Abstract

Bent structures are formed in DNA by the binding of small molecules or proteins. We developed a chemical method to detect bent DNA structures. Oligonucleotide duplexes in which two mercaptoalkyl groups were attached to the positions facing each other across the major groove were prepared. When the duplex contained the cisplatin adduct, which was proved to induce static helix bending, interstrand disulfide bond formation under an oxygen atmosphere was detected by HPLC analyses, but not in the non-adducted duplex, when the two thiol-tethered nucleosides were separated by six base pairs. When the insert was five and seven base pairs, the disulfide bond was formed and was not formed, respectively, regardless of the cisplatin adduct formation. The same reaction was observed in the duplexes containing an abasic site analog and the (6–4) photoproduct. Compared with the cisplatin case, the disulfide bond formation was slower in these duplexes, but the reaction rate was nearly independent of the linker length. These results indicate that dynamic structural changes of the abasic site- and (6–4) photoproduct-containing duplexes could be detected by our method. It is strongly suggested that the UV-damaged DNA-binding protein, which specifically binds these duplexes and functions at the first step of global-genome nucleotide excision repair, recognizes the easily bendable nature of damaged DNA.

Highlights

  • DNA bending is observed in various processes of life

  • If a mercaptoalkyl group was attached to this position, this side chain should point toward the complementary strand across the major groove

  • The 2’ lower position might have a problem of steric hindrance with the 3’ flanking nucleoside, and the other sugar protons were not located in the major groove

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Summary

Introduction

DNA bending is observed in various processes of life. There are two types of DNA bends. The TATA-binding protein (TBP), which is a subunit of the general transcription factor TFIID, binds to the minor groove of the TATA box sequence located upstream of the transcription start site, and induces a sharp kink in the DNA [7, 8]. This preformed TBP–DNA complex structure is recognized by another

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