The mutational spectrum of the mitochondrial DNA (mtDNA) does not resemble any of the known mutational signatures of the nuclear genome and variation in mtDNA mutational spectra between different organisms is still incomprehensible. Since mitochondria are responsible for aerobic respiration, it is expected that mtDNA mutational spectrum is affected by oxidative damage. Assuming that oxidative damage increases with age, we analyse mtDNA mutagenesis of different species in regards to their generation length. Analysing, (i) dozens of thousands of somatic mtDNA mutations in samples of different ages (ii) 70053 polymorphic synonymous mtDNA substitutions reconstructed in 424 mammalian species with different generation lengths and (iii) synonymous nucleotide content of 650 complete mitochondrial genomes of mammalian species we observed that the frequency of AH > GH substitutions (H: heavy strand notation) is twice bigger in species with high versus low generation length making their mtDNA more AH poor and GH rich. Considering that AH > GH substitutions are also sensitive to the time spent single-stranded (TSSS) during asynchronous mtDNA replication we demonstrated that AH > GH substitution rate is a function of both species-specific generation length and position-specific TSSS. We propose that AH > GH is a mitochondria-specific signature of oxidative damage associated with both aging and TSSS.
It has been shown recently that mitochondrial (mtDNA) somatic variants are numerous enough to trace cellular lineages in our body. Here we extend this statement and demonstrate that mtDNA variants can be interpreted not only as neutral markers of cell divisions but the relative frequency of different mtDNA substitutions (i.e. mtDNA mutational spectrum) can inform us about important biological properties such as cell longevity. Analysing 7611 somatic mtDNA mutations from 37 types of human cancers and more than 2000 somatic mtDNA mutations from 25 healthy human tissues we observed that mtDNA mutational spectrum is associated with cell turnover rate: the ratio of T>C to G>A is increasing with cell longevity. To extend this logic we considered that, if universal, the discovered mutation bias may drive the differences in mtDNA mutational spectrum between mammalian species with short-(‘mice’) and long-(‘elephants’) lived oocytes. Based on presumably neutral polymorphisms in MT-CYB we reconstructed mutational spectra for 424 mammalian species and obtained that the fraction of T>C positively correlated with the species-specific generation length, which is a good proxy for oocyte longevity. Next, comparing complete mitochondrial genomes of 650 mammalian species we confirmed that exactly the same process shapes the nucleotide content of the most neutral sites in the whole mitochondrial genomes of short-(high T, low C) versus long-(low T, high C) lived mammals. Altogether analysing mtDNA mutations in time interval from dozens of years (somatic mutations) through the hundreds of thousands of years (within species polymorphisms) to millions of years (between species substitutions) we demonstrated that T>C/G>A positively correlates with cellular and organismal longevity. We hypothesize that the discovered mtDNA signature presents a chemical damage which is associated with the level of oxidative metabolism which, in turn, correlates with cellular and organismal longevity. The described properties of mtDNA mutational spectrum shed light on mtDNA replication, mtDNA evolution of mammals and can be used as a marker of cell longevity in single-cell analyses of heterogeneous samples.
The hypothesis that the evolution of humans involves hybridization between diverged species has been actively debated in recent years. We present the following novel evidence in support of this hypothesis: the analysis of nuclear pseudogenes of mtDNA (“NUMTs”). NUMTs are considered “mtDNA fossils” as they preserve sequences of ancient mtDNA and thus carry unique information about ancestral populations. Our comparison of a NUMT sequence shared by humans, chimpanzees, and gorillas with their mtDNAs implies that, around the time of divergence between humans and chimpanzees, our evolutionary history involved the interbreeding of individuals whose mtDNA had diverged as much as ~4.5 Myr prior. This large divergence suggests a distant interspecies hybridization. Additionally, analysis of two other NUMTs suggests that such events occur repeatedly. Our findings suggest a complex pattern of speciation in primate/human ancestors and provide one potential explanation for the mosaic nature of fossil morphology found at the emergence of the hominin lineage. A preliminary version of this manuscript was uploaded to the preprint server BioRxiv in 2017 (10.1101/134502).
Every cell in our body contains a vibrant population of mitochondria, or, more precisely, of mitochondrial DNA molecules (mtDNAs). Just like members of any population mtDNAs multiply (by replication) and die (i.e., are removed, either by degradation or by distribution into the sister cell in mitosis). An intriguing question is whether all mitochondria in this population are equal, especially whether some are responsible primarily for reproduction and some - for empowering the various jobs of the mitochondrion, oxidative phosphorylation in the first place. Importantly, because mtDNA is highly damaged such a separation of responsibilities could help greatly reduce the conversion of DNA damage into real inheritable mutations. An unexpected twist in the resolution of this problem has been brought about by a recent high-precision analysis of mtDNA mutations (Sanchez-Contreras et al. 2023). They discovered that certain transversion mutations, unlike more common transitions, are not accumulating with age in mice. We argue that this observation requires the existence of a permanent replicating subpopulation/lineage of mtDNA molecules, which are protected from DNA damage, a.k.a. the stem mtDNA. This also implies the existence of its antipode i.e., the worker mtDNA, which empowers OSPHOS, sustains damage and rarely replicates. The analysis of long HiFi reads of mtDNA performed by PacBio closed circular sequencing confirms this assertion.
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