Protein binding to a single termination-associated sequence in the mitochondrial DNA D-loop region

Starting the engine of the powerhouse: mitochondrial transcription and beyond

Mitochondria are central hubs for cellular metabolism, coordinating a variety of metabolic reactions crucial for human health. Mitochondria provide most of the cellular energy via their oxidative phosphorylation (OXPHOS) system, which requires the coordinated expression of genes encoded by both the nuclear (nDNA) and mitochondrial genomes (mtDNA). Transcription of mtDNA is not only essential for the biogenesis of the OXPHOS system, but also generates RNA primers necessary to initiate mtDNA replication. Like the prokaryotic system, mitochondria have no membrane-based compartmentalization to separate the different steps of mtDNA maintenance and expression and depend entirely on nDNA-encoded factors imported into the organelle. Our understanding of mitochondrial transcription in mammalian cells has largely progressed, but the mechanisms regulating mtDNA gene expression are still poorly understood despite their profound importance for human disease. Here, we review mechanisms of mitochondrial gene expression with a focus on the recent findings in the field of mammalian mtDNA transcription and disease phenotypes caused by defects in proteins involved in this process.

Endonuclease G promotes mitochondrial genome cleavage and replication

Endonuclease G (EndoG) is a nuclear-encoded endonuclease, mostly localised in mitochondria. In the nucleus EndoG participates in site-specific cleavage during replication stress and genome-wide DNA degradation during apoptosis. However, the impact of EndoG on mitochondrial DNA (mtDNA) metabolism is poorly understood. Here, we investigated whether EndoG is involved in the regulation of mtDNA replication and removal of aberrant copies. We applied the single-cell mitochondrial Transcription and Replication Imaging Protocol (mTRIP) and PCR-based strategies on human cells after knockdown/knockout and re-expression of EndoG. Our analysis revealed that EndoG stimulates both mtDNA replication initiation and mtDNA depletion, the two events being interlinked and dependent on EndoG's nuclease activity. Stimulation of mtDNA replication by EndoG was independent of 7S DNA processing at the replication origin. Importantly, both mtDNA-directed activities of EndoG were promoted by oxidative stress. Inhibition of base excision repair (BER) that repairs oxidative stress-induced DNA damage unveiled a pronounced effect of EndoG on mtDNA removal, reminiscent of recently discovered links between EndoG and BER in the nucleus. Altogether with the downstream effects on mitochondrial transcription, protein expression, redox status and morphology, this study demonstrates that removal of damaged mtDNA by EndoG and compensatory replication play a critical role in mitochondria homeostasis.

Adaptive evidence of mitochondrial genomes in Dolycoris baccarum (Hemiptera: Pentatomidae) to divergent altitude environments

Given mitochondrion is the 'energy and oxygen usage factories', adaptive signatures of mitochondrial genes have been extensively investigated in vertebrates from different altitudes, but few studies focus on insects. Here, we sequenced the complete mitochondrial genome (mitogenome) of Dolycoris. baccarum living in the Tibetan Plateau (DBHC, ∼3200 m above sea level (asl)) and conducted a detailed comparative analysis with another D. baccarum mitogenome (DBQY) from relatively low altitude (∼1300 m asl). All the 37 mitochondrial genes were highly conserved and under purifying selection, except for two mitochondrial protein-coding genes (MPCGs) (atp6 and nad5) that showed positively selected signatures. We therefore further examined non-synonymous substitutions in atp6 and nad5, by sequencing more individuals from three populations with different altitudes. We found that these non-synonymous substitutions were polymorphic in these populations, likely due to relaxed selection constraints in different altitudes. Purifying selection in all mitochondrial genes may be due to their functional importance for the precision of ATP production usually. Length difference in mitochondrial control regions between DBHC and DBQY was also conversed at the population level, indicating that sequence size adjustments in control region may be associated with adaptation to divergent altitudes. Quantitatively real-time PCR analysis for 12 MPCGs showed that gene expression patterns had a significant change between the two populations, suggesting that expression levels of MPCGs could be modulated by divergent environmental pressures (e.g. oxygen content and ambient temperature). These results provided an important guide for further uncovering genetic mechanisms of ecological adaptation in insects.

Strictly conserved tri-nucleotide motif "CAT" is associated with TAS DNA protein-binding sites in human mitochondrial DNA control region

The mitochondrial DNA (mtDNA) control region is a highly variable segment that contains functional elements that control mtDNA transcription and replication. By analysis of the polymorphic nucleotide spectrum of that segment, we aimed to identify the most conserved sites that should be associated with these elements. For that aim, we analyzed 50 033 human mtDNA control region sequences (mtDNA positions 16 066-16 374). We identified 10 conserved tri-nucleotides, one conserved tetra-nucleotide, and one conserved penta-nucleotide, containing six repetitions of the motif CAT, and two of its complement motif ATG (p value < 2 × 10 ^- 4). Three other appearances of the tri-nucleotide CAT were almost perfectly preserved. The positions of the preserved CAT elements are associated with the location of previously identified termination-associated sequences (TAS) which are the binding locations for proteins involved in mtDNA replication. We, therefore, hypothesize that the CAT tri-nucleotide elements within the control region may be the binding sites for TAS proteins and are directly involved in mtDNA transcription and replication.

Regulation of DNA replication at the end of the mitochondrial D-loop involves the helicase TWINKLE and a conserved sequence element

The majority of mitochondrial DNA replication events are terminated prematurely. The nascent DNA remains stably associated with the template, forming a triple-stranded displacement loop (D-loop) structure. However, the function of the D-loop region of the mitochondrial genome remains poorly understood. Using a comparative genomics approach we here identify two closely related 15 nt sequence motifs of the D-loop, strongly conserved among vertebrates. One motif is at the D-loop 5'-end and is part of the conserved sequence block 1 (CSB1). The other motif, here denoted coreTAS, is at the D-loop 3'-end. Both these sequences may prevent transcription across the D-loop region, since light and heavy strand transcription is terminated at CSB1 and coreTAS, respectively. Interestingly, the replication of the nascent D-loop strand, occurring in a direction opposite to that of heavy strand transcription, is also terminated at coreTAS, suggesting that coreTAS is involved in termination of both transcription and replication. Finally, we demonstrate that the loading of the helicase TWINKLE at coreTAS is reversible, implying that this site is a crucial component of a switch between D-loop formation and full-length mitochondrial DNA replication.

An evolutionary preserved intergenic spacer in gadiform mitogenomes generates a long noncoding RNA

Background

Vertebrate mitogenomes are economically organized and usually lack intergenic sequences other than the control region. Intergenic spacers located between the tRNA^Thr and tRNA^Pro genes (“T-P spacers”) have been observed in several taxa, including gadiform species, but information about their biological roles and putative functions is still lacking.

Results

Sequence characterization of the complete European hake Merluccius merluccius mitogenome identified a complex T-P spacer ranging in size from 223–532 bp. Further analyses of 32 gadiform species, representing 8 families and 28 genera, revealed the evolutionary preserved presence of T-P spacers across all taxa. Molecular complexity of the T-P spacers was found to be coherent with the phylogenetic relationships, supporting a common ancestral origin and gain of function during codfish evolution. Intraspecific variation of T-P spacer sequences was assessed in 225 Atlantic cod specimens and revealed 26 haplotypes. Pyrosequencing data representing the mito-transcriptome poly (A) fraction in Atlantic cod identified an abundant H-strand specific long noncoding RNA of about 375 nt. The T-P spacer corresponded to the 5’ part of this transcript, which terminated within the control region in a tail-to-tail configuration with the L-strand specific transcript (the 7S RNA).

Conclusions

The T-P spacer is inferred to be evolutionary preserved in gadiform mitogenomes due to gain of function through a long noncoding RNA. We suggest that the T-P spacer adds stability to the H-strand specific long noncoding RNA by forming stable hairpin structures and additional protein binding sites.

In D-loop: 40 years of mitochondrial 7S DNA

Given the tiny size of the mammalian mitochondrial genome, at only 16.5 kb, it is often surprising how little we know about some of its molecular features, and the molecular mechanisms governing its maintenance. One such conundrum is the biogenesis and function of the mitochondrial displacement loop (D-loop). The mitochondrial D-loop is a triple-stranded region found in the major non-coding region (NCR) of many mitochondrial genomes, and is formed by stable incorporation of a third, short DNA strand known as 7S DNA. In this article we review the current affairs regarding the main features of the D-loop structure, the diverse frequency of D-loops in the mtDNAs of various species and tissues, and also the mechanisms of its synthesis and turnover. This is followed by an account of the possible functions of the mitochondrial D-loop that have been proposed over the last four decades. In the last section, we discuss the potential links of the D-loop with mammalian ageing.

Recombination and evolution of duplicate control regions in the mitochondrial genome of the Asian big-headed turtle, Platysternon megacephalum

Complete mitochondrial (mt) genome sequences with duplicate control regions (CRs) have been detected in various animal species. In Testudines, duplicate mtCRs have been reported in the mtDNA of the Asian big-headed turtle, Platysternon megacephalum, which has three living subspecies. However, the evolutionary pattern of these CRs remains unclear. In this study, we report the completed sequences of duplicate CRs from 20 individuals belonging to three subspecies of this turtle and discuss the micro-evolutionary analysis of the evolution of duplicate CRs. Genetic distances calculated with MEGA 4.1 using the complete duplicate CR sequences revealed that within turtle subspecies, genetic distances between orthologous copies from different individuals were 0.63% for CR1 and 1.2% for CR2app:addword:respectively, and the average distance between paralogous copies of CR1 and CR2 was 4.8%. Phylogenetic relationships were reconstructed from the CR sequences, excluding the variable number of tandem repeats (VNTRs) at the 3' end using three methods: neighbor-joining, maximum likelihood algorithm, and Bayesian inference. These data show that any two CRs within individuals were more genetically distant from orthologous genes in different individuals within the same subspecies. This suggests independent evolution of the two mtCRs within each P. megacephalum subspecies. Reconstruction of separate phylogenetic trees using different CR components (TAS, CD, CSB, and VNTRs) suggested the role of recombination in the evolution of duplicate CRs. Consequently, recombination events were detected using RDP software with break points at ≈290 bp and ≈1,080 bp. Based on these results, we hypothesize that duplicate CRs in P. megacephalum originated from heterological ancestral recombination of mtDNA. Subsequent recombination could have resulted in homogenization during independent evolutionary events, thus maintaining the functions of duplicate CRs in the mtDNA of P. megacephalum.

Live sharksucker Echeneis naucrates (Linnaeus 1758) mitochondrial genome: the first report of Echeneidae complete mitochondrial genome

The complete mitochondrial genome of Echeneis naucrates is 16,611 bp in length. It comprises a control region, 13 protein-coding genes, 2 ribosomal RNAs (rRNAs) and 22 transfer RNAs (tRNAs), with an arrangement typical of vertebrate mitochondrial genomes. Base composition on the heavy strand is 30.24% A, 25.45% C, 15.02% G and 29.29% T. The control region is 940 bp in length, containing putative termination associated sequences (TASs) and conserved sequence blocks (CSBs). Two copies of a tandem repeat (AATATTAT) were found in all six individuals investigated. The hypothesis of selection for an optimal number of repeats as well as the evolutionary dynamics of tandem repeats in E. naucrates control regions await further investigations.

Complete mitochondrial DNA sequences of the threadfin cichlid (Petrochromis trewavasae) and the blunthead cichlid (Tropheus moorii) and patterns of mitochondrial genome evolution in cichlid fishes

The cichlid fishes of the East African Great Lakes represent a model especially suited to study adaptive radiation and speciation. With several African cichlid genome projects being in progress, a promising set of closely related genomes is emerging, which is expected to serve as a valuable data base to solve questions on genotype-phenotype relations. The mitochondrial (mt) genomes presented here are the first results of the assembly and annotation process for two closely related but eco-morphologically highly distinct Lake Tanganyika cichlids, Petrochromis trewavasae and Tropheus moorii. The genomic sequences comprise 16,588 bp (P. trewavasae) and 16,590 bp (T. moorii), and exhibit the typical mitochondrial structure, with 13 protein-coding genes, 2 rRNA genes, 22 tRNA genes, and a non-coding control region. Analyses confirmed that the two species are very closely related with an overall sequence similarity of 96%. We analyzed the newly generated sequences in the phylogenetic context of 21 published labroid fish mitochondrial genomes. Consistent with other vertebrates, the D-loop region was found to evolve faster than protein-coding genes, which in turn are followed by the rRNAs; the tRNAs vary greatly in the rate of sequence evolution, but on average evolve the slowest. Within the group of coding genes, ND6 evolves most rapidly. Codon usage is similar among examined cichlid tribes and labroid families; although a slight shift in usage patterns down the gene tree could be observed. Despite having a clearly different nucleotide composition, ND6 showed a similar codon usage. C-terminal ends of Cox1 exhibit variations, where the varying number of amino acids is related to the structure of the obtained phylogenetic tree. This variation may be of functional relevance for Cox1 synthesis.

Mitochondrial genome sequences of Artemia tibetiana and Artemia urmiana: assessing molecular changes for high plateau adaptation

Brine shrimps, Artemia (Crustacea, Anostraca), inhabit hypersaline environments and have a broad geographical distribution from sea level to high plateaus. Artemia therefore possess significant genetic diversity, which gives them their outstanding adaptability. To understand this remarkable plasticity, we sequenced the mitochondrial genomes of two Artemia tibetiana isolates from the Tibetan Plateau in China and one Artemia urmiana isolate from Lake Urmia in Iran and compared them with the genome of a low-altitude Artemia, A. franciscana. We compared the ratio of the rate of nonsynonymous (Ka) and synonymous (Ks) substitutions (Ka/Ks ratio) in the mitochondrial protein-coding gene sequences and found that atp8 had the highest Ka/Ks ratios in comparisons of A. franciscana with either A. tibetiana or A. urmiana and that atp6 had the highest Ka/Ks ratio between A. tibetiana and A. urmiana. Atp6 may have experienced strong selective pressure for high-altitude adaptation because although A. tibetiana and A. urmiana are closely related they live at different altitudes. We identified two extended termination-associated sequences and three conserved sequence blocks in the D-loop region of the mitochondrial genomes. We propose that sequence variations in the D-loop region and in the subunits of the respiratory chain complexes independently or collectively contribute to the adaptation of Artemia to different altitudes.

Multiple independent origins of mitochondrial control region duplications in the order Psittaciformes

Mitochondrial genomes are generally thought to be under selection for compactness, due to their small size, consistent gene content, and a lack of introns or intergenic spacers. As more animal mitochondrial genomes are fully sequenced, rearrangements and partial duplications are being identified with increasing frequency, particularly in birds (Class Aves). In this study, we investigate the evolutionary history of mitochondrial control region states within the avian order Psittaciformes (parrots and cockatoos). To this aim, we reconstructed a comprehensive multi-locus phylogeny of parrots, used PCR of three diagnostic fragments to classify the mitochondrial control region state as single or duplicated, and mapped these states onto the phylogeny. We further sequenced 44 selected species to validate these inferences of control region state. Ancestral state reconstruction using a range of weighting schemes identified six independent origins of mitochondrial control region duplications within Psittaciformes. Analysis of sequence data showed that varying levels of mitochondrial gene and tRNA homology and degradation were present within a given clade exhibiting duplications. Levels of divergence between control regions within an individual varied from 0-10.9% with the differences occurring mainly between 51 and 225 nucleotides 3' of the goose hairpin in domain I. Further investigations into the fates of duplicated mitochondrial genes, the potential costs and benefits of having a second control region, and the complex relationship between evolutionary rates, selection, and time since duplication are needed to fully explain these patterns in the mitochondrial genome.

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.

The complete mitochondrial DNA sequence of the guanaco (Lama guanicoe): comparative analysis with the vicuña (Vicugna vicugna) genome

South American camelids comprise the guanaco (Lama guanicoe) and the vicuña (Vicugna vicugna), which are wild species, and the domestic llama (Lama glama) and alpaca (Lama pacos). This paper presents the first complete mitochondrial (mt) genome of the guanaco and the mt coding sequence of the vicuña. The guanaco mtDNA is 16,649 nt long and its composition and organization are similar to the mitochondrial genome of other mammals. Excluding the control region, comparison of the complete guanaco and vicuña mtDNA showed 4.4% sequence divergence. Nucleotide differences in peptide coding genes varied from 1.9% in ATP6 to 6.4% in Cyt b. These values are compatible with the close relatedness of both species identified by other authors. Based on the differences between the control region sequence here reported and that previously described, we also discuss the occurrence of NUMTs in the genome of South American camelids.

The human mitochondrial replication fork in health and disease

Mitochondria are organelles whose main function is to generate power by oxidative phosphorylation. Some of the essential genes required for this energy production are encoded by the mitochondrial genome, a small circular double stranded DNA molecule. Human mtDNA is replicated by a specialized machinery distinct from the nuclear replisome. Defects in the mitochondrial replication machinery can lead to loss of genetic information by deletion and/or depletion of the mtDNA, which subsequently may cause disturbed oxidative phosphorylation and neuromuscular symptoms in patients. We discuss here the different components of the mitochondrial replication machinery and their role in disease. We also review the mode of mammalian mtDNA replication.

Thyroid hormone and myocardial mitochondrial biogenesis

Mitochondria have been central in the development of some of the most important ideas in modern biology. Since the discovery that mitochondria have its own DNA and specific mutations and deletions were found in association with neuromuscular and heart diseases, as well as in aging, an extraordinary number of publications have followed, and the term mitochondrial medicine was coined. Recently, it has been found that thyroid hormone (TH) stimulates cardiac mitochondrial biogenesis increasing myocardial mitochondrial mass, mitochondrial respiration, oxidative phosphorylation (OXPHOS), enzyme activities, mitochondrial protein synthesis (by stimulation in a T3-dependent manner), cytochrome, phospholipid and mtDNA content. Also, TH therapy may modulate cardiac mitochondrial protein-import apparatus. To identify the sequence of events, molecules and signaling pathways that is activated by TH affecting mitochondrial structure, biogenesis and function further research is warranted.

Evolution of the mitochondrial genome in mammals living at high altitude: new insights from a study of the tribe Caprini (Bovidae, Antilopinae)

Organisms living at high altitude are exposed to severe environmental stress associated with decreased oxygen pressure, cold temperatures, increased levels of UV radiation, steep slopes, and scarce food supplies, which may have imposed important selective constraints on the evolution of the mitochondrial genome. Within mammals, the tribe Caprini is of particular interest for studying the evolutionary effects of life at high altitude, as most species live in mountain regions, where they developed morphological and physiological adaptations for climbing. In this report, we analyzed the complete mitochondrial genome of 24 ruminants, including 20 species of Caprini. The phylogenetic analyses based on 16,117 nucleotides suggested the existence of a new large clade, here named subtribe Caprina, containing all genera, but Pantholops (Pantholopina), Capricornis, Naemorhedus, and Ovibos (Ovibovina). The alignment of the control region showed that all Caprini have between two and four tandem repeats of ~75 bp in the RS2 region, and that several of these copies emerged from recent and independent duplication events. We proposed therefore that the maintenance of at least two RS2 repeats in the control region of Caprini is positively selected, probably for producing a higher number of D-loop strands 3'-ending at different locations. The analyses of base composition at third-codon positions of protein-coding genes revealed that Caprini have the highest percentage of A nucleotide and the lowest percentage of G nucleotide, a pattern which suggests increased rates of cytosine deamination (C-->T transitions) on the H strand of mtDNA. Two nonexclusive hypotheses related to high-altitude life can explain such a mutational pattern: more severe oxidative stress (ROS) and higher metabolic rates. By comparing the relative rates of nonsynonymous and synonymous substitutions in protein-coding genes, we identified that Caprini have higher levels of adaptive variation in the ATPase complex. In addition, we detected several changes in mitochondrial genes that should be tested for their potential role in mountain adaptation.

Transcript analysis of dinoflagellate plastid gene minicircles

The dinoflagellate chloroplast genome is fragmented into a number of plasmid-like minicircles, mostly containing one or more genes, and with a conserved core. We show here that, in addition to the transcripts of similar sizes to individual genes that have been reported previously, there are larger transcripts beginning and ending close to the core region. These may give rise to the smaller transcripts by processing. We also show that previously reported ORFs (open reading frames) are represented by transcripts that are significantly more abundant than those for non-coding regions, indicating that the ORFs are indeed functional. We show that 'empty' minicircles are also transcribed. We propose a model for linkage of DNA replication and transcription in dinoflagellate chloroplasts.

The mitochondrial transcription termination factor mTERF modulates replication pausing in human mitochondrial DNA

The mammalian mitochondrial transcription termination factor mTERF binds with high affinity to a site within the tRNA(Leu(UUR)) gene and regulates the amount of read through transcription from the ribosomal DNA into the remaining genes of the major coding strand of mitochondrial DNA (mtDNA). Electrophoretic mobility shift assays (EMSA) and SELEX, using mitochondrial protein extracts from cells induced to overexpress mTERF, revealed novel, weaker mTERF-binding sites, clustered in several regions of mtDNA, notably in the major non-coding region (NCR). Such binding in vivo was supported by mtDNA immunoprecipitation. Two-dimensional neutral agarose gel electrophoresis (2DNAGE) and 5' end mapping by ligation-mediated PCR (LM-PCR) identified the region of the canonical mTERF-binding site as a replication pause site. The strength of pausing was modulated by the expression level of mTERF. mTERF overexpression also affected replication pausing in other regions of the genome in which mTERF binding was found. These results indicate a role for TERF in mtDNA replication, in addition to its role in transcription. We suggest that mTERF could provide a system for coordinating the passage of replication and transcription complexes, analogous with replication pause-region binding proteins in other systems, whose main role is to safeguard the integrity of the genome whilst facilitating its efficient expression.

DNA replication and transcription in mammalian mitochondria

The mitochondrion was originally a free-living prokaryotic organism, which explains the presence of a compact mammalian mitochondrial DNA (mtDNA) in contemporary mammalian cells. The genome encodes for key subunits of the electron transport chain and RNA components needed for mitochondrial translation. Nuclear genes encode the enzyme systems responsible for mtDNA replication and transcription. Several of the key components of these systems are related to proteins replicating and transcribing DNA in bacteriophages. This observation has led to the proposition that some genes required for DNA replication and transcription were acquired together from a phage early in the evolution of the eukaryotic cell, already at the time of the mitochondrial endosymbiosis. Recent years have seen a rapid development in our molecular understanding of these machineries, but many aspects still remain unknown.

3D model of RNA polymerase and bidirectional transcription

In the in vitro mitochondrial (mt) transcription initiation system with mt RNA polymerase fraction and mt lysate, the transcription initiation products were shown to be synthesized bidirectionally from the only H-strand-promoter (HSP)/L-strand-promoter region (LSP) of the mitochondrial D-loop genome segment. These transcription products ranged between >100 and >800 bp with the purified mitochondrial RNA polymerase fraction, but were larger (>2030-4000 bp) in size with the mitochondrial lysate in both human and mouse. In this brief report, an in vitro reconstituted mitochondrial transcription system purified by affinity chromatography (heparin-Sepharose) from mouse hypotetraploid letter Ehrlich ascites tumor cell mitochondria was shown to initiate transcription bidirectionally from the mitochondrial D-loop region (HSP/LSP), as evidenced by in vitro generated transcription products. The in vitro generated transcription products were separated by sequencing gel. But this in vitro reconstituted transcription system was not studied beyond the D-loop region. A 3D model of the enzyme RNA polymerase was docked with both ATP and CTP.

The C-terminal Tail of Mitochondrial Transcription Factor A Markedly Strengthens its General Binding to DNA

Mitochondrial transcription factor A (TFAM) contains a basic C-terminal tail which is essential for the promoter-specific transcription. TFAM is also a major component of a protein-mitochondrial DNA (mtDNA) complex, called nucleoid, as a non-specific DNA-binding protein. However, little is known about a role of the C-tail in the nucleoid. Overexpression of full-length TFAM decreased the amount of a D-loop form of mtDNA in cells, while overexpression of TFAM lacking its C-tail (TFAM-DeltaC) did not, suggesting that the C-tail is involved in destabilization or formation of the D-loop. An mRNA for mtDNA-derived ND1 was hardly decreased in the former but rather decreased in the latter. Given that the D-loop formation is coupled with the transcription, the decrease in the D-loop is likely due to its destabilization. The recombinant full-length TFAM much strongly unwound DNA than TFAM-DeltaC, which is consistent with the above idea because D-loop is resolved by unwinding of the supercoiling state. Notably, truncation of the C-tail decreased DNA-binding activity of TFAM by three orders of magnitude. Thus, the C-terminal tail of TFAM is important for the strong general binding to mtDNA. This strong DNA-binding conferred by the C-tail may play an important role in the nucleoid structure.

Structure and evolution of the avian mitochondrial control region

The structural and evolutionary characteristics of the mitochondrial control region were studied by using control region sequences of 68 avian species. The distribution of the variable nucleotide positions within the control region was found to be genus specific and not dependant on the level of divergence, as suggested before. Saturation was shown to occur at the level of divergence of 10% in pairwise comparisons of the control region sequences, as has also been reported for the third codon positions in ND2 and cytochrome b genes of mtDNA. The ratio of control region vs cytochrome b divergence in pairwise comparisons of the sequences was shown to vary from 0.13 to 21.65, indicating that the control region is not always the most variable region of the mtDNA, but also that there are differences in the rate of divergence among the lineages. Only two of the conserved sequence blocks localized earlier for other species, D box and CSB-1, were found to show a considerable amount of sequence conservation across the avian and mammalian sequences. Additionally, a novel avian-specific sequence block was found.

Animal mitochondrial biogenesis and function: a regulatory cross-talk between two genomes

Mitochondria play a pivotal role in cell physiology, producing the cellular energy and other essential metabolites as well as controlling apoptosis by integrating numerous death signals. The biogenesis of the oxidative phosphorylation system (OXPHOS) depends on the coordinated expression of two genomes, nuclear and mitochondrial. As a consequence, the control of mitochondrial biogenesis and function depends on extremely complex processes that require a variety of well orchestrated regulatory mechanisms. It is now clear that in order to provide cells with the correct number of structural and functional differentiated mitochondria, a variety of intracellular and extracellular signals including hormones and environmental stimuli need to be integrated. During the last few years a considerable effort has been devoted to study the factors that regulate mtDNA replication and transcription as well as the expression of nuclear-encoded mitochondrial genes in physiological and pathological conditions. Although still in their infancy, these studies are starting to provide the molecular basis that will allow to understand the mechanisms involved in the nucleo-mitochondrial communication, a cross-talk essential for cell life and death.

Identification of a novel human mitochondrial D-loop RNA species which exhibits upregulated expression following cellular immortalization

We report the identification and characterization of a novel human mitochondrial RNA species approximately 0.47 kb long that is transcribed from the mtDNA L-strand and is derived from the D-loop. Its expression increases when human cells become immortal, a key event in tumorigenesis. The RNA is therefore designated IDL (Immortalization-associated D-Loop). Sequence and hybrid cell analyses suggest that the increased level of IDL RNA in immortal cells is due to a recessive change, possibly in the activity of a trans-acting factor that controls IDL RNA expression.

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.

Sequence variation and evolution of the mitochondrial DNA control region in the musk shrew, Suncus murinus

The complete mitochondrial DNA (mtDNA) control region was cloned and sequenced in the musk shrew, Suncus murinus, Insectivora. The general aspect was similar to that found in other mammals. We have found in two locations of this region the presence of arrays of tandem repeats like those in other shrew species. One array was located in the left domain containing the termination-associated sequences (TAS) and the length of a copy was 77 bp. The other repeats were situated upstream from the recognition site for the end of H-strand replication in the right domain and were 20 bp long. The left halves of the control region containing the former repeats were sequenced and compared in several laboratory lines and wild animals from different localities, variations in copy number of repeated sequences were found both among individuals and within an individual. A comparative study of repeated sequences provides useful indication for the origin and evolution of tandem repeated sequences. Strand slippage and mispairing during replication of mtDNA with concerted manner is currently regarded as a dominant theory to account molecular mechanism for tandemly repeated sequences, and the pattern of sequence and length variation in our study supports this theory. Our results, however, suggest that the evolution of the repeated sequences containing the TAS in the musk shrew might go through the process of two steps; at the first step one complete repeated and several incomplete repeated sequences had reproduced in common ancestor of the shrew, and the second stage step-up of complete repeated sequences occurred with concerted evolution after differentiation into continental and insular groups.

Mitochondrial DNA replication in human T lymphocytes is regulated primarily at the H-strand termination site

The most unique feature in the replication of mitochondrial DNA (mtDNA) is that most of the newly synthesized heavy strands (H-strands) terminate prematurely, resulting in the formation of displacement loop (D-loop) strands. Only the H-strand which proceeds past the termination site is a true nascent H-strand leading to the overall replication on a circular mtDNA molecule. The physiological significance of the D-loop formation has long been unclear. To examine the role of premature termination in mtDNA replication, we therefore developed a method for selectively measuring both the total amount of nascent H-strands and the amount of true nascent H-strands using ligation-mediated polymerase chain reaction, which, for the first time, enabled us to estimate the frequency of premature termination. The stimulation of cell proliferation with interleukin 2 and phytohemagglutinin in human peripheral T lymphocytes caused an increase in the net replication rate of mtDNA. In stimulated cells, in comparison to resting ones, the amount of true nascent H-strands increased approx. 2.6-fold while the total amount of nascent H-strands remained unchanged, indicating that premature termination decreased while the initiation of replication remained the same. Our findings thus demonstrate the first clear example that premature termination plays a primary role in the up-regulation of the net rate of mtDNA replication in human cells.

Identification of human GC-box-binding zinc finger protein, a new Krüppel-like zinc finger protein, by the yeast one-hybrid screening with a GC-rich target sequence

A new human zinc finger DNA-binding protein was identified by using a yeast one-hybrid selection system. Two versions of the cDNA, encoding the same protein, were detected that differ for a 584 bp extension at the 5' region. Sequence analysis showed that the longer clone is a full length version containing part of the 5' untranslated region. The smaller version was fused in frame with the yeast GAL4 activation domain whereas the 5' region of the longer clone displayed a stop codon interrupting the fusion with the GAL4 domain. Nevertheless, this clone activated the yeast HIS3 reporter gene with the same efficiency as the smaller version. Sequence comparison of the derived protein with the database showed that it belongs to a family of zinc finger DNA-binding proteins which regulate the expression of genes involved in cell proliferation. Expression of the protein in an in vitro system, DNA-binding studies and genetic experiments identify this factor as a new zinc finger DNA-binding protein which binds GC-rich sequences and contains a domain probably functioning as a transcriptional activator. The new human protein identified in this study was therefore named GC-box-binding zinc finger protein).

Cloning and characterisation of mtDBP, a DNA-binding protein which binds two distinct regions of sea urchin mitochondrial DNA

The cDNA for the sea urchin mitochondrial D-loop-binding protein (mtDBP), a 40 kDa protein which binds two homologous regions of mitochondrial DNA (the D-loop region and the boundary between the oppositely transcribed ND5 and ND6 genes), has been cloned. Four different 3'-untranslated regions have been detected that are related to each other in pairs and do not contain the canonical polyadenylation signal. The in vitro synthesised mature protein (348 amino acids), deprived of the putative signal sequence, binds specifically to its DNA target sequence and produces a DNase I footprint identical to that given by the natural protein. mtDBP contains two leucine zippers, one of which is bipartite, and two small N- and C-terminal basic domains. A deletion mutation analysis of the recombinant protein has shown that the N-terminal region and the two leucine zippers are necessary for the binding. Furthermore, evidence was provided that mtDBP binds DNA as a monomer. This rules out a dimerization role for the leucine zippers and rather suggests that intramolecular interactions between leucine zippers take place. A database search has revealed as the most significative homology a match with the human mitochondrial transcription termination factor (mTERF), a protein that also binds DNA as a monomer and contains three leucine zippers forming intramolecular interactions. These similarities, and the observation that mtDBP-binding sites contain the 3'-ends of mtRNAs coded by opposite strands and the 3'-end of the D-loop structure, point to a dual function of the protein in modulating sea urchin mitochondrial DNA transcription and replication.

The mitochondrial genome: structure, transcription, translation and replication

Mitochondria play a central role in cellular energy provision. The organelles contain their own genome with a modified genetic code. The mammalian mitochondrial genome is transmitted exclusively through the female germ line. The human mitochondrial DNA (mtDNA) is a double-stranded, circular molecule of 16569 bp and contains 37 genes coding for two rRNAs, 22 tRNAs and 13 polypeptides. The mtDNA-encoded polypeptides are all subunits of enzyme complexes of the oxidative phosphorylation system. Mitochondria are not self-supporting entities but rely heavily for their functions on imported nuclear gene products. The basic mechanisms of mitochondrial gene expression have been solved. Cis-acting mtDNA sequences have been characterised by sequence comparisons, mapping studies and mutation analysis both in vitro and in patients harbouring mtDNA mutations. Characterisation of trans-acting factors has proven more difficult but several key enzymes involved in mtDNA replication, transcription and protein synthesis have now been biochemically identified and some have been cloned. These studies revealed that, although some factors may have an additional function elsewhere in the cell, most are unique to mitochondria. It is expected that cell cultures of patients with mitochondrial diseases will increasingly be used to address fundamental questions about mtDNA expression.

Genetic variation in functionally important domains of the bovine mtDNA control region

DNA sequences of the mitochondrial control region (CR) of 32 unrelated Austrian cattle were analysed in order to determine the extent of variability in functionally important domains. Using sequencing of PCR products, allele-specific PCR (AS-PCR) and primer introduced restriction analysis (PIRA), 43 differences were observed. They included 33 transitions, five transversions, one deletion and four differences in the number of consecutive cytosines. Twenty-three of these polymorphisms have not been reported before. In addition, we analysed all available European cattle sequences for this region. The transcriptional start sites, the conserved sequence block CSB 1 and both binding sites for the mitochondrial transcription factor mtTFA were highly conserved. We found a transition in each of the inter-specifically conserved Mt4 and Mt5 elements, three nucleotide substitutions in the termination-associated sequence TAS-A and six polymorphisms in the conserved sequence block CSB 2+3, a region which has been implicated in mitochondrial RNA processing.

Heteroplasmy, length and sequence variation in the mtDNA control regions of three percid fish species (Perca fluviatilis, Acerina cernua, Stizostedion lucioperca)

The nucleotide sequence of the control region and flanking tRNA genes of perch (Perca fluviatilis) mtDNA was determined. The organization of this region is similar to that of other vertebrates. A tandem array of 10-bp repeats, associated with length variation and heteroplasmy was observed in the 5' end. While the location of the array corresponds to that reported in other species, the length of the repeated unit is shorter than previously observed for tandem repeats in this region. The repeated sequence was highly similar to the Mt5 element which has been shown to specifically bind a putative D-loop DNA termination protein. Of 149 perch analyzed, 74% showed length variation heteroplasmy. Single-cell PCR on oocytes suggested that the high level of heteroplasmy is passively maintained by maternal transmission. The array was also observed in the two other percid species, ruffe (Acerina cernua) and zander (Stizostedion lucioperca). The array and the associated length variation heteroplasmy are therefore likely to be general features of percid mtDNAs. Among the perch repeats, the mutation pattern is consistent with unidirectional slippage, and statistical analyses supported the notion that the various haplotypes are associated with different levels of heteroplasmy. The variation in array length among and within species is ascribed to differences in predicted stability of secondary structures made between repeat units.

Multiple protein-binding sites in the TAS-region of human and rat mitochondrial DNA

To study the molecular mechanisms responsible for the regulation of mitochondrial DNA copy number, in vivo and in organello dimethyl sulfate footprinting experiments in human fibroblasts and rat liver mitochondria were carried out. By this approach we identified in both species two specific protein binding sites in the 3' region of the displacement loop of mitochondrial DNA. One site contains the TAS-D element of human and rat mitochondrial DNA; the other covers TAS-C and TAS-B in human, whereas in rat it comprises part of TAS-B. We suggest that the protected sequences might be the site of action of protein factors involved in the premature termination of mitochondrial DNA heavy-strand synthesis.

Mammalian mitochondrial D-loop region structural analysis: identification of new conserved sequences and their functional and evolutionary implications

This paper reports the first comprehensive analysis of Displacement loop (D-loop) region sequences from ten different mammalian orders. It represents a systematic evolutionary study at the molecular level on regulatory homologous regions in organisms belonging to a well defined class, mammalia, which radiated about 150 million years ago (Mya). We have aligned and analyzed 26 complete D-loop region sequences available in the literature and the fat dormouse sequence, recently determined in our laboratory. The novelty of our alignment consists of the extensive manual revision of the preliminary output obtained by computer program to optimize sequence similarity, particularly for the two peripheral domains displaying heterogeneity in length and the presence of repeated sequences. The multialignment is available at the WWW site: http://www.ba.cnr.it/dloop.html. Our comparative study has allowed us to identify new conserved sequence blocks present in all the species under consideration and events of insertion/deletion which have important implications in both functional and evolutionary aspects. In particular we have detected two blocks, about 60 bp long, extended termination associated sequences (ETAS1 and ETAS2) conserved in all the organisms considered. Evaluation against experimental work suggests a possible functional role of ETAS1 and ETAS2 in the regulation of replication and transcription and targeted experimental approaches. The analyses on conserved sequence blocks (CSBs) clearly indicate that CSB1 is the only very essential element, common to all mammalian mt genomes, while CSB2 and CSB3 could be involved in different though related functions, probably species specific, and thus more linked to nuclear mitochondrial coevolutionary processes. Our hypothesis on the different functional implications of the conserved elements, CSBs and TASs, reported so far as main regulatory signals, would explain the different conservation of these elements in evolution. Moreover the intra-order comparison of the D-loop regions highlights peculiar features useful to define the evolutionary dynamics of this region in closely related species.

Functional analysis of in vivo and in organello footprinting of HeLa cell mitochondrial DNA in relationship to ATP and ethidium bromide effects on transcription

In vivo and in organello footprinting techniques based on methylation interference have been utilized to investigate protein-DNA interactions in the transcription initiation and rDNA transcription termination regions of human mitochondrial DNA (mtDNA) in functionally active mitochondria. In particular, the changes in methylation reactivity of these regions in response to treatment of the organelles with ATP or ethidium bromide, which affects differentially the rates of mitochondrial rRNA and mRNA synthesis, have been analyzed. Two major sites of protein-DNA interactions have been identified in the main control region of mtDNA, both in vivo and in organello, which correspond to the regions of the light-strand promoter and heavy-strand rRNA-specific promoter. The in organello footprinting of the latter showed ATP- and ethidium bromide-dependent modifications that could be correlated with changes in the rate of rRNA but not of mRNA synthesis. By contrast, no ATP effects were observed on the in organello footprinting pattern of the termination region and on in vitro transcription termination, strongly suggesting that ATP control of rRNA synthesis occurs at the initiation level. Several methylation interference sites were found upstream of the whole H-strand transcription unit, pointing to possible protein-DNA interactions related to the activity of this unit. In vivo footprinting of the rDNA transcription termination region of human mtDNA has revealed a very strong protection pattern, indicating a high degree of occupancy of the termination site by mitochondrial transcription termination factor (approximately 80%).

Artemia mitochondrial genome: molecular biology and evolutive considerations

During the last two decades an increasing amount of information has been accumulated regarding the gene structure and organization of the mitochondrial genome from various organisms. Many studies carried out mainly in mammals, have contributed to the knowledge of the basic elements involved in the replication and transcription of mitochondrial DNA. However, very little is known about these processes in invertebrates. In this review we discuss our current knowledge of the animal mitochondrial genetic system and briefly summarize the structure of the Artemia mitochondrial genome, the characteristics of its transcriptional machinery and how its expression is controlled during early development, in relation with what is known in other organisms. Artemia is the only crustacean where the mtDNA has been studied at this level of detail up to date.

Evolution of repeated sequence arrays in the D-loop region of bat mitochondrial DNA

Analysis of mitochondrial DNA control region sequences from 41 species of bats representing 11 families revealed that repeated sequence arrays near the tRNA-Pro gene are present in all vespertilionine bats. Across 18 species tandem repeats varied in size from 78 to 85 bp and contained two to nine repeats. Heteroplasmy ranged from 15% to 63%. Fewer repeats among heteroplasmic than homoplasmic individuals in a species with up to nine repeats indicates selection may act against long arrays. A lower limit of two repeats and more repeats among heteroplasmic than homoplasmic individuals in two species with few repeats suggests length mutations are biased. Significant regressions of heteroplasmy, theta and pi, on repeat number further suggest that repeat duplication rate increases with repeat number. Comparison of vespertilionine bat consensus repeats to mammal control region sequences revealed that tandem repeats of similar size, sequence and number also occur in shrews, cats and bighorn sheep. The presence of two conserved protein-binding sequences in all repeat units indicates that convergent evolution has occurred by duplication of functional units. We speculate that D-loop region tandem repeats may provide signal redundancy and a primitive repair mechanism in the event of somatic mutations to these binding sites.

Evolution of repeated sequence arrays in the D-loop region of bat mitochondrial DNA

Analysis of mitochondrial DNA control region sequences from 41 species of bats representing 11 families revealed that repeated sequence arrays near the tRNA-Pro gene are present in all vespertilionine bats. Across 18 species tandem repeats varied in size from 78 to 85 bp and contained two to nine repeats. Heteroplasmy ranged from 15% to 63%. Fewer repeats among heteroplasmic than homoplasmic individuals in a species with up to nine repeats indicates selection may act against long arrays. A lower limit of two repeats and more repeats among heteroplasmic than homoplasmic individuals in two species with few repeats suggests length mutations are biased. Significant regressions of heteroplasmy, theta and pi, on repeat number further suggest that repeat duplication rate increases with repeat number. Comparison of vespertilionine bat consensus repeats to mammal control region sequences revealed that tandem repeats of similar size, sequence and number also occur in shrews, cats and bighorn sheep. The presence of two conserved protein-binding sequences in all repeat units indicates that convergent evolution has occurred by duplication of functional units. We speculate that D-loop region tandem repeats may provide signal redundancy and a primitive repair mechanism in the event of somatic mutations to these binding sites.

Expression of the smooth muscle myosin heavy chain gene is regulated by a negative-acting GC-rich element located between two positive-acting serum response factor-binding elements

To identify cis- and trans-acting factors that regulate smooth muscle-specific gene expression, we studied the smooth muscle myosin heavy chain gene, a rigorous marker of differentiated smooth muscle. A comparison of smooth muscle myosin heavy chain promoter sequences from multiple species revealed the presence of a highly conserved 227-base pair domain (nucleotides -1321 to -1095 in rat). Results of a deletion analysis of a 4.3-kilobase pair segment of the rat promoter (nucleotides -4220 to +88) demonstrated that this domain was necessary for maximal transcriptional activity in smooth muscle cells. Gel-shift analysis and site-directed mutagenesis demonstrated that one true CArG and another CArG-like element contained within this domain were both recognized by the serum response factor and were both required for the positive activity attributable to this domain. Additional studies demonstrated that mutation of a GC-rich sequence within the 227-base pair conserved domain resulted in a nearly 100% increase in transcriptional activity. Gel-shift analysis showed that this GC-rich repressor element was recognized by both Sp1 and Sp3. These data demonstrate that transcriptional control of the smooth muscle myosin heavy chain gene is highly complex, involving both negative and positive regulatory elements, including CArG sequences found in the promoters of multiple smooth muscle differentiation marker genes.

In organello footprinting analysis of rat mitochondrial DNA: protein interaction upstream of the Ori-L

An in organello footprinting approach has been used to probe a protein-DNA interaction of a nuclear coded 25 kDa protein, previously isolated in our laboratory, that binds "in vitro" a region within the ND2 gene, located upstream of the Ori-L. Footprinting studies with the purine-modifying reagent dimethyl sulfate and the pirimidine-modifying reagent potassium permanganate were carried out in isolated mitochondria from rat liver. Dimethyl sulfate footprinting has allowed the detection of a protein-DNA interaction within the curved ND2 region with contact sites located in both the strands. Potassium permanganate footprinting allowed detection of an adjacent permanganate-reactive region. We hypothesize that the permanganate-reactive region is a single stranded DNA due to a profound helix distortion induced by a 25 kDa protein binding to the nearest region.

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.

Length variation, heteroplasmy and sequence divergence in the mitochondrial DNA of four species of sturgeon (Acipenser)

The extent of mtDNA length variation and heteroplasmy as well as DNA sequences of the control region and two tRNA genes were determined for four North American sturgeon species: Acipenser transmontanus, A. medirostris, A. fulvescens and A. oxyrhnychus. Across the Continental Divide, a division in the occurrence of length variation and heteroplasmy was observed that was concordant with species biogeography as well as with phylogenies inferred from restriction fragment length polymorphisms (RFLP) of whole mtDNA and pairwise comparisons of unique sequences of the control region. In all species, mtDNA length variation was due to repeated arrays of 78-82-bp sequences each containing a D-loop strand synthesis termination associated sequence (TAS). Individual repeats showed greater sequence conservation within individuals and species rather than between species, which is suggestive of concerted evolution. Differences in the frequencies of multiple copy genomes and heteroplasmy among the four species may be ascribed to differences in the rates of recurrent mutation. A mechanism that may offset the high rate of mutation for increased copy number is suggested on the basis that an increase in the number of functional TAS motifs might reduce the frequency of successfully initiated H-strand replications.

Variation in the control region sequence of the sheep mitochondrial genome

The DNA sequences of the control region of the mitochondrial genome of fifty unrelated sheep were determined in order to ascertain the extent and distribution of its variability. A consensus sequence was derived, and 1081 differences from it were observed amongst the fifty animals. Some constant groups of differences were observed that were held in common by a number of animals, which thus fell into two main groups, although neither group was typical of any of the breeds sampled. The consensus sequence also allowed comparison between the control region sequences of sheep and other mammals. The sequence contains four tandem repeats of a 75 base-pair motif that accounts for the difference in its size from the cattle control region, to which it is otherwise very similar. Comparison with the cattle sequence allowed the determination of the homologues of various functionally important sites. The homologues of the transcription promoters, the origin of replication and the central conserved sequence block were all identified by this method.