Abstract
Copy number variants (CNVs) resulting from genomic deletions and duplications and common fragile sites (CFSs) seen as breaks on metaphase chromosomes are distinct forms of structural chromosome instability precipitated by replication inhibition. Although they share a common induction mechanism, it is not known how CNVs and CFSs are related or why some genomic loci are much more prone to their occurrence. Here we compare large sets of de novo CNVs and CFSs in several experimental cell systems to each other and to overlapping genomic features. We first show that CNV hotpots and CFSs occurred at the same human loci within a given cultured cell line. Bru-seq nascent RNA sequencing further demonstrated that although genomic regions with low CNV frequencies were enriched in transcribed genes, the CNV hotpots that matched CFSs specifically corresponded to the largest active transcription units in both human and mouse cells. Consistently, active transcription units >1 Mb were robust cell-type-specific predictors of induced CNV hotspots and CFS loci. Unlike most transcribed genes, these very large transcription units replicated late and organized deletion and duplication CNVs into their transcribed and flanking regions, respectively, supporting a role for transcription in replication-dependent lesion formation. These results indicate that active large transcription units drive extreme locus- and cell-type-specific genomic instability under replication stress, resulting in both CNVs and CFSs as different manifestations of perturbed replication dynamics.
Highlights
Structural chromosome alterations account for a large proportion of genomic diversity and cause many human genomic disorders and cancers
To determine whether the observations above establish a predictive model for Copy number variants (CNVs) and Common fragile sites (CFSs) formation under replication stress, we performed a prospective study of a new cell line UMHF1 (HF1) for which we have reported detailed Bru-seq descriptions (Paulsen et al 2013b)
transcription units (TUs) length predominantly determined the degree of transcription-dependent sensitization to replication stress, with nonrecurrent CNV hotspots and CFSs strongly associated with active TUs > 1 Mb
Summary
Structural chromosome alterations account for a large proportion of genomic diversity and cause many human genomic disorders and cancers. Support for a replication-error origin of nonrecurrent CNVs comes from experimental studies of cultured cells. Both simple and complex CNVs with nonhomologous breakpoint junctions arise sporadically and are induced in normal human cells by partial inhibition of replication with low-doses of aphidicolin (APH), hydroxyurea (HU), or ionizing radiation (IR) (Fig. 1A; Arlt et al 2009, 2011, 2014). Many of the spontaneous and replication stress-induced CNVs seen in experimental cell systems overlap in specific genomic regions called hotspots, some of which correspond to CFSs (Durkin et al 2008; Arlt et al 2011).
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