Replicating animal mitochondrial DNA

The field of mitochondrial DNA (mtDNA) replication has been experiencing incredible progress in recent years, and yet little is certain about the mechanism(s) used by animal cells to replicate this plasmid-like genome. The long-standing strand-displacement model of mammalian mtDNA replication (for which single-stranded DNA intermediates are a hallmark) has been intensively challenged by a new set of data, which suggests that replication proceeds via coupled leading- and lagging-strand synthesis (resembling bacterial genome replication) and/or via long stretches of RNA intermediates laid on the mtDNA lagging-strand (the so called RITOLS). The set of proteins required for mtDNA replication is small and includes the catalytic and accessory subunits of DNA polymerase γ, the mtDNA helicase Twinkle, the mitochondrial single-stranded DNA-binding protein, and the mitochondrial RNA polymerase (which most likely functions as the mtDNA primase). Mutations in the genes coding for the first three proteins are associated with human diseases and premature aging, justifying the research interest in the genetic, biochemical and structural properties of the mtDNA replication machinery. Here we summarize these properties and discuss the current models of mtDNA replication in animal cells.     

Number matters: control of mammalian mitochondrial DNA copy number

Regulation of mitochondrial biogenesis is essential for proper cellular functioning. Mitochondrial DNA （mtDNA） depletion and the resulting mitochondrial malfunction have been implicated in cancer, neurodegeneration, diabetes, aging, and many other human diseases. Although it is known that the dynamics of the mammalian mitochondrial genome are not linked with that of the nuclear genome, very little is known about the mechanism of mtDNA propagation. Nevertheless, our understanding of the mode of mtDNA replication has ad- vanced in recent years, though not without some controversies. This review summarizes our current knowledge of mtDNA copy number control in mammalian cells, while focusing on both mtDNA replication and turnover. Although mtDNA copy number is seemingly in excess, we reason that mtDNA copy number control is an important aspect of mitochondrial genetics and biogenesis and is essential for normal cellular function.     

Of circles, forks and humanity: Topological organisation and replication of mammalian mitochondrial DNA

The organisation of mammalian mitochondrial DNA (mtDNA) is more complex than usually assumed. Despite often being depicted as a simple circle, the topology of mtDNA can vary from supercoiled monomeric circles over catenanes and oligomers to complex multimeric networks. Replication of mtDNA is also not clear cut. Two different mechanisms of replication have been found in cultured cells and in most tissues: a strand-asynchronous mode involving temporary RNA coverage of one strand, and a strand-coupled mode rather resembling conventional nuclear DNA replication. In addition, a recombination-initiated replication mechanism is likely to be associated with the multimeric mtDNA networks found in human heart. Although an insight into the general principles and key factors of mtDNA organisation and maintenance has been gained over the last few years, there are many open questions regarding replication initiation, termination and physiological factors determining mtDNA organisation and replication mode. However, common themes in mtDNA maintenance across eukaryotic kingdoms can provide valuable lessons for future work.     

Reconstitution of a minimal mtDNA replisome in vitro

We here reconstitute a minimal mammalian mitochondrial DNA (mtDNA) replisome in vitro. The mtDNA polymerase (POLgamma) cannot use double-stranded DNA (dsDNA) as template for DNA synthesis. Similarly, the TWINKLE DNA helicase is unable to unwind longer stretches of dsDNA. In combination, POLgamma and TWINKLE form a processive replication machinery, which can use dsDNA as template to synthesize single-stranded DNA (ssDNA) molecules of about 2 kb. The addition of the mitochondrial ssDNA-binding protein stimulates the reaction further, generating DNA products of about 16 kb, the size of the mammalian mtDNA molecule. The observed DNA synthesis rate is 180 base pairs (bp)/min, corresponding closely to the previously calculated value of 270 bp/min for in vivo DNA replication. Our findings provide the first biochemical evidence that TWINKLE is the helicase at the mitochondrial DNA replication fork. Furthermore, mutations in TWINKLE and POLgamma cause autosomal dominant progressive external ophthalmoplegia (adPEO), a disorder associated with deletions in mitochondrial DNA. The functional interactions between TWINKLE and POLgamma thus explain why mutations in these two proteins cause an identical syndrome.     

The mitochondrial DNA helicase TWINKLE can assemble on a closed circular template and support initiation of DNA synthesis

Mitochondrial DNA replication is performed by a simple machinery, containing the TWINKLE DNA helicase, a single-stranded DNA-binding protein, and the mitochondrial DNA polymerase γ. In addition, mitochondrial RNA polymerase is required for primer formation at the origins of DNA replication. TWINKLE adopts a hexameric ring-shaped structure that must load on the closed circular mtDNA genome. In other systems, a specialized helicase loader often facilitates helicase loading. We here demonstrate that TWINKLE can function without a specialized loader. We also show that the mitochondrial replication machinery can assemble on a closed circular DNA template and efficiently elongate a DNA primer in a manner that closely resembles initiation of mtDNA synthesis in vivo.     

Mitochondrial DNA mutations in disease and aging

The small mammalian mitochondrial DNA (mtDNA) is very gene dense and encodes factors critical for oxidative phosphorylation. Mutations of mtDNA cause a variety of human mitochondrial diseases and are also heavily implicated in age-associated disease and aging. There has been considerable progress in our understanding of the role for mtDNA mutations in human pathology during the last two decades, but important mechanisms in mitochondrial genetics remain to be explained at the molecular level. In addition, mounting evidence suggests that most mtDNA mutations may be generated by replication errors and not by accumulated damage.     

New features of mitochondrial DNA replication system in yeast and man

In this review, we sum up the research carried out over two decades on mitochondrial DNA (mtDNA) replication, primarily by comparing this system in Saccharomyces cerevisiae and Homo sapiens. Brief incursions into systems of other organisms have also been achieved when they provide new information.S. cerevisiae and H. sapiens mitochondrial DNA (mtDNA) have been thought for a long time to share closely related architecture and replication mechanisms. However, recent studies suggest that mitochondrial genome of S. cerevisiae may be formed, at least partially, from linear multimeric molecules, while human mtDNA is circular. Although several proteins involved in the replication of these two genomes are very similar, divergences are also now increasingly evident. As an example, the recently cloned human mitochondrial DNA polymerase beta-subunit has no counterpart in yeast. Yet, yeast Abf2p and human mtTFA are probably not as closely functionally related as thought previously. Some mtDNA metabolism factors, like DNA ligases, were until recently largely uncharacterized, and have been found to be derived from alternative nuclear products. Many factors involved in the metabolism of mitochondrial DNA are linked through genetic or biochemical interconnections. These links are presented on a map. Finally, we discuss recent studies suggesting that the yeast mtDNA replication system diverges from that observed in man, and may involve recombination, possibly coupled to alternative replication mechanisms like rolling circle replication.     

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.     

人类线粒体DNA异质性研究进展及其法医学应用

线粒体DNA(mitochondrial DNA mtDNA)的异质性自从被发现以来,一直被遗传学、进化学、发育遗传学以及法医遗传学、分子生物学领域所重视。由于线粒体异质性的存在,使得很多涉及疾病、进化、系统发育线粒体基因组与核基因组的相互作用关系、线粒体DNA复制机制以及法医学运用线粒体DNA进行实际案件评估的问题变得复杂化。此外线粒体DNA异质性的发生原因以及对线粒体异质性的检测方法标准化问题还没有一个统一的答案。针对线粒体DNA异质性带来的种种问题,近年来国内外取得了不少研究进展。     

Prominent mitochondrial DNA recombination intermediates in human heart muscle

Recombination intermediates containing four-way (Holliday) junctions are generated during DNA repair and replication in many systems, including yeast mitochondrial DNA (mtDNA). In contrast, convincing evidence for recombination in mammalian mtDNA is lacking. We have used two-dimensional agarose-gel electrophoresis to analyse non-linear forms of mtDNA in human heart muscle. Replication intermediates from both the coupled and strand-asynchronous mtDNA replication pathways were detected. An additional class of non-linear molecules, with the electrophoretic properties of four-way junctions, was also prominent. These molecules were insensitive to topoisomerase I or RNase H, but were diminished by branch migration or RuvC treatment. Junctional molecules were detected in all regions of the mitochondrial genome, were found in myocardial DNA from young and old adults, but were present at lower levels in skeletal muscle and placenta. We suggest that they could represent intermediates of mtDNA repair, given their prevalence in the oxyradical-rich environment of heart muscle mitochondria.     

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.     

Replication of mitochondrial DNA occurs throughout the mitochondria of cultured human cells

Replication of mitochondrial DNA (mtDNA) is dependent on nuclear-encoded factors. It has been proposed that this reliance may exert spatial restrictions on the sites of mtDNA replication within the cytoplasm, as a previous study only detected mtDNA synthesis in perinuclear mitochondria. We have studied mtDNA replication in situ in a variety of human cell cultures labeled with 5-bromo-2'-deoxyuridine. In contrast to what has been reported, mtDNA synthesis was detected at multiple sites throughout the mitochondrial network following short pulses with bromodeoxyuridine. Although no bromodeoxyuridine incorporation was observed in anuclear platelets, incorporation into mtDNA of fibroblasts that had been enucleated 2 h prior to labeling was readily detectable. Blotting experiments indicated that the bromodeoxyuridine incorporation into mtDNA observed in situ represents replication of the entire mtDNA molecule. The studies also showed that replication of mtDNA occurred at any stage of the cell cycle in proliferating cells and continued in postmitotic cells, although at a lower level. These results demonstrate that mtDNA replication is not restricted to mitochondria in the proximity of the nucleus and imply that all components of the replication machinery are available at sufficient levels throughout the mitochondrial network to permit mtDNA replication throughout the cytoplasm.