In Vivo Occupancy of Mitochondrial Single-Stranded DNA Binding Protein Supports the Strand Displacement Mode of DNA Replication

Mitochondrial DNA (mtDNA) encodes for proteins required for oxidative phosphorylation, and mutations affecting the genome have been linked to a number of diseases as well as the natural ageing process in mammals. Human mtDNA is replicated by a molecular machinery that is distinct from the nuclear replisome, but there is still no consensus on the exact mode of mtDNA replication. We here demonstrate that the mitochondrial single-stranded DNA binding protein (mtSSB) directs origin specific initiation of mtDNA replication. MtSSB covers the parental heavy strand, which is displaced during mtDNA replication. MtSSB blocks primer synthesis on the displaced strand and restricts initiation of light-strand mtDNA synthesis to the specific origin of light-strand DNA synthesis (OriL). The in vivo occupancy profile of mtSSB displays a distinct pattern, with the highest levels of mtSSB close to the mitochondrial control region and with a gradual decline towards OriL. The pattern correlates with the replication products expected for the strand displacement mode of mtDNA synthesis, lending strong in vivo support for this debated model for mitochondrial DNA replication.     

Mitochondrial DNA synthesis in synchronous cultures of the yeast,Saccharomyces cerevisiae

The synthesis of mitochondrial DNA (mtDNA) has been investigated by three independent methods of analysis during consecutive synchronous cell cycles in the yeast, Saccharomyces cerevisiae. The rates of pulse-label incorporation indicate maximal [³H]adenine uptake into mtDNA at the time of nuclear DNA synthesis. In contrast, the relative concentrations of mtDNA as determined by both the ratio of mtDNA to total cellular DNA and by the kinetics of isotope dilution analysis were found to increase continuously during synchronous growth. We conclude that whereas nuclear DNA replicates discontinuously during the cell cycle, mitochondrial DNA is synthesized continuously during this time. The discontinuous pattern of pulse-label incorporation into mtDNA is not considered to reflect its true mode of replication during the cell cycle.     

Mitochondrial DNA synthesis in cell cycle mutants of saccharomyces cerevisiae

Mitochondrial DNA replication was examined in mutants for seven different Saccharomyces cerevisiae genes which are essential for nuclear DNA replication. In cdc8 and cdc21, mutants defective in continued replication during the S phase of the cell cycle, mitochondrial DNA replication ceases at the nonpermissive temperature. Replication is temperature sensitive even when these mutants are arrested in the G1 phase of the cell cycle with α factor, a condition where mitochondrial DNA replication continues for the equivalent of several generations at the permissive temperature. Therefore the cessation of replication results from a defect in mitochondrial replication per se, rather than from an indirect consequence of cells being blocked in a phase of the cell cycle where mitochondrial DNA is not normally synthesized. Since the temperature-sensitive mutations are recessive, the products of genes cdc8 and cdc21 must be required for both nuclear and mitochondrial DNA replication. In contrast to cdc8 and cdc21, mitochondrial DNA replication continues for a long time at the nonpermissive temperature in five other cell division cycle mutants in which nuclear DNA synthesis ceases within one cell cycle: cdc4, cdc7, and cdc28, which are defective in the initiation of nuclear DNA synthesis, and cdc14 and cdc23, which are defective in nuclear division. The products of these genes, therefore, are apparently not required for the initiation of mitochondrial DNA replication.     

Evidence for a role of FEN1 in maintaining mitochondrial DNA integrity

Although the nuclear processes responsible for genomic DNA replication and repair are well characterized, the pathways involved in mitochondrial DNA (mtDNA) replication and repair remain unclear. DNA repair has been identified as being particularly important within the mitochondrial compartment due to the organelle's high propensity to accumulate oxidative DNA damage. It has been postulated that continual accumulation of mtDNA damage and subsequent mutagenesis may function in cellular aging. Mitochondrial base excision repair (mtBER) plays a major role in combating mtDNA oxidative damage; however, the proteins involved in mtBER have yet to be fully characterized. It has been established that during nuclear long-patch (LP) BER, FEN1 is responsible for cleavage of 5′ flap structures generated during DNA synthesis. Furthermore, removal of 5′ flaps has been observed in mitochondrial extracts of mammalian cell lines; yet, the mitochondrial localization of FEN1 has not been clearly demonstrated. In this study, we analyzed the effects of deleting the yeast FEN1 homolog, RAD27, on mtDNA stability in Saccharomyces cerevisiae. Our findings demonstrate that Rad27p/FEN1 is localized in the mitochondrial compartment of both yeast and mice and that Rad27p has a significant role in maintaining mtDNA integrity.     

Replication Intermediates of the Linear Mitochondrial DNA of Candida parapsilosis Suggest a Common Recombination Based Mechanism for Yeast Mitochondria

Variation in the topology of mitochondrial DNA (mtDNA) in eukaryotes evokes the question if differently structured DNAs are replicated by a common mechanism. RNA-primed DNA synthesis has been established as a mechanism for replicating the circular animal/mammalian mtDNA. In yeasts, circular mtDNA molecules were assumed to be templates for rolling circle DNA-replication. We recently showed that in Candida albicans, which has circular mapping mtDNA, recombination driven replication is a major mechanism for replicating a complex branched mtDNA network. Careful analyses of C. albicans-mtDNA did not reveal detectable amounts of circular DNA molecules. In the present study we addressed the question of how the unit sized linear mtDNA of Candida parapsilosis terminating at both ends with arrays of tandem repeats (mitochondrial telomeres) is replicated. Originally, we expected to find replication intermediates diagnostic of canonical bi-directional replication initiation at the centrally located bi-directional promoter region. However, we found that the linear mtDNA of Candida parapsilosis also employs recombination for replication initiation. The most striking findings were that the mitochondrial telomeres appear to be hot spots for recombination driven replication, and that stable RNA:DNA hybrids, with a potential role in mtDNA replication, are also present in the mtDNA preparations.     

Deoxyribonucleic Acid Synthesis in Saccharomyces cerevisiae Cells Permeabilized with Ether

Cells of Saccharomyces cerevisiae permeabilized by treatment with ether take up and incorporate exogenous deoxynucleoside triphosphate into deoxyribonucleic acid (DNA). With rho(+) strains, more than 95% of the product was mitochondrial DNA (mtDNA). This report characterizes ether-permeabilized yeast cells and describes studies on the mechanism of mtDNA synthesis with this system. The initial rate of in vitro mtDNA synthesis with one strain (X2180-1Brho(+)) was close to the rate of mtDNA replication in vivo. The extent of synthesis after 45 min was sufficient for the duplication of about 25% of the total mtDNA in the cells. The incorporated radioactivity resulting from in vitro DNA synthesis appeared in fragments that were an average of 30% mitochondrial genome size. Density-labeling experiments showed that continuous strands of at least 7 kilobases after denaturation, and up to 25 kilobase pairs before denaturation, were synthesized by this system. Pulse-chase experiments demonstrated that a large proportion of DNA product after short labeling times appeared in 0.25-kilobase fragments (after denaturation), which served as precursors of high-molecular-weight DNA. It is not yet clear whether the short pieces participate in a mechanism of discontinuous replication similar to that of bacterial and animal cell chromosomal DNA or whether they are related to the rapidly turning over, short initiation sequence of animal cell mtDNA. In rho(0) strains, which lack mtDNA, the initial rate of nuclear DNA synthesis in vitro was 1 to 2% of the average in vivo rate. With temperature-sensitive DNA replication mutants (cdc8), the synthesis of nuclear DNA was temperature sensitive in vitro as well, and in vitro DNA synthesis was blocked in an initiation mutant (cdc7) that was shifted to the restrictive temperature before the ether treatment.     

Multifactorial nature of high frequency of mitochondrial DNA mutations in somatic mammalian cells

The high frequency of mitochondrial DNA (mtDNA) mutations in somatic mammalian cells, which is more than two orders of magnitude higher than the mutation frequency of nuclear DNA (nDNA), significantly correlates with development of a variety of mitochondrial diseases (neurodegenerative diseases, cardiomyopathies, type II diabetes mellitus, cancer, etc.). A direct cause—consequence relationship has been established between mtDNA mutations and aging phenotypes in mammals. However, the unclear nature of the high frequency of mtDNA mutations requires a comprehensive consideration of factors that contribute to this phenomenon: oxidative stress, features of structural organization and repair of the mitochondrial genome, ribonucleotide reductase activity, replication errors, mutations of nuclear genes encoding mitochondrial proteins.     

Differential regulation of full-length genome and a single-stranded 7S DNA along the cell cycle in human mitochondria

Mammalian mitochondria contain full-length genome and a single-stranded 7S DNA. Although the copy number of mitochondrial DNA (mtDNA) varies depending on the cell type and also in response to diverse environmental stresses, our understanding of how mtDNA and 7S DNA are maintained and regulated is limited, partly due to lack of reliable in vitro assay systems that reflect the in vivo functionality of mitochondria. Here we report an in vitro assay system to measure synthesis of both mtDNA and 7S DNA under a controllable in vitro condition. With this assay system, we demonstrate that the replication capacity of mitochondria correlates with endogenous copy numbers of mtDNA and 7S DNA. Our study also shows that higher nucleotide concentrations increasingly promote 7S DNA synthesis but not mtDNA synthesis. Consistently, the mitochondrial capacity to synthesize 7S DNA but not mtDNA noticeably varied along the cell cycle, reaching its highest level in S phase. These findings suggest that syntheses of mtDNA and 7S DNA proceed independently and that the mitochondrial capacity to synthesize 7S DNA dynamically changes not only with cell-cycle progression but also in response to varying nucleotide concentrations.     

Deletion of mtDNA disrupts mitochondrial function and structure, but not biogenesis

The role of nuclear DNA (nDNA)-encoded proteins in the regulation of mitochondrial fission and fusion has been documented, yet the role of mitochondrial DNA (mtDNA) and encoded proteins in mitochondrial biogenesis remains unknown. Long-term treatment of a lymphoblastoid cell line Molt-4 with ethidium bromide generated mtDNA-deficient rho0 mutants. Depletion of mtDNA in rho0 cells produced functional and morphological changes in mitochondria without affecting the nuclear genome and encoded proteins. Indeed, the gene encoding subunit II of mitochondrial cytochrome c oxidase (COX II), a prototypical mitochondrial gene, was reduced in rho0 mutants blunting the activity of mitochondrial cytochrome coxidase. Yet, the amount of the nuclear beta-actin gene and the activity of citrate synthase, a mitochondrial matrix enzyme encoded by nDNA, remained unaffected in rho0 cells. Loss of mtDNA in rho0 cells was associated with significant distortion of mitochondrial structure, decreased electron density of the matrix and disorganized inner and outer membranes, resulting in the appearance of 'ghost-like' mitochondria. However, the number of mitochondria-like structures was not significantly different between mtDNA-deficient and parental cells. Thus, we conclude that cells lacking mtDNA still generate mitochondrial scaffolds, albeit with aberrant function.     

Mitochondrial diseases

By convention, the term "mitochondrial diseases" refers to disorders of the mitochondrial respiratory chain, which is the only metabolic pathway in the cell that is under the dual control of the mitochondrial genome (mtDNA) and the nuclear genome (nDNA). Therefore, a genetic classification of the mitochondrial diseases distinguishes disorders due to mutations in mtDNA, which are governed by the relatively lax rules of mitochondrial genetics, and disorders due to mutations in nDNA, which are governed by the stricter rules of mendelian genetics. Mutations in mtDNA can be divided into those that impair mitochondrial protein synthesis in toto and those that affect any one of the 13 respiratory chain subunits encoded by mtDNA. Essential clinical features for each group of diseases are reviewed. Disorders due to mutations in nDNA are more abundant not only because most respiratory chain subunits are nucleus-encoded but also because correct assembly and functioning of the respiratory chain require numerous steps, all of which are under the control of nDNA. These steps (and related diseases) include: (i) synthesis of assembly proteins; (ii) intergenomic signaling; (iii) mitochondrial importation of nDNA-encoded proteins; (iv) synthesis of inner mitochondrial membrane phospholipids; (v) mitochondrial motility and fission.     

DNA extraction procedures meaningfully influence qPCR-based mtDNA copy number determination

Quantitative real time PCR (qPCR) is commonly used to determine cell mitochondrial DNA (mtDNA) copy number. This technique involves obtaining the ratio of an unknown variable (number of copies of an mtDNA gene) to a known parameter (number of copies of a nuclear DNA gene) within a genomic DNA sample. We considered the possibility that mtDNA:nuclear DNA (nDNA) ratio determinations could vary depending on the method of genomic DNA extraction used, and that these differences could substantively impact mtDNA copy number determination via qPCR. To test this we measured mtDNA:nDNA ratios in genomic DNA samples prepared using organic solvent (phenol–chloroform–isoamyl alcohol) extraction and two different silica-based column methods, and found mtDNA:nDNA ratio estimates were not uniform. We further evaluated whether different genomic DNA preparation methods could influence outcomes of experiments that use mtDNA:nDNA ratios as endpoints, and found the method of genomic DNA extraction can indeed alter experimental outcomes. We conclude genomic DNA sample preparation can meaningfully influence mtDNA copy number determination by qPCR.     

Simultaneous extraction of nuclear and mitochondrial DNA from human blood

A method of simultaneous isolation of nuclear DNA (nDNA) and mitochondrial DNA (mtDNA) from human blood has been proposed by improvising Lahiri's method of isolation of nuclear DNA. The approach presented here provides selectively enriched fractions and eliminates the need for two different methods or separate reagent sets for the extraction of nDNA and mtDNA. It employs an initial nuclear/ cytoplasm partitioning, followed by the similar procedural steps for the two fractions separately. It gives good quality and quantity of the nDNA as well as the mtDNA, suitable for processes like PCR amplification and sequencing and may prove to be useful for people studying population genetics and evolution using molecular markers maximizing the available resources, especially in cases where a large database needs to be generated from limited amount of blood sample. From 3 ml of blood, the yields of mtDNA salvaged from the supernatant were sufficient to set approximately 4x10(5) reactions (starting with 250 fg DNA per reactions) of mtDNA loci which otherwise would have been discarded as per original Lahiri's procedure. The quality of mtDNA from the mitochondrial fraction was suitable for all major downstream processes as confirmed by locus specific PCR amplifications and sequencing. Through this procedure, the wastage of nDNA can be avoided when mtDNA loci is studied.     

Synchronous synthesis of DNA in coleoptiles and the initial leaf of developing etiolated wheat shoots: the nature and correlation of nuclear and mitochondrial DNA syntheses

In etiolated coleoptiles and initial leaf of developing wheat shoots the DNA synthesis is periodical and synchronous. In the initial leaf each step of DNA synthesis results in a stepwise increase of DNA content and is doubled at the first three steps. During the leaf plane formation the synthesis of nuclear DNA (nDNA) is decreased, while that of mitochondrial DNA (mitDNA) continues in synchronous cycles. This is the cause of relative stabilization of DNA content per unit of leaf plane length. The DNA increase in this organ occurs due to synchronous synthesis of nDNA and mitDNA in intercalary meristem cells. In coleoptiles a marked replication of nDNA is observed at the first three steps of the synthesis; in each cycle nDNA synthesis precedes that of mitDNA. With completion of coleoptile formation the nDNA synthesis in it practically ceases, whereas that of mitDNA continues in synchronous cycles. MitDNA is non-methylated and its composition (56 mol.% GC) differs significantly from that of the newly synthesized nDNA (44 mol.% GC; 100 X m5C/(C + m5C) = 16-17%). It may be concluded that in various organs of wheat shoots the composition and methylation of newly synthesized DNA depend on the age of the shoot and on the ratio of nDNA/mitDNA syntheses.     

A Rolling Circle Replication Mechanism Produces Multimeric Lariats of Mitochondrial DNA in Caenorhabditis elegans

Mitochondrial DNA (mtDNA) encodes respiratory complex subunits essential to almost all eukaryotes; hence respiratory competence requires faithful duplication of this molecule. However, the mechanism(s) of its synthesis remain hotly debated. Here we have developed Caenorhabditis elegans as a convenient animal model for the study of metazoan mtDNA synthesis. We demonstrate that C. elegans mtDNA replicates exclusively by a phage-like mechanism, in which multimeric molecules are synthesized from a circular template. In contrast to previous mammalian studies, we found that mtDNA synthesis in the C. elegans gonad produces branched-circular lariat structures with multimeric DNA tails; we were able to detect multimers up to four mtDNA genome unit lengths. Further, we did not detect elongation from a displacement-loop or analogue of 7S DNA, suggesting a clear difference from human mtDNA in regard to the site(s) of replication initiation. We also identified cruciform mtDNA species that are sensitive to cleavage by the resolvase RusA; we suggest these four-way junctions may have a role in concatemer-to-monomer resolution. Overall these results indicate that mtDNA synthesis in C. elegans does not conform to any previously documented metazoan mtDNA replication mechanism, but instead are strongly suggestive of rolling circle replication, as employed by bacteriophages. As several components of the metazoan mitochondrial DNA replisome are likely phage-derived, these findings raise the possibility that the rolling circle mtDNA replication mechanism may be ancestral among metazoans.