TY - JOUR
T1 - Paired-Duplication Signatures Mark Cryptic Inversions and Other Complex Structural Variation
AU - Brand, Harrison
AU - Collins, Ryan L.
AU - Hanscom, Carrie
AU - Rosenfeld, Jill A.
AU - Pillalamarri, Vamsee
AU - Stone, Matthew R.
AU - Kelley, Fontina
AU - Mason, Tamara
AU - Margolin, Lauren
AU - Eggert, Stacey
AU - Mitchell, Elyse
AU - Hodge, Jennelle C.
AU - Gusella, James F.
AU - Sanders, Stephan J.
AU - Talkowski, Michael E.
N1 - Funding Information:
We are grateful to all of the families at the participating Simons Simplex Collection sites, as well as the principal investigators (A. Beaudet, R. Bernier, J. Constantino, E. Cook, E. Fombonne, D. Geschwind, R. Goin-Kochel, E. Hanson, D. Grice, A. Klin, D. Ledbetter, C. Lord, C. Martin, D. Martin, R. Maxim, J. Miles, O. Ousley, K. Pelphrey, B. Peterson, J. Piggot, C. Saulnier, M. State, W. Stone, J. Sutcliffe, C. Walsh, Z. Warren, and E. Wijsman). We also thank Matthew State, Bernie Devlin, and Kathryn Roeder for contributing to the generation and analysis of the microarray copy-number-variant data and Patricia Greipp for coordinating efforts at the Mayo Clinic. We thank Dr. Lisa Shaffer, formerly of Signature Genomics, and Dr. Yiping Shen of Boston Children’s Hospital for making the clinical diagnostic chromosomal-microarray data available to us. This work was supported by funding from the Simons Foundation for Autism Research (SFARI 238504), the Nancy Lurie Marks Family Foundation, the March of Dimes, the Charles Hood Foundation, the Brain & Behavioral Research Foundation, and the National Institute of Mental Health (R00MH095867 and GM061354) to M.E.T. H.B. is supported by a T32 fellowship from the National Institute of Child Health and Human Development (HD007396).
Publisher Copyright:
© 2015 The American Society of Human Genetics.
PY - 2015
Y1 - 2015
N2 - Copy-number variants (CNVs) have been the predominant focus of genetic studies of structural variation, and chromosomal microarray (CMA) for genome-wide CNV detection is the recommended first-tier genetic diagnostic screen in neurodevelopmental disorders. We compared CNVs observed by CMA to the structural variation detected by whole-genome large-insert sequencing in 259 individuals diagnosed with autism spectrum disorder (ASD) from the Simons Simplex Collection. These analyses revealed a diverse landscape of complex duplications in the human genome. One remarkably common class of complex rearrangement, which we term dupINVdup, involves two closely located duplications ("paired duplications") that flank the breakpoints of an inversion. This complex variant class is cryptic to CMA, but we observed it in 8.1% of all subjects. We also detected other paired-duplication signatures and duplication-mediated complex rearrangements in 15.8% of all ASD subjects. Breakpoint analysis showed that the predominant mechanism of formation of these complex duplication-associated variants was microhomology-mediated repair. On the basis of the striking prevalence of dupINVdups in this cohort, we explored the landscape of all inversion variation among the 235 highest-quality libraries and found abundant complexity among these variants: only 39.3% of inversions were canonical, or simple, inversions without additional rearrangement. Collectively, these findings indicate that dupINVdups, as well as other complex duplication-associated rearrangements, represent relatively common sources of genomic variation that is cryptic to population-based microarray and low-depth whole-genome sequencing. They also suggest that paired-duplication signatures detected by CMA warrant further scrutiny in genetic diagnostic testing given that they might mark complex rearrangements of potential clinical relevance.
AB - Copy-number variants (CNVs) have been the predominant focus of genetic studies of structural variation, and chromosomal microarray (CMA) for genome-wide CNV detection is the recommended first-tier genetic diagnostic screen in neurodevelopmental disorders. We compared CNVs observed by CMA to the structural variation detected by whole-genome large-insert sequencing in 259 individuals diagnosed with autism spectrum disorder (ASD) from the Simons Simplex Collection. These analyses revealed a diverse landscape of complex duplications in the human genome. One remarkably common class of complex rearrangement, which we term dupINVdup, involves two closely located duplications ("paired duplications") that flank the breakpoints of an inversion. This complex variant class is cryptic to CMA, but we observed it in 8.1% of all subjects. We also detected other paired-duplication signatures and duplication-mediated complex rearrangements in 15.8% of all ASD subjects. Breakpoint analysis showed that the predominant mechanism of formation of these complex duplication-associated variants was microhomology-mediated repair. On the basis of the striking prevalence of dupINVdups in this cohort, we explored the landscape of all inversion variation among the 235 highest-quality libraries and found abundant complexity among these variants: only 39.3% of inversions were canonical, or simple, inversions without additional rearrangement. Collectively, these findings indicate that dupINVdups, as well as other complex duplication-associated rearrangements, represent relatively common sources of genomic variation that is cryptic to population-based microarray and low-depth whole-genome sequencing. They also suggest that paired-duplication signatures detected by CMA warrant further scrutiny in genetic diagnostic testing given that they might mark complex rearrangements of potential clinical relevance.
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U2 - 10.1016/j.ajhg.2015.05.012
DO - 10.1016/j.ajhg.2015.05.012
M3 - Article
C2 - 26094575
AN - SCOPUS:84937522527
SN - 0002-9297
VL - 97
SP - 170
EP - 176
JO - American journal of human genetics
JF - American journal of human genetics
IS - 1
ER -