G4-forming Sequences in the Non-transcribed DNA Strand Pose Blocks to T7 RNA Polymerase and Mammalian RNA Polymerase II

Silvia Tornaletti,Shaun Park-Snyder,Philip C Hanawalt

doi:10.1074/jbc.m705003200

Silvia Tornaletti, Shaun Park-Snyder + Show 1 more

Open Access

https://doi.org/10.1074/jbc.m705003200

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Abstract

DNA sequences rich in runs of guanine have the potential to form G4 DNA, a four-stranded non-canonical DNA structure stabilized by formation and stacking of G quartets, planar arrays of four hydrogen-bonded guanines. It was reported recently that G4 DNA can be generated in Escherichia coli during transcription of plasmids containing G-rich sequences in the non-transcribed strand. In addition, a stable RNA/DNA hybrid is formed with the transcribed strand. These novel structures, termed G loops, are suppressed in recQ(+) strains, suggesting that their persistence may generate genomic instability and that the RecQ helicase may be involved in their dissolution. However, little is known about how such non-canonical DNA structures are processed when encountered by an elongating polymerase. To assess whether G4-forming sequences interfere with transcription, we studied their effect on transcription elongation by T7 RNA polymerase and mammalian RNA polymerase II. We used a reconstituted transcription system in vitro with purified polymerase and initiation factors and with substrates containing G-rich sequences in either the transcribed or non-transcribed strand downstream of the T7 promoter or the adenovirus major late promoter. We report that G-rich sequences located in the transcribed strand do not affect transcription by either polymerase, but when the sequences are located in the non-transcribed strand, they partially arrest both polymerases. The efficiency of arrest increases with negative supercoiling and also with multiple rounds of transcription compared with single events.

Highlights

Result of hydrogen bonding within each quartet, stacking of the hydrophobic quartets, and charge coordination by monovalent cations in the central cavity [6]
Transcription-coupled DNA repair (TCR) has been well documented for transcription-arresting damage, little is known about whether this repair pathway may be involved in processing other types of transcription impediments, such as those generated by natural DNA sequences that can adopt non-B form structures and that may be responsible for transcription pausing
As a first step to determining whether G4-forming sequences might interfere with RNAP progression and initiate TCR, we studied the effect of G-rich sequences on transcription elongation by T7 RNAP and mammalian RNAP II

Summary

Introduction

Result of hydrogen bonding within each quartet, stacking of the hydrophobic quartets, and charge coordination by monovalent cations in the central cavity [6]. Formation of G4 DNA in vivo has been documented recently in Escherichia coli, in which transcription of plasmids containing G-rich sequences in the non-transcribed strand produced novel structures called G loops; G4 DNA formed in the nontranscribed strand and a stable RNA/DNA hybrid in the other [3].

Results

Conclusion