Interstitial telomeric sequences promote gross chromosomal rearrangement via multiple mechanisms

Abstract

AbstractTelomeric DNA sequences are difficult to replicate. Replication forks frequently pause or stall at telomeres, which can lead to telomere truncation and dysfunction. In addition to being at chromosome ends, telomere repeats are also present at internal locations within chromosomes, known as interstitial telomeric sequences (ITSs). These sequences are unstable and prone to triggering gross chromosomal rearrangements (GCRs). In this study, we quantitatively examined the effect of ITSs on GCR rate inSaccharomyces cerevisiaeusing a genetic assay. We find that GCR rate increases exponentially with ITS length. This increase can be attributed to the telomere repeat binding protein Rap1 impeding DNA replication and a bias of repairing DNA breaks at or distal to the ITS via de novo telomere addition. Additionally, we performed a genome-wide screen for genes that modulate the rate of ITS-induced GCRs. We find that mutation of core components of the DNA replication machinery leads to an increase in GCRs, but many mutants known to increase GCR rate in the absence of an ITS do not significantly affect GCR rate when an ITS is present. We also identified genes that promote the formation of ITS-induced GCRs, including genes with roles in telomere maintenance, nucleotide excision repair, and transcription. Our work thus uncovers multiple mechanisms by which an ITS promotes GCR.Significance statementTelomeric DNA repeats are found at the ends of linear chromosomes where they, together with specialized proteins that bind to them, protect chromosome ends from degradation and unwanted DNA repair activities. Telomeric repeats can also be found at internal locations in the genome, where they are called interstitial telomeric sequences (ITSs). ITSs are prone to breakage and are associated with human diseases. In this study, using baker’s yeast as a model organism, we show that instability at ITSs is driven by multiple factors, and identify genes that either promote or suppress gross chromosomal rearrangements induced by the presence of an ITS.