Precise sequence assignment of replication origin in the control region of chick mitochondrial DNA relative to 5' and 3' D-loop ends, secondary structure, DNA synthesis, and protein binding

Structural Variation of the Turtle Mitochondrial Control Region

The present study describes the most comprehensive comparison of turtle mtD-loop regions to date. The primary structure was compared from DNA sequences accessed from GenBank from 48 species in 13 families of extant turtles, and secondary structures of the mtD-loop region were inferred from thermal stabilities, using the program Mfold, for each superfamiliy of turtles. Both primary and secondary structures were found to be highly variable across the order. The Cryptodira showed conservation in the primary structure at conserved sequence blocks (CSBs), but the Pleurodira displayed limited conservation of primary structural characters, other than the coreTAS, a binding site for the helicase TWINKLE, which was highly conserved in the Central and Right Domains across the order. No secondary structure was associated with a TAS, but an AT-rich fold (secondary structure) near the 3' terminus of the mtD-loop region was detected in all turtle superfamilies. Mapping of character states of structural features of the mtD-loop region revealed that most character states were autapomorphies and inferred a number of homoplasies. The Left Domain of turtles, containing no highly conserved structural elements, likely does not serve a functional role; therefore, the Central Domain in turtles is likely equivalent to the Left Domain of mammals. The AT-rich secondary structural element near the 3' terminus of the mtD-loop region may be conserved across turtles because of a functional role, perhaps containing the Light Strand Promotor, or perhaps interacting with the TWINKLE-coreTAS complex in the Central and Right Domains to regulate mtDNA replication and transcription.

Animal Mitochondrial DNA Replication

Recent advances in the field of mitochondrial DNA (mtDNA) replication highlight the diversity of both the mechanisms utilized and the structural and functional organization of the proteins at mtDNA replication fork, despite the relative simplicity of the animal mtDNA genome. DNA polymerase γ, mtDNA helicase and mitochondrial single-stranded DNA-binding protein-the key replisome proteins, have evolved distinct structural features and biochemical properties. These appear to be correlated with mtDNA genomic features in different metazoan taxa and with their modes of DNA replication, although substantial integrative research is warranted to establish firmly these links. To date, several modes of mtDNA replication have been described for animals: rolling circle, theta, strand-displacement, and RITOLS/bootlace. Resolution of a continuing controversy relevant to mtDNA replication in mammals/vertebrates will have a direct impact on the mechanistic interpretation of mtDNA-related human diseases. Here we review these subjects, integrating earlier and recent data to provide a perspective on the major challenges for future research.

Species radiation by DNA replication that systematically exchanges nucleotides?

RNA and DNA syntheses share many properties. Therefore, the existence of 'swinger' RNAs, presumed 'orphan' transcripts matching genomic sequences only if transcription systematically exchanged nucleotides, suggests replication producing swinger DNA. Transcripts occur in many short-lived copies, the few cellular DNA molecules are long-lived. Hence pressures for functional swinger DNAs are greater than for swinger RNAs. Protein coding properties of swinger sequences differ from original sequences, suggesting rarity of corresponding swinger DNA. For genes producing structural RNAs, such as tRNAs and rRNAs, three exchanges (A<->T, C<->G and A<->T+C<->G) conserve self-hybridization properties. All nuclear eukaryote swinger DNA sequences detected in GenBank are for rRNA genes assuming A<->T+C<->G exchanges. In brachyuran crabs, 25 species had A<->T+C<->G swinger 18S rDNA, all matching the reverse-exchanged version of regular 18S rDNA of a related species. In this taxon, swinger replication of 18S rDNA apparently associated with, or even resulted in species radiation. A<->T+C<->G transformation doesn't invert sequence direction, differing from inverted repeats. Swinger repeats (detectable only assuming swinger transformations, A<->T+C<->G swinger repeats most frequent) within regular human rRNAs, independently confirm swinger polymerizations for most swinger types. Swinger replication might be an unsuspected molecular mechanism for ultrafast speciation.

Thermodynamic characterization of specific interactions between the human Lon protease and G-quartet DNA

Lon is an ATP-powered protease that binds DNA. However, the function of DNA binding by Lon remains elusive. Studies suggest that human Lon (hLon) binds preferentially to a G-rich single-stranded DNA (ssDNA) sequence overlapping the light strand promoter of mitochondrial DNA. This sequence is contained within a 24-base oligonucleotide referred to as LSPas. Here, we use biochemical and biophysical approaches to elucidate the structural properties of ssDNAs bound by hLon, as well as the thermodynamics of DNA binding by hLon. Electrophoretic mobility shift assay and circular dichroism show that ssDNAs with a propensity for forming parallel G-quartets are specifically bound by hLon. Isothermal titration calorimetry demonstrates that hLon binding to LSPas is primarily driven by enthalpy change associated with a significant reduction in heat capacity. Differential scanning calorimetry pinpoints an excess heat capacity upon hLon binding to LSPas. By contrast, hLon binding to an 8-base G-rich core sequence is entropically driven with a relatively negligible change in heat capacity. A considerable enhancement of thermal stability accompanies hLon binding to LSPas as compared to the G-rich core. Taken together, these data support the notion that hLon binds G-quartets through rigid-body binding and that binding to LSPas is coupled with structural adaptation.

Bidirectional replication initiates at sites throughout the mitochondrial genome of birds

Analysis of mitochondrial replication intermediates of Gallus gallus on fork-direction gels indicates that replication occurs in both directions around circular mitochondrial DNA. This finding was corroborated by a study of chick mitochondrial DNA on standard neutral two-dimensional agarose gels, which yielded archetypal initiation arcs in fragments covering the entire genome. There was, however, considerable variation in initiation arc intensity. The majority of initiation events map to regions flanking the major non-coding region, in particular the NADH dehydrogenase subunit 6 (ND6) gene. Initiation point mapping of the ND6 gene identified prominent free 5' ends of DNA, which are candidate start sites for DNA synthesis. Therefore we propose that the initiation zone of G. gallus mitochondrial DNA encompasses most, if not all, of the genome, with preferred initiation sites in regions flanking the major non-coding region. Comparison with mammals suggests a common mechanism of initiation of mitochondrial DNA replication in higher vertebrates.

Slow rate of evolution in the mitochondrial control region of gulls (Aves: Laridae)

We sequenced part of the mitochondrial control region and the cytochrome b gene in 72 specimens from 32 gull species (Laridae, Larini) and 2 outgroup representatives (terns: Laridae, Sternini). Our control region segment spanned the conserved central domain II and the usually hypervariable 3' domain III. Apart from some heteroplasmy at the 3' end of the control region, domain III was not more variable than domain II or the cytochrome b gene. Furthermore, variation in the tempo of evolution of domain III was apparent between phyletic species groups. The lack of variation of the gull control region could not be explained by an increase in the proportion of conserved sequences in these birds, and the gull control region showed an organization similar to those of other avian control regions studied to date. A novel invariant direct repeat was identified in domain II of gulls, and in domain III, two to three inverted, sometimes imperfect, repeats are able to form a significantly stable stem-and-loop structure. These putative secondary structures have not been reported before, and a comparison between species groups showed that they are more stable in the group with the more conserved control region. The unusually slow rate of evolution of control region part III of the gulls could thus be partly explained by the existence of secondary structures in domain III of these species.

A repeat complex in the mitochondrial control region of Adélie penguins from Antarctica

We have determined the nucleotide sequence of the entire mitochondrial control region (CR) of the Adélie penguin (Pygoscelis adeliae) from Antarctica. Like in most other birds, this CR region is flanked by the gene nad6 and transfer (t)RNA trnE(uuc) at the 5' end and the gene rns and trnF(gaa) at the 3' end. Sequence analysis shows that the Adelie penguin CR contains many elements in common with other CRs including the termination associated sequences (TAS), conserved F, E, D, and C boxes, the conserved sequence block (CSB)-1, as well as the putative light and heavy strand promoters sites (LSP-HSP). We report an extraordinarily long avian control region (1758 bp) which can be attributed to the presence, at the 3' peripheral domain, of five 81-bp repeat sequences, each containing a putative LSP-HSP, followed by 30 tetranucleotide microsatellite repeat sequences consisting of (dC-dA-dA-dA)30. The microsatellite and the 81-bp repeat reside in an area known to be transcribed in other species.

Mitochondrial DNA maintenance in vertebrates

The discovery that mutations in mitochondrial DNA (mtDNA) can be pathogenic in humans has increased interest in understanding mtDNA maintenance. The functional state of mtDNA requires a great number of factors for gene expression, DNA replication, and DNA repair. These processes are ultimately controlled by the cell nucleus, because the requisite proteins are all encoded by nuclear genes and imported into the mitochondrion. DNA replication and transcription are linked in vertebrate mitochondria because RNA transcripts initiated at the light-strand promoter are the primers for mtDNA replication at the heavy-strand origin. Study of this transcription-primed DNA replication mechanism has led to isolation of key factors involved in mtDNA replication and transcription and to elucidation of unique nucleic acid structures formed at this origin. Because features of a transcription-primed mechanism appear to be conserved in vertebrates, a general model for initiation of vertebrate heavy-strand DNA synthesis is proposed. In many organisms, mtDNA maintenance requires not only faithful mtDNA replication, but also mtDNA repair and recombination. The extent to which these latter two processes are involved in mtDNA maintenance in vertebrates is also appraised.