Abstract
It has been argued that DNA repair by homologous recombination in the context of endonuclease-mediated cleavage can cause mutations. To better understand this phenomenon, we examined homologous recombination following endonuclease cleavage in a native genomic context: the movement of self-splicing introns in the mitochondrial genomes of Metschnikowia yeasts. Self-splicing mitochondrial introns are mobile elements, which can copy and paste themselves at specific insertion sites in mitochondrial DNA using a homing endonuclease in conjunction with homologous recombination. Here, we explore the mutational effects of self-splicing introns by comparing sequence variation within the intron-rich cox1 and cob genes from 71 strains (belonging to 40 species) from the yeast genus Metschnikowia. We observed a higher density of single nucleotide polymorphisms around self-splicing-intron insertion sites. Given what is currently known about the movement of organelle introns, it is likely that their mutational effects result from the high binding affinity of endonucleases and their interference with repair machinery during homologous recombination (or, alternatively, via gene conversion occurring during the intron insertion process). These findings suggest that there are fitness costs to harbouring self-splicing, mobile introns and will help us better understand the risks associated with modern biotechnologies that use endonuclease-mediated homologous recombination, such as CRISPR-Cas9 gene editing.
Highlights
The ability to safely modify the DNA of living organisms may soon be within our grasp thanks to CRISPR-Cas9
If the movement of self-splicing introns is mutagenic, this could help explain why Metschnikowia mitogenomes are so diverse. To explore this idea further, we studied the relationship between single nucleotide polymorphisms (SNPs) and their proximity to selfsplicing-intron insertion sites within cox1 and cob from 71 different species/strains of Metschnikowia
We binned the SNPs into the following window sizes: one nucleotide, 5 nt, and 10 nt to the left and right of each intron insertion site
Summary
The ability to safely modify the DNA of living organisms may soon be within our grasp thanks to CRISPR-Cas. CRISPR-Cas gene editing has not yet been approved for widespread therapeutic use because of its potential for introducing unwanted mutations (Kosicki et al, 2018). Recent reports have proposed that homologous recombination following endonuclease cleavage is responsible for CRISPR-Cas9’s on-target mutagenicity. This is because DNA-binding proteins, such as endonucleases, interfere with double-strand break repair by competing with the repair machinery for the target site (Reijns et al, 2015; Kaiser et al, 2016; Sabarinathan et al, 2016). An excellent model for studying the relationship between endonuclease activity and on-target mutagenicity in a native genomic context is the movement of self-splicing introns in mitochondrial genomes. Self-splicing introns are a class of mobile element commonly found in the mitochondrial
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