Defining the diverse spectrum of inversions, complex structural variation, and chromothripsis in the morbid human genome

Ryan L Collins; Harrison Brand; Claire E. Redin; Carrie Hanscom; Caroline Antolik; Matthew R Stone; Joseph T. Glessner; Tamara Mason; Giulia Pregno; Naghmeh Dorrani; Giorgia Mandrile; Daniela Giachino; Danielle Perrin; Cole Walsh; Michelle Cipicchio; Maura Costello; Alexei Stortchevoi; Joon Yong An; Benjamin B Currall; Catarina M Seabra; Ashok Ragavendran; Lauren Margolin; Julian A. Martinez-Agosto; Diane Lucente; Brynn Levy; Jan-Stephan Sanders; Ronald J. Wapner; Fabiola Quintero-Rivera; Wigard Kloosterman; Michael E. Talkowski

doi:10.1186/s13059-017-1158-6

Defining the diverse spectrum of inversions, complex structural variation, and chromothripsis in the morbid human genome

Ryan L Collins, Harrison Brand, Claire E. Redin, Carrie Hanscom, Caroline Antolik, Matthew R Stone, Joseph T. Glessner, Tamara Mason, Giulia Pregno, Naghmeh Dorrani, Giorgia Mandrile, Daniela Giachino, Danielle Perrin, Cole Walsh, Michelle Cipicchio, Maura Costello, Alexei Stortchevoi, Joon Yong An, Benjamin B Currall, Catarina M SeabraAshok Ragavendran, Lauren Margolin, Julian A. Martinez-Agosto, Diane Lucente, Brynn Levy, Jan-Stephan Sanders, Ronald J. Wapner, Fabiola Quintero-Rivera, Wigard Kloosterman, Michael E. Talkowski^*

^*Corresponding author for this work

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

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Abstract

Background: Structural variation (SV) influences genome organization and contributes to human disease. However, the complete mutational spectrum of SV has not been routinely captured in disease association studies. Results: We sequenced 689 participants with autism spectrum disorder (ASD) and other developmental abnormalities to construct a genome-wide map of large SV. Using long-insert jumping libraries at 105X mean physical coverage and linked-read whole-genome sequencing from 10X Genomics, we document seven major SV classes at ~5 kb SV resolution. Our results encompass 11,735 distinct large SV sites, 38.1% of which are novel and 16.8% of which are balanced or complex. We characterize 16 recurrent subclasses of complex SV (cxSV), revealing that: (1) cxSV are larger and rarer than canonical SV; (2) each genome harbors 14 large cxSV on average; (3) 84.4% of large cxSVs involve inversion; and (4) most large cxSV (93.8%) have not been delineated in previous studies. Rare SVs are more likely to disrupt coding and regulatory non-coding loci, particularly when truncating constrained and disease-associated genes. We also identify multiple cases of catastrophic chromosomal rearrangements known as chromoanagenesis, including somatic chromoanasynthesis, and extreme balanced germline chromothripsis events involving up to 65 breakpoints and 60.6 Mb across four chromosomes, further defining rare categories of extreme cxSV. Conclusions: These data provide a foundational map of large SV in the morbid human genome and demonstrate a previously underappreciated abundance and diversity of cxSV that should be considered in genomic studies of human disease.

Original language	English
Article number	36
Journal	Genome Biology
Volume	18
Issue number	1
DOIs	https://doi.org/10.1186/s13059-017-1158-6
Publication status	Published - 6 Mar 2017

Keywords

Autism
Chromoanagenesis
Chromothripsis
Complex chromosomal rearrangement
Copynumber variation
Germline mutation
Inversion
Neurodevelopmental disorders
Structural variation
Whole-genome sequencing

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Collins, R. L., Brand, H., Redin, C. E., Hanscom, C., Antolik, C., Stone, M. R., Glessner, J. T., Mason, T., Pregno, G., Dorrani, N., Mandrile, G., Giachino, D., Perrin, D., Walsh, C., Cipicchio, M., Costello, M., Stortchevoi, A., An, J. Y., Currall, B. B., ... Talkowski, M. E. (2017). Defining the diverse spectrum of inversions, complex structural variation, and chromothripsis in the morbid human genome. Genome Biology, 18(1), Article 36. https://doi.org/10.1186/s13059-017-1158-6

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title = "Defining the diverse spectrum of inversions, complex structural variation, and chromothripsis in the morbid human genome",

abstract = "Background: Structural variation (SV) influences genome organization and contributes to human disease. However, the complete mutational spectrum of SV has not been routinely captured in disease association studies. Results: We sequenced 689 participants with autism spectrum disorder (ASD) and other developmental abnormalities to construct a genome-wide map of large SV. Using long-insert jumping libraries at 105X mean physical coverage and linked-read whole-genome sequencing from 10X Genomics, we document seven major SV classes at ~5 kb SV resolution. Our results encompass 11,735 distinct large SV sites, 38.1% of which are novel and 16.8% of which are balanced or complex. We characterize 16 recurrent subclasses of complex SV (cxSV), revealing that: (1) cxSV are larger and rarer than canonical SV; (2) each genome harbors 14 large cxSV on average; (3) 84.4% of large cxSVs involve inversion; and (4) most large cxSV (93.8%) have not been delineated in previous studies. Rare SVs are more likely to disrupt coding and regulatory non-coding loci, particularly when truncating constrained and disease-associated genes. We also identify multiple cases of catastrophic chromosomal rearrangements known as chromoanagenesis, including somatic chromoanasynthesis, and extreme balanced germline chromothripsis events involving up to 65 breakpoints and 60.6 Mb across four chromosomes, further defining rare categories of extreme cxSV. Conclusions: These data provide a foundational map of large SV in the morbid human genome and demonstrate a previously underappreciated abundance and diversity of cxSV that should be considered in genomic studies of human disease.",

keywords = "Autism, Chromoanagenesis, Chromothripsis, Complex chromosomal rearrangement, Copynumber variation, Germline mutation, Inversion, Neurodevelopmental disorders, Structural variation, Whole-genome sequencing",

author = "Collins, {Ryan L} and Harrison Brand and Redin, {Claire E.} and Carrie Hanscom and Caroline Antolik and Stone, {Matthew R} and Glessner, {Joseph T.} and Tamara Mason and Giulia Pregno and Naghmeh Dorrani and Giorgia Mandrile and Daniela Giachino and Danielle Perrin and Cole Walsh and Michelle Cipicchio and Maura Costello and Alexei Stortchevoi and An, {Joon Yong} and Currall, {Benjamin B} and Seabra, {Catarina M} and Ashok Ragavendran and Lauren Margolin and Martinez-Agosto, {Julian A.} and Diane Lucente and Brynn Levy and Jan-Stephan Sanders and Wapner, {Ronald J.} and Fabiola Quintero-Rivera and Wigard Kloosterman and Talkowski, {Michael E.}",

note = "Funding Information: Funding for this work was provided by the Simons Foundation for Autism Research (SFARI #346042), the Nancy Lurie Marks Family Foundation, the March of Dimes, the Charles Hood Foundation, NARSAD, and the National Institutes of Health (R00MH095867, HD081256, GM061354) to MET. The principal investigators of the Simons Simplex Collection (SSC), which is sponsored by the Simons Foundation, collected the samples in the SSC. No funding body played a role in the study design, analysis, or interpretation of data. RLC is supported by a Ruth L. Kirschstein NRSA training grant from the National Institutes of Health (NHGRI #T32HG002295-14) to the PhD Program in Bioinformatics and Integrative Genomics of Harvard Medical School. MET is the supported as the MGH Desmond and Ann Heathwood Research Scholar. Publisher Copyright: {\textcopyright} 2017 The Author(s).",

year = "2017",

month = mar,

day = "6",

doi = "10.1186/s13059-017-1158-6",

language = "English",

volume = "18",

journal = "Genome Biology",

issn = "1474-7596",

publisher = "BioMed Central",

number = "1",

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Collins, RL, Brand, H, Redin, CE, Hanscom, C, Antolik, C, Stone, MR, Glessner, JT, Mason, T, Pregno, G, Dorrani, N, Mandrile, G, Giachino, D, Perrin, D, Walsh, C, Cipicchio, M, Costello, M, Stortchevoi, A, An, JY, Currall, BB, Seabra, CM, Ragavendran, A, Margolin, L, Martinez-Agosto, JA, Lucente, D, Levy, B, Sanders, J-S, Wapner, RJ, Quintero-Rivera, F, Kloosterman, W & Talkowski, ME 2017, 'Defining the diverse spectrum of inversions, complex structural variation, and chromothripsis in the morbid human genome', Genome Biology, vol. 18, no. 1, 36. https://doi.org/10.1186/s13059-017-1158-6

TY - JOUR

T1 - Defining the diverse spectrum of inversions, complex structural variation, and chromothripsis in the morbid human genome

AU - Collins, Ryan L

AU - Brand, Harrison

AU - Redin, Claire E.

AU - Hanscom, Carrie

AU - Antolik, Caroline

AU - Stone, Matthew R

AU - Glessner, Joseph T.

AU - Mason, Tamara

AU - Pregno, Giulia

AU - Dorrani, Naghmeh

AU - Mandrile, Giorgia

AU - Giachino, Daniela

AU - Perrin, Danielle

AU - Walsh, Cole

AU - Cipicchio, Michelle

AU - Costello, Maura

AU - Stortchevoi, Alexei

AU - An, Joon Yong

AU - Currall, Benjamin B

AU - Seabra, Catarina M

AU - Ragavendran, Ashok

AU - Margolin, Lauren

AU - Martinez-Agosto, Julian A.

AU - Lucente, Diane

AU - Levy, Brynn

AU - Sanders, Jan-Stephan

AU - Wapner, Ronald J.

AU - Quintero-Rivera, Fabiola

AU - Kloosterman, Wigard

AU - Talkowski, Michael E.

N1 - Funding Information: Funding for this work was provided by the Simons Foundation for Autism Research (SFARI #346042), the Nancy Lurie Marks Family Foundation, the March of Dimes, the Charles Hood Foundation, NARSAD, and the National Institutes of Health (R00MH095867, HD081256, GM061354) to MET. The principal investigators of the Simons Simplex Collection (SSC), which is sponsored by the Simons Foundation, collected the samples in the SSC. No funding body played a role in the study design, analysis, or interpretation of data. RLC is supported by a Ruth L. Kirschstein NRSA training grant from the National Institutes of Health (NHGRI #T32HG002295-14) to the PhD Program in Bioinformatics and Integrative Genomics of Harvard Medical School. MET is the supported as the MGH Desmond and Ann Heathwood Research Scholar. Publisher Copyright: © 2017 The Author(s).

PY - 2017/3/6

Y1 - 2017/3/6

N2 - Background: Structural variation (SV) influences genome organization and contributes to human disease. However, the complete mutational spectrum of SV has not been routinely captured in disease association studies. Results: We sequenced 689 participants with autism spectrum disorder (ASD) and other developmental abnormalities to construct a genome-wide map of large SV. Using long-insert jumping libraries at 105X mean physical coverage and linked-read whole-genome sequencing from 10X Genomics, we document seven major SV classes at ~5 kb SV resolution. Our results encompass 11,735 distinct large SV sites, 38.1% of which are novel and 16.8% of which are balanced or complex. We characterize 16 recurrent subclasses of complex SV (cxSV), revealing that: (1) cxSV are larger and rarer than canonical SV; (2) each genome harbors 14 large cxSV on average; (3) 84.4% of large cxSVs involve inversion; and (4) most large cxSV (93.8%) have not been delineated in previous studies. Rare SVs are more likely to disrupt coding and regulatory non-coding loci, particularly when truncating constrained and disease-associated genes. We also identify multiple cases of catastrophic chromosomal rearrangements known as chromoanagenesis, including somatic chromoanasynthesis, and extreme balanced germline chromothripsis events involving up to 65 breakpoints and 60.6 Mb across four chromosomes, further defining rare categories of extreme cxSV. Conclusions: These data provide a foundational map of large SV in the morbid human genome and demonstrate a previously underappreciated abundance and diversity of cxSV that should be considered in genomic studies of human disease.

AB - Background: Structural variation (SV) influences genome organization and contributes to human disease. However, the complete mutational spectrum of SV has not been routinely captured in disease association studies. Results: We sequenced 689 participants with autism spectrum disorder (ASD) and other developmental abnormalities to construct a genome-wide map of large SV. Using long-insert jumping libraries at 105X mean physical coverage and linked-read whole-genome sequencing from 10X Genomics, we document seven major SV classes at ~5 kb SV resolution. Our results encompass 11,735 distinct large SV sites, 38.1% of which are novel and 16.8% of which are balanced or complex. We characterize 16 recurrent subclasses of complex SV (cxSV), revealing that: (1) cxSV are larger and rarer than canonical SV; (2) each genome harbors 14 large cxSV on average; (3) 84.4% of large cxSVs involve inversion; and (4) most large cxSV (93.8%) have not been delineated in previous studies. Rare SVs are more likely to disrupt coding and regulatory non-coding loci, particularly when truncating constrained and disease-associated genes. We also identify multiple cases of catastrophic chromosomal rearrangements known as chromoanagenesis, including somatic chromoanasynthesis, and extreme balanced germline chromothripsis events involving up to 65 breakpoints and 60.6 Mb across four chromosomes, further defining rare categories of extreme cxSV. Conclusions: These data provide a foundational map of large SV in the morbid human genome and demonstrate a previously underappreciated abundance and diversity of cxSV that should be considered in genomic studies of human disease.

KW - Autism

KW - Chromoanagenesis

KW - Chromothripsis

KW - Complex chromosomal rearrangement

KW - Copynumber variation

KW - Germline mutation

KW - Inversion

KW - Neurodevelopmental disorders

KW - Structural variation

KW - Whole-genome sequencing

UR - http://www.scopus.com/inward/record.url?scp=85014470424&partnerID=8YFLogxK

U2 - 10.1186/s13059-017-1158-6

DO - 10.1186/s13059-017-1158-6

M3 - Article

C2 - 28260531

AN - SCOPUS:85014470424

SN - 1474-7596

VL - 18

JO - Genome Biology

JF - Genome Biology

IS - 1

M1 - 36

ER -

Defining the diverse spectrum of inversions, complex structural variation, and chromothripsis in the morbid human genome

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Keywords

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