Driving force dependence of electron transfer dynamics in synthetic DNA hairpins

F. D. Lewis; R. S. Kalgutkar; Y. Wu; X. Liu; J. Liu; R. T. Hayes; S. E. Miller; M. R. Wasielewski

doi:10.1021/ja0028267

Driving force dependence of electron transfer dynamics in synthetic DNA hairpins

F. D. Lewis^*, R. S. Kalgutkar, Y. Wu, X. Liu, J. Liu, R. T. Hayes, S. E. Miller, M. R. Wasielewski

^*Corresponding author for this work

Chemistry

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173 Scopus citations

Abstract

The driving force dependence of photoinduced electron-transfer dynamics in duplex DNA has been investigated for 16 synthetic DNA hairpins in which an acceptor chromophore serves as a linker connecting two complementary oligonucleotide arms containing a single donor nucleobase located either adjacent to the linker or separated from the linker by two unreactive base pairs. The rate constants for both charge separation and charge recombination processes have been determined by means of subpicosecond time-resolved transient absorption spectroscopy and the results analyzed using quantum mechanical Marcus theory. This analysis provides intimate details about electron-transfer processes in DNA including the distance dependence of the electronic coupling between the acceptor and nucleobase donor and the solvent and nuclear reorganization energies.

Original language	English (US)
Pages (from-to)	12346-12351
Number of pages	6
Journal	Journal of the American Chemical Society
Volume	122
Issue number	49
DOIs	https://doi.org/10.1021/ja0028267
State	Published - Dec 13 2000

ASJC Scopus subject areas

Catalysis
Chemistry(all)
Biochemistry
Colloid and Surface Chemistry

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title = "Driving force dependence of electron transfer dynamics in synthetic DNA hairpins",

abstract = "The driving force dependence of photoinduced electron-transfer dynamics in duplex DNA has been investigated for 16 synthetic DNA hairpins in which an acceptor chromophore serves as a linker connecting two complementary oligonucleotide arms containing a single donor nucleobase located either adjacent to the linker or separated from the linker by two unreactive base pairs. The rate constants for both charge separation and charge recombination processes have been determined by means of subpicosecond time-resolved transient absorption spectroscopy and the results analyzed using quantum mechanical Marcus theory. This analysis provides intimate details about electron-transfer processes in DNA including the distance dependence of the electronic coupling between the acceptor and nucleobase donor and the solvent and nuclear reorganization energies.",

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T1 - Driving force dependence of electron transfer dynamics in synthetic DNA hairpins

AU - Lewis, F. D.

AU - Kalgutkar, R. S.

AU - Wu, Y.

AU - Liu, X.

AU - Liu, J.

AU - Hayes, R. T.

AU - Miller, S. E.

AU - Wasielewski, M. R.

PY - 2000/12/13

Y1 - 2000/12/13

N2 - The driving force dependence of photoinduced electron-transfer dynamics in duplex DNA has been investigated for 16 synthetic DNA hairpins in which an acceptor chromophore serves as a linker connecting two complementary oligonucleotide arms containing a single donor nucleobase located either adjacent to the linker or separated from the linker by two unreactive base pairs. The rate constants for both charge separation and charge recombination processes have been determined by means of subpicosecond time-resolved transient absorption spectroscopy and the results analyzed using quantum mechanical Marcus theory. This analysis provides intimate details about electron-transfer processes in DNA including the distance dependence of the electronic coupling between the acceptor and nucleobase donor and the solvent and nuclear reorganization energies.

AB - The driving force dependence of photoinduced electron-transfer dynamics in duplex DNA has been investigated for 16 synthetic DNA hairpins in which an acceptor chromophore serves as a linker connecting two complementary oligonucleotide arms containing a single donor nucleobase located either adjacent to the linker or separated from the linker by two unreactive base pairs. The rate constants for both charge separation and charge recombination processes have been determined by means of subpicosecond time-resolved transient absorption spectroscopy and the results analyzed using quantum mechanical Marcus theory. This analysis provides intimate details about electron-transfer processes in DNA including the distance dependence of the electronic coupling between the acceptor and nucleobase donor and the solvent and nuclear reorganization energies.

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JF - Journal of the American Chemical Society

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Driving force dependence of electron transfer dynamics in synthetic DNA hairpins

Abstract

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