Abstract
Nicks are the most frequent form of DNA damage and a potential source of mutagenesis in human cells. By deep sequencing, we have identified factors and pathways that promote and limit mutagenic repair at a targeted nick in human cells. Mutations were distributed asymmetrically around the nick site. BRCA2 inhibited all categories of mutational events, including indels, SNVs and HDR. DNA2 and RPA promoted resection. DNA2 inhibited 1 bp deletions but contributed to longer deletions, as did REV7. POLQ stimulated SNVs. Parallel analysis of DSBs targeted to the same site identified similar roles for DNA2 and POLQ (but not REV7) in promoting deletions and for POLQ in stimulating SNVs. Insertions were infrequent at nicks, and most were 1 bp in length, as at DSBs. The translesion polymerase REV1 stimulated +1 insertions at one nick site but not another, illustrating the potential importance of sequence context in determining the outcome of mutagenic repair. These results highlight the potential for nicks to promote mutagenesis, especially in BRCA-deficient cells, and identify mutagenic signatures of DNA2, REV1, REV3, REV7 and POLQ.
Highlights
Nicks are the most frequent form of DNA damage and a potential source of genomic instability in human cells
Nicks were until recently ignored as a potential source of genomic instability
Nicks are significantly less mutagenic than double-strand break (DSB) [3,4,5,6] but possess considerable potential to contribute to the overall burden of mutagenesis because of the frequency with which they occur
Summary
Nicks are the most frequent form of DNA damage and a potential source of genomic instability in human cells. Nicks can initiate both mutagenesis and homology-directed repair (HDR; reviewed in [1]). Nicks occur naturally in the course of transcription and DNA repair, and they result from chemical exposures and ionizing radiation (IR), which generates 100. Mutagenesis at DNA nicks nicks for every double-strand break (DSB; [2]). Nicks are significantly less mutagenic than DSBs [3,4,5,6] but possess considerable potential to contribute to the overall burden of mutagenesis because of the frequency with which they occur. Nicks may pose a particular threat to genomic stability in tumors treated with IR, which has been a mainstay of cancer therapy for decades, and is currently used to treat over half of solid tumors
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