8-Oxoguanine Affects DNA Backbone Conformation in the EcoRI Recognition Site and Inhibits Its Cleavage by the Enzyme

Overview

Journal PLoS One

Specialties General Medicine
Science

Date 2016 Oct 18

PMID 27749894

Citations 8

Authors

Joanna J Hoppins

David R Gruber

Heather L Miears

Alexey S Kiryutin

Rustem D Kasymov

Darya V Petrova

Anton V Endutkin

Alexander V Popov

Alexandra V Yurkovskaya

Stanislav O Fedechkin

Jacob A Brockerman

Dmitry O Zharkov

Serge L Smirnov

Affiliations

Soon will be listed here.

Abstract

8-oxoguanine is one of the most abundant and impactful oxidative DNA lesions. However, the reasons underlying its effects, especially those not directly explained by the altered base pairing ability, are poorly understood. We report the effect of the lesion on the action of EcoRI, a widely used restriction endonuclease. Introduction of 8-oxoguanine inside, or adjacent to, the GAATTC recognition site embedded within the Drew-Dickerson dodecamer sequence notably reduced the EcoRI activity. Solution NMR revealed that 8-oxoguanine in the DNA duplex causes substantial alterations in the sugar-phosphate backbone conformation, inducing a BI→BII transition. Moreover, molecular dynamics of the complex suggested that 8-oxoguanine, although does not disrupt the sequence-specific contacts formed by the enzyme with DNA, shifts the distribution of BI/BII backbone conformers. Based on our data, we propose that the disruption of enzymatic cleavage can be linked with the altered backbone conformation and dynamics in the free oxidized DNA substrate and, possibly, at the protein-DNA interface.

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