A human-specific, concerted repression of microcephaly genes contributes to radiation-induced growth defects in cortical organoids

Jessica Honorato Ribeiro; Emre Etlioglu; Jasmine Buset; Ann Janssen; Hanne Puype; Lisa Berden; André Mbouombouo Mfossa; Winnok H. De Vos; Vanessa Vermeirssen; Sarah Baatout; Nicholas Rajan; Roel Quintens

doi:10.1016/j.isci.2025.111853

A human-specific, concerted repression of microcephaly genes contributes to radiation-induced growth defects in cortical organoids

Jessica Honorato Ribeiro, Emre Etlioglu, Jasmine Buset, Ann Janssen, Hanne Puype, Lisa Berden, André Mbouombouo Mfossa, Winnok H. De Vos, Vanessa Vermeirssen, Sarah Baatout, Nicholas Rajan, Roel Quintens

Research output › peer-review

Abstract

Prenatal radiation-induced DNA damage poses a significant threat to neurodevelopment, resulting in microcephaly which primarily affects the cerebral cortex. So far, mechanistic studies were done in rodents. Here, we leveraged human cortical organoids to model fetal corticogenesis. Organoids were X-irradiated with moderate or high doses at different time points. Irradiation caused a dose- and time-dependent reduction in organoid size, which was more prominent in younger organoids. This coincided with a delayed and attenuated DNA damage response (DDR) in older organoids. Besides the DDR, radiation induced premature differentiation of neural progenitor cells (NPCs). Our transcriptomic analysis demonstrated a concerted p53-E2F4/DREAM-dependent repression of primary microcephaly genes, which was independently confirmed in cultured human NPCs and neurons. This was a human-specific feature, as it was not observed in mouse embryonic brains or primary NPCs. Thus, human cortical organoids are an excellent model for DNA damage-induced microcephaly and to uncover potentially targetable human-specific pathways.

Original language	English
Article number	111853
Number of pages	30
Journal	iScience
Volume	28
Issue number	2
DOIs	https://doi.org/10.1016/j.isci.2025.111853
State	Published - 21 Feb 2025

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10.1016/j.isci.2025.111853

Cite this

Honorato Ribeiro, J., Etlioglu, E., Buset, J., Janssen, A., Puype, H., Berden, L., Mbouombouo Mfossa, A., De Vos, W. H., Vermeirssen, V., Baatout, S., Rajan, N., & Quintens, R. (2025). A human-specific, concerted repression of microcephaly genes contributes to radiation-induced growth defects in cortical organoids. iScience, 28(2), Article 111853. https://doi.org/10.1016/j.isci.2025.111853

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title = "A human-specific, concerted repression of microcephaly genes contributes to radiation-induced growth defects in cortical organoids",

abstract = "Prenatal radiation-induced DNA damage poses a significant threat to neurodevelopment, resulting in microcephaly which primarily affects the cerebral cortex. So far, mechanistic studies were done in rodents. Here, we leveraged human cortical organoids to model fetal corticogenesis. Organoids were X-irradiated with moderate or high doses at different time points. Irradiation caused a dose- and time-dependent reduction in organoid size, which was more prominent in younger organoids. This coincided with a delayed and attenuated DNA damage response (DDR) in older organoids. Besides the DDR, radiation induced premature differentiation of neural progenitor cells (NPCs). Our transcriptomic analysis demonstrated a concerted p53-E2F4/DREAM-dependent repression of primary microcephaly genes, which was independently confirmed in cultured human NPCs and neurons. This was a human-specific feature, as it was not observed in mouse embryonic brains or primary NPCs. Thus, human cortical organoids are an excellent model for DNA damage-induced microcephaly and to uncover potentially targetable human-specific pathways.",

keywords = "DNA damage, MCPH gene repression, Radiation, Prenatal radiation, Developmental neuroscience, Neuroscience",

author = "{Honorato Ribeiro}, Jessica and Emre Etlioglu and Jasmine Buset and Ann Janssen and Hanne Puype and Lisa Berden and {Mbouombouo Mfossa}, Andr{\'e} and {De Vos}, {Winnok H.} and Vanessa Vermeirssen and Sarah Baatout and Nicholas Rajan and Roel Quintens",

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Honorato Ribeiro, J, Etlioglu, E, Buset, J , Janssen, A, Puype, H, Berden, L , Mbouombouo Mfossa, A, De Vos, WH, Vermeirssen, V, Baatout, S, Rajan, N & Quintens, R 2025, 'A human-specific, concerted repression of microcephaly genes contributes to radiation-induced growth defects in cortical organoids', iScience, vol. 28, no. 2, 111853. https://doi.org/10.1016/j.isci.2025.111853

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AU - Honorato Ribeiro, Jessica

AU - Etlioglu, Emre

AU - Buset, Jasmine

AU - Janssen, Ann

AU - Puype, Hanne

AU - Berden, Lisa

AU - Mbouombouo Mfossa, André

AU - De Vos, Winnok H.

AU - Vermeirssen, Vanessa

AU - Baatout, Sarah

AU - Rajan, Nicholas

AU - Quintens, Roel

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N2 - Prenatal radiation-induced DNA damage poses a significant threat to neurodevelopment, resulting in microcephaly which primarily affects the cerebral cortex. So far, mechanistic studies were done in rodents. Here, we leveraged human cortical organoids to model fetal corticogenesis. Organoids were X-irradiated with moderate or high doses at different time points. Irradiation caused a dose- and time-dependent reduction in organoid size, which was more prominent in younger organoids. This coincided with a delayed and attenuated DNA damage response (DDR) in older organoids. Besides the DDR, radiation induced premature differentiation of neural progenitor cells (NPCs). Our transcriptomic analysis demonstrated a concerted p53-E2F4/DREAM-dependent repression of primary microcephaly genes, which was independently confirmed in cultured human NPCs and neurons. This was a human-specific feature, as it was not observed in mouse embryonic brains or primary NPCs. Thus, human cortical organoids are an excellent model for DNA damage-induced microcephaly and to uncover potentially targetable human-specific pathways.

AB - Prenatal radiation-induced DNA damage poses a significant threat to neurodevelopment, resulting in microcephaly which primarily affects the cerebral cortex. So far, mechanistic studies were done in rodents. Here, we leveraged human cortical organoids to model fetal corticogenesis. Organoids were X-irradiated with moderate or high doses at different time points. Irradiation caused a dose- and time-dependent reduction in organoid size, which was more prominent in younger organoids. This coincided with a delayed and attenuated DNA damage response (DDR) in older organoids. Besides the DDR, radiation induced premature differentiation of neural progenitor cells (NPCs). Our transcriptomic analysis demonstrated a concerted p53-E2F4/DREAM-dependent repression of primary microcephaly genes, which was independently confirmed in cultured human NPCs and neurons. This was a human-specific feature, as it was not observed in mouse embryonic brains or primary NPCs. Thus, human cortical organoids are an excellent model for DNA damage-induced microcephaly and to uncover potentially targetable human-specific pathways.

KW - DNA damage

KW - MCPH gene repression

KW - Radiation

KW - Prenatal radiation

KW - Developmental neuroscience

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