Article Synopsis
- Recent advances in genetic manipulation have allowed for precise changes in mitochondrial DNA (mtDNA) and the removal of harmful mutations, but fixing mtDNA deletions related to mitochondrial myopathies is still tough.
- Researchers created mtDNA deletions in human cells by using specific end-joining tools and endonucleases, resulting in cell lines with varying levels of mtDNA deletion.
- The study found that when about 75% of genomes were deleted, it led to protein loss and metabolic issues, while single-cell analysis revealed different nuclear gene responses based on the deletion levels, highlighting a potential path for developing targeted treatments for these diseases.
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Article Abstract
Recent breakthroughs in the genetic manipulation of mitochondrial DNA (mtDNA) have enabled precise base substitutions and the efficient elimination of genomes carrying pathogenic mutations. However, reconstituting mtDNA deletions linked to mitochondrial myopathies remains challenging. Here, we engineered mtDNA deletions in human cells by co-expressing end-joining (EJ) machinery and targeted endonucleases. Using mitochondrial EJ (mito-EJ) and mito-ScaI, we generated a panel of clonal cell lines harboring a ∼3.5 kb mtDNA deletion across the full spectrum of heteroplasmy. Investigating these cells revealed a critical threshold of ∼75% deleted genomes, beyond which oxidative phosphorylation (OXPHOS) protein depletion, metabolic disruption, and impaired growth in galactose-containing media were observed. Single-cell multiomic profiling identified two distinct nuclear gene deregulation responses: one triggered at the deletion threshold and another progressively responding to heteroplasmy. Ultimately, we show that our method enables the modeling of disease-associated mtDNA deletions across cell types and could inform the development of targeted therapies.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC12085298 | PMC |
| http://dx.doi.org/10.1016/j.cell.2025.02.009 | DOI Listing |
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