Replication of mitochondrial DNA occurs by strand displacement with alternative light-strand origins, not via a strand-coupled mechanism

Abstract G-quadruplexes (G4s) are noncanonical structures that can form in the genomes of a range of organisms and are known to play various roles in cellular function. G4s can also form in mitochondrial DNA (mtDNA) because of their high guanine content, and these G4s may play roles in regulating gene expression, DNA replication, and genome stability. However, little is known regarding the evolution and dissemination of G4s in mitochondria. Here we analyzed the potential G4-forming sequences in mtDNA of 16 species from various families and demonstrated that the heavy strand of mtDNA of higher-order organisms contained higher levels of G4 regions than that of lower-order organisms. Analysis of the codons in the light strand revealed enrichment of guanine/cytosine-rich regions in higher eukaryotes and of adenine/thymidine-rich regions in lower-order organisms. Our study showed the diversity of G4s in species ranging from lower to higher orders. In particular, mammals such as humans, chimpanzees, and monkeys display a greater number of G4s than lower-order organisms. These potentially play a role in a range of cellular functions and assist in the evolution of higher organisms.

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Mechanism of mitochondrial DNA replication in mouse L-cells: Localization and sequence of the light-strand origin of replication

Journal of Molecular Biology ◽

10.1016/0022-2836(79)90440-6 ◽

1979 ◽

Vol 135 (2) ◽

pp. 327-351 ◽

Cited By ~ 84

Author(s):

Phillip A. Martens ◽

David A. Clayton

Keyword(s):

Mitochondrial Dna ◽

Dna Replication ◽

Origin Of Replication ◽

L Cells ◽

Mitochondrial Dna Replication ◽

Light Strand

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Replication-competent human mitochondrial DNA lacking the heavy-strand promoter region

Molecular and Cellular Biology ◽

10.1128/mcb.11.3.1631-1637.1991 ◽

1991 ◽

Vol 11 (3) ◽

pp. 1631-1637

Author(s):

C T Moraes ◽

F Andreetta ◽

E Bonilla ◽

S Shanske ◽

S DiMauro ◽

...

Keyword(s):

Mitochondrial Dna ◽

Promoter Region ◽

Direct Repeat ◽

Progressive External Ophthalmoplegia ◽

Mitochondrial Transcription Factor ◽

Mtdna Deletion ◽

Heavy Strand ◽

Light Strand

We identified two patients with progressive external ophthalmoplegia, a mitochondrial disease, who harbored a population of partially deleted mitochondrial DNA (mtDNA) with unusual properties. These molecules were deleted from mtDNA positions 548 to 4,442 and encompassed not only rRNA sequences but the heavy-strand promoter region as well. A 13-bp direct repeat was found flanking the breakpoint precisely, with the repeat at positions 535 to 547 located within the binding site for mitochondrial transcription factor 1 (mtTF1). This is the second mtDNA deletion involving a 13-bp direct repeat reported but is at least 10 times less frequent in the patient population than the former one. In situ hybridization studies showed that transcripts under the control of the light-strand promoter were abundant in muscle fibers with abnormal proliferation of mitochondria, while transcripts directed by the heavy-strand promoter, whether of genes residing inside or outside the deleted region, were not. The efficient transcription from the light-strand promoter implies that the major heavy-and light-strand promoters, although physically close, are functionally independent, confirming previous in vitro studies.

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Novel Lines of Evidence for the Asymmetric Strand Displacement Model of Mitochondrial DNA Replication

Molecular and Cellular Biology ◽

10.1128/mcb.00406-18 ◽

2018 ◽

Vol 39 (2) ◽

Cited By ~ 1

Author(s):

Chih-Lin Hsieh

Keyword(s):

Mitochondrial Dna ◽

Mitochondrial Genome ◽

Nuclear Genome ◽

Strand Displacement ◽

Single Stranded Dna ◽

Quantitative Evidence ◽

Qualitative And Quantitative ◽

Mtdna Replication ◽

Displacement Model

ABSTRACT The mitochondrial genome, which consists of 16,569 bp of DNA with a cytosine-rich light (L) strand and a heavy (H) strand, exists as a multicopy closed circular genome within the mitochondrial matrix. The machinery for replication of the mammalian mitochondrial genome is distinct from that for replication of the nuclear genome. Three models have been proposed for mitochondrial DNA (mtDNA) replication, and one of the key differences among them is whether extensive single-stranded regions exist on the H strand. Here, three different methods that can detect single-stranded DNA (ssDNA) are utilized to identify the presence, location, and abundance of ssDNA on mtDNA. Importantly, none of these newly described methods involve the complication of prior mtDNA fractionation. The H strand was found to have extensive single-stranded regions with a profile consistent with the strand displacement model of mtDNA replication, whereas single strandedness was predominantly absent on the L strand. These findings are consistent with the in vivo occupancy of mitochondrial single-stranded DNA binding protein reported previously and provide strong new qualitative and quantitative evidence for the asymmetric strand displacement model of mtDNA replication.

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Identification of primary transcriptional start sites of mouse mitochondrial DNA: accurate in vitro initiation of both heavy- and light-strand transcripts.

Molecular and Cellular Biology ◽

10.1128/mcb.6.5.1446 ◽

1986 ◽

Vol 6 (5) ◽

pp. 1446-1453 ◽

Cited By ~ 25

Author(s):

D D Chang ◽

D A Clayton

Keyword(s):

Mitochondrial Dna ◽

Transcriptional Control ◽

Spatial Relationship ◽

S1 Nuclease ◽

Loop Region ◽

Loop Sequence ◽

Transcriptional Start Sites ◽

Heavy Strand ◽

Light Strand

The major transcriptional control sequences of vertebrate mitochondrial DNA lie within the displacement loop region. Transcription events initiating in the displacement loop sequence of the mouse genome were identified by 5' end mapping of primary transcripts by S1 nuclease protection and primer extension techniques. Light-strand transcription initiates at a single site, 165 nucleotides upstream of the major heavy-strand origin of replication. Transcription of the heavy strand occurs at two distinct sites, 5 and 13 nucleotides upstream of the gene for phenylalanyl-tRNA, the first heavy-strand-encoded gene. This spatial relationship of the two transcriptional start sites with each other and with the origin of heavy-strand replication and the gene for tRNAPhe is quite similar to that for human mitochondrial DNA. The predominant form of primary heavy-strand transcript in mouse is a short, ca. 75-nucleotide, RNA containing the sequences of tRNAPhe and a few additional nucleotides at the 5' end of tRNAPhe, suggesting that the processing of tRNA involves independent cleavages at the 5' and 3' ends of tRNA sequences.

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Precise assignment of the light-strand promoter of mouse mitochondrial DNA: a functional promoter consists of multiple upstream domains

Molecular and Cellular Biology ◽

10.1128/mcb.6.9.3253-3261.1986 ◽

1986 ◽

Vol 6 (9) ◽

pp. 3253-3261

Author(s):

D D Chang ◽

D A Clayton

Keyword(s):

Mitochondrial Dna ◽

Initiation Site ◽

Upstream Region ◽

Mitochondrial Rna ◽

Base Pairs ◽

Transcriptional Initiation ◽

Mitochondrial Rna Polymerase ◽

Template Dna ◽

Light Strand ◽

Transcriptional Initiation Site

Using deletion mutagenesis we localized the promoter for the light strand of mouse mitochondrial DNA to a 97-base-pair region, from -88 to +9 nucleotides of the transcriptional initiation site. Within this region the light-strand promoter could be dissected into at least three different functional domains. The specificity region, a maximum of 19 base pairs between -10 and +9 of the transcriptional initiation site, was essential and sufficient for accurate transcriptional initiation. A second region, extending to -29 nucleotides from the initiation site, facilitated the formation of a preinitiation complex between the template DNA and factor(s) present in the mitochondrial RNA polymerase fraction and was required for efficient transcription. A third, ill-defined upstream region, which extended up to -88 nucleotides from the initiation site, appeared to influence template transcriptional efficiencies in competition assays. Without the specificity domain, the upstream regions were incapable of supporting any transcription. The presence of multiple upstream domains was confirmed by disrupting nucleotide sequences in the upstream region by using linker insertion and linker replacement techniques.

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