Replicative and non-replicative mechanisms in the formation of clustered CNVs are indicated by whole genome characterization.

Lusine Nazaryan‐Petersen ,Rayan Houssari,Maria Pettersson,Jelena Gacic,Max Käller,Mads Bak,Ann Nordgren,Jesper Ottosson,Outi Mäkitie,Johanna Lundin,Elisabeth Syk Lundberg,Josephine Wincent,Jesper Eisfeldt,Tina Duelund Hjortshøj,Laura Pignata,Francesco Vezzi,Cathrine Jespersgaard,Valtteri Wirta,Daniel Nilsson,Lovisa Lovmar,Zeynep Tümer,Niels Tommerup,Agne Liedén ,Anna Wedell

doi:10.1371/journal.pgen.1007780

Abstract

Clustered copy number variants (CNVs) as detected by chromosomal microarray analysis (CMA) are often reported as germline chromothripsis. However, such cases might need further investigations by massive parallel whole genome sequencing (WGS) in order to accurately define the underlying complex rearrangement, predict the occurrence mechanisms and identify additional complexities. Here, we utilized WGS to delineate the rearrangement structure of 21 clustered CNV carriers first investigated by CMA and identified a total of 83 breakpoint junctions (BPJs). The rearrangements were further sub-classified depending on the patterns observed: I) Cases with only deletions (n = 8) often had additional structural rearrangements, such as insertions and inversions typical to chromothripsis; II) cases with only duplications (n = 7) or III) combinations of deletions and duplications (n = 6) demonstrated mostly interspersed duplications and BPJs enriched with microhomology. In two cases the rearrangement mutational signatures indicated both a breakage-fusion-bridge cycle process and haltered formation of a ring chromosome. Finally, we observed two cases with Alu- and LINE-mediated rearrangements as well as two unrelated individuals with seemingly identical clustered CNVs on 2p25.3, possibly a rare European founder rearrangement.In conclusion, through detailed characterization of the derivative chromosomes we show that multiple mechanisms are likely involved in the formation of clustered CNVs and add further evidence for chromoanagenesis mechanisms in both “simple” and highly complex chromosomal rearrangements. Finally, WGS characterization adds positional information, important for a correct clinical interpretation and deciphering mechanisms involved in the formation of these rearrangements.

Highlights

Structural variants (SVs) contribute to genomic diversity in human [1] and include copy number variants (CNVs), as well as copy number neutral variants, and more complex rearrangements, resulting from chromothripsis and/or chromoanasynthesis [2,3]
The rearrangements were further sub-classified depending on the patterns observed: I) Cases with only deletions (n = 8) often had additional structural rearrangements, such as insertions and inversions typical to chromothripsis; II) cases with only duplications (n = 7) or III) combinations of deletions and duplications (n = 6) demonstrated mostly interspersed duplications and BPJs enriched with microhomology
Clustered copy number variants (CNVs) as detected by chromosomal microarray are often reported as germline chromoanagenesis

Summary

Introduction

Structural variants (SVs) contribute to genomic diversity in human [1] and include copy number variants (CNVs) (deletions, duplications), as well as copy number neutral (balanced) variants (inversions and translocations), and more complex rearrangements, resulting from chromothripsis and/or chromoanasynthesis [2,3]. A previous WGS study of two closely located duplications revealed additional copy-neutral complex genomic rearrangements associated with pairedduplications, such as inverted fragments, duplications with a nested deletion and other complexities, which were cryptic to CMA [5]. Proposed mechanisms that could explain the formation of multiple CNVs on the same chromosome include chromothripsis and chromoanasynthesis [6,7] while the term chromoanagenesis, a form of chromosome rebirth, describe the two phenomena independent of the underlying mechanism [8]

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Discussion

Conclusion