Mechanism of mitochondrial DNA replication in mouse L-cells: asynchronous replication of strands, segregation of circular daughter molecules, aspects of topology and turnover of an initiation sequence

Examination of in vivo long-labeled, pulse-labeled and pulse-chase-labeled mitochondrial DNA has corroborated and extended the basic elements of the displacement model of replication. Mitochondrial DNA molecules are shown to replicate an average of once per cell doubling in exponentially growing cultures. Analysis of the separate strands of partially replicated molecules indicates that replication is highly asynchronous with heavy-strand synthesis preceding light-strand synthesis. Native and denatured pulse-labeled replicating molecules exhibit sedimentation properties predicted by the displacement model of replication. Pulse-label incorporated into molecules isolated in the lower band region of ethidium bromide/cesium chloride gradients is found primarily in heavy daughter strands. Pulse-label incorporated into molecules isolated in the upper band region is found primarily in light daughter strands. The results of a series of pulse-chase experiments indicate that the complete process of replication requires approximately 120 minutes. Both daughter molecules are shown to segregate in an open circular form. They are then converted to closed circular molecules having a superhelix density near zero. After closure, the 7 S heavy-strand initation sequence is synthesized, and this process is accompanied by nicking, unwinding and closing of at least one of the parental strands resulting in the formation of the D-loop structure. The 7 S heavy-strand initiation sequence of the D-loop structure is not stable and turns over with a half-life of 7·9 hours. We suggest that all in vivo forms of parental closed circular mitochondrial DNA have superhelix densities of near zero, and that the previously observed superhelix density of closed circular mitochondrial DNA, σ~ ?0·02, results from the loss of the 7 S heavy-strand initiation sequence from D-loop mitochondrial DNA molecules during isolation.