The D-loop structure of human mtDNA is destabilized directly by 1-methyl-4-phenylpyridinium ion (MPP+), a parkinsonism-causing toxin.

1-Methyl-4-phenyl-1,2,3,6-tetrahydropyridine has been reported to cause parkinsonism via its neurotoxic form, 1-methyl-4-phenylpyridinium ion (MPP+), which inhibits complex I of the mitochondrial respiratory chain. Its parkinsonism-causing mechanisms attract a great deal of interest as a model of the disease. Recently, we reported that MPP+ strongly decreases the amount of mtDNA independent of the inhibition of complex I. Maintenance of a proper amount of mtDNA is essential for the normal function of mitochondria as exemplified in many mitochondrial diseases. The most characteristic feature in vertebral mtDNA replication is that H-strand synthesis proceeds displacing the parental H-strand as a long single strand. It forms the D-loop, a triplex replication intermediate composed of the parental L-strand, nascent H-strand and displaced H-strand. Here we show that MPP+ does not inhibit DNA synthesis by DNA polymerase gamma, but rather releases the nascent H-strands from mtDNA both in organello and in vitro. This indicates that MPP+ directly destabilizes the D-loop structure, thereby inhibiting replication. This study raises a new mechanism, i.e. destabilization of replication intermediates, for depletion of mtDNA.     

Release of replication termination controls mitochondrial DNA copy number after depletion with 2',3'-dideoxycytidine

Although cellular mitochondrial DNA (mtDNA) copy number varies widely among cell lines and tissues, little is known about the mechanism of mtDNA copy number control. Most nascent replication strands from the leading, heavy-strand origin (O_H) are prematurely terminated, defining the 3′ boundary of the displacement loop (D-loop). We have depleted mouse LA9 cell mtDNA to ~20% of normal levels by treating with 2′,3′-dideoxycytidine (ddC) and subsequently allowed recovery to normal levels of mtDNA. A quantitative ligation-mediated PCR assay was used to determine the levels of both terminated and extended nascent O_H strands during mtDNA depletion and repopulation. Depleting mtDNA leads to a release of replication termination until mtDNA copy number approaches a normal level. Detectable total nascent strands per mtDNA genome remain below normal. Therefore, it is likely that the level of replication termination plays a significant role in copy number regulation in this system. However, termination of D-loop strand synthesis is persistent, indicating formation of the D-loop structure has a purpose that is required under conditions of rapid recovery of depleted mtDNA.     

Sequence and properties of the human KB cell and mouse L cell D-loop regions of mitochondrial DNA.

The sequences of the displacement-loop (D-loop) regions of mitochondrial DNA (mtDNA) from mouse L cells and human KB cells have been determined and provide physical maps to aid in the identification of sequences involved in the regulation of replication and expression of mammalian mtDNA. Both D-loop regions are bounded by the genes for tRNAPhe and tRNAPro. This region contains the most highly divergent sequences in mtDNA with the exceptions of three small conserved sequence blocks near the 5' ends of D-loop strands, a 225 nucleotide conserved sequence block in the center of the D-loop strand template region, and a short sequence associated with the 3' ends of D-loop strands. A sequence similar to that associated with the 3' termini of D-loop strands overlaps one of the conserved sequence blocks near the 5' ends of D-loop strands. The large, central conserved sequence probably does not code for a protein since no open reading frames are discretely conserved. Numerous symmetric sequences and potential secondary structures exist in these sequences, but none appear to be clearly conserved between species.     

Patterns of single nucleotide polymorphism distribution in hypervariable regions of the D-loop of human mitochondrial DNA

The D4oop of mtDNA is a noncoding locus actively used as an individualizing marker in molecular genetic research. Uneven distribution of SNPs in the D-loop suggests that the functional load within this region is irregular. The nucleotide sequence analysis was used to evaluate the structural and functional role of various D-loop sites of a single individual’s mtDNA an d their importance in terms of phylogenetic conservatism. The role of duplication of various D-loop elements (TAS, ETAS, CSB elements) in increasing the reliability of the mtDNA replication initiation and termination is discussed.     

The Chromatin Assembly Factor 1 Promotes Rad51-Dependent Template Switches at Replication Forks by Counteracting D-Loop Disassembly by the RecQ-Type Helicase Rqh1

At blocked replication forks, homologous recombination mediates the nascent strands to switch template in order to ensure replication restart, but faulty template switches underlie genome rearrangements in cancer cells and genomic disorders. Recombination occurs within DNA packaged into chromatin that must first be relaxed and then restored when recombination is completed. The chromatin assembly factor 1, CAF-1, is a histone H3-H4 chaperone involved in DNA synthesis-coupled chromatin assembly during DNA replication and DNA repair. We reveal a novel chromatin factor-dependent step during replication-coupled DNA repair: Fission yeast CAF-1 promotes Rad51-dependent template switches at replication forks, independently of the postreplication repair pathway. We used a physical assay that allows the analysis of the individual steps of template switch, from the recruitment of recombination factors to the formation of joint molecules, combined with a quantitative measure of the resulting rearrangements. We reveal functional and physical interplays between CAF-1 and the RecQ-helicase Rqh1, the BLM homologue, mutations in which cause Bloom''s syndrome, a human disease associating genome instability with cancer predisposition. We establish that CAF-1 promotes template switch by counteracting D-loop disassembly by Rqh1. Consequently, the likelihood of faulty template switches is controlled by antagonistic activities of CAF-1 and Rqh1 in the stability of the D-loop. D-loop stabilization requires the ability of CAF-1 to interact with PCNA and is thus linked to the DNA synthesis step. We propose that CAF-1 plays a regulatory role during template switch by assembling chromatin on the D-loop and thereby impacting the resolution of the D-loop.     

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.     

Replication terminus for DNA polymerase I during initiation of pAMβ1 replication: role of the plasmid-encoded resolution system

Replication of plasmid pAMβ1 is initiated by DNA polymerase I (Pol I) and completed by DNA polymerase III holoenzyme contained in the replisome machinery. In this study we report that initiation of DNA replication generates D-loop structures containing the nascent leading strand paired to its template, and that D-loop extension is arrested ≈230 bp from the initiation site of DNA synthesis in the presence of the plasmid-encoded resolvase. In vitro and in vivo data suggest that this arrest is caused by a collision between Pol I and the resolvase bound to its target. As the arrested D-loop replication intermediates carry a single-stranded primosome-assembly site, we hypothesize that the biological role of the replication arrest is to limit the region replicated by Pol I and to promote the replacement of Pol I by the replisome in order to initiate concerted synthesis of the leading and lagging strands.     

Synthesis of high molecular weight DNA strands during S phase

The organization of the mammalian S phase was studied in synchronized mouse embryo cells in terms of the spatial relationship between replication units whose synthesis is initiated at different times in S phase and the rate of assimilation of replication units into high molecular weight DNA strands.The formation of high molecular weight nascent DNA strands several replication units in length was analyzed by velocity sedimentation in alkaline sucrose gradients and by isopycnic centrifugation in alkaline Cs₂SO₄/CsCl gradients. Differential labeling with an isotopic and a density label shows that replication units synthesized at different stages of the S phase are not found within the same high molecular weight polynucleotide strand. It is thus concluded that replication units duplicated at different stages of the S phase are spatially organized in clusters along the mammalian genome.The rate of formation of high molecular weight nascent DNA strands is at least 4 to 8 times slower than that predicted from the spatial organization of replication units and the rate of chain growth within replication units. It is concluded that the process of joining of the completed nascent strands of adjacent replication units plays a major role in the rate of completion of high molecular weight strands.     

Both heavy strand replication origins are active in partially duplicated human mitochondrial DNAs

The replication of human mitochondrial DNA (mtDNA) is initiated from a pair of displaced origins, one priming continuous synthesis of daughter-strand DNA from the heavy strand (OH) and the other priming continuous synthesis from the light strand (OL). In patients with sporadic large-scale rearrangements of mitochondrial DNA (i.e., partially-deleted [Delta-mtDNA] and partially-duplicated [dup-mtDNA] molecules), the dup-mtDNAs typically contain extra origins of replication, but it is unknown at present whether they are competent for initiation of replication. Using cybrids harboring each of two types of dup-mtDNAs-one containing two OHs and two OLs, and one containing two OHs and one OL-we used ligation-mediated polymerase chain reaction (LMPCR) to measure the presence and relative amounts of nascent heavy strands originating from each OH. We found that the nascent heavy strands originated almost equally from the two OHs in each cell line, indicating that the extra OH present on a partially duplicated mtDNA is competent for heavy strand synthesis. This extra OH could potentially confer a replicative advantage to dup-mtDNAs, as these molecules may have twice as many opportunities to initiate replication compared to wild-type (or partially deleted) molecules.     

在小鼠发育过程中线粒体基因组新型R环的表达

本实验室在成年小鼠线粒体DNA(mtDNA)D环上发现了一个新颖的轻链RNA转录本,这个RNA能够同DNA双链结合,形成一个稳定的DNA-RNA杂合结构(R环)。在此基础上,利用RT-PCR和Northern印迹法检测了小鼠线粒体基因组中R环的时空表达的特点。发现R环在小鼠不同组织、不同发育阶段中的表达水平有差异,其表达模式具有分化的位相性和时序性,提示R环有可能作为参与调控线粒体基因表达的分子,因而具有重要意义。     

Adenovirus DNA replication in vitro: a protein linked to the 5' end of nascent DNA strands.

Soluble nuclear extracts prepared from adenovirus-infected HeLa cells supported adenovirus DNA replication with exogenous DNA-protein complex as template, but protease-treated, phenol-extracted DNA was less active. Replication was enhanced when creatine phosphate and creatine phosphokinase were included in the reaction mixture, rendering the reaction independent of exogenous ATP. Genomic-length, newly synthesized DNA strands were first observed 30 min after initiation of replication and continued to increase in amount for at least 4 h. Thus, the rate of replication is consistent with previous estimates of the rate of replication in vivo. Nascent DNA strands bound to benzoylated, naphthoylated DEAE-cellulose due to their association with protein. The 5' termini of nascent DNA strands were resistant to the 5'- to 3'-specific T7 exonuclease, and the 3' termini of nascent strands were sensitive to the 3'- to 5'-specific exonuclease III. These results suggest that a protein becomes covalently linked to the 5' termini of nascent DNA strands replicated in vitro. Nuclear extracts prepared from adenovirus type 2-infected cells also supported replication of DNA-protein complex prepared from the unrelated type 7 adenovirus. The limited sequence homology between these two viruses at the origin of replication further defines recognition sequences at the origin. These results are discussed in terms of a model for adenovirus DNA replication in which the terminal protein and sequences within the inverted terminal repetition are involved in the formation of an initiation complex that is able to prime DNA replication.     

Mapping at the nucleotide level of Xenopus laevis mitochondrial D-loop H strand: structural features of the 3' region

The D-loop resulting from limited synthesis of the newly replicated heavy (H) strand of mitochondrial DNA provides a good opportunity to examine both the origin and termination of DNA synthesis. We report here the precise determination of the 3' and 5' termini of nascent Xenopus laevis D-loop H strand. We observe two major classes of newly synthesized D-loop H strands, 1641 and 1675 nucleotides long. A stable putative secondary structure located around its 3' end is described. Analogous secondary structures are also found in the same region of the mammalian D-loop mitochondrial DNAs. Moreover a pentanucleotide (5' TACAT 3'), base-paired in these secondary structures and most often present in two copies, is conserved in all vertebrate species so far studied. The termination associated sequence previously described in mammals is part of the putative stop signal represented by the secondary structure except in man. These results show that the mechanism of arrest of H strand synthesis is common to vertebrates.