DNA methylation protects cancer cells against senescence

Xiaoying Chen; Kosuke Yamaguchi; Brianna Rodgers; Delphine Goehrig; David Vindrieux; Xavier Lahaye; Matthieu Nolot; Laure Ferry; Sophie Lanciano; Nadine Martin; Pierre Dubus; Fumihito Miura; Takashi Ito; Gael Cristofari; Nicolas Manel; Masato T. Kanemaki; David Bernard; Pierre Antoine Defossez

doi:10.1038/s41467-025-61157-7

DNA methylation protects cancer cells against senescence

Xiaoying Chen
, Kosuke Yamaguchi
, Brianna Rodgers
, Delphine Goehrig
, David Vindrieux
, Xavier Lahaye
, Matthieu Nolot
, Laure Ferry
, Sophie Lanciano
, Nadine Martin
, Pierre Dubus
, Fumihito Miura
, Takashi Ito
, Gael Cristofari
, Nicolas Manel
, Masato T. Kanemaki
, David Bernard
, Pierre Antoine Defossez

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

Abstract

Inhibitors of DNA methylation such as 5-aza-deoxycytidine are widely used in experimental and clinical settings. However, their mechanism of action is such that DNA damage inevitably co-occurs with loss of DNA methylation, making it challenging to discern their respective effects. Here we deconvolute the effects of decreased DNA methylation and DNA damage on cancer cells, by using degron alleles of key DNA methylation regulators. We report that cancer cells with decreased DNA methylation—but no DNA damage—enter cellular senescence, with G1 arrest, SASP expression, and SA-β-gal positivity. This senescence is independent of p53 and Rb, but involves p21, which is cytoplasmic and inhibits apoptosis, and cGAS, playing a STING-independent role in the nucleus. Xenograft experiments show that tumor cells can be made senescent in vivo by decreasing DNA methylation. These findings reveal the intrinsic effects of loss of DNA methylation in cancer cells and have practical implications for future therapeutic approaches.

Original language	English
Article number	5901
Journal	Nature Communications
Volume	16
Issue number	1
DOIs	https://doi.org/10.1038/s41467-025-61157-7
Publication status	Published - 1 Dec 2025
Externally published	Yes

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SDG 3 Good Health and Well-being

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10.1038/s41467-025-61157-7

Cite this

Chen, X., Yamaguchi, K., Rodgers, B., Goehrig, D., Vindrieux, D., Lahaye, X., Nolot, M., Ferry, L., Lanciano, S., Martin, N., Dubus, P., Miura, F., Ito, T., Cristofari, G., Manel, N., Kanemaki, M. T., Bernard, D., & Defossez, P. A. (2025). DNA methylation protects cancer cells against senescence. Nature Communications, 16(1), Article 5901. https://doi.org/10.1038/s41467-025-61157-7

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title = "DNA methylation protects cancer cells against senescence",

abstract = "Inhibitors of DNA methylation such as 5-aza-deoxycytidine are widely used in experimental and clinical settings. However, their mechanism of action is such that DNA damage inevitably co-occurs with loss of DNA methylation, making it challenging to discern their respective effects. Here we deconvolute the effects of decreased DNA methylation and DNA damage on cancer cells, by using degron alleles of key DNA methylation regulators. We report that cancer cells with decreased DNA methylation—but no DNA damage—enter cellular senescence, with G1 arrest, SASP expression, and SA-β-gal positivity. This senescence is independent of p53 and Rb, but involves p21, which is cytoplasmic and inhibits apoptosis, and cGAS, playing a STING-independent role in the nucleus. Xenograft experiments show that tumor cells can be made senescent in vivo by decreasing DNA methylation. These findings reveal the intrinsic effects of loss of DNA methylation in cancer cells and have practical implications for future therapeutic approaches.",

author = "Xiaoying Chen and Kosuke Yamaguchi and Brianna Rodgers and Delphine Goehrig and David Vindrieux and Xavier Lahaye and Matthieu Nolot and Laure Ferry and Sophie Lanciano and Nadine Martin and Pierre Dubus and Fumihito Miura and Takashi Ito and Gael Cristofari and Nicolas Manel and Kanemaki, \{Masato T.\} and David Bernard and Defossez, \{Pierre Antoine\}",

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doi = "10.1038/s41467-025-61157-7",

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AU - Chen, Xiaoying

AU - Yamaguchi, Kosuke

AU - Rodgers, Brianna

AU - Goehrig, Delphine

AU - Vindrieux, David

AU - Lahaye, Xavier

AU - Nolot, Matthieu

AU - Ferry, Laure

AU - Lanciano, Sophie

AU - Martin, Nadine

AU - Dubus, Pierre

AU - Miura, Fumihito

AU - Ito, Takashi

AU - Cristofari, Gael

AU - Manel, Nicolas

AU - Kanemaki, Masato T.

AU - Bernard, David

AU - Defossez, Pierre Antoine

PY - 2025/12/1

Y1 - 2025/12/1

N2 - Inhibitors of DNA methylation such as 5-aza-deoxycytidine are widely used in experimental and clinical settings. However, their mechanism of action is such that DNA damage inevitably co-occurs with loss of DNA methylation, making it challenging to discern their respective effects. Here we deconvolute the effects of decreased DNA methylation and DNA damage on cancer cells, by using degron alleles of key DNA methylation regulators. We report that cancer cells with decreased DNA methylation—but no DNA damage—enter cellular senescence, with G1 arrest, SASP expression, and SA-β-gal positivity. This senescence is independent of p53 and Rb, but involves p21, which is cytoplasmic and inhibits apoptosis, and cGAS, playing a STING-independent role in the nucleus. Xenograft experiments show that tumor cells can be made senescent in vivo by decreasing DNA methylation. These findings reveal the intrinsic effects of loss of DNA methylation in cancer cells and have practical implications for future therapeutic approaches.

AB - Inhibitors of DNA methylation such as 5-aza-deoxycytidine are widely used in experimental and clinical settings. However, their mechanism of action is such that DNA damage inevitably co-occurs with loss of DNA methylation, making it challenging to discern their respective effects. Here we deconvolute the effects of decreased DNA methylation and DNA damage on cancer cells, by using degron alleles of key DNA methylation regulators. We report that cancer cells with decreased DNA methylation—but no DNA damage—enter cellular senescence, with G1 arrest, SASP expression, and SA-β-gal positivity. This senescence is independent of p53 and Rb, but involves p21, which is cytoplasmic and inhibits apoptosis, and cGAS, playing a STING-independent role in the nucleus. Xenograft experiments show that tumor cells can be made senescent in vivo by decreasing DNA methylation. These findings reveal the intrinsic effects of loss of DNA methylation in cancer cells and have practical implications for future therapeutic approaches.

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DO - 10.1038/s41467-025-61157-7

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AN - SCOPUS:105009737463

SN - 2041-1723

VL - 16

JO - Nature Communications

JF - Nature Communications

IS - 1

M1 - 5901

ER -

DNA methylation protects cancer cells against senescence

Abstract

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