Efficient mitochondrial A-to-G base editors for the generation of mitochondrial disease models

Liang Chen; Mengjia Hong; Changming Luan; Meng Yuan; Yiming Wang; Xinyuan Guo; Yue Fang; Hao Huang; Xiaohua Dong; Hongyi Gao; Dan Zhang; Xi Chen; Dihao Meng; Molin Huang; Zongyi Yi; Mingyao Liu; Wensheng Wei; Liangcai Gao; Gaojie Song; Xiaoming Zhou; Dali Li

doi:10.1038/s41587-025-02685-x

Efficient mitochondrial A-to-G base editors for the generation of mitochondrial disease models

Liang Chen^*
, Mengjia Hong
, Changming Luan
, Meng Yuan
, Yiming Wang
, Xinyuan Guo
, Yue Fang
, Hao Huang
, Xiaohua Dong
, Hongyi Gao
, Dan Zhang
, Xi Chen
, Dihao Meng
, Molin Huang
, Zongyi Yi
, Mingyao Liu
, Wensheng Wei
, Liangcai Gao
, Gaojie Song
, Xiaoming Zhou

Dali Li^*

^*Corresponding author for this work

School of Life Sciences

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

10 Scopus citations

Abstract

Existing A-to-G base editors for mitochondrial DNA (mtDNA) are limited by low efficiency. We used directed evolution to discover variants of the TadA-8e base editors that have substantially increased activity and expanded targeting compatibility for both nuclear and mitochondrial adenine base editing, especially in previously unfavored sequence contexts. The engineered mtDNA editors (eTd-mtABEs) showed up to 87% editing efficiency in human cells, with greatly reduced DNA and RNA off-target effects. Strand-selective A-to-G editing was enhanced by an average of 3.2-fold with substitution of DddA to DNA nickases in eTd-mtABE backbones compared to mitochondrial ABEs. In rat cells, editing efficiencies of eTd-mtABEs were up to 145-fold higher compared to split DddA transcription activator-like effector-linked deaminase. We also generated rats with sensorineural hearing loss by installing targeted mutations with frequencies of up to 44% through embryonic injection. The developed eTd-mtABEs are efficient and precise mtDNA-engineering tools for basic research and translational studies.

Original language	English
Article number	3210
Journal	Nature Biotechnology
DOIs	https://doi.org/10.1038/s41587-025-02685-x
State	Accepted/In press - 2025

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Chen, L., Hong, M., Luan, C., Yuan, M., Wang, Y., Guo, X., Fang, Y., Huang, H., Dong, X., Gao, H., Zhang, D., Chen, X., Meng, D., Huang, M., Yi, Z., Liu, M., Wei, W., Gao, L., Song, G., ... Li, D. (Accepted/In press). Efficient mitochondrial A-to-G base editors for the generation of mitochondrial disease models. Nature Biotechnology, Article 3210. https://doi.org/10.1038/s41587-025-02685-x

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title = "Efficient mitochondrial A-to-G base editors for the generation of mitochondrial disease models",

abstract = "Existing A-to-G base editors for mitochondrial DNA (mtDNA) are limited by low efficiency. We used directed evolution to discover variants of the TadA-8e base editors that have substantially increased activity and expanded targeting compatibility for both nuclear and mitochondrial adenine base editing, especially in previously unfavored sequence contexts. The engineered mtDNA editors (eTd-mtABEs) showed up to 87\% editing efficiency in human cells, with greatly reduced DNA and RNA off-target effects. Strand-selective A-to-G editing was enhanced by an average of 3.2-fold with substitution of DddA to DNA nickases in eTd-mtABE backbones compared to mitochondrial ABEs. In rat cells, editing efficiencies of eTd-mtABEs were up to 145-fold higher compared to split DddA transcription activator-like effector-linked deaminase. We also generated rats with sensorineural hearing loss by installing targeted mutations with frequencies of up to 44\% through embryonic injection. The developed eTd-mtABEs are efficient and precise mtDNA-engineering tools for basic research and translational studies.",

author = "Liang Chen and Mengjia Hong and Changming Luan and Meng Yuan and Yiming Wang and Xinyuan Guo and Yue Fang and Hao Huang and Xiaohua Dong and Hongyi Gao and Dan Zhang and Xi Chen and Dihao Meng and Molin Huang and Zongyi Yi and Mingyao Liu and Wensheng Wei and Liangcai Gao and Gaojie Song and Xiaoming Zhou and Dali Li",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive licence to Springer Nature America, Inc. 2025.",

year = "2025",

doi = "10.1038/s41587-025-02685-x",

language = "英语",

journal = "Nature Biotechnology",

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T1 - Efficient mitochondrial A-to-G base editors for the generation of mitochondrial disease models

AU - Chen, Liang

AU - Hong, Mengjia

AU - Luan, Changming

AU - Yuan, Meng

AU - Wang, Yiming

AU - Guo, Xinyuan

AU - Fang, Yue

AU - Huang, Hao

AU - Dong, Xiaohua

AU - Gao, Hongyi

AU - Zhang, Dan

AU - Chen, Xi

AU - Meng, Dihao

AU - Huang, Molin

AU - Yi, Zongyi

AU - Liu, Mingyao

AU - Wei, Wensheng

AU - Gao, Liangcai

AU - Song, Gaojie

AU - Zhou, Xiaoming

AU - Li, Dali

PY - 2025

Y1 - 2025

N2 - Existing A-to-G base editors for mitochondrial DNA (mtDNA) are limited by low efficiency. We used directed evolution to discover variants of the TadA-8e base editors that have substantially increased activity and expanded targeting compatibility for both nuclear and mitochondrial adenine base editing, especially in previously unfavored sequence contexts. The engineered mtDNA editors (eTd-mtABEs) showed up to 87% editing efficiency in human cells, with greatly reduced DNA and RNA off-target effects. Strand-selective A-to-G editing was enhanced by an average of 3.2-fold with substitution of DddA to DNA nickases in eTd-mtABE backbones compared to mitochondrial ABEs. In rat cells, editing efficiencies of eTd-mtABEs were up to 145-fold higher compared to split DddA transcription activator-like effector-linked deaminase. We also generated rats with sensorineural hearing loss by installing targeted mutations with frequencies of up to 44% through embryonic injection. The developed eTd-mtABEs are efficient and precise mtDNA-engineering tools for basic research and translational studies.

AB - Existing A-to-G base editors for mitochondrial DNA (mtDNA) are limited by low efficiency. We used directed evolution to discover variants of the TadA-8e base editors that have substantially increased activity and expanded targeting compatibility for both nuclear and mitochondrial adenine base editing, especially in previously unfavored sequence contexts. The engineered mtDNA editors (eTd-mtABEs) showed up to 87% editing efficiency in human cells, with greatly reduced DNA and RNA off-target effects. Strand-selective A-to-G editing was enhanced by an average of 3.2-fold with substitution of DddA to DNA nickases in eTd-mtABE backbones compared to mitochondrial ABEs. In rat cells, editing efficiencies of eTd-mtABEs were up to 145-fold higher compared to split DddA transcription activator-like effector-linked deaminase. We also generated rats with sensorineural hearing loss by installing targeted mutations with frequencies of up to 44% through embryonic injection. The developed eTd-mtABEs are efficient and precise mtDNA-engineering tools for basic research and translational studies.

UR - https://www.scopus.com/pages/publications/105007084964

U2 - 10.1038/s41587-025-02685-x

DO - 10.1038/s41587-025-02685-x

M3 - 文章

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SN - 1087-0156

JO - Nature Biotechnology

JF - Nature Biotechnology

M1 - 3210

ER -

Efficient mitochondrial A-to-G base editors for the generation of mitochondrial disease models

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