From the journal:

Chemical Science

Unlocking atom-specific radiotherapy – DNA backbone breakage caused by X-ray photoactivation

Pamela H. W. Svensson, ORCID logo *a   Brian Rydgren, ORCID logo a   Lucas Schwob, ORCID logo b   Marta Berholts, ORCID logo c   Bo Stenerlöw, ORCID logo d   Ouassim Hocine Hafiani, ORCID logo a   Tomas André, ORCID logo a   Oscar Grånäs, ORCID logo a   Nicusor Timneanu, ORCID logo a   Juliette Leroux, ORCID logo b   Aarathi Nair, ORCID logo e   Laura Pille, ORCID logo b   Bart Oostenrijk, ORCID logo b   Sadia Bari, ORCID logo bf   Olle Björneholm ORCID logo a  and  Carl Caleman ORCID logo *ag  

* Corresponding authors

a Department of Physics and Astronomy, Uppsala University, Box 516, Uppsala, Sweden
E-mail: pamela.svensson@physics.uu.se, carl.caleman@physics.uu.se

b Deutsches Elektronen-Synchrotron DESY, DE-22603 Hamburg, Germany

c Institute of Physics, University of Tartu, EE50411 Tartu, Estonia

d Cancer Precision Medicine, Department of Immunology, Uppsala University, Genetics and Pathology, Box 256, Uppsala, Sweden

e The Hamburg Centre for Ultrafast Imaging, 22761 Hamburg, Germany

f Zernike Institute for Advanced Materials, University of Groningen, 9747 AG Groningen, The Netherlands

g Center for Free-Electron Laser Science, DESY, DE-22607 Hamburg, Germany

Abstract

The effectiveness of radiation therapy can be enhanced by understanding the fragmentation mechanisms of iodine-doped DNA oligonucleotide under tender X-rays, as explored experimentally and computationally in our study. By primarily targeting iodine atoms above their L-edge ionization energies, we observed a significant increase in the production of fragments critical to DNA backbone breakage, particularly within mass ranges associated with phosphate and sugar groups. The mass spectroscopy experiments demonstrated that iodine-doped DNA oligonucleotides undergo intense fragmentation at long distances from the initial photoactivation site. Born–Oppenheimer based molecular dynamics simulations confirmed the generation of numerous small fragments, including reactive oxygen species, which are pivotal in enhancing the radiation damage. These findings highlight the effectiveness of iodine doping in amplifying DNA damage in radiotherapy via iodine photoactivation, thereby improving the potential for targeted cancer treatment.

Graphical abstract: Unlocking atom-specific radiotherapy – DNA backbone breakage caused by X-ray photoactivation

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DOI
https://doi.org/10.1039/D5SC03414K
Article type
Edge Article
Submitted
12 May 2025
Accepted
01 Sep 2025
First published
11 Sep 2025
This article is Open Access

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

Chem. Sci., 2025, Advance Article

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Unlocking atom-specific radiotherapy – DNA backbone breakage caused by X-ray photoactivation

P. H. W. Svensson, B. Rydgren, L. Schwob, M. Berholts, B. Stenerlöw, O. Hocine Hafiani, T. André, O. Grånäs, N. Timneanu, J. Leroux, A. Nair, L. Pille, B. Oostenrijk, S. Bari, O. Björneholm and C. Caleman, Chem. Sci., 2025, Advance Article , DOI: 10.1039/D5SC03414K

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