Abstract
Recently, somatic recombination of human mitochondrial DNA (mtDNA) was discovered in skeletal muscle. To determine whether recombinant mtDNA molecules can be transmitted through the germ line, we investigated two families, each harboring two inherited heteroplasmic mtDNA mutations. Using allele-specific polymerase chain reaction and single-cell and single-molecule mutational analyses, we discovered, in both families, all four possible allelic combinations of the two heteroplasmic mutations (tetraplasmy), the hallmark of mtDNA recombination. We strongly suggest that these recombinant mtDNA molecules were inherited rather than de novo generated somatically, because they (1) are highly abundant and (2) are present in different tissues of maternally related family members, including young individuals. Moreover, the comparison of the complete mtDNA sequence of one of the families with database sequences revealed an irregular, nontreelike pattern of mutations, reminiscent of a reticulation. We therefore propose that certain reticulations of the human mtDNA phylogenetic tree might be explained by recombination of coexisting mtDNA molecules harboring multiple mutations.