Issue 18, 2022

Exciton decay mechanism in DNA single strands: back-electron transfer and ultrafast base motions

Abstract

The photochemistry of DNA systems is characterized by the ultraviolet (UV) absorption of π-stacked nucleobases, resulting in exciton states delocalized over several bases. As their relaxation sensitively depends on local stacking conformations, disentangling the ensuing electronic and structural dynamics has remained an experimental challenge, despite their fundamental role in protecting the genome from potentially harmful UV radiation. Here we use transient absorption and transient absorption anisotropy spectroscopy with broadband femtosecond deep-UV pulses (250–360 nm) to resolve the exciton dynamics of UV-excited adenosine single strands under physiological conditions. Due to the exceptional deep-UV bandwidth and polarization sensitivity of our experimental approach, we simultaneously resolve the population dynamics, charge-transfer (CT) character and conformational changes encoded in the UV transition dipoles of the π-stacked nucleotides. Whilst UV excitation forms fully charge-separated CT excitons in less than 0.3 ps, we find that most decay back to the ground state via a back-electron transfer. Based on the anisotropy measurements, we propose that this mechanism is accompanied by a structural relaxation of the photoexcited base-stack, involving an inter-base rotation of the nucleotides. Our results finally complete the exciton relaxation mechanism for adenosine single strands and offer a direct view into the coupling of electronic and structural dynamics in aggregated photochemical systems.

Graphical abstract: Exciton decay mechanism in DNA single strands: back-electron transfer and ultrafast base motions

Supplementary files

Article information

Article type
Edge Article
Submitted
18 Nov 2021
Accepted
09 Apr 2022
First published
19 Apr 2022
This article is Open Access

All publication charges for this article have been paid for by the Royal Society of Chemistry
Creative Commons BY-NC license

Chem. Sci., 2022,13, 5230-5242

Exciton decay mechanism in DNA single strands: back-electron transfer and ultrafast base motions

B. Bauer, R. Sharma, M. Chergui and M. Oppermann, Chem. Sci., 2022, 13, 5230 DOI: 10.1039/D1SC06450A

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