Unscheduled DNA synthesis leads to elevated uracil residues at highly transcribed genomic loci in Saccharomyces cerevisiae.

Norah Owiti,Nayun Kim,Shanqiao Wei,Ashok S Bhagwat

doi:10.1371/journal.pgen.1007516

Norah Owiti, Nayun Kim + Show 2 more

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https://doi.org/10.1371/journal.pgen.1007516

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Abstract

Recombination and mutagenesis are elevated by active transcription. The correlation between transcription and genome instability is largely explained by the topological and structural changes in DNA and the associated physical obstacles generated by the transcription machinery. However, such explanation does not directly account for the unique types of mutations originating from the non-canonical residues, uracil or ribonucleotide, which are also elevated at highly transcribed regions. Based on the previous findings that abasic (AP) lesions derived from the uracil residues incorporated into DNA in place of thymine constitute a major component of the transcription-associated mutations in yeast, we formed the hypothesis that DNA synthesis ensuing from the repair of the transcription-induced DNA damage provide the opportunity for uracil-incorporation. In support of this hypothesis, we show here the positive correlation between the level of transcription and the density of uracil residues in the yeast genome indirectly through the mutations generated by the glycosylase that excise undamaged cytosine as well as uracil. The higher uracil-density at actively transcribed regions is confirmed by the long-amplicon PCR analysis. We also show that the uracil-associated mutations at a highly transcribed region are elevated by the induced DNA damage and reduced by the overexpression of a dUTP-catalyzing enzyme Dut1 in G1- or G2-phases of the cell cycle. Overall, our results show that the DNA composition can be modified to include higher uracil-content through the non-replicative, repair-associated DNA synthesis.

Highlights

Transcription, a fundamental cellular process, can incongruously pose a serious threat to genome stability
Recent studies in yeast have shown that the uracil-associated mutations occur more frequently at highly transcribed regions
The rate of A>C and T>G mutations was significantly reduced when the Deoxyuridine triphosphatase (dUTPase)-encoding DUT1 gene was highly overexpressed to reduce the level of free dUTP available for incorporation into the genome

Summary

Introduction

Transcription, a fundamental cellular process, can incongruously pose a serious threat to genome stability. Transcription necessitates a change in DNA topology and the ensuing accumulation of both negative and positive supercoils promotes the formation of non-canonical secondary structures such as R-loops, the stable hybrids of transcribed DNA and nascent RNA or G-quadruplex DNAs (G4 DNA), the four-stranded DNA configuration held together by Hoogsteen bonds among guanine bases [9, 10]. These structures leave the non-transcribed DNA in the susceptible single-stranded state and frequently lead to stalling and eventual collapse of the replication fork, which must be restarted/ repaired via homologous recombination [11,12,13]. These collisions induce helical stress and can trigger replication fork reversal giving rise to non-canonical DNA structures that can be processed into double stranded breaks [16, 17]

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