elizabeth Thompson and Kathryn Friend and Zaamin Hussain and Anna Hackett and Michael Field and Alessandra Renieri and Roger Stevenson and Charles Schwartz and Floyd, {James A B} and Jamie Bentham and Catherine Cosgrove and Bernard Keavney and Shoumo Bhattacharya and Matthew Hurles and Raymond, {F Lucy}",

year = "2015",

month = dec,

doi = "10.1002/humu.22901",

language = "English",

volume = "36",

journal = "Human Mutation",

issn = "1059-7794",

publisher = "John Wiley & Sons Ltd",

number = "12",

}

Grozeva, D, Carss, K, Spasic-Boskovic, O, Tejada, M-I, Gecz, J, Shaw, M, Corbett, M, Haan, E, Thompson, E, Friend, K, Hussain, Z, Hackett, A, Field, M, Renieri, A, Stevenson, R, Schwartz, C, Floyd, JAB, Bentham, J, Cosgrove, C, Keavney, B, Bhattacharya, S, Hurles, M & Raymond, FL 2015, 'Targeted Next-Generation Sequencing Analysis of 1,000 Individuals with Intellectual Disability.', Human Mutation, vol. 36, no. 12. https://doi.org/10.1002/humu.22901

TY - JOUR

T1 - Targeted Next-Generation Sequencing Analysis of 1,000 Individuals with Intellectual Disability.

AU - Grozeva, Detelina

AU - Carss, Keren

AU - Spasic-Boskovic, Olivera

AU - Tejada, Maria-Isabel

AU - Gecz, Jozef

AU - Shaw, Marie

AU - Corbett, Mark

AU - Haan, Eric

AU - Thompson, Elizabeth

AU - Friend, Kathryn

AU - Hussain, Zaamin

AU - Hackett, Anna

AU - Field, Michael

AU - Renieri, Alessandra

AU - Stevenson, Roger

AU - Schwartz, Charles

AU - Floyd, James A B

AU - Bentham, Jamie

AU - Cosgrove, Catherine

AU - Keavney, Bernard

AU - Bhattacharya, Shoumo

AU - Hurles, Matthew

AU - Raymond, F Lucy

PY - 2015/12

Y1 - 2015/12

N2 - To identify genetic causes of intellectual disability (ID), we screened a cohort of 986 individuals with moderate to severe ID for variants in 565 known or candidate ID-associated genes using targeted next-generation sequencing. Likely pathogenic rare variants were found in ∼11% of the cases (113 variants in 107/986 individuals: ∼8% of the individuals had a likely pathogenic loss-of-function [LoF] variant, whereas ∼3% had a known pathogenic missense variant). Variants in SETD5, ATRX, CUL4B, MECP2, and ARID1B were the most common causes of ID. This study assessed the value of sequencing a cohort of probands to provide a molecular diagnosis of ID, without the availability of DNA from both parents for de novo sequence analysis. This modeling is clinically relevant as 28% of all UK families with dependent children are single parent households. In conclusion, to diagnose patients with ID in the absence of parental DNA, we recommend investigation of all LoF variants in known genes that cause ID and assessment of a limited list of proven pathogenic missense variants in these genes. This will provide 11% additional diagnostic yield beyond the 10%-15% yield from array CGH alone.

AB - To identify genetic causes of intellectual disability (ID), we screened a cohort of 986 individuals with moderate to severe ID for variants in 565 known or candidate ID-associated genes using targeted next-generation sequencing. Likely pathogenic rare variants were found in ∼11% of the cases (113 variants in 107/986 individuals: ∼8% of the individuals had a likely pathogenic loss-of-function [LoF] variant, whereas ∼3% had a known pathogenic missense variant). Variants in SETD5, ATRX, CUL4B, MECP2, and ARID1B were the most common causes of ID. This study assessed the value of sequencing a cohort of probands to provide a molecular diagnosis of ID, without the availability of DNA from both parents for de novo sequence analysis. This modeling is clinically relevant as 28% of all UK families with dependent children are single parent households. In conclusion, to diagnose patients with ID in the absence of parental DNA, we recommend investigation of all LoF variants in known genes that cause ID and assessment of a limited list of proven pathogenic missense variants in these genes. This will provide 11% additional diagnostic yield beyond the 10%-15% yield from array CGH alone.

KW - Mendelian disease

KW - developmental delay

KW - intellectual disability

KW - next-generation sequencing

U2 - 10.1002/humu.22901

DO - 10.1002/humu.22901

M3 - Article

C2 - 26350204

SN - 1059-7794

VL - 36

JO - Human Mutation

JF - Human Mutation

IS - 12

ER -

Targeted Next-Generation Sequencing Analysis of 1,000 Individuals with Intellectual Disability.

Abstract

Keywords

Access to Document

Fingerprint

Cite this