Mechanism of replication of human mitochondrial DNA. Localization of the 5' ends of nascent daughter strands

Human mitochondrial DNA contains two physically separate and distinct origins of DNA replication. The initiation of each strand (heavy and light) occurs at a unique site and elongation proceeds unidirectionally. Animal mitochondrial DNA is novel in that short nascent strands are maintained at one origin (D-loop) in a significant percentage of the molecules. In the case of human mitochondrial DNA, there are three distinct D-loop heavy strands differing in length at the 5' end. We report here the localization of the 5' ends of nascent daughter heavy strands originating from the D-loop region. Analyses of the map positions of 5' ends relative to known restriction endonuclease cleavage sites and 5' end nucleotides indicate that the points of initiation of D-loop synthesis and actual daughter strands are the same. In contrast, the second origin is located two-thirds of the way around the genome where light strand synthesis is presumably initiated on a single-stranded template. Mapping of 5' ends of daughter light strands at this origin relative to known restriction endonuclease cleavage sites reveals two distinct points of initiation separated by 37 nucleotides. This origin is in the same relative genomic position and shows a high degree of DNA sequence homology to that of mouse mitochondrial DNA. In both cases, the DNA region within and immediately flanking the origin of DNA replication contains five tightly clustered tRNA genes. A major portion of the pronounced DNA template secondary structure at this origin includes the known tDNA sequences.     

Sequence-dependent DNA curvature: conformational signal present in the main regulatory region of the rat mitochondrial genome.

Theoretical analysis and experimental approaches by gel electrophoresis in retarding conditions allowed us to identify the presence of an intrinsic bending in the D-loop containing region of the rat mitochondrial genome. The curvature was located in the right domain of the sequence analyzed, between the origin of replication of the heavy strand and its promoter. The preliminary evidence of a specific recognition of the bent DNA with mitochondrial matrix proteins suggests a probable role of this DNA conformation in the duplication and/or expression of the mammalian mitochondrial genome.     

A bidirectional origin of replication maps to the major noncoding region of human mitochondrial DNA

In solid tissues of vertebrates, initiation of mitochondrial DNA replication encompasses a broad zone downstream of the major noncoding region (NCR). In contrast, analysis with two-dimensional agarose gel electrophoresis of mitochondrial DNA replication intermediates in cultured human cells revealed initiation concentrated in the NCR. Mapping of prominent free 5' ends on the heavy strand of mitochondrial DNA identified two clusters of potential start sites. One mapped to the previously assigned origin of strand-asynchronous replication (O(H)); the other lay several hundred nucleotides away from O(H), toward the other end of the NCR. The latter cluster is proposed to be the major site of bidirectional replication initiation on the basis of the following: its prominence is enhanced in cells amplifying mitochondrial DNA after experimentally induced mitochondrial DNA depletion; free 5' ends are found in corresponding positions on the opposite strand; it is transient in nature; and it is associated with bubble arcs.     

Template-directed arrest of mammalian mitochondrial DNA synthesis.

Mammalian mitochondrial DNA often contains a short DNA displacement loop at the heavy-strand origin of replication. This short nascent DNA molecule has been used to study site-specific termination of mitochondrial DNA synthesis in human and mouse cells. We examined D-loop strand termination in two distantly related artiodactyls, the pig and the cow. Porcine mitochondrial DNA was unique among mammals in that it contained only a single species of D-loop single-stranded DNA. Its 3' end mapped to a site 187 nucleotides from the 5' end of the proline tRNA gene. This site was 21 and 47 nucleotides 5' to two very similar sequences (5' ACATATPyATTAT 3') which are closely related to the human and mouse termination-associated sequences noted by Doda et al. (J. N. Doda, D. T. Wright, and D. A. Clayton, Proc. Nat. Acad. Sci. USA 78:616-6120, 1981). Bovine mitochondrial DNA contained three major D-loop DNA species whose 3' ends mapped to three different sites. These sites were not found in the porcine sequence. However, the bovine termination sites were located 60 to 64 base pairs 5' from sequences which were also very similar to the termination-associated sequences present in pigs and other mammals. These results firmly establish the concept that arrest of heavy-strand DNA synthesis is an event determined, at least in part, by template sequence. They also suggest that arrest is determined by sequences which are a considerable physical distance away from the actual termination site.     

Organization and closing of mitochondrial deoxyribonucleic acid from Paramecium tetraaurelia and Paramecium primaurelia.

Previously we showed that the mitochondrial deoxyribonucleic acid (DNA) from Paramecium aurelia consists of a linear genome and that replication of this genome is initiated at one terminus and proceeds unidirectionally to the other terminus. Analyses of mitochondria from four closely related species (1, 4, 5, and 7) indicated that the species 1, 5, and 7 DNAs are essentially completely homologous but that the species 4 mitochondrial DNA is only 40 to 50% homologous with that from species 1. The major regions of homology are those containing the genes for ribosomal ribonucleic acid (RNA). To understand the replication and organization of the linear mitochondrial genome better, we compared species 1 (Paramecium primaurelia) and 4 (Paramecium tetraaurelia) DNAs with regard to restriction fragment mapping and homology between initiation regions; we also identified the sites of the genes for ribosomal RNA. In general, the structures of the species 1 and 4 mitochondrial genomes were quite similar. Each ribosomal RNA gene was present in one copy per genome, with the large ribosomal RNA gene located near the terminal region of replication and the small ribosomal RNA gene located more centrally. These two genes were separated by about 10 kilobases in the species 1 genome and by about 12 kilobases in the species 4 genome. In contrast to our previous findings, by using nonstringent hybridization conditions we detected homology between the species 1 and 4 DNA fragments containing the initiation regions. We constructed recombinant DNA clones for many fragments, especially those containing the initiation region and the ribosomal RNA genes. We also constructed restriction enzyme maps for six enzymes for both P. primaurelia and P. tetraaurelia.