Mechanism of DNA Alkylation-induced Transcriptional Stalling, Lesion Bypass, and Mutagenesis

Overview

Journal Proc Natl Acad Sci U S A

Specialty Science

Date 2017 Aug 9

PMID 28784758

Citations 25

Authors

Liang Xu

Wei Wang

Jiabin Wu

Ji Hyun Shin

Pengcheng Wang

Ilona Christy Unarta

Jenny Chong

Yinsheng Wang

Dong Wang

Affiliations

Soon will be listed here.

Abstract

Alkylated DNA lesions, induced by both exogenous chemical agents and endogenous metabolites, interfere with the efficiency and accuracy of DNA replication and transcription. However, the molecular mechanisms of DNA alkylation-induced transcriptional stalling and mutagenesis remain unknown. In this study, we systematically investigated how RNA polymerase II (pol II) recognizes and bypasses regioisomeric -, 3-, and -ethylthymidine (-, 3-, and -EtdT) lesions. We observed distinct pol II stalling profiles for the three regioisomeric EtdT lesions. Intriguingly, pol II stalling at -EtdT and 3-EtdT sites is exacerbated by TFIIS-stimulated proofreading activity. Assessment for the impact of the EtdT lesions on individual fidelity checkpoints provided further mechanistic insights, where the transcriptional lesion bypass routes for the three EtdT lesions are controlled by distinct fidelity checkpoints. The error-free transcriptional lesion bypass route is strongly favored for the minor-groove -EtdT lesion. In contrast, a dominant error-prone route stemming from GMP misincorporation was observed for the major-groove -EtdT lesion. For the 3-EtdT lesion that disrupts base pairing, multiple transcriptional lesion bypass routes were found. Importantly, the results from the present in vitro transcriptional studies are well correlated with in vivo transcriptional mutagenesis analysis. Finally, we identified a minor-groove-sensing motif from pol II (termed Pro-Gate loop). The Pro-Gate loop faces toward the minor groove of RNA:DNA hybrid and is involved in modulating the translocation of minor-groove alkylated DNA template after nucleotide incorporation opposite the lesion. Taken together, this work provides important mechanistic insights into transcriptional stalling, lesion bypass, and mutagenesis of alkylated DNA lesions.

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