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7. Correcting a pathogenic mitochondrial DNA mutation by base editing in mice.

Author

Barrera-Paez, Jose D., Bacman, Sandra R., Balla, Till, Van Booven, Derek, Gannamedi, Durga P., Stewart, James B., Mok, Beverly, Liu, David R., Lombard, David B., Griswold, Anthony J., Nedialkova, Danny D., and Moraes, Carlos T.

Subjects
GENOME editing, MYOCARDIUM, MITOCHONDRIAL DNA, TRANSFER RNA, MITOCHONDRIAL pathology
Abstract

Primary mitochondrial disorders are most often caused by deleterious mutations in the mitochondrial DNA (mtDNA). Here, we used a mitochondrial DddA-derived cytosine base editor (DdCBE) to introduce a compensatory edit in a mouse model that carries the pathological mutation in the mitochondrial transfer RNA (tRNA) alanine (mt-tRNAAla) gene. Because the original m.5024C→T mutation (G→A in the mt-tRNAAla) destabilizes the mt-tRNAAla aminoacyl stem, we designed a compensatory m.5081G→A edit (C→T in the mt-tRNAAla) that could restore the secondary structure of the tRNAAla aminoacyl stem. For this, the DdCBE gene construct was initially tested in an m.5024C→T mutant cell line. The reduced mt-tRNAAla amounts in these cells were increased after editing up to 78% of the mtDNA. Then, DdCBE was packaged in recombinant adeno-associated virus 9 (AAV9) and intravenously administered by retro-orbital injections into mice. Expression of the transduced DdCBE was observed in the heart and skeletal muscle. Total mt-tRNAAla amounts were restored in heart and muscle by the m.5081G→A edit in a dose-dependent manner. Lactate amounts, which were increased in the heart, were also decreased in treated mice. However, the highest dose tested of AAV9-DdCBE also induced severe adverse effects in vivo because of the extensive mtDNA off-target editing that it generated. These results show that although DdCBE is a promising gene therapy tool for mitochondrial disorders, the doses of the therapeutic constructs must be carefully monitored to avoid deleterious off-target editing. Editor's summary: Mitochondrial disorders are inherited and often linked to mitochondrial DNA (mtDNA) mutations. Pathologically mutated mtDNA can cause diverse physiological dysfunction that is limited to palliative care. Barrera-Paez et al. used a mitochondrial DddA-derived cytosine base editor (DdCBE) to correct a mutation in the mtDNA encoding a mitochondrial transfer RNA (tRNA) alanine. The mutation disrupted the aminoacyl stem of the tRNA. Correction with DdCBE restored the structure and amounts of the tRNA in cell culture and in mouse heart and muscle tissue. Mice carrying the mtDNA mutation had low mitochondrial tRNA alanine and increased lactate in heart, and editing with DdCBE reversed these abnormalities. At the highest amounts of editing, DdCBE also induced off-target edits that resulted in severe adverse effects in mice. These data suggest that while DdCBE is a promising therapeutic avenue for mitochondrial gene editing, caution and further study are warranted to avoid damaging off-target effects. —Brandon Berry [ABSTRACT FROM AUTHOR]

Published
2025
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13. List of Contributors

Author

Achilli, Alessandro, primary, Attimonelli, Marcella, additional, Bacman, Sandra R., additional, Barrientos, Antoni, additional, Berridge, Michael V., additional, Burr, Stephen P., additional, Calabrese, Claudia, additional, Calabrese, Francesco Maria, additional, Chinnery, Patrick F., additional, De Luise, Monica, additional, Diaz, Francisca, additional, Doimo, Mara, additional, Fontanesi, Flavia, additional, Fu, Yi, additional, Gammage, Payam A., additional, Garone, Caterina, additional, Gasparre, Giuseppe, additional, Ghelli, Anna, additional, Girolimetti, Giulia, additional, Glasgow, Ruth I.C., additional, Gomez-Duran, Aurora, additional, Grasso, Carole, additional, Herst, Patries M., additional, Holt, Ian James, additional, Iommarini, Luisa, additional, Kang, Dongchon, additional, Kurelac, Ivana, additional, Lim, Albert Z., additional, Lott, Marie T., additional, Matsuda, Shigeru, additional, McFarland, Robert, additional, Minczuk, Michal, additional, Moraes, Carlos T., additional, Nicholls, Thomas J., additional, Oláhová, Monika, additional, Olivieri, Anna, additional, Pfeiffer, Annika, additional, Pinheiro, Pedro, additional, Pitceathly, Robert D.S., additional, Porcelli, Anna Maria, additional, Preste, Roberto, additional, Procaccio, Vincent, additional, Quadalti, Corinne, additional, Rahman, Shamima, additional, Reyes, Aurelio, additional, Semino, Ornella, additional, Sfeir, Agnel, additional, Shiping, Zhang, additional, Sia, Elaine Ayres, additional, Spinazzola, Antonella, additional, Stein, Alexis, additional, Szczepanowska, Karolina, additional, Tagliabracci, Adriano, additional, Taylor, Robert W., additional, Tigano, Marco, additional, Torroni, Antonio, additional, Trifunovic, Aleksandra, additional, Turchi, Chiara, additional, Vitale, Ornella, additional, Wallace, Douglas C., additional, Wanrooij, Paulina H., additional, Wanrooij, Sjoerd, additional, and Yasukawa, Takehiro, additional

Published
2020
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18. Selective Elimination of Mitochondrial Mutations in the Germline by Genome Editing

Author

Reddy, Pradeep, Ocampo, Alejandro, Suzuki, Keiichiro, Luo, Jinping, Bacman, Sandra R., Williams, Sion L., Sugawara, Atsushi, Okamura, Daiji, Tsunekawa, Yuji, Wu, Jun, Lam, David, Xiong, Xiong, Montserrat, Nuria, Esteban, Concepcion Rodriguez, Liu, Guang-Hui, Sancho-Martinez, Ignacio, Manau, Dolors, Civico, Salva, Cardellach, Francesc, del Mar O’Callaghan, Maria, Campistol, Jaime, Zhao, Huimin, Campistol, Josep M., Moraes, Carlos T., and Izpisua Belmonte, Juan Carlos

Published
2015
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20. Emerging Therapeutic Approaches to Mitochondrial Diseases

Author

Wenz, Tina, Williams, Sion L., and Bacman, Sandra R.

Abstract

Mitochondrial diseases are very heterogeneous and can affect different tissues and organs. Moreover, they can be caused by genetic defects in either nuclear or mitochondrial DNA as well as by environmental factors. All of these factors have made the development of therapies difficult. In this review article, we will discuss emerging approaches to the therapy of mitochondrial disorders, some of which are targeted to specific conditions whereas others may be applicable to a more diverse group of patients. (Contains 1 figure.)

Published
2010
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22. Specific elimination of mutant mitochondrial genomes in patient-derived cells by mitoTALENs

Author

Bacman, Sandra R., Williams, Sion L., Pinto, Milena, Peralta, Susana, and Moraes, Carlos T.

Subjects
Physiological aspects, Properties, Gene mutation -- Physiological aspects, Nucleases -- Properties, Mitochondrial DNA -- Properties, Gene mutations -- Physiological aspects
Abstract

Mitochondrial diseases are commonly caused by mutated mitochondrial DNA (mtDNA), which in most cases coexists with wild-type mtDNA, resulting in mtDNA heteroplasmy. We have engineered transcription activator-like effector nucleases (TALENs) [...]

Published
2013
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32. mitoTev‐TALE: a monomeric DNA editing enzyme to reduce mutant mitochondrial DNA levels

Author

Pereira, Claudia V, Bacman, Sandra R, Arguello, Tania, Ugne Zekonyte, Williams, Sion L, Edgell, David R, and Moraes, Carlos T

Subjects
FOS: Biological sciences, Genetics, Biological Techniques, Cell Biology, Molecular Biology
Abstract

This work describes the development of a mitochondrial‐targeted DNA editing enzyme that can specifically cleave the MERRF m.8344A>G mtDNA mutation. The novel feature of this enzyme is that it is monomeric, in contrast to mitoTALEN and mitoZFN, which are heterodimeric.

Published
2019
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36. Transient mitochondrial DNA double strand breaks in mice cause accelerated aging phenotypes in a ROS-dependent but p53/p21-independent manner

Author

Pinto, Milena, primary, Pickrell, Alicia M, additional, Wang, Xiao, additional, Bacman, Sandra R, additional, Yu, Aixin, additional, Hida, Aline, additional, Dillon, Lloye M, additional, Morton, Paul D, additional, Malek, Thomas R, additional, Williams, Siôn L, additional, and Moraes, Carlos T, additional

Published
2016
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38. MitoTALEN reduces mutant mtDNA load and restores tRNAAlalevels in a mouse model of heteroplasmic mtDNA mutation

Author

Bacman, Sandra R., Kauppila, Johanna H. K., Pereira, Claudia V., Nissanka, Nadee, Miranda, Maria, Pinto, Milena, Williams, Sion L., Larsson, Nils-Göran, Stewart, James B., and Moraes, Carlos T.

Abstract

Mutations in the mitochondrial DNA (mtDNA) are responsible for several metabolic disorders, commonly involving muscle and the central nervous system1. Because of the critical role of mtDNA in oxidative phosphorylation, the majority of pathogenic mtDNA mutations are heteroplasmic, co-existing with wild-type molecules1. Using a mouse model with a heteroplasmic mtDNA mutation2, we tested whether mitochondrial-targeted TALENs (mitoTALENs)3,4could reduce the mutant mtDNA load in muscle and heart. AAV9-mitoTALEN was administered via intramuscular, intravenous, and intraperitoneal injections. Muscle and heart were efficiently transduced and showed a robust reduction in mutant mtDNA, which was stable over time. The molecular defect, namely a decrease in transfer RNAAlalevels, was restored by the treatment. These results showed that mitoTALENs, when expressed in affected tissues, could revert disease-related phenotypes in mice.

Published
2018
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45. Transient mitochondrial DNA double strand breaks in mice cause accelerated aging phenotypes in a ROS-dependent but p53/p21-independent manner

Author

Pinto, Milena, Pickrell, Alicia M, Wang, Xiao, Bacman, Sandra R, Yu, Aixin, Hida, Aline, Dillon, Lloye M, Morton, Paul D, Malek, Thomas R, Williams, Siôn L, and Moraes, Carlos T

Abstract

We observed that the transient induction of mtDNA double strand breaks (DSBs) in cultured cells led to activation of cell cycle arrest proteins (p21/p53 pathway) and decreased cell growth, mediated through reactive oxygen species (ROS). To investigate this process in vivo we developed a mouse model where we could transiently induce mtDNA DSBs ubiquitously. This transient mtDNA damage in mice caused an accelerated aging phenotype, preferentially affecting proliferating tissues. One of the earliest phenotypes was accelerated thymus shrinkage by apoptosis and differentiation into adipose tissue, mimicking age-related thymic involution. This phenotype was accompanied by increased ROS and activation of cell cycle arrest proteins. Treatment with antioxidants improved the phenotype but the knocking out of p21 or p53 did not. Our results demonstrate that transient mtDNA DSBs can accelerate aging of certain tissues by increasing ROS. Surprisingly, this mtDNA DSB-associated senescence phenotype does not require p21/p53, even if this pathway is activated in the process.

Published
2017
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47. Cytochrome c Association with the Inner Mitochondrial Membrane Is Impaired in the CNS of G93A-SOD1 Mice.

Author

Kirkinezos, Ilias G., Bacman, Sandra R., Hernandez, Dayami, Oca-Cossio, Jose, Arias, Laura J., Perez-Pinzon, Miguel A., Bradley, Walter G., and Moraes, Carlos T.

Subjects
*CYTOCHROME c, *SUPEROXIDE dismutase, *AMYOTROPHIC lateral sclerosis, *GENES, *MOTOR neurons, *APOPTOSIS
Abstract

A "gain-of-function" toxic property of mutant Cu-Zn superoxide dismutase 1 (SOD1) is involved in the pathogenesis of some familial cases of amyotrophic lateral sclerosis (ALS). Expression of a mutant form of the human SOD1 gene in mice causes a degeneration of motor neurons, leading to progressive muscle weakness and hindlimb paralysis. Transgenic mice overexpressing a mutant human SOD1 gene (G93A-SOD1) were used to examine the mitochondrial involvement in familial ALS. We observed a decrease in mitochondrial respiration in brain and spinal cord of the G93A-SOD1 mice. This decrease was significant only at the last step of the respiratory chain (complex IV), and it was not observed in transgenic wild-type SOD1 and nontransgenic mice. Interestingly, this decrease was evident even at a very early age in mice, long before any clinical symptoms arose. The effect seemed to be CNS specific, because no decrease was observed in liver mitochondria. Differences in complex IV respiration between brain mitochondria of G93A-SOD1 and control mice were abolished when reduced cytochrome c was used as an electron donor, pinpointing the defect to cytochrome c. Submitochondrial studies showed that cytochrome c in the brain of G93A-SOD1 mice had a reduced association with the inner mitochondrial membrane (IMM). Brain mitochondrial lipids, including cardiolipin, had increased peroxidation in G93A-SOD1 mice. These results suggest a mechanism by which mutant SOD1 can disrupt the association of cytochrome c with the IMM, thereby priming an apoptotic program. [ABSTRACT FROM AUTHOR]

Published
2005
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48. Author Correction: MitoTALEN reduces mutant mtDNA load and restores tRNAAlalevels in a mouse model of heteroplasmic mtDNA mutation

Author

Bacman, Sandra R., Kauppila, Johanna H. K., Pereira, Claudia V., Nissanka, Nadee, Miranda, Maria, Pinto, Milena, Williams, Sion L., Larsson, Nils-Göran, Stewart, James B., and Moraes, Carlos T.

Abstract

In the version of this article originally published, there was an error in Fig. 1a. The m.5024C>T mutation, shown as a green T, was displaced by one base. The error has been corrected in the print, HTML and PDF versions of this article.

Published
2018
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