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.