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  • Electrochemical properties of interstrand cross-linked DNA duplexes labeled with Nile blue.

Electrochemical properties of interstrand cross-linked DNA duplexes labeled with Nile blue.

Langmuir : the ACS journal of surfaces and colloids (2012-11-17)
Yasuhiro Mie, Keiko Kowata, Naoshi Kojima, Yasuo Komatsu
ABSTRACT

DNA molecules have attracted considerable attention as functional materials in various fields such as electrochemical sensors with redox-labeled DNA. However, the recently developed interstrand cross-link (ICL) technique for double-stranded DNA can adequately modify the electronic properties inside the duplex. Hence, the electrochemical investigation of ICL-DNA helps us to understand the electron transfer of redox-labeled DNA at an electrode surface, which would develop useful sensors. In this study, the first insight into this matter is presented. We prepared 17-mer DNA duplexes incorporating Nile blue (NB-DNA) at one end as a redox marker and a disulfide tether at the other end for immobilization onto an electrode. The duplexes were covalently cross-linked by bifunctional cross-linkers that utilize either a propyl or naphthalene residue to replace a base pair. Their electrochemical responses at the electrode surface were compared to evaluate the effect of the ICL on the electron-transfer reactions of the redox-labeled DNA duplexes. A direct transfer of electrons between NB and the electrode was observed for a standard DNA, as previously reported, whereas interstrand cross-linked DNA (CL-DNA) strands showed a decrease in the direct electron-transfer pathway. This is expected to result from constraining the elastic bending/flexibility of the duplex caused by the covalent cross-links. Interestingly, the CL-DNA incorporating naphthalene residues exhibited additional voltammetric peaks derived from DNA-mediated electron transfer (through base π stacking), which was not observed in the mismatched CL-DNA. The present results indicate that the ICL significantly affects electron transfer in the redox-labeled DNA at the electrode and can be an important determinant for electrochemical signaling in addition to its role in stabilizing the duplex structure.

MATERIALS
Product Number
Brand
Product Description

Sigma-Aldrich
Nile Blue A, Dye content ≥75 %
Sigma-Aldrich
Nile Blue A perchlorate, Dye content 95 %
Sigma-Aldrich
Nile Blue chloride, Dye content 85 %
Sigma-Aldrich
Nile Blue A, certified by the Biological Stain Commission