Re-epithelialization of cancer cells increases autophagy and DNA damage: Implications for breast cancer dormancy and relapse

Diana Drago-Garcia; Suvendu Giri; Rishita Chatterjee; Arturo Simoni-Nieves; Maha Abedrabbo; Alessandro Genna; Mary Luz Uribe Rios; Moshit Lindzen; Arunachalam Sekar; Nitin Gupta; Noa Aharoni; Tithi Bhandari; Agalyan Mayalagu; Luisa Schwarzmüller; Nooraldeen Tarade; Rong Zhu; Harsha Raj Mohan-Raju; Feride Karatekin; Francesco Roncato; Yaniv Eyal-Lubling; Tal Keidar; Yam Nof; Nishanth Belugali Nataraj; Karin Shira Bernshtein; Bettina Wagner; Nishanth Ulhas Nair; Neel Sanghvi; Ronen Alon; Rony Seger; Eli Pikarsky; Sara Donzelli; Giovanni Blandino; Stefan Wiemann; Sima Lev; Ron Prywes; Dalit Barkan; Oscar M. Rueda; Carlos Caldas; Eytan Ruppin; Yosef Shiloh; Maik Dahlhoff; Yosef Yarden

doi:10.1126/scisignal.ado3473

Re-epithelialization of cancer cells increases autophagy and DNA damage: Implications for breast cancer dormancy and relapse

Diana Drago-Garcia, Suvendu Giri, Rishita Chatterjee, Arturo Simoni-Nieves, Maha Abedrabbo, Alessandro Genna, Mary Luz Uribe Rios, Moshit Lindzen, Arunachalam Sekar, Nitin Gupta, Noa Aharoni, Tithi Bhandari, Agalyan Mayalagu, Luisa Schwarzmüller, Nooraldeen Tarade, Rong Zhu, Harsha Raj Mohan-Raju, Feride Karatekin, Francesco Roncato, Yaniv Eyal-LublingTal Keidar, Yam Nof, Nishanth Belugali Nataraj, Karin Shira Bernshtein, Bettina Wagner, Nishanth Ulhas Nair, Neel Sanghvi, Ronen Alon, Rony Seger, Eli Pikarsky, Sara Donzelli, Giovanni Blandino, Stefan Wiemann, Sima Lev, Ron Prywes, Dalit Barkan, Oscar M. Rueda, Carlos Caldas, Eytan Ruppin, Yosef Shiloh, Maik Dahlhoff, Yosef Yarden^*

^*Corresponding author for this work

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

Abstract

Cellular plasticity mediates tissue development as well as cancer growth and progression. In breast cancer, a shift to a more epithelial phenotype (epithelialization) underlies a state of reversible cell growth arrest called tumor dormancy, which enables drug resistance, tumor recurrence, and metastasis. Here, we explored the mechanisms driving epithelialization and dormancy in aggressive mesenchymal-like breast cancer cells in three-dimensional cultures. Overexpressing either of the epithelial lineage-associated transcription factors OVOL1 or OVOL2 suppressed cell proliferation and migration and promoted transition to an epithelial morphology. The expression of OVOL1 (and of OVOL2 to a lesser extent) was regulated by steroid hormones and growth factors and was more abundant in tumors than in normal mammary cells. An uncharacterized and indirect target of OVOL1/2, C1ORF116, exhibited genetic and epigenetic aberrations in breast tumors, and its expression correlated with poor prognosis in patients. We further found that C1ORF116 was an autophagy receptor that directed the degradation of antioxidant proteins, including thioredoxin. Through C1ORF116 and unidentified mediators, OVOL1 expression dysregulated both redox homeostasis (in association with increased ROS, decreased glutathione, and redistribution of the transcription factor NRF2) and DNA damage and repair (in association with increased DNA oxidation and double-strand breaks and an altered interplay among the kinases p38-MAPK, ATM, and others). Because these effects, as they accumulate in cells, can promote metastasis and dormancy escape, the findings suggest that OVOLs not only promote dormancy entry and maintenance in breast cancer but also may ultimately drive dormancy exit and tumor recurrence.

Original language	English
Article number	eado3473
Journal	Science Signaling
Volume	18
Issue number	883
DOIs	https://doi.org/10.1126/scisignal.ado3473
Publication status	Published - 22 Apr 2025

Funding

We thank all members of our laboratory for insightful comments. In addition, we thank M. Itkin, S. Malitsky, N. Wigoda, S. Ben-Dor, H. Keren-Shaul, Y. Vinik, and M. Kedmi for performing specific analyses. We also thank U. Klingmüller, D. Helm, and J. Krijgsvels for providing MS measurement time on an MSCoreSys-funded instrument. This work was performed in the Marvin Tanner Laboratory for Research on Cancer. Y.Y. is the incumbent of the Harold and Zelda Goldenberg Professorial Chair in Molecular Cell Biology. Funding: This work was supported by the Israel Science Foundation, the European Research Council, the Israel Cancer Research Fund, and the Dr. Miriam and Sheldon G. Adelson Medical Research Foundation. This work was additionally supported by the Intramural Research Program of the National Institutes of Health and the National Cancer Institute Center for Cancer Research (to N.U.N.) as well as the Israel Ministry of Science and Technology (to D.B.).

All Science Journal Classification (ASJC) codes

Biochemistry
Molecular Biology
Cell Biology

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10.1126/scisignal.ado3473

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Drago-Garcia, D., Giri, S., Chatterjee, R., Simoni-Nieves, A., Abedrabbo, M., Genna, A., Uribe Rios, M. L., Lindzen, M., Sekar, A., Gupta, N., Aharoni, N., Bhandari, T., Mayalagu, A., Schwarzmüller, L., Tarade, N., Zhu, R., Mohan-Raju, H. R., Karatekin, F., Roncato, F., ... Yarden, Y. (2025). Re-epithelialization of cancer cells increases autophagy and DNA damage: Implications for breast cancer dormancy and relapse. Science Signaling, 18(883), Article eado3473. https://doi.org/10.1126/scisignal.ado3473

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title = "Re-epithelialization of cancer cells increases autophagy and DNA damage: Implications for breast cancer dormancy and relapse",

abstract = "Cellular plasticity mediates tissue development as well as cancer growth and progression. In breast cancer, a shift to a more epithelial phenotype (epithelialization) underlies a state of reversible cell growth arrest called tumor dormancy, which enables drug resistance, tumor recurrence, and metastasis. Here, we explored the mechanisms driving epithelialization and dormancy in aggressive mesenchymal-like breast cancer cells in three-dimensional cultures. Overexpressing either of the epithelial lineage-associated transcription factors OVOL1 or OVOL2 suppressed cell proliferation and migration and promoted transition to an epithelial morphology. The expression of OVOL1 (and of OVOL2 to a lesser extent) was regulated by steroid hormones and growth factors and was more abundant in tumors than in normal mammary cells. An uncharacterized and indirect target of OVOL1/2, C1ORF116, exhibited genetic and epigenetic aberrations in breast tumors, and its expression correlated with poor prognosis in patients. We further found that C1ORF116 was an autophagy receptor that directed the degradation of antioxidant proteins, including thioredoxin. Through C1ORF116 and unidentified mediators, OVOL1 expression dysregulated both redox homeostasis (in association with increased ROS, decreased glutathione, and redistribution of the transcription factor NRF2) and DNA damage and repair (in association with increased DNA oxidation and double-strand breaks and an altered interplay among the kinases p38-MAPK, ATM, and others). Because these effects, as they accumulate in cells, can promote metastasis and dormancy escape, the findings suggest that OVOLs not only promote dormancy entry and maintenance in breast cancer but also may ultimately drive dormancy exit and tumor recurrence.",

author = "Diana Drago-Garcia and Suvendu Giri and Rishita Chatterjee and Arturo Simoni-Nieves and Maha Abedrabbo and Alessandro Genna and {Uribe Rios}, {Mary Luz} and Moshit Lindzen and Arunachalam Sekar and Nitin Gupta and Noa Aharoni and Tithi Bhandari and Agalyan Mayalagu and Luisa Schwarzm{\"u}ller and Nooraldeen Tarade and Rong Zhu and Mohan-Raju, {Harsha Raj} and Feride Karatekin and Francesco Roncato and Yaniv Eyal-Lubling and Tal Keidar and Yam Nof and Nataraj, {Nishanth Belugali} and Bernshtein, {Karin Shira} and Bettina Wagner and Nair, {Nishanth Ulhas} and Neel Sanghvi and Ronen Alon and Rony Seger and Eli Pikarsky and Sara Donzelli and Giovanni Blandino and Stefan Wiemann and Sima Lev and Ron Prywes and Dalit Barkan and Rueda, {Oscar M.} and Carlos Caldas and Eytan Ruppin and Yosef Shiloh and Maik Dahlhoff and Yosef Yarden",

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year = "2025",

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doi = "10.1126/scisignal.ado3473",

language = "English",

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journal = "Science Signaling",

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Drago-Garcia, D, Giri, S , Chatterjee, R , Simoni-Nieves, A , Abedrabbo, M , Genna, A, Uribe Rios, ML, Lindzen, M, Sekar, A, Gupta, N , Aharoni, N , Bhandari, T, Mayalagu, A, Schwarzmüller, L, Tarade, N, Zhu, R, Mohan-Raju, HR, Karatekin, F, Roncato, F, Eyal-Lubling, Y, Keidar, T, Nof, Y, Nataraj, NB, Bernshtein, KS, Wagner, B, Nair, NU, Sanghvi, N, Alon, R , Seger, R, Pikarsky, E, Donzelli, S, Blandino, G, Wiemann, S, Lev, S, Prywes, R, Barkan, D, Rueda, OM, Caldas, C, Ruppin, E, Shiloh, Y, Dahlhoff, M & Yarden, Y 2025, 'Re-epithelialization of cancer cells increases autophagy and DNA damage: Implications for breast cancer dormancy and relapse', Science Signaling, vol. 18, no. 883, eado3473. https://doi.org/10.1126/scisignal.ado3473

TY - JOUR

T1 - Re-epithelialization of cancer cells increases autophagy and DNA damage

T2 - Implications for breast cancer dormancy and relapse

AU - Drago-Garcia, Diana

AU - Giri, Suvendu

AU - Chatterjee, Rishita

AU - Simoni-Nieves, Arturo

AU - Abedrabbo, Maha

AU - Genna, Alessandro

AU - Uribe Rios, Mary Luz

AU - Lindzen, Moshit

AU - Sekar, Arunachalam

AU - Gupta, Nitin

AU - Aharoni, Noa

AU - Bhandari, Tithi

AU - Mayalagu, Agalyan

AU - Schwarzmüller, Luisa

AU - Tarade, Nooraldeen

AU - Zhu, Rong

AU - Mohan-Raju, Harsha Raj

AU - Karatekin, Feride

AU - Roncato, Francesco

AU - Eyal-Lubling, Yaniv

AU - Keidar, Tal

AU - Nof, Yam

AU - Nataraj, Nishanth Belugali

AU - Bernshtein, Karin Shira

AU - Wagner, Bettina

AU - Nair, Nishanth Ulhas

AU - Sanghvi, Neel

AU - Alon, Ronen

AU - Seger, Rony

AU - Pikarsky, Eli

AU - Donzelli, Sara

AU - Blandino, Giovanni

AU - Wiemann, Stefan

AU - Lev, Sima

AU - Prywes, Ron

AU - Barkan, Dalit

AU - Rueda, Oscar M.

AU - Caldas, Carlos

AU - Ruppin, Eytan

AU - Shiloh, Yosef

AU - Dahlhoff, Maik

AU - Yarden, Yosef

PY - 2025/4/22

Y1 - 2025/4/22

N2 - Cellular plasticity mediates tissue development as well as cancer growth and progression. In breast cancer, a shift to a more epithelial phenotype (epithelialization) underlies a state of reversible cell growth arrest called tumor dormancy, which enables drug resistance, tumor recurrence, and metastasis. Here, we explored the mechanisms driving epithelialization and dormancy in aggressive mesenchymal-like breast cancer cells in three-dimensional cultures. Overexpressing either of the epithelial lineage-associated transcription factors OVOL1 or OVOL2 suppressed cell proliferation and migration and promoted transition to an epithelial morphology. The expression of OVOL1 (and of OVOL2 to a lesser extent) was regulated by steroid hormones and growth factors and was more abundant in tumors than in normal mammary cells. An uncharacterized and indirect target of OVOL1/2, C1ORF116, exhibited genetic and epigenetic aberrations in breast tumors, and its expression correlated with poor prognosis in patients. We further found that C1ORF116 was an autophagy receptor that directed the degradation of antioxidant proteins, including thioredoxin. Through C1ORF116 and unidentified mediators, OVOL1 expression dysregulated both redox homeostasis (in association with increased ROS, decreased glutathione, and redistribution of the transcription factor NRF2) and DNA damage and repair (in association with increased DNA oxidation and double-strand breaks and an altered interplay among the kinases p38-MAPK, ATM, and others). Because these effects, as they accumulate in cells, can promote metastasis and dormancy escape, the findings suggest that OVOLs not only promote dormancy entry and maintenance in breast cancer but also may ultimately drive dormancy exit and tumor recurrence.

AB - Cellular plasticity mediates tissue development as well as cancer growth and progression. In breast cancer, a shift to a more epithelial phenotype (epithelialization) underlies a state of reversible cell growth arrest called tumor dormancy, which enables drug resistance, tumor recurrence, and metastasis. Here, we explored the mechanisms driving epithelialization and dormancy in aggressive mesenchymal-like breast cancer cells in three-dimensional cultures. Overexpressing either of the epithelial lineage-associated transcription factors OVOL1 or OVOL2 suppressed cell proliferation and migration and promoted transition to an epithelial morphology. The expression of OVOL1 (and of OVOL2 to a lesser extent) was regulated by steroid hormones and growth factors and was more abundant in tumors than in normal mammary cells. An uncharacterized and indirect target of OVOL1/2, C1ORF116, exhibited genetic and epigenetic aberrations in breast tumors, and its expression correlated with poor prognosis in patients. We further found that C1ORF116 was an autophagy receptor that directed the degradation of antioxidant proteins, including thioredoxin. Through C1ORF116 and unidentified mediators, OVOL1 expression dysregulated both redox homeostasis (in association with increased ROS, decreased glutathione, and redistribution of the transcription factor NRF2) and DNA damage and repair (in association with increased DNA oxidation and double-strand breaks and an altered interplay among the kinases p38-MAPK, ATM, and others). Because these effects, as they accumulate in cells, can promote metastasis and dormancy escape, the findings suggest that OVOLs not only promote dormancy entry and maintenance in breast cancer but also may ultimately drive dormancy exit and tumor recurrence.

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U2 - 10.1126/scisignal.ado3473

DO - 10.1126/scisignal.ado3473

M3 - Article

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AN - SCOPUS:105003610895

SN - 1945-0877

VL - 18

JO - Science Signaling

JF - Science Signaling

IS - 883

M1 - eado3473

ER -

Re-epithelialization of cancer cells increases autophagy and DNA damage: Implications for breast cancer dormancy and relapse

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