Correction of pathogenic mitochondrial DNA in patient-derived disease models using mitochondrial base editors

Indi P Joore; Sawsan Shehata; Irena Muffels; Jose Castro-Alpízar; Elena Jiménez-Curiel; Emilia Nagyova; Natacha Levy; Ziqin Tang; Kimberly Smit; Wilbert P Vermeij; Richard Rodenburg; Raymond Schiffelers; Edward E S Nieuwenhuis; Peter M van Hasselt; Sabine A Fuchs; Martijn A J Koppens

doi:10.1371/journal.pbio.3003207

Correction of pathogenic mitochondrial DNA in patient-derived disease models using mitochondrial base editors

Indi P Joore, Sawsan Shehata, Irena Muffels, Jose Castro-Alpízar, Elena Jiménez-Curiel, Emilia Nagyova, Natacha Levy, Ziqin Tang, Kimberly Smit, Wilbert P Vermeij, Richard Rodenburg, Raymond Schiffelers, Edward E S Nieuwenhuis, Peter M van Hasselt, Sabine A Fuchs, Martijn A J Koppens^*

^*Corresponding author for this work

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

Abstract

Mutations in the mitochondrial genome can cause maternally inherited diseases, cancer, and aging-related conditions. Recent technological progress now enables the creation and correction of mutations in the mitochondrial genome, but it remains relatively unknown how patients with primary mitochondrial disease can benefit from this technology. Here, we demonstrate the potential of the double-stranded DNA deaminase toxin A-derived cytosine base editor (DdCBE) to develop disease models and therapeutic strategies for mitochondrial disease in primary human cells. Introduction of the m.15150G > A mutation in liver organoids resulted in organoid lines with varying degrees of heteroplasmy and correspondingly reduced ATP production, providing a unique model to study functional consequences of different levels of heteroplasmy of this mutation. Correction of the m.4291T > C mutation in patient-derived fibroblasts restored mitochondrial membrane potential. DdCBE generated sustainable edits with high specificity and product purity. To prepare for clinical application, we found that mRNA-mediated mitochondrial base editing resulted in increased efficiency and cellular viability compared to DNA-mediated editing. Moreover, we showed efficient delivery of the mRNA mitochondrial base editors using lipid nanoparticles, which is currently the most advanced non-viral in vivo delivery system for gene products. Our study thus demonstrates the potential of mitochondrial base editing to not only generate unique in vitro models to study these diseases, but also to functionally correct mitochondrial mutations in patient-derived cells for future therapeutic purposes.

Original language	English
Article number	e3003207
Journal	PLoS Biology
Volume	23
Issue number	6
DOIs	https://doi.org/10.1371/journal.pbio.3003207
Publication status	Published - Jun 2025

Keywords

Humans
DNA, Mitochondrial/genetics
Mitochondrial Diseases/genetics
Gene Editing/methods
Mitochondria/genetics
Organoids/metabolism
Mutation
Fibroblasts/metabolism
Genome, Mitochondrial
Membrane Potential, Mitochondrial/genetics

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10.1371/journal.pbio.3003207Licence: CC BY

Correction of pathogenic mitochondrial DNA in patient-derived disease models using mitochondrial base editorsFinal published version, 1.47 MBLicence: CC BY

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Joore, I. P., Shehata, S., Muffels, I., Castro-Alpízar, J., Jiménez-Curiel, E., Nagyova, E., Levy, N., Tang, Z., Smit, K., Vermeij, W. P., Rodenburg, R., Schiffelers, R., Nieuwenhuis, E. E. S., van Hasselt, P. M., Fuchs, S. A., & Koppens, M. A. J. (2025). Correction of pathogenic mitochondrial DNA in patient-derived disease models using mitochondrial base editors. PLoS Biology, 23(6), Article e3003207. https://doi.org/10.1371/journal.pbio.3003207

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title = "Correction of pathogenic mitochondrial DNA in patient-derived disease models using mitochondrial base editors",

abstract = "Mutations in the mitochondrial genome can cause maternally inherited diseases, cancer, and aging-related conditions. Recent technological progress now enables the creation and correction of mutations in the mitochondrial genome, but it remains relatively unknown how patients with primary mitochondrial disease can benefit from this technology. Here, we demonstrate the potential of the double-stranded DNA deaminase toxin A-derived cytosine base editor (DdCBE) to develop disease models and therapeutic strategies for mitochondrial disease in primary human cells. Introduction of the m.15150G > A mutation in liver organoids resulted in organoid lines with varying degrees of heteroplasmy and correspondingly reduced ATP production, providing a unique model to study functional consequences of different levels of heteroplasmy of this mutation. Correction of the m.4291T > C mutation in patient-derived fibroblasts restored mitochondrial membrane potential. DdCBE generated sustainable edits with high specificity and product purity. To prepare for clinical application, we found that mRNA-mediated mitochondrial base editing resulted in increased efficiency and cellular viability compared to DNA-mediated editing. Moreover, we showed efficient delivery of the mRNA mitochondrial base editors using lipid nanoparticles, which is currently the most advanced non-viral in vivo delivery system for gene products. Our study thus demonstrates the potential of mitochondrial base editing to not only generate unique in vitro models to study these diseases, but also to functionally correct mitochondrial mutations in patient-derived cells for future therapeutic purposes.",

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note = "Copyright: {\textcopyright} 2025 Joore et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.",

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Joore, IP, Shehata, S, Muffels, I, Castro-Alpízar, J, Jiménez-Curiel, E, Nagyova, E, Levy, N, Tang, Z, Smit, K, Vermeij, WP, Rodenburg, R, Schiffelers, R , Nieuwenhuis, EES , van Hasselt, PM , Fuchs, SA & Koppens, MAJ 2025, 'Correction of pathogenic mitochondrial DNA in patient-derived disease models using mitochondrial base editors', PLoS Biology, vol. 23, no. 6, e3003207. https://doi.org/10.1371/journal.pbio.3003207

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AU - Joore, Indi P

AU - Shehata, Sawsan

AU - Muffels, Irena

AU - Castro-Alpízar, Jose

AU - Jiménez-Curiel, Elena

AU - Nagyova, Emilia

AU - Levy, Natacha

AU - Tang, Ziqin

AU - Smit, Kimberly

AU - Vermeij, Wilbert P

AU - Rodenburg, Richard

AU - Schiffelers, Raymond

AU - Nieuwenhuis, Edward E S

AU - van Hasselt, Peter M

AU - Fuchs, Sabine A

AU - Koppens, Martijn A J

N1 - Copyright: © 2025 Joore et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

PY - 2025/6

Y1 - 2025/6

N2 - Mutations in the mitochondrial genome can cause maternally inherited diseases, cancer, and aging-related conditions. Recent technological progress now enables the creation and correction of mutations in the mitochondrial genome, but it remains relatively unknown how patients with primary mitochondrial disease can benefit from this technology. Here, we demonstrate the potential of the double-stranded DNA deaminase toxin A-derived cytosine base editor (DdCBE) to develop disease models and therapeutic strategies for mitochondrial disease in primary human cells. Introduction of the m.15150G > A mutation in liver organoids resulted in organoid lines with varying degrees of heteroplasmy and correspondingly reduced ATP production, providing a unique model to study functional consequences of different levels of heteroplasmy of this mutation. Correction of the m.4291T > C mutation in patient-derived fibroblasts restored mitochondrial membrane potential. DdCBE generated sustainable edits with high specificity and product purity. To prepare for clinical application, we found that mRNA-mediated mitochondrial base editing resulted in increased efficiency and cellular viability compared to DNA-mediated editing. Moreover, we showed efficient delivery of the mRNA mitochondrial base editors using lipid nanoparticles, which is currently the most advanced non-viral in vivo delivery system for gene products. Our study thus demonstrates the potential of mitochondrial base editing to not only generate unique in vitro models to study these diseases, but also to functionally correct mitochondrial mutations in patient-derived cells for future therapeutic purposes.

AB - Mutations in the mitochondrial genome can cause maternally inherited diseases, cancer, and aging-related conditions. Recent technological progress now enables the creation and correction of mutations in the mitochondrial genome, but it remains relatively unknown how patients with primary mitochondrial disease can benefit from this technology. Here, we demonstrate the potential of the double-stranded DNA deaminase toxin A-derived cytosine base editor (DdCBE) to develop disease models and therapeutic strategies for mitochondrial disease in primary human cells. Introduction of the m.15150G > A mutation in liver organoids resulted in organoid lines with varying degrees of heteroplasmy and correspondingly reduced ATP production, providing a unique model to study functional consequences of different levels of heteroplasmy of this mutation. Correction of the m.4291T > C mutation in patient-derived fibroblasts restored mitochondrial membrane potential. DdCBE generated sustainable edits with high specificity and product purity. To prepare for clinical application, we found that mRNA-mediated mitochondrial base editing resulted in increased efficiency and cellular viability compared to DNA-mediated editing. Moreover, we showed efficient delivery of the mRNA mitochondrial base editors using lipid nanoparticles, which is currently the most advanced non-viral in vivo delivery system for gene products. Our study thus demonstrates the potential of mitochondrial base editing to not only generate unique in vitro models to study these diseases, but also to functionally correct mitochondrial mutations in patient-derived cells for future therapeutic purposes.

KW - Humans

KW - DNA, Mitochondrial/genetics

KW - Mitochondrial Diseases/genetics

KW - Gene Editing/methods

KW - Mitochondria/genetics

KW - Organoids/metabolism

KW - Mutation

KW - Fibroblasts/metabolism

KW - Genome, Mitochondrial

KW - Membrane Potential, Mitochondrial/genetics

U2 - 10.1371/journal.pbio.3003207

DO - 10.1371/journal.pbio.3003207

M3 - Article

C2 - 40554457

SN - 1544-9173

VL - 23

JO - PLoS Biology

JF - PLoS Biology

IS - 6

M1 - e3003207

ER -

Correction of pathogenic mitochondrial DNA in patient-derived disease models using mitochondrial base editors

Abstract

Keywords

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