Author
Listed:
- Sarah J. Aitken
(University of Cambridge
University of Cambridge
Cambridge University Hospitals NHS Foundation Trust)
- Craig J. Anderson
(University of Edinburgh)
- Frances Connor
(University of Cambridge)
- Oriol Pich
(The Barcelona Institute of Science and Technology)
- Vasavi Sundaram
(University of Cambridge
European Bioinformatics Institute)
- Christine Feig
(University of Cambridge)
- Tim F. Rayner
(University of Cambridge)
- Margus Lukk
(University of Cambridge)
- Stuart Aitken
(University of Edinburgh)
- Juliet Luft
(University of Edinburgh)
- Elissavet Kentepozidou
(European Bioinformatics Institute)
- Claudia Arnedo-Pac
(The Barcelona Institute of Science and Technology)
- Sjoerd V. Beentjes
(University of Edinburgh)
- Susan E. Davies
(Cambridge University Hospitals NHS Foundation Trust)
- Ruben M. Drews
(University of Cambridge)
- Ailith Ewing
(University of Edinburgh)
- Vera B. Kaiser
(University of Edinburgh)
- Ava Khamseh
(University of Edinburgh
University of Edinburgh)
- Erika López-Arribillaga
(The Barcelona Institute of Science and Technology)
- Aisling M. Redmond
(University of Cambridge)
- Javier Santoyo-Lopez
(The University of Edinburgh)
- Inés Sentís
(The Barcelona Institute of Science and Technology)
- Lana Talmane
(University of Edinburgh)
- Andrew D. Yates
(European Bioinformatics Institute)
- Colin A. Semple
(University of Edinburgh)
- Núria López-Bigas
(The Barcelona Institute of Science and Technology
Universitat Pompeu Fabra (UPF)
Institució Catalana de Recerca i Estudis Avançats (ICREA))
- Paul Flicek
(University of Cambridge
European Bioinformatics Institute)
- Duncan T. Odom
(University of Cambridge
Division of Regulatory Genomics and Cancer Evolution)
- Martin S. Taylor
(University of Edinburgh)
Abstract
Cancers arise through the acquisition of oncogenic mutations and grow by clonal expansion1,2. Here we reveal that most mutagenic DNA lesions are not resolved into a mutated DNA base pair within a single cell cycle. Instead, DNA lesions segregate, unrepaired, into daughter cells for multiple cell generations, resulting in the chromosome-scale phasing of subsequent mutations. We characterize this process in mutagen-induced mouse liver tumours and show that DNA replication across persisting lesions can produce multiple alternative alleles in successive cell divisions, thereby generating both multiallelic and combinatorial genetic diversity. The phasing of lesions enables accurate measurement of strand-biased repair processes, quantification of oncogenic selection and fine mapping of sister-chromatid-exchange events. Finally, we demonstrate that lesion segregation is a unifying property of exogenous mutagens, including UV light and chemotherapy agents in human cells and tumours, which has profound implications for the evolution and adaptation of cancer genomes.
Suggested Citation
Sarah J. Aitken & Craig J. Anderson & Frances Connor & Oriol Pich & Vasavi Sundaram & Christine Feig & Tim F. Rayner & Margus Lukk & Stuart Aitken & Juliet Luft & Elissavet Kentepozidou & Claudia Arne, 2020.
"Pervasive lesion segregation shapes cancer genome evolution,"
Nature, Nature, vol. 583(7815), pages 265-270, July.
Handle:
RePEc:nat:nature:v:583:y:2020:i:7815:d:10.1038_s41586-020-2435-1
DOI: 10.1038/s41586-020-2435-1
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Cited by:
- Ewart Kuijk & Onno Kranenburg & Edwin Cuppen & Arne Van Hoeck, 2022.
"Common anti-cancer therapies induce somatic mutations in stem cells of healthy tissue,"
Nature Communications, Nature, vol. 13(1), pages 1-10, December.
- Yi-Li Feng & Qian Liu & Ruo-Dan Chen & Si-Cheng Liu & Zhi-Cheng Huang & Kun-Ming Liu & Xiao-Ying Yang & An-Yong Xie, 2022.
"DNA nicks induce mutational signatures associated with BRCA1 deficiency,"
Nature Communications, Nature, vol. 13(1), pages 1-15, December.
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