Identification by in Organello footprinting of protein contact sites and of single-stranded DNA sequences in the regulatory region of rat mitochondrial DNA. Protein binding sites and single-stranded DNA regions in isolated rat liver mitochondria

Deletion of OGG1 Results in a Differential Signature of Oxidized Purine Base Damage in mtDNA Regions

Mitochondrial oxidative stress accumulates with aging and age-related diseases and induces alterations in mitochondrial DNA (mtDNA) content. Since mtDNA qualitative alterations are also associated with aging, repair of mtDNA damage is of great importance. The most relevant form of DNA repair in this context is base excision repair (BER), which removes oxidized bases such as 8-oxoguanine (8-oxoG) and thymine glycol through the action of the mitochondrial isoform of the specific 8-oxoG DNA glycosylase/apurinic or apyrimidinic (AP) lyase (OGG1) or the endonuclease III homolog (NTH1). Mouse strains lacking OGG1 (OGG1^−/−) or NTH1 (NTH1^−/−) were analyzed for mtDNA alterations. Interestingly, both knockout strains presented a significant increase in mtDNA content, suggestive of a compensatory mtDNA replication. The mtDNA “common deletion” was not detected in either knockout mouse strain, likely because of the young age of the mice. Formamidopyrimidine DNA glycosylase (Fpg)-sensitive sites accumulated in mtDNA from OGG1^−/− but not from NTH1^−/− mice. Interestingly, the D-loop region was most severely affected by the absence of OGG1, suggesting that this region may be a hotspot for oxidative damage. Thus, we speculate that mtDNA alterations may send a stress message to evoke cell changes through a retrograde mitochondrial–nucleus communication.

Defective mitochondrial disulfide relay system, altered mitochondrial morphology and function in Huntington's disease

A number of studies have been conducted that link mitochondrial dysfunction (MD) to Huntington's disease (HD); however, contradicting results had resulted in a lack of a clear mechanism that links expression of mutant Huntingtin protein and MD. Mouse homozygous (HM) and heterozygous (HT) mutant striatal cells with two or one allele encoding for a mutant huntingtin protein with 111 polyGln repeats showed a significant impairment of the mitochondrial disulfide relay system (MDRS). This system (consisting of two proteins, Gfer and Mia40) is involved in the mitochondrial import of Cys-rich proteins. The Gfer-to-Mia40 ratio was significantly altered in HM cells compared with controls, along with the expression of mitochondrial proteins considered substrates of the MDRS. In progenitors and differentiated neuron-like HM cells, impairment of MDRS were accompanied by deficient oxidative phosphorylation, Complex I, IV and V activities, decreased mtDNA copy number and transcripts, accumulation of mtDNA deletions and changes in mitochondrial morphology, consistent with other MDRS-deficient biological models, thus providing a framework for the energy deficits observed in this HD model. The majority (>90%) of the mitochondrial outcomes exhibited a gene-dose dependency with the expression of mutant Htt. Finally, decreases in the mtDNA copy number, along with the accumulation of mtDNA deletions, provide a mechanism for the progressive neurodegeneration observed in HD patients.

ILPR repeats adopt diverse G-quadruplex conformations that determine insulin binding

The insulin-linked polymorphic region (ILPR) is a VNTR region located upstream of the insulin (INS) gene consisting of the repeat 5'-ACAGGGGTGTGGGG (repeat a) and several less abundant sequence repeats (b-n). Here, we have investigated the structural polymorphism of G-quadruplexes formed from the most common repeat sequences (a-c) and their effect on insulin protein binding. We first established that the ILPR repeats "b" and "c" can form quadruplex structures. Insulin has previously been shown to bind a G-quadruplex formed by a dimer of the repeat "a". Our findings show that insulin binds preferentially to the repeat "a" G-quadruplex (K(d) = 0.17 + or - 0.03 microM) over G-quadruplexes formed from other ILPR repeats that were tested (K(d)s from 0.71 + or - 0.15 to 1.07 + or - 0.09 microM). Additionally, the Watson-Crick complementary relationship between the loop regions of repeat "a" (ACA and TGT) seemingly play an important role in favoring a specific G-quadruplex conformation, which based on our data is critical for insulin binding. Affinity for insulin is reduced in sequences lacking the putative WC complementarity, however upon engineered restoration of complementarity, insulin binding is recovered. A DMS footprinting assay on the repeat "a" G-quadruplex in the presence of insulin, combined with binding affinities for ILPR mutants led to identification of a loop nucleotide critical for binding. Uniquely, insulin shows clear preference for binding to the G-quadruplexes with the more antiparallel feature. Collectively, our results illustrate the specific nature of insulin binding to the ILPR G-quadruplexes and begin to provide molecular details on such interactions.

Comparative sequence analysis of the non-protein-coding mitochondrial DNA of inbred rat strains

The proper function of mammalian mitochondria necessitates a coordinated expression of both nuclear and mitochondrial genes, most likely due to the co-evolution of nuclear and mitochondrial genomes. The non-protein coding regions of mitochondrial DNA (mtDNA) including the D-loop, tRNA and rRNA genes form a major component of this regulated expression unit. Here we present comparative analyses of the non-protein-coding regions from 27 Rattus norvegicus mtDNA sequences. There were two variable positions in 12S rRNA, 20 in 16S rRNA, eight within the tRNA genes and 13 in the D-loop. Only one of the three neutrality tests used demonstrated statistically significant evidence for selection in 16S rRNA and tRNA-Cys. Based on our analyses of conserved sequences, we propose that some of the variable nucleotide positions identified in 16S rRNA and tRNA-Cys, and the D-loop might be important for mitochondrial function and its regulation.

Alterations to the expression level of mitochondrial transcription factor A, TFAM, modify the mode of mitochondrial DNA replication in cultured human cells

Mitochondrial transcription factor A (TFAM) is an abundant mitochondrial protein of the HMG superfamily, with various putative roles in mitochondrial DNA (mtDNA) metabolism. In this study we have investigated the effects on mtDNA replication of manipulating TFAM expression in cultured human cells. Mammalian mtDNA replication intermediates (RIs) fall into two classes, whose mechanistic relationship is not properly understood. One class is characterized by extensive RNA incorporation on the lagging strand, whereas the other has the structure of products of conventional, strand-coupled replication. TFAM overexpression increased the overall abundance of RIs and shifted them substantially towards those of the conventional, strand-coupled type. The shift was most pronounced in the rDNA region and at various replication pause sites and was accompanied by a drop in the relative amount of replication-termination intermediates, a substantial reduction in mitochondrial transcripts, mtDNA decatenation and progressive copy number depletion. TFAM overexpression could be partially phenocopied by treatment of cells with dideoxycytidine, suggesting that its effects are partially attributable to a decreased rate of fork progression. TFAM knockdown also resulted in mtDNA depletion, but RIs remained mainly of the ribosubstituted type, although termination intermediates were enhanced. We propose that TFAM influences the mode of mtDNA replication via its combined effects on different aspects of mtDNA metabolism.

Conserved Sequence Box II Directs Transcription Termination and Primer Formation in Mitochondria

The human mitochondrial transcription machinery generates the RNA primers needed for initiation of heavy strand DNA synthesis. Most DNA replication events from the heavy strand origin are prematurely terminated, forming a persistent RNA-DNA hybrid, which remains annealed to the parental DNA strand. This triple-stranded structure is called the D-loop and encompasses the conserved sequence box II, a DNA element required for proper primer formation. We here use a purified recombinant mitochondrial transcription system and demonstrate that conserved sequence box II is a sequence-dependent transcription termination element in vitro. Transcription from the light strand promoter is prematurely terminated at positions 300-282 in the mitochondrial genome, which coincide with the major RNA-DNA transition points in the D-loop of human mitochondria. Based on our findings, we propose a model for primer formation at the origin of heavy strand DNA replication.

Natural competence of mammalian mitochondria allows the molecular investigation of mitochondrial gene expression

Respiration, a fundamental process in mammalian cells, requires two genomes, those of the nucleus and the mitochondrion (mtDNA). Mutations of mtDNA are being increasingly recognized in disease and may play an important role in the ageing process. Accepting the vital role of mtDNA gene products, our limited knowledge concerning the details of mitochondrial gene expression is surprising. This is, in part, due to our inability to transfect mitochondria and to manipulate their genome. There have been claims of successful DNA import into isolated organelles, but most reports lacked evidence of expression and no method has furthered our understanding of gene expression. Here, we report that mammalian mitochondria possess a natural competence for DNA import. Using five functional assays, we show imported DNA can act as templates for DNA synthesis or promoter-driven transcription, with the resultant polycistronic RNA being processed (5' and 3') and excised mt-tRNA matured. Exploiting this natural competence will allow us to explore mitochondrial gene expression in organello and provides the potential for mitochondrial transfection in vivo.

Vascular smooth muscle cell proliferation is dependent upon upregulation of mitochondrial transcription factor A (mtTFA) expression in injured rat carotid artery

Consistent with the physiological response to increased energy demand in proliferating cells, the number of mitochondria is upregulated in synthetic states of vascular smooth muscle cells (VSMC) in atherosclerotic lesion. We hypothesized that mitochondrial transcription factor A (mtTFA), a prerequisite factor for the transcription and replication of mtDNA, may be upregulated in VSMC of injured rat carotid artery, and that inhibition of its expression can attenuate the intimal thickening. Changes of intimal thickening and mtTFA expression by a treatment with antisense oligodeoxynucleotides (ODN) for mtTFA were investigated in balloon-injured rat carotid artery model. The expression of mtTFA was upregulated as early as 3 h up to 7 days after balloon injury. Delivery of ansisense ODN for mtTFA from adventitia side to injured arterial wall caused a significant decrease in intima-to-media (I/M) ratio. Furthermore, the increase in immunoreactivity and mRNA expression of mtTFA in injured artery as well as the number of mitochondria in intimal VSMC was abrogated by antisense ODN treatment. These data demonstrate that expression of mtTFA is upregulated in intimal VSMC of injured rat carotid artery, and that suppression of mtTFA expression by antisense ODN can attenuate intimal thickening after balloon injury.

Transient overexpression of mitochondrial transcription factor A (TFAM) is sufficient to stimulate mitochondrial DNA transcription, but not sufficient to increase mtDNA copy number in cultured cells

Mitochondrial transcription factor A (TFAM) stimulates transcription from mitochondrial DNA (mtDNA) promoters in vitro and in organello. To investigate whether changes of TFAM levels also modulate transcription and replication in situ, the protein was transiently overexpressed in cultured cells. Mitochondrial mRNAs were significantly elevated at early time points, when no expansion of the TFAM pool was yet observed, but were decreased when TFAM levels had doubled, resemb-ling in vitro results. HEK cells contain about 35 molecules of TFAM per mtDNA. High levels of TFAM were not associated with increases of full-length mtDNA, but nucleic acid species sensitive to RNAse H increased. Stimulation of transcription was more evident when TFAM was transiently overexpressed in cells pre-treated with ethidium bromide (EBr) having lowered mtDNA, TFAM and mitochondrial transcript levels. EBr rapidly inhibited mtDNA transcription, while decay of mtDNA was delayed and preferentially slowly migrating, relaxed mtDNA species were depleted. In conclusion, we show that transcription of mtDNA is submaximal in cultured cells and that a subtle increase of TFAM within the matrix is sufficient to stimulate mitochondrial transcription. Thus, this protein meets all criteria for being a key factor regulating mitochondrial transcription in vivo, but other factors are necessary for increasing mtDNA copy number, at least in cultured cells.

Import of mitochondrial transcription factor A (TFAM) into rat liver mitochondria stimulates transcription of mitochondrial DNA

Mitochondrial transcription factor A (TFAM) has been shown to stimulate transcription from mitochondrial DNA promoters in vitro. In order to determine whether changes in TFAM levels also regulate RNA synthesis in situ, recombinant human precursor proteins were imported into the matrix of rat liver mitochondria. After uptake of wt-TFAM, incorporation of [alpha-32P]UTP into mitochondrial mRNAs as well as rRNAs was increased 2-fold (P < 0.05), whereas import of truncated TFAM lacking 25 amino acids at the C-terminus had no effect. Import of wt-TFAM into liver mitochondria from hypothyroid rats stimulated RNA synthesis up to 4-fold. We conclude that the rate of transcription is submaximal in freshly isolated rat liver mitochondria and that increasing intra-mitochondrial TFAM levels is sufficient for stimulation. The low transcription rate associated with the hypothyroid state observed in vivo as well as in organello seems to be a result of low TFAM levels, which can be recovered by treating animals with T3 in vivo or by importing TFAM in organello. Thus, this protein meets the criteria for being a key factor in regulating mitochondrial gene expression in vivo.

Transcriptional initiation under conditions of anoxia-induced quiescence in mitochondria from Artemia franciscana embryos

In response to anoxia, embryos of the brine shrimp Artemia franciscana are able coordinately to downregulate metabolism to levels low enough to permit survival for several years at room temperature. In addition to dramatic decreases in free ATP levels and heat production, intracellular pH drops from 7.8 to 6.3 overnight. Use of isolated mitochondria to study transcriptional responses to anoxia offers several advantages: (1). the localized nature of transcript initiation, processing and degradation, all of which may be followed in organello; (2). the relatively simple cis- and trans-machinery involved and (3). the ability to provide relevant physiological treatments in vitro. In response to anoxic incubation of embryos in vivo for 4 h followed by anoxic mitochondrial isolation and anoxic transcription assay at pH 6.4, a significant decrease in overall UTP incorporation (77%) was seen after 30 min relative to normoxic, pH 7.9 controls. A less severe inhibition of transcription under anoxia (52%) was observed compared with controls when pH was raised to 7.9. Similarly, under normoxia, the incubation at low pH (6.4) reduced transcription by 59%. Ribonuclease protection assays showed that the contribution of in vitro initiation during the assay fell from 78% at pH 7.9 to approximately 32% at pH 6.4 under either normoxic or anoxic conditions. DNA footprinting of putative transcriptional promoters revealed proteins at regular intervals upstream of the 12S rRNA in the control region, which previously had been indirectly inferred to contain promoters for H-strand transcription. The area between 1230 and 12065 contains a sequence in the tRNA(leu) gene believed to bind the transcription termination factor mTERF or TERM, and we provide the first evidence that this sequence is protein-bound in A. franciscana. However, our hypothesis that initiation is reduced at low pH because of a change in DNA binding by mitochondrial transcription factors was not confirmed. We propose that regulation of initiation may be mediated by covalent modification or by protein-protein interactions not detected by footprinting.

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.

Mechanism of mammalian mitochondrial DNA replication: import of mitochondrial transcription factor A into isolated mitochondria stimulates 7S DNA synthesis

The light strand promoter of mammalian mitochondrial DNA gives rise to a primary transcript, but also to the RNA primer necessary for initiation of replication and 7S DNA synthesis as well as 7S RNA. Here we have studied the turnover of 7S DNA in isolated rat liver mitochondria and whether import of mitochondrial transcription factor A (mtTFA), which is necessary for transcription initiation, increases its rate of synthesis. 7S DNA was present as two species, probably due to two different sites of RNA-DNA transition. Time course and pulse-chase experiments showed that the half-life of this DNA is approximately 45 min. Import of mtTFA, produced in vitro, into the mitochondrial matrix in stoichiometric amounts significantly increased the rate of 7S DNA formation. We conclude that isolated rat liver mitochondria faithfully synthesize and degrade 7S DNA and that increased matrix levels of mtTFA are sufficient to increase its rate of synthesis, strongly supporting the hypothesis that this process is transcription primed.

Effects of contractile activity on mitochondrial transcription factor A expression in skeletal muscle

Mitochondrial transcription factor A (Tfam) is a nuclear-encoded gene product that is imported into mitochondria and is required for the transcription of mitochondrial DNA (mtDNA). We hypothesized that conditions known to produce mitochondrial biogenesis in skeletal muscle would be preceded by an increase in Tfam expression. Therefore, rat muscle was stimulated (10 Hz, 3 h/day). Tfam mRNA levels were significantly elevated (by 55%) at 4 days and returned to control levels at 14 days. Tfam import into intermyofibrillar (IMF) mitochondria was increased by 52 and 61% (P < 0.05) at 5 and 7 days, respectively. This corresponded to an increase in the level of import machinery components. Immunoblotting data indicated that IMF Tfam protein content was increased by 63% (P < 0.05) at 7 days of stimulation. This was associated with a 49% (P < 0.05) increase in complex formation at the mtDNA promoter and a 65% (P < 0.05) increase in the levels of a mitochondrial transcript, cytochrome-c oxidase (COX) subunit III. Similarly, COX enzyme activity was elevated by 71% (P < 0.05) after 7 days of contractile activity. These results indicate that early events in mitochondrial biogenesis include increases in Tfam mRNA, followed by accelerations in mitochondrial import and increased Tfam content, which correspond with increased binding to the mtDNA promoter region. This was accompanied by increased mitochondrial transcript levels and elevated COX activity. These data support the role of Tfam as a regulatory protein involved in contractile activity-induced mitochondrial biogenesis.

Stimulation of mitochondrial gene expression and proliferation of mitochondria following impairment of cellular energy transfer by inhibition of the phosphocreatine circuit in rat hearts

Mitochondria proliferate when cellular energy demand increases. However, the pathways leading to enhanced expression of mitochondrial genes are largely unknown. We tested the hypothesis that an altered flux through energy metabolism is the key regulatory event by decreasing mitochondrial energy supply to rat heart cells by creatine depletion. Electron microscopy showed that the density of mitochondria increased by 75% in such hearts (p < 0.01). Levels of representative mRNAs encoded on mitochondrial DNA (mtDNA) or on nuclear chromosomes were elevated 1.5 to 2-fold (p < 0.05), while the mtDNA content was unchanged. The mRNA for the nuclear encoded mitochondrial transcription factor A (mtTFA) was increased after GPA feeding (p < 0.05). Thus, we have shown that an impairment of mitochondrial energy supply causes stimulation of gene expression resulting in mitochondrial proliferation, probably as a compensatory mechanism. The observed activation of the mtTFA gene corroborates the important function of this protein in nuclear-mitochondrial communication.

Stimulation of mitochondrial gene expression and proliferation of mitochondria following impairment of cellular energy transfer by inhibition of the phosphocreatine circuit in rat hearts

Mitochondria proliferate when cellular energy demand increases. However, the pathways leading to enhanced expression of mitochondrial genes are largely unknown. We tested the hypothesis that an altered flux through energy metabolism is the key regulatory event by decreasing mitochondrial energy supply to rat heart cells by creatine depletion. Electron microscopy showed that the density of mitochondria increased by 75% in such hearts (p < 0.01). Levels of representative mRNAs encoded on mitochondrial DNA (mtDNA) or on nuclear chromosomes were elevated 1.5 to 2-fold (p < 0.05), while the mtDNA content was unchanged. The mRNA for the nuclear encoded mitochondrial transcription factor A (mtTFA) was increased after GPA feeding (p < 0.05). Thus, we have shown that an impairment of mitochondrial energy supply causes stimulation of gene expression resulting in mitochondrial proliferation, probably as a compensatory mechanism. The observed activation of the mtTFA gene corroborates the important function of this protein in nuclear-mitochondrial communication.

The 25 kDa protein recognizing the rat curved region upstream of the origin of the L-strand replication is the rat homologue of the human mitochondrial transcription factor A

Mass spectrometry matrix-assisted laser desorption ionization (MALDI) analysis and N-terminus sequencing as well as immunoblotting experiments using human and mouse antibodies have allowed us to identify the 25 kDa protein, previously isolated from rat liver using magnetic beads coated with a rat liver mitochondrial (mt) DNA region upstream of the Ori-L, as the homologue of human mt transcription factor A (mtTFA). We can therefore identify this DNA binding protein as the rat mtTFA. Furthermore, since we previously showed that the 25 kDa protein purified from rat liver was able to bind the curved mtDNA region upstream of the Ori-L as well as the curved mtDNA in the D-loop region, the results here reported lead us to state, for the first time, that mtTFA binds both the curved regions of mtDNA upstream of the two replication origins.

Mitochondrial DNA 4977 bp deletion and OH8dG levels correlate in the brain of aged subjects but not Alzheimer's disease patients

The levels of mitochondrial DNA 4977 bp deletion (mtDNA4977) and mitochondrial DNA 8'-hydroxy-2'-deoxyguanosine (OH8dG) were determined in the same samples from two brain areas of healthy subjects and Alzheimer's disease (AD) patients. A positive correlation between the age-related increases of mtDNA4977 and of OH8dG levels was found in the brain of healthy individuals. On the contrary, in both brain areas of AD patients, mtDNA4977 levels were very low in the presence of high OH8dG amounts. These results might be explained assuming that the increase of OH8dG above a threshold level, as in AD patients, implies consequences for mtDNA replication and neuronal cell survival.

Direct regulation of mitochondrial RNA synthesis by thyroid hormone

We have analyzed the influence of in vivo treatment and in vitro addition of thyroid hormone on in organello mitochondrial DNA (mtDNA) transcription and, in parallel, on the in organello footprinting patterns at the mtDNA regions involved in the regulation of transcription. We found that thyroid hormone modulates mitochondrial RNA levels and the mRNA/rRNA ratio by influencing the transcriptional rate. In addition, we found conspicuous differences between the mtDNA dimethyl sulfate footprinting patterns of mitochondria derived from euthyroid and hypothyroid rats at the transcription initiation sites but not at the mitochondrial transcription termination factor (mTERF) binding region. Furthermore, direct addition of thyroid hormone to the incubation medium of mitochondria isolated from hypothyroid rats restored the mRNA/rRNA ratio found in euthyroid rats as well as the mtDNA footprinting patterns at the transcription initiation area. Therefore, we conclude that the regulatory effect of thyroid hormone on mitochondrial transcription is partially exerted by a direct influence of the hormone on the mitochondrial transcription machinery. Particularly, the influence on the mRNA/rRNA ratio is achieved by selective modulation of the alternative H-strand transcription initiation sites and does not require the previous activation of nuclear genes. These results provide the first functional demonstration that regulatory signals, such as thyroid hormone, that modify the expression of nuclear genes can also act as primary signals for the transcriptional apparatus of mitochondria.

Increase in intracellular hydrogen peroxide and upregulation of a nuclear respiratory gene evoked by impairment of mitochondrial electron transfer in human cells

We have investigated an interorganelle communication pathway between the nucleus and mitochondria. We loaded a stress specific to mitochondria of human fibroblast cells by antimycin A (AA), an inhibitor of the mitochondrial cytochrome bc1 complex. AA inhibited cellular respiration in a dose-dependent manner. When the respiratory capacity was reduced to 50-70% of the original one, mRNA levels of cytochrome c1 as well as cytochrome b increased at 24 h after AA treatment, resulting in maintenance of the cell viability. In contrast, the cells retaining less than 40% of the original capacity showed no increase in either mRNA level and were targeted for death. Intracellular H2O2 level monitored by the fluorescence of dichlorofluorescein increased within 3 h in both the cases, although this increase was higher in the cells where the mRNA levels increased. An antioxidant N-acetylcysteine repressed the increases of not only H2O2 but also cytochrome c1 mRNA levels. These results suggest that the cells can respond to a limited impairment of electron transfer by promoting expression of nuclear and mitochondrial genes, probably through an H2O2-dependent signaling pathway.

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%).

Interferons suppress mitochondrial gene transcription by depleting mitochondrial transcription factor A (mtTFA)

Mitochondrial gene transcription activity in organello was suppressed after culturing HeLa cells with 1000 U/ml of interferon-alpha (IFN-alpha) or IFN-gamma for 18 h. The suppression was associated with reduced levels of mitochondrial gene transcripts. Northern blot analysis of HeLa cell RNA showed marked reduction of the mRNA encoding for mitochondrial transcription factor A (mtTFA). Immunoblotting with antiserum directed against recombinant mtTFA showed a reduced level of the protein as well. Consistently, gel-retardation assay of mitochondrial extract showed reduced level of functional mtTFA, which is known to bind to both heavy and light strand promoters of bidirectionally transcribed mitochondrial DNA. We suggest that depletion of mtTFA is a pathway through which IFNs depress the mitochondrial respiration.

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.

Rearrangements in the shorter arc of rat mitochondrial DNA involving the region of the heavy and light strand promoters

Brain mtDNA from rats ranging in age from 1 day to 33 months were analyzed for large-scale rearrangements using nested PCR. The region of the mtDNA targeted by the primers was the shorter are between the two origins of replication and encompassed the heavy (H) and light (L) strand promoters (HSP) and (LSP). Rearrangements lacking 4 to 5 kb of genomic sequence were found in animals of all ages. Twenty-two different rearrangements were sequenced; two of these were found replicated in several different animals. All the rearrangements identified lacked an HSP and six lacked an LSP as well. The end points of each rearrangement had short direct repeats of 9 bp or less, but repeats of 4 bp or less were the most common. The mode of involvement of the direct repeats in the rearrangement mechanism varied since in some cases a sequence precisely equivalent to one member of the paired repeats was found at the junction; whereas in other cases, more or less than one complete member was found. Sixteen of the 22 rearrangements terminated on one side within a 22-bp locus, or hot spot, located at a potential stem-loop structure midway between the HSP and LSP. The other ends of these rearrangements were at different sites. In addition, a secondary hot spot was found near the junction between the tRNA(Ala) and tRNA(Asn) genes, which lie in a cluster of five tRNA genes that surround the stem-loop structure of the L-strand origin of replication. The data suggest a link between secondary structure and short direct repeats and the rearrangement mechanism(s). The results of this study, in conjunction with out previous study of the longer arc of rat mtDNA (Van Tuyle, G.C., J.P. Gudikote, V.H. Hurt, B.B. Miller and C.A. Moore (1996) Multiple, Large deletions in rat mitochondrial DNA: Evidence for a major hot spot, Mutation Res., 349, 95-107), indicate that nearly the entire mitochondrial genome is subject to rearrangement mutations that are detectable in brain tissue throughout an animal's life span.