Chimeric RNA/DNA oligonucleotides (ONs) have been used successfully for site-specific modifications of episomal and chromosomal DNA in eukaryotic cells. We explored the possibility of applying this technique to mitochondrial DNA, as single-nucleotide defects in this genome are associated with a series of human diseases. Therefore, we determined whether mitochondria possess the enzymatic machinery for chimeric ON-mediated DNA alterations. We utilized an in vitro DNA repair assay and an Escherichia coil readout system with mutagenized plasmids carrying point mutations in antibiotic resistance genes. RNA/DNA ONs were designed to correct the defects and restore kanamycin and tetracyclin resistance. Using this system, we demonstrated that extracts from highly purified rat liver mitochondria possess the essential enzymatic activity to mediate precise single-nucleotide changes. Interestingly, the frequency of gene conversion was similar in both mitochondrial and nuclear extracts, as well as from quiescent and regenerating liver. The results indicate that mitochondria contain the machinery required for repair of genomic single-point mutations, and suggest that RNA/DNA ONs may provide a novel approach to the treatment of certain mitochondrial-based diseases.