Tissue-specific mutagenesis from endogenous guanine damage is suppressed by Polκ and DNA repair

Yang Jiang; Moritz Przybilla; Linda Bakker; Foster C Jacobs; Dylan Mckeon; Roxanne van der Sluijs; Koichi Sato; Juliëtte Wezenbeek; Joeri van Strien; Jeroen Willems; Alexander E E Verkennis; Jamie Barnett; Adrian Baez Ortega; Federico Abascal; Peter W Villalta; Puck Knipscheer; Inigo Martincorena; Silvia Balbo; Juan Garaycoechea

doi:10.1038/s41467-025-67072-1

Tissue-specific mutagenesis from endogenous guanine damage is suppressed by Polκ and DNA repair

Yang Jiang
, Moritz Przybilla
, Linda Bakker
, Foster C Jacobs
, Dylan Mckeon
, Roxanne van der Sluijs
, Koichi Sato
, Juliëtte Wezenbeek
, Joeri van Strien
, Jeroen Willems
, Alexander E E Verkennis
, Jamie Barnett
, Adrian Baez Ortega
, Federico Abascal
, Peter W Villalta
, Puck Knipscheer
, Inigo Martincorena
, Silvia Balbo
, Juan Garaycoechea^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

Knowledge of mutational patterns has expanded significantly, but linking these patterns to specific molecular mechanisms or sources of endogenous DNA damage remains challenging. Translesion synthesis (TLS) is a key determinant of mutagenesis, yet the endogenous lesions that require TLS and how TLS polymerases shape mammalian mutational landscapes are unclear. Here, we characterize somatic mutational patterns across mouse tissues deficient in the TLS polymerase Polκ and find that Polκ suppresses a distinct tissue-specific mutational signature in the liver and kidney. This signature, enriched for C > A/G/T mutations with strong transcriptional-strand bias, indicates that Polκ performs error-free bypass of endogenous guanine adducts. Nucleotide excision repair (NER) acts in parallel, mitigating some of this damage. Targeted adductomics and biochemical analyses identify endogenous N2-dG lesions requiring Polκ-mediated bypass, while untargeted adductomics reveal new guanine lesions that engage NER. These findings uncover the nature of endogenous DNA damage and the coordinated roles of repair and tolerance pathways that limit mutagenesis in tissues.

Original language	English
Article number	436
Journal	Nature Communications
Volume	17
Issue number	1
Early online date	12 Dec 2025
DOIs	https://doi.org/10.1038/s41467-025-67072-1
Publication status	Published - 13 Jan 2026
Externally published	Yes

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Tissue-specific mutagenesis from endogenous guanine damage is suppressed by Polκ and DNA repairFinal published version, 1.96 MBLicence: CC BY-NC-ND

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Jiang, Y., Przybilla, M., Bakker, L., Jacobs, F. C., Mckeon, D., van der Sluijs, R., Sato, K., Wezenbeek, J., van Strien, J., Willems, J., Verkennis, A. E. E., Barnett, J., Ortega, A. B., Abascal, F., Villalta, P. W., Knipscheer, P., Martincorena, I., Balbo, S., & Garaycoechea, J. (2026). Tissue-specific mutagenesis from endogenous guanine damage is suppressed by Polκ and DNA repair. Nature Communications, 17(1), Article 436. https://doi.org/10.1038/s41467-025-67072-1

@article{31d9170c234f4ee5bc853bdf71398652,

title = "Tissue-specific mutagenesis from endogenous guanine damage is suppressed by Polκ and DNA repair",

abstract = "Knowledge of mutational patterns has expanded significantly, but linking these patterns to specific molecular mechanisms or sources of endogenous DNA damage remains challenging. Translesion synthesis (TLS) is a key determinant of mutagenesis, yet the endogenous lesions that require TLS and how TLS polymerases shape mammalian mutational landscapes are unclear. Here, we characterize somatic mutational patterns across mouse tissues deficient in the TLS polymerase Polκ and find that Polκ suppresses a distinct tissue-specific mutational signature in the liver and kidney. This signature, enriched for C > A/G/T mutations with strong transcriptional-strand bias, indicates that Polκ performs error-free bypass of endogenous guanine adducts. Nucleotide excision repair (NER) acts in parallel, mitigating some of this damage. Targeted adductomics and biochemical analyses identify endogenous N2-dG lesions requiring Polκ-mediated bypass, while untargeted adductomics reveal new guanine lesions that engage NER. These findings uncover the nature of endogenous DNA damage and the coordinated roles of repair and tolerance pathways that limit mutagenesis in tissues.",

author = "Yang Jiang and Moritz Przybilla and Linda Bakker and Jacobs, \{Foster C\} and Dylan Mckeon and \{van der Sluijs\}, Roxanne and Koichi Sato and Juli{\"e}tte Wezenbeek and \{van Strien\}, Joeri and Jeroen Willems and Verkennis, \{Alexander E E\} and Jamie Barnett and Ortega, \{Adrian Baez\} and Federico Abascal and Villalta, \{Peter W\} and Puck Knipscheer and Inigo Martincorena and Silvia Balbo and Juan Garaycoechea",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025.",

year = "2026",

month = jan,

day = "13",

doi = "10.1038/s41467-025-67072-1",

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Jiang, Y, Przybilla, M, Bakker, L, Jacobs, FC, Mckeon, D, van der Sluijs, R, Sato, K, Wezenbeek, J, van Strien, J, Willems, J, Verkennis, AEE, Barnett, J, Ortega, AB, Abascal, F, Villalta, PW, Knipscheer, P, Martincorena, I, Balbo, S & Garaycoechea, J 2026, 'Tissue-specific mutagenesis from endogenous guanine damage is suppressed by Polκ and DNA repair', Nature Communications, vol. 17, no. 1, 436. https://doi.org/10.1038/s41467-025-67072-1

TY - JOUR

T1 - Tissue-specific mutagenesis from endogenous guanine damage is suppressed by Polκ and DNA repair

AU - Jiang, Yang

AU - Przybilla, Moritz

AU - Bakker, Linda

AU - Jacobs, Foster C

AU - Mckeon, Dylan

AU - van der Sluijs, Roxanne

AU - Sato, Koichi

AU - Wezenbeek, Juliëtte

AU - van Strien, Joeri

AU - Willems, Jeroen

AU - Verkennis, Alexander E E

AU - Barnett, Jamie

AU - Ortega, Adrian Baez

AU - Abascal, Federico

AU - Villalta, Peter W

AU - Knipscheer, Puck

AU - Martincorena, Inigo

AU - Balbo, Silvia

AU - Garaycoechea, Juan

PY - 2026/1/13

Y1 - 2026/1/13

N2 - Knowledge of mutational patterns has expanded significantly, but linking these patterns to specific molecular mechanisms or sources of endogenous DNA damage remains challenging. Translesion synthesis (TLS) is a key determinant of mutagenesis, yet the endogenous lesions that require TLS and how TLS polymerases shape mammalian mutational landscapes are unclear. Here, we characterize somatic mutational patterns across mouse tissues deficient in the TLS polymerase Polκ and find that Polκ suppresses a distinct tissue-specific mutational signature in the liver and kidney. This signature, enriched for C > A/G/T mutations with strong transcriptional-strand bias, indicates that Polκ performs error-free bypass of endogenous guanine adducts. Nucleotide excision repair (NER) acts in parallel, mitigating some of this damage. Targeted adductomics and biochemical analyses identify endogenous N2-dG lesions requiring Polκ-mediated bypass, while untargeted adductomics reveal new guanine lesions that engage NER. These findings uncover the nature of endogenous DNA damage and the coordinated roles of repair and tolerance pathways that limit mutagenesis in tissues.

AB - Knowledge of mutational patterns has expanded significantly, but linking these patterns to specific molecular mechanisms or sources of endogenous DNA damage remains challenging. Translesion synthesis (TLS) is a key determinant of mutagenesis, yet the endogenous lesions that require TLS and how TLS polymerases shape mammalian mutational landscapes are unclear. Here, we characterize somatic mutational patterns across mouse tissues deficient in the TLS polymerase Polκ and find that Polκ suppresses a distinct tissue-specific mutational signature in the liver and kidney. This signature, enriched for C > A/G/T mutations with strong transcriptional-strand bias, indicates that Polκ performs error-free bypass of endogenous guanine adducts. Nucleotide excision repair (NER) acts in parallel, mitigating some of this damage. Targeted adductomics and biochemical analyses identify endogenous N2-dG lesions requiring Polκ-mediated bypass, while untargeted adductomics reveal new guanine lesions that engage NER. These findings uncover the nature of endogenous DNA damage and the coordinated roles of repair and tolerance pathways that limit mutagenesis in tissues.

U2 - 10.1038/s41467-025-67072-1

DO - 10.1038/s41467-025-67072-1

M3 - Article

C2 - 41387429

SN - 2041-1723

VL - 17

JO - Nature Communications

JF - Nature Communications

IS - 1

M1 - 436

ER -

Tissue-specific mutagenesis from endogenous guanine damage is suppressed by Polκ and DNA repair

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