Increased DNA damage in full-grown oocytes is correlated with diminished autophagy activation

Fei Sun; Nourhan Nashat Ali; Daniela Londoño-Vásquez; Constantine A. Simintiras; Huanyu Qiao; M. Sofia Ortega; Yuksel Agca; Masashi Takahashi; Rocío M. Rivera; Andrew M. Kelleher; Peter Sutovsky; Amanda L. Patterson; Ahmed Z. Balboula

doi:10.1038/s41467-024-53559-w

Increased DNA damage in full-grown oocytes is correlated with diminished autophagy activation

Fei Sun, Nourhan Nashat Ali, Daniela Londoño-Vásquez, Constantine A. Simintiras, Huanyu Qiao, M. Sofia Ortega, Yuksel Agca, Masashi Takahashi, Rocío M. Rivera, Andrew M. Kelleher, Peter Sutovsky, Amanda L. Patterson, Ahmed Z. Balboula

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

Abstract

Unlike mild DNA damage exposure, DNA damage repair (DDR) is reported to be ineffective in full-grown mammalian oocytes exposed to moderate or severe DNA damage. The underlying mechanisms of this weakened DDR are unknown. Here, we show that moderate DNA damage in full-grown oocytes leads to aneuploidy. Our data reveal that DNA-damaged oocytes have an altered, closed, chromatin state, and suggest that the failure to repair damaged DNA could be due to the inability of DDR proteins to access damaged loci. Our data also demonstrate that, unlike somatic cells, mouse and porcine oocytes fail to activate autophagy in response to DNA double-strand break-inducing treatment, which we suggest may be the cause of the altered chromatin conformation and inefficient DDR. Importantly, autophagy activity is further reduced in maternally aged oocytes (which harbor severe DNA damage), and its induction is correlated with reduced DNA damage in maternally aged oocytes. Our findings provide evidence that reduced autophagy activation contributes to weakened DDR in oocytes, especially in those from aged females, offering new possibilities to improve assisted reproductive therapy in women with compromised oocyte quality.

Original language	English (US)
Article number	9463
Journal	Nature communications
Volume	15
Issue number	1
DOIs	https://doi.org/10.1038/s41467-024-53559-w
State	Published - Dec 2024

ASJC Scopus subject areas

General Chemistry
General Biochemistry, Genetics and Molecular Biology
General Physics and Astronomy

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10.1038/s41467-024-53559-w

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Sun, F., Ali, N. N., Londoño-Vásquez, D., Simintiras, C. A., Qiao, H., Ortega, M. S., Agca, Y., Takahashi, M., Rivera, R. M., Kelleher, A. M., Sutovsky, P., Patterson, A. L., & Balboula, A. Z. (2024). Increased DNA damage in full-grown oocytes is correlated with diminished autophagy activation. Nature communications, 15(1), Article 9463. https://doi.org/10.1038/s41467-024-53559-w

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title = "Increased DNA damage in full-grown oocytes is correlated with diminished autophagy activation",

abstract = "Unlike mild DNA damage exposure, DNA damage repair (DDR) is reported to be ineffective in full-grown mammalian oocytes exposed to moderate or severe DNA damage. The underlying mechanisms of this weakened DDR are unknown. Here, we show that moderate DNA damage in full-grown oocytes leads to aneuploidy. Our data reveal that DNA-damaged oocytes have an altered, closed, chromatin state, and suggest that the failure to repair damaged DNA could be due to the inability of DDR proteins to access damaged loci. Our data also demonstrate that, unlike somatic cells, mouse and porcine oocytes fail to activate autophagy in response to DNA double-strand break-inducing treatment, which we suggest may be the cause of the altered chromatin conformation and inefficient DDR. Importantly, autophagy activity is further reduced in maternally aged oocytes (which harbor severe DNA damage), and its induction is correlated with reduced DNA damage in maternally aged oocytes. Our findings provide evidence that reduced autophagy activation contributes to weakened DDR in oocytes, especially in those from aged females, offering new possibilities to improve assisted reproductive therapy in women with compromised oocyte quality.",

author = "Fei Sun and Ali, {Nourhan Nashat} and Daniela Londo{\~n}o-V{\'a}squez and Simintiras, {Constantine A.} and Huanyu Qiao and Ortega, {M. Sofia} and Yuksel Agca and Masashi Takahashi and Rivera, {Roc{\'i}o M.} and Kelleher, {Andrew M.} and Peter Sutovsky and Patterson, {Amanda L.} and Balboula, {Ahmed Z.}",

note = "We would like to thank all Balboula lab members, Luhui Zhang and Jason Rizo for their valuable help and support. The authors thank Zhiyuan Chen for his technical expertise and valuable help. The authors also thank Wen-Xing Ding for sharing Atg5flox/flox mice from his laboratory colony. This research was supported by a research grant from the American Society for Reproductive Medicine, the NIH (R35 GM142537), the NIH (R01 HD113358) and the National Institute of Food and Agriculture, grant number 2022-67015-36301 to A.Z.B. P.S. was funded by USDA National Institute of Food and Agriculture, Agriculture and Food Research Initiative Competitive grant number 2020-67015-31017 and seed funding from the College of Agriculture, Food and Natural Resources, University of Missouri.",

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doi = "10.1038/s41467-024-53559-w",

language = "English (US)",

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T1 - Increased DNA damage in full-grown oocytes is correlated with diminished autophagy activation

AU - Sun, Fei

AU - Ali, Nourhan Nashat

AU - Londoño-Vásquez, Daniela

AU - Simintiras, Constantine A.

AU - Qiao, Huanyu

AU - Ortega, M. Sofia

AU - Agca, Yuksel

AU - Takahashi, Masashi

AU - Rivera, Rocío M.

AU - Kelleher, Andrew M.

AU - Sutovsky, Peter

AU - Patterson, Amanda L.

AU - Balboula, Ahmed Z.

N1 - We would like to thank all Balboula lab members, Luhui Zhang and Jason Rizo for their valuable help and support. The authors thank Zhiyuan Chen for his technical expertise and valuable help. The authors also thank Wen-Xing Ding for sharing Atg5flox/flox mice from his laboratory colony. This research was supported by a research grant from the American Society for Reproductive Medicine, the NIH (R35 GM142537), the NIH (R01 HD113358) and the National Institute of Food and Agriculture, grant number 2022-67015-36301 to A.Z.B. P.S. was funded by USDA National Institute of Food and Agriculture, Agriculture and Food Research Initiative Competitive grant number 2020-67015-31017 and seed funding from the College of Agriculture, Food and Natural Resources, University of Missouri.

PY - 2024/12

Y1 - 2024/12

N2 - Unlike mild DNA damage exposure, DNA damage repair (DDR) is reported to be ineffective in full-grown mammalian oocytes exposed to moderate or severe DNA damage. The underlying mechanisms of this weakened DDR are unknown. Here, we show that moderate DNA damage in full-grown oocytes leads to aneuploidy. Our data reveal that DNA-damaged oocytes have an altered, closed, chromatin state, and suggest that the failure to repair damaged DNA could be due to the inability of DDR proteins to access damaged loci. Our data also demonstrate that, unlike somatic cells, mouse and porcine oocytes fail to activate autophagy in response to DNA double-strand break-inducing treatment, which we suggest may be the cause of the altered chromatin conformation and inefficient DDR. Importantly, autophagy activity is further reduced in maternally aged oocytes (which harbor severe DNA damage), and its induction is correlated with reduced DNA damage in maternally aged oocytes. Our findings provide evidence that reduced autophagy activation contributes to weakened DDR in oocytes, especially in those from aged females, offering new possibilities to improve assisted reproductive therapy in women with compromised oocyte quality.

AB - Unlike mild DNA damage exposure, DNA damage repair (DDR) is reported to be ineffective in full-grown mammalian oocytes exposed to moderate or severe DNA damage. The underlying mechanisms of this weakened DDR are unknown. Here, we show that moderate DNA damage in full-grown oocytes leads to aneuploidy. Our data reveal that DNA-damaged oocytes have an altered, closed, chromatin state, and suggest that the failure to repair damaged DNA could be due to the inability of DDR proteins to access damaged loci. Our data also demonstrate that, unlike somatic cells, mouse and porcine oocytes fail to activate autophagy in response to DNA double-strand break-inducing treatment, which we suggest may be the cause of the altered chromatin conformation and inefficient DDR. Importantly, autophagy activity is further reduced in maternally aged oocytes (which harbor severe DNA damage), and its induction is correlated with reduced DNA damage in maternally aged oocytes. Our findings provide evidence that reduced autophagy activation contributes to weakened DDR in oocytes, especially in those from aged females, offering new possibilities to improve assisted reproductive therapy in women with compromised oocyte quality.

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JO - Nature communications

JF - Nature communications

IS - 1

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ER -

Increased DNA damage in full-grown oocytes is correlated with diminished autophagy activation

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