Genome Editing of Plant Mitochondrial and Chloroplast Genomes

Arimura, Shin-ichi; Nakazato, Issei

doi:10.1093/pcp/pcad162

Cited by 3 publications

(1 citation statement)

References 53 publications

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“…However, the construction process of mito-TALENs vectors is complex, making it difficult for general laboratories to master this technology. Meanwhile, the simpler and more efficient CRISPR-Cas9 technology has not yet achieved a breakthrough in plant mitochondrial gene editing [25,26]. Therefore, traditional transgenic technology remains the main method for verifying mitochondrial gene functions.…”

Section: Introductionmentioning

confidence: 99%

Re-Sequencing the Mitochondrial Genome Unveils a Novel Isomeric Form of NWB CMS Line in Radish and Functional Verification of Its Candidate Sterile Gene

Li,

Liang,

Ran

et al. 2024

Horticulturae

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Radish (Raphanus sativus L.) is a globally significant vegetable and relies on cytoplasmic male sterile (CMS) lines for hybrid seed production. The NWB CMS type is favored over Ogura CMS for its ease in maintainer screening. Despite its varied mitochondrial configurations and unvalidated sterile gene, we re-sequenced the mitochondrial genome of NWB CMS Tibet A and verified the function of the sterility gene via genetic transformation of Arabidopsis thaliana. The mitochondrial genomes of Tibet A could be assembled into circular DNA molecules, with a mitochondrial genome size of 239,184 bp. Our analysis indicated that the specific orf463a was the CMS-associated gene in Tibet A, sharing sequence consistency with the CMS gene in DCGMS and NWB CMS YB-A. Collinearity analysis showed that the mitochondrial genomes of NWB CMS Tibet A, DCGMS, and NWB CMS YB-A share the same mitotype, with structural variations due to recombination via 9731 bp long repeat sequences and 508 bp short repeat sequences. Driven by the Ap3 promoter, transgenic Arabidopsis with orf463a exhibited male sterility, confirming the gene’s potential role in CMS. In this study, we assembled a new isomeric form of NWB CMS mitochondrial genome and proved the function of the candidate sterile gene.

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Section: Introductionmentioning

confidence: 99%

Re-Sequencing the Mitochondrial Genome Unveils a Novel Isomeric Form of NWB CMS Line in Radish and Functional Verification of Its Candidate Sterile Gene

Li,

Liang,

Ran

et al. 2024

Horticulturae

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Multilayered Regulation of Plastids and Mitochondria

Arimura,

Finkemeier,

Kühn

et al. 2024

Plant and Cell Physiology

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Genome editing in angiosperm chloroplasts: targeted DNA double‐strand break and base editing

Nakazato,

Arimura

2024

The Plant Journal

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SUMMARYChloroplasts are organelles that are derived from a photosynthetic bacterium and have their own genome. Genome editing is a recently developing technology that allows for specific modifications of target sequences. The first successful application of genome editing in chloroplasts was reported in 2021, and since then, this research field has been expanding. Although the chloroplast genome of several dicot species can be stably modified by a conventional method, which involves inserting foreign DNAs into the chloroplast genome via homologous recombination, genome editing offers several advantages over this method. In this review, we introduce genome editing methods targeting the chloroplast genome and describe their advantages and limitations. So far, CRISPR/Cas systems are inapplicable for editing the chloroplast genome because guide RNAs, unlike proteins, cannot be efficiently delivered into chloroplasts. Therefore, protein‐based enzymes are used to edit the chloroplast genome. These enzymes contain a chloroplast‐transit peptide, the DNA‐binding domain of transcription activator‐like effector nuclease (TALEN), or a catalytic domain that induces DNA modifications. To date, genome editing methods can cause DNA double‐strand break or introduce C:G‐to‐T:A and A:T‐to‐G:C base edits at or near the target sequence. These methods are expected to contribute to basic research on the chloroplast genome in many species and to be fundamental methods of plant breeding utilizing the chloroplast genome.

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Genome Editing of Plant Mitochondrial and Chloroplast Genomes

Cited by 3 publications

References 53 publications

Re-Sequencing the Mitochondrial Genome Unveils a Novel Isomeric Form of NWB CMS Line in Radish and Functional Verification of Its Candidate Sterile Gene

Re-Sequencing the Mitochondrial Genome Unveils a Novel Isomeric Form of NWB CMS Line in Radish and Functional Verification of Its Candidate Sterile Gene

Multilayered Regulation of Plastids and Mitochondria

Genome editing in angiosperm chloroplasts: targeted DNA double‐strand break and base editing

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