Identification of initiation sites for heavy-strand and light-strand transcription in human mitochondrial DNA

Multiple initiation sites for transcription of a gene for subunit 1 of F1-ATPase (atp1) in rice mitochondria

We identified the sites for the initiation of transcription of a gene for subunit 1 of F1-ATPase (atp1) in rice mitochondrial DNA. Capping and ribonuclease protection experiments in vitro, together with primer extension analysis, demonstrated that there were at least eight transcription initiation sites upstream of atp1. One initiation site, expressed most actively, was flanked by a sequence identical to the consensus promotor motif of rice mitochondrial genes. However, the sequences surrounding the other seven initiation sites exhibited no similarity to the consensus sequence.

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

Footprinting studies with the purine-modifying reagent dimethyl sulfate and with the single-stranded DNA probing reagent potassium permanganate were carried out in isolated mitochondria from rat liver. Dimethyl sulfate footprinting allowed the detection of protein-DNA interactions within the rat analogues of the human binding sites for the transcription termination factor mTERF and for the transcription activating factor mt-TFA. Although mTERF contacts were localized only at the boundary between the 16S rRNA/tRNA(Leu)UUR genes, multiple mtTFA contacts were detected. Contact sites were located in the light and the heavy strand promoters and, in agreement with in vitro footprinting data on human mitochondria, between the conserved sequence blocks (CSB) 1 and 2 and inside CSB-1. Potassium permanganate footprinting allowed detection of a 25-base pair region entirely contained in CSB-1 in which both strands were permanganate-reactive. No permanganate reactivity was associated with the other regions of the D-loop, including CSB-2 and -3, and with the mTERF contact site. We hypothesize that the single-stranded DNA at CSB-1 may be due to a profound helix distortion induced by mtTFA binding or be associated with a RNA polymerase pause site. In any case the location in CSB-1 of the 3' end of the most abundant replication primer and of the 5' end of the prominent D-loop DNA suggests that protein-induced DNA conformational changes play an important role in directing the transition from transcription to replication in mammalian mitochondria.

Complete sequence of the mitochondrial DNA of the annelid worm Lumbricus terrestris

We have determined the complete nucleotide (nt) sequence of the mitochondrial genome of an oligochaete annelid, the earthworm Lumbricus terrestris. This genome contains the 37 genes typical of metazoan mitochondrial DNA (mtDNA), including ATPase8, which is missing from some invertebrate mtDNAs. ATPase8 is not immediately upstream of ATPase6, a condition found previously only in the mtDNA of snails. All genes are transcribed from the same DNA strand. The largest noncoding region is 384 nt and is characterized by several homopolymer runs, a tract of alternating TA pairs, and potential secondary structures. All protein-encoding genes either overlap the adjacent downstream gene or end at an abbreviated stop codon. In Lumbricus mitochondria, the variation of the genetic code that is typical of most invertebrate mitochondrial genomes is used. Only the codon ATG is used for translation initiation. Lumbricus mtDNA is A + T rich, which appears to affect the codon usage pattern. The DHU arm appears to be unpaired not only in tRNAser(AGN), as is typical for metazoans, but perhaps also in tRNAser(UCN), a condition found previously only in a chiton and among nematodes. Relating the Lumbricus gene organization to those of other major protostome groups requires numerous rearrangements.

Mitochondrial transcription initiation: promoter structures and RNA polymerases

A diversity of promoter structures. It is evident that tremendous diversity exists between the modes of mitochondrial transcription initiation in the different eukaryotic kingdoms, at least in terms of promoter structures. Within vertebrates, a single promoter for each strand exists, which may be unidirectional or bidirectional. In fungi and plants, multiple promoters are found, and in each case, both the extent and the primary sequences of promoters are distinct. Promoter multiplicity in fungi, plants and trypanosomes reflects the larger genome size and scattering of genes relative to animals. However, the dual roles of certain promoters in transcription and replication, at least in yeast, raises the interesting question of how the relative amounts of RNA versus DNA synthesis are regulated, possibly via cis-elements downstream from the promoters. Mitochondrial RNA polymerases. With respect to mitochondrial RNA polymerases, characterization of human, mouse, Xenopus and yeast enzymes suggests a marked degree of conservation in their behavior and protein composition. In general, these systems consist of a relatively non-selective core enzyme, which itself is unable to recognize promoters, and at least one dissociable specificity factor, which confers selectivity to the core subunit. In most of these systems, components of the RNA polymerase have been shown to induce a conformational change in their respective promoters and have also been assigned the role of a primase in the replication of mtDNA. While studies of the yeast RNA polymerase have suggested it has both eubacterial (mtTFB) and bacteriophage (RPO41) origins, it is not yet clear whether these characteristics will be conserved in the mitochondrial RNA polymerases of all eukaryotes. mtTFA-mtTFB; conserved but dissimilar functions. With respect to transcription factors, mtTFA has been found in both vertebrates and yeast, and may be a ubiquitous protein in mitochondria. However, the divergence in non-HMG portions of the proteins, combined with differences in promoter structure, has apparently relegated mtTFA to alternative, or at least non-identical, physiological roles in vertebrates and fungi. The relative ease with which mtTFA can be purified (Fisher et al. 1991) suggests that, where present, it should be facile to detect. mtTFB may represent a eubacterial sigma factor adapted for interaction with the mitochondrial RNA polymerase.(ABSTRACT TRUNCATED AT 400 WORDS)

Analysis of the transcription products of the rainbow trout (Oncorynchus mykiss) liver mitochondrial genome: detection of novel mitochondrial transcripts

We have isolated and, by electrophoresis, using agarose slab gels in the presence of methylmercury hydroxide, analyzed the mitochondrial RNA content of the liver of rainbow trout. The RNAs corresponding to most of the mitochondrial DNA-encoded genes have been identified. Furthermore, among the transcription products we have also identified the nature of the RNA 8 previously described in human mitochondria, and detected a novel transcript that may represent the mRNA for ND6.

Nucleotide sequence of the sheep mitochondrial DNA D-loop and its flanking tRNA genes

The nucleotide sequence of the sheep mitochondrial DNA displacement-loop (D-loop) region and its flanking tRNA genes has been determined. Several conserved motifs among mammals have been identified along the 1189-bp sequence of the sheep control region: ten termination-associated sequences (TASs) and one conserved sequence block (CSB-1). CSB-2 and CSB-3, which are frequently found in most species, are not present in the sheep D-loop, which shows instead a short direct repeat at their usual localization. A long polypyrimidine tract between CSB-1 and the tRNA(Phe) gene is also present. Furthermore, the sheep mtDNA D-loop region displays tandem repeats in the left domain (adjacent to the tRNA(Pro) gene) comprising three different termination-associated sequences (TAS-5, TAS-6 and TAS-7).

Identification of a stable RNA encoded by the H-strand of the mouse mitochondrial D-loop region and a conserved sequence motif immediately upstream of its polyadenylation site

By using a combination of Northern blot hybridization with strand-specific DNA probes, S1 nuclease protection, and sequencing of oligo-dT-primed cDNA clones, we have identified a 0.8 kb poly(A)-containing RNA encoded by the H-strand of the mouse mitochondrial D-loop region. The 5' end of the RNA maps to nucleotide 15417, a region complementary to the start of tRNA(Pro) gene and the 3' polyadenylated end maps to nucleotide 16295 of the genome, immediately upstream of tRNA(Phe) gene. The H-strand D-loop region encoded transcripts of similar size are also detected in other vertebrate systems. In the mouse, rat, and human systems, the 3' ends of the D-loop encoded RNA are preceded by conserved sequences AAUAAA, AAUUAA, or AACUAA, that resemble the polyadenylation signal. The steady-state level of the RNA is generally low in dividing or in vitro cultured cells, and markedly higher in differentiated tissues like liver, kidney, heart, and brain. Furthermore, an over 10-fold increase in the level of this RNA is observed during the induced differentiation of C2C12 mouse myoblast cells into myotubes. These results suggest that the D-loop H-strand encoded RNA may have yet unknown biological functions. A 20 base pair DNA sequence from the 3' terminal region containing the conserved sequence motif binds to a protein from the mitochondrial extracts in a sequence-specific manner. The binding specificity of this protein is distinctly different from the previously characterized H-strand DNA termination sequence in the D-loop or the H-strand transcription terminator immediately downstream of the 16S rRNA gene. Thus, we have characterized a novel poly(A)-containing RNA encoded by the H-strand of the mitochondrial D-loop region and also identified the putative ultimate termination site for the H-strand transcription.

In organello footprint analysis of human mitochondrial DNA: human mitochondrial transcription factor A interactions at the origin of replication

Using in organello footprint analysis, we demonstrate that within human placental mitochondria there is a high level of protein-DNA binding at regularly phased intervals throughout a 500-bp region encompassing the D-loop DNA origins and two promoter regions. Comparison with in vitro DNase I protection studies indicates that this protein-DNA interaction is due to non-sequence-specific binding by human mitochondrial transcription factor A (h-mtTFA). Since h-mtTFA can bend and wrap DNA, like its yeast counterpart ABF2, a primary function of h-mtTFA appears to be specific packaging of the mitochondrial DNA control region in vivo. Intervals of protein binding coincide with the spacing of the RNA start sites and prominent D-loop DNA 5' ends, suggesting a role for phased h-mtTFA binding in defining transcription and H-strand DNA replication origins. Significant protein-DNA interaction was also observed within the human homolog of conserved sequence block 1, both in organello and in vitro, using purified h-mtTFA.

In organello footprint analysis of human mitochondrial DNA: human mitochondrial transcription factor A interactions at the origin of replication

Using in organello footprint analysis, we demonstrate that within human placental mitochondria there is a high level of protein-DNA binding at regularly phased intervals throughout a 500-bp region encompassing the D-loop DNA origins and two promoter regions. Comparison with in vitro DNase I protection studies indicates that this protein-DNA interaction is due to non-sequence-specific binding by human mitochondrial transcription factor A (h-mtTFA). Since h-mtTFA can bend and wrap DNA, like its yeast counterpart ABF2, a primary function of h-mtTFA appears to be specific packaging of the mitochondrial DNA control region in vivo. Intervals of protein binding coincide with the spacing of the RNA start sites and prominent D-loop DNA 5' ends, suggesting a role for phased h-mtTFA binding in defining transcription and H-strand DNA replication origins. Significant protein-DNA interaction was also observed within the human homolog of conserved sequence block 1, both in organello and in vitro, using purified h-mtTFA.

Complete DNA sequence of the mitochondrial genome of the black chiton, Katharina tunicata

The DNA sequence of the 15,532-base pair (bp) mitochondrial DNA (mtDNA) of the chiton Katharina tunicata has been determined. The 37 genes typical of metazoan mtDNA are present: 13 for protein subunits involved in oxidative phosphorylation, 2 for rRNAs and 22 for tRNAs. The gene arrangement resembles those of arthropods much more than that of another mollusc, the bivalve Mytilus edulis. Most genes abut directly or overlap, and abbreviated stop codons are inferred for four genes. Four junctions between adjacent pairs of protein genes lack intervening tRNA genes; however, at each of these junctions there is a sequence immediately adjacent to the start codon of the downstream gene that is capable of forming a stem-and-loop structure. Analysis of the tRNA gene sequences suggests that the D arm is unpaired in tRNA(ser)(AGN), which is typical of metazoan mtDNAs, and also in tRNA(ser)(UCN), a condition found previously only in nematode mtDNAs. There are two additional sequences in Katharina mtDNA that can be folded into structures resembling tRNAs; whether these are functional genes is unknown. All possible codons except the stop codons TAA and TAG are used in the protein-encoding genes, and Katharina mtDNA appears to use the same variation of the mitochondrial genetic code that is used in Drosophila and Mytilus. Translation initiates at the codons ATG, ATA and GTG. A + T richness appears to have affected codon usage patterns and, perhaps, the amino acid composition of the encoded proteins. A 142-bp non-coding region between tRNA(glu) and CO3 contains a 72-bp tract of alternating A and T.

Alterations in mitochondrial RNA expression after renal ischemia

Ischemia and reperfusion damage mitochondrial structure and impair respiratory function. In this study, 45 min of renal ischemia followed by varying periods of reflow profoundly depressed the activity of several respiratory complexes in mitochondria isolated from rat kidneys. The respiratory complexes are composed of subunits encoded by both the nuclear and mitochondrial genomes. To determine the role of mitochondrial gene expression in recovery of respiratory function, expression of mitochondrial RNA was examined during reperfusion. Both mature and incompletely processed cytochrome b mRNA levels were depressed after 45 min of ischemia and 15 min of reflow; levels rebounded to above normal after 2 h of reflow and then declined over the next 22 h. Another mitochondrial RNA showed a similar pattern; in contrast, the levels of a nuclear-encoded subunit mRNA for a respiratory enzyme and of 28S rRNA were unchanged. These data demonstrate that renal ischemia followed by reperfusion alters mitochondrial RNA expression. We speculate that mitochondrial RNA turnover is increased in response to continuing injury and that recovery is accompanied by enhanced RNA synthesis.

Codons AGA and AGG are read as glycine in ascidian mitochondria

A 1.2-kb DNA fragment of the cytochrome oxidase subunit I (CO I) gene of mitochondria isolated from an ascidian, Halocynthia roretzi, was amplified by polymerase chain reaction (PCR) and sequenced. Codons AGA and AGG appeared in its reading frame, indicating that these are sense codons in this organelle. Sequence comparisons with the corresponding regions of other animal mitochondrial CO I genes suggest that codons AGA and AGG correspond to glycine in the ascidian mitochondrial genome, but not to serine as in most invertebrate genomes, nor to stops as in vertebrate genomes. The other codons are identical to those of vertebrate mitochondria.

The mitochondrial genomes of two nematodes, Caenorhabditis elegans and Ascaris suum

The nucleotide sequences of the mitochondrial DNA (mtDNA) molecules of two nematodes, Caenorhabditis elegans [13,794 nucleotide pairs (ntp)], and Ascaris suum (14,284 ntp) are presented and compared. Each molecule contains the genes for two ribosomal RNAs (s-rRNA and l-rRNA), 22 transfer RNAs (tRNAs) and 12 proteins, all of which are transcribed in the same direction. The protein genes are the same as 12 of the 13 protein genes found in other metazoan mtDNAs: Cyt b, cytochrome b; COI-III, cytochrome c oxidase subunits I-III; ATPase6, Fo ATPase subunit 6; ND1-6 and 4L, NADH dehydrogenase subunits 1-6 and 4L: a gene for ATPase subunit 8, common to other metazoan mtDNAs, has not been identified in nematode mtDNAs. The C. elegans and A. suum mtDNA molecules both include an apparently noncoding sequence that contains runs of AT dinucleotides, and direct and inverted repeats (the AT region: 466 and 886 ntp, respectively). A second, apparently noncoding sequence in the C. elegans and A. suum mtDNA molecules (109 and 117 ntp, respectively) includes a single, hairpin-forming structure. There are only 38 and 89 other intergenic nucleotides in the C. elegans and A. suum mtDNAs, and no introns. Gene arrangements are identical in the C. elegans and A. suum mtDNA molecules except that the AT regions have different relative locations. However, the arrangement of genes in the two nematode mtDNAs differs extensively from gene arrangements in all other sequenced metazoan mtDNAs. Unusual features regarding nematode mitochondrial tRNA genes and mitochondrial protein gene initiation codons, previously described by us, are reviewed. In the C. elegans and A. suum mt-genetic codes, AGA and AGG specify serine, TGA specifies tryptophan and ATA specifies methionine. From considerations of amino acid and nucleotide sequence similarities it appears likely that the C. elegans and A. suum ancestral lines diverged close to the time of divergence of the cow and human ancestral lines, about 80 million years ago.

Molecular characterization and cloning of sheep mitochondrial DNA

Mitochondrial DNA from the liver of a single Rasa Aragonesa sheep has been isolated and characterized. The size of the genome, determined by restriction enzyme analysis, was found to be 16.58 kbp. The cleavage sites for the restriction endonucleases BamHI, HindIII, EcoRI, BglII, PvuII, BstEII and PstI were mapped, and the gene organization deduced through heterologous hybridization using different cloned fragments of the rat mitochondrial genome. Fragments representative of the entire sheep genome were cloned in plasmid vectors pGEM3Z and pUN121.

Saturation of the processing of newly synthesized rRNA in isolated brain mitochondria

Isolated rat brain mitochondria, when incubated in the presence of [alpha-32P]UTP in an appropriate incubation buffer, in which the energy requirements are provided by exogenous ADP in the presence of an oxidizable substrate, are able to support mitochondrial DNA transcription and RNA processing in a way faithfully resembling the in vivo process. Furthermore, we have strikingly found a saturation of the synthesis of mature 16 S and 12 S rRNA under conditions in which their RNA precursor as well as the mature mRNAs continue being synthesized. This suggests that synthesis of mature rRNAs could be regulated at the level of processing of their precursor rather than at the level of transcription.

Mitochondrial DNA structure and expression in specialized subtypes of mammalian striated muscle

Mitochondrial DNA (mt DNA) in cells of vertebrate organisms can assume an unusual triplex DNA structure known as the displacement loop (D loop). This triplex DNA structure forms when a partially replicated heavy strand of mtDNA (7S mtDNA) remains annealed to the light strand, displacing the native heavy strand in this region. The D-loop region contains the promoters for both heavy- and light-strand transcription as well as the origin of heavy-strand replication. However, the distribution of triplex and duplex forms of mtDNA in relation to respiratory activity of mammalian tissues has not been systematically characterized, and the functional significance of the D-loop structure is unknown. In comparisons of specialized muscle subtypes within the same species and of the same muscle subtype in different species, the relative proportion of D-loop versus duplex forms of mtDNA in striated muscle tissues of several mammalian species demonstrated marked variation, ranging from 1% in glycolytic fast skeletal fibers of the rabbit to 65% in the mouse heart. There was a consistent and direct correlation between the ratio of triplex to duplex forms of mtDNA and the capacity of these tissues for oxidative metabolism. The proportion of D-loop forms likewise correlated directly with mtDNA copy number, mtRNA abundance, and the specific activity of the mtDNA (gamma) polymerase. The D-loop form of mtDNA does not appear to be transcribed at greater efficiency than the duplex form, since the ratio of mtDNA copy number to mtRNA was unrelated to the proportion of triplex mtDNA genomes. However, tissues with a preponderance of D-loop forms tended to express greater levels of cytochrome b mRNA relative to mitochondrial rRNA transcripts, suggesting that the triplex structure may be associated with variations in partial versus full-length transcription of the heavy strand.

Mitochondrial DNA structure and expression in specialized subtypes of mammalian striated muscle

Mitochondrial DNA (mt DNA) in cells of vertebrate organisms can assume an unusual triplex DNA structure known as the displacement loop (D loop). This triplex DNA structure forms when a partially replicated heavy strand of mtDNA (7S mtDNA) remains annealed to the light strand, displacing the native heavy strand in this region. The D-loop region contains the promoters for both heavy- and light-strand transcription as well as the origin of heavy-strand replication. However, the distribution of triplex and duplex forms of mtDNA in relation to respiratory activity of mammalian tissues has not been systematically characterized, and the functional significance of the D-loop structure is unknown. In comparisons of specialized muscle subtypes within the same species and of the same muscle subtype in different species, the relative proportion of D-loop versus duplex forms of mtDNA in striated muscle tissues of several mammalian species demonstrated marked variation, ranging from 1% in glycolytic fast skeletal fibers of the rabbit to 65% in the mouse heart. There was a consistent and direct correlation between the ratio of triplex to duplex forms of mtDNA and the capacity of these tissues for oxidative metabolism. The proportion of D-loop forms likewise correlated directly with mtDNA copy number, mtRNA abundance, and the specific activity of the mtDNA (gamma) polymerase. The D-loop form of mtDNA does not appear to be transcribed at greater efficiency than the duplex form, since the ratio of mtDNA copy number to mtRNA was unrelated to the proportion of triplex mtDNA genomes. However, tissues with a preponderance of D-loop forms tended to express greater levels of cytochrome b mRNA relative to mitochondrial rRNA transcripts, suggesting that the triplex structure may be associated with variations in partial versus full-length transcription of the heavy strand.

Expression of six mitochondrial genes during Drosophila oogenesis: analysis by in situ hybridization

We have done a comparative analysis of RNA from six mitochondrial genes (rDNA, ND2, COI, COIII, ND4-ND5, Cyt b) during Drosophila oogenesis, using in situ hybridization. This study showed the same variation for each of these transcripts, which is similar to that obtained with the total mitochondrial RNA (Tourmente et al. (1990) Biol. Cell 60, 119-127). A constant RNA density until stage 9, followed by a rapid decline, was observed in follicle and nurse cells. These results confirm those previously obtained (Tourmente et al., (1990) Biol. Cell 60, 119-127), in favor of the existence of a correlation between the mtRNA level and the cell volume and/or the nuclear DNA content, and suggest a global extra-mitochondrial, transcriptional control mechanism. We also show that the relative proportions of the different RNA are similar, whatever the stage and cell type examined, even though the total mtRNA quantity is different. They are comparable to those previously obtained by Northern analysis of Drosophila embryos (Berthier et al. (1986) Nucleic Acids Res. 14, 1400-1412, suggesting a posttranscriptional control independent of the cell type. Surprisingly, we have detected an extra-mitochondrial hybridization for COIII, both in light and electron microscopy. Northern analysis of poly(A)+RNA from ovaries or cultured cells revealed an 1.7 kb extra-mitochondrial RNA, which is probably of nuclear origin.

The complete and symmetric transcription of the main non coding region of rat mitochondrial genome: in vivo mapping of heavy and light transcripts

The experiments here reported demonstrate that the main non-coding region of rat mitochondrial DNA is symmetrically transcribed. We have identified stable heavy and light transcripts, whose pattern is rather complex, in the D-loop region of rat mitochondrial DNA. Their relative concentrations have been determined. We detected heavy transcripts which encompass the whole D-loop and more abundant heavy RNA species which we interpreted as transcripts terminating downstream of the 3' end of the last coded gene (Thr-tRNA). The processed heavy RNA species contain polyA, suggesting a strict association between cleavage and polyadenylation. The pattern of light transcripts shows a long RNA, which, starting from the light strand promoter, covers the whole segment, and shorter RNA species which seems to be actively processed at the level of the conserved sequence boxes, probably acting as primers. The symmetric transcription of the D-loop containing region of rat mitochondrial DNA, and in particular the presence of stable transcripts complementary to the putative RNA primers, suggest that mechanisms mediated by interaction between complementary transcripts (antisense RNAs) might play a role in the regulation of mitochondrial DNA replication and expression.

Effect of DNA conformation on the transcription of mitochondrial DNA

The importance of the conformation of the DNA template for in vitro transcription experiments was investigated using a mitochondrial RNA polymerase preparation from Xenopus laevis oocyte mitochondria. A premature termination transcription assay has been devised and the levels of the formation of transcriptional complexes have been identified using agarose gel electrophoresis. It was found that accurate initiation of transcription from in vivo promoter sequences was enhanced by supercoiling and that the two mitochondrial DNA-binding proteins, previously characterized by us, inhibited the transcription of DNA as gauged by these assays.

Mutually exclusive synthetic pathways for sea urchin mitochondrial rRNA and mRNA

The structure and abundance of mitochondrial transcripts in sea urchin embryos were investigated by a combination of RNA blot-hybridization, S1 mapping, and primer extension assays. Between the egg and blastula stages, the relative abundance of mitochondrial rRNAs declined slightly, while that of mitochondrial mRNAs increased up to 10-fold. Fine mapping of the termini of the rRNAs and of the adjacent transcripts indicated that, although they appeared to be butt-joined at their 5' ends to the upstream transcripts, tRNA-Phe 5' to the small subunit (12S) rRNA and NADH dehydrogenase subunit 2 mRNA 5' to the large subunit (16S) rRNA, respectively, their 3' ends were found to overlap the 5' ends of the downstream transcripts. 12S rRNA was found to extend 7 to 13 nucleotides into the sequence of tRNA-Glu; 16S rRNA was shown to terminate 3 to 5 nucleotides inside the coding region of cytochrome oxidase subunit 1 (COI) and 8 to 10 nucleotides from the mapped 5' end of COI mRNA. The rRNAs and the downstream transcripts must therefore be synthesized by distinct pathways, either by alternative processing of the same primary transcript(s) or by processing of different precursors. In either case, the events which select the ribosomal 3' ends preclude the production of functional transcripts of the downstream genes from the same precursor molecule. No developmental alterations in transcript structure were detected. We propose that mitochondrial RNA levels are regulated in early development by the selection of alternate and mutually exclusive RNA-processing pathways.

Mutually exclusive synthetic pathways for sea urchin mitochondrial rRNA and mRNA

The structure and abundance of mitochondrial transcripts in sea urchin embryos were investigated by a combination of RNA blot-hybridization, S1 mapping, and primer extension assays. Between the egg and blastula stages, the relative abundance of mitochondrial rRNAs declined slightly, while that of mitochondrial mRNAs increased up to 10-fold. Fine mapping of the termini of the rRNAs and of the adjacent transcripts indicated that, although they appeared to be butt-joined at their 5' ends to the upstream transcripts, tRNA-Phe 5' to the small subunit (12S) rRNA and NADH dehydrogenase subunit 2 mRNA 5' to the large subunit (16S) rRNA, respectively, their 3' ends were found to overlap the 5' ends of the downstream transcripts. 12S rRNA was found to extend 7 to 13 nucleotides into the sequence of tRNA-Glu; 16S rRNA was shown to terminate 3 to 5 nucleotides inside the coding region of cytochrome oxidase subunit 1 (COI) and 8 to 10 nucleotides from the mapped 5' end of COI mRNA. The rRNAs and the downstream transcripts must therefore be synthesized by distinct pathways, either by alternative processing of the same primary transcript(s) or by processing of different precursors. In either case, the events which select the ribosomal 3' ends preclude the production of functional transcripts of the downstream genes from the same precursor molecule. No developmental alterations in transcript structure were detected. We propose that mitochondrial RNA levels are regulated in early development by the selection of alternate and mutually exclusive RNA-processing pathways.

Comparisons of ape and human sequences that regulate mitochondrial DNA transcription and D-loop DNA synthesis

The mitochondrial DNA (mtDNA) control regions for common chimpanzee, pygmy chimpanzee and gorilla were sequenced and the lengths and termini of their D-loop DNA's characterized. In these and all other species for which there are data, 5' termini map to sequences that contain the trinucleotide YAY. 3' termini are 25-51 nucleotides downstream from a sequence that is moderately conserved among vertebrates. Substitutions were greater than 1.5 times more frequent in the control region than in regions encoding structural genes. Additions and deletions were also frequent, especially in gorilla. Sequences of promoters and of two of four transcription factor binding sites were highly conserved. Comparisons of sequence similarity and transition/transversion ratios suggest that human and chimpanzees may be more closely related to each other than either is to gorilla, if substitution rates are approximately equal among these species.

RNA processing and multiple transcription initiation sites result in transcript size heterogeneity in maize mitochondria

Variation in the length of the 5' non-coding region of mitochondrial gene transcripts could result from multiple transcription initiation sites or post-transcriptional processing events. To distinguish between these possibilities, we have utilized the in vitro capping reaction catalyzed by guanylyl transferase to specifically label the 5' end of primary, unprocessed transcripts. Hybridization of in vitro capped mtRNA to immobilized DNA from the 5' flanking regions of 26 S, 18 S and 5 S rRNA genes and two protein-coding genes, ATP synthase subunit 9 (atp9) and apocytochrome b (cob), identified regions where transcription initiates. Single-strand specific RNase treatment of in vitro capped RNA hybridized to immobilized DNA containing the 5' flanking sequences from cob and atp9 suggests that these genes have multiple transcription initiation sites. Direct mapping of transcription initiation sites for the rRNA genes indicated that single major transcription initiation sites exist at approximately 180 and 230 nucleotides upstream from the mature 26 S and 18 + 5 S rRNA genes, respectively. Labeling of processed transcripts bearing a 5' hydroxyl moiety with T4 polynucleotide kinase and subsequent hybridization to the rRNA genes indicated that the mature forms of the rRNA are processed.

Drosophila mitochondrial DNA: conserved sequences in the A + T-rich region and supporting evidence for a secondary structure model of the small ribosomal RNA

The sequence of a segment of the Drosophila virilis mitochondrial DNA (mtDNA) molecule that contains the A + T-rich region, the small rRNA gene, the tRNA(f-met), tRNA(gln), and tRNA(ile) genes, and portions of the ND2 and tRNA(val) genes is presented and compared with the corresponding segment of the D. yakuba mtDNA molecule. The A + T-rich regions of D. virilis and D. yakuba contain two correspondingly located sequences of 49 and 276/274 nucleotides that appear to have been conserved during evolution. In each species the replication origin of the mtDNA molecule is calculated to lie within a region that overlaps the larger conserved sequence, and within this overlap is found a potential hairpin structure. Substitutions between the larger conserved sequences of the A + T-rich regions, the small mt-rRNA genes, and the ND2 genes are biased in favor of transversions, 71-97% of which are A----T changes. There is a 13.8 times higher frequency of nucleotide differences between the 5' halves than between the 3' halves of the D. virilis and D. yakuba small mt-rRNA genes. Considerations of the effects of observed substitutions and deletion/insertions on possible nucleotide pairing within the small mt-rRNA genes of D. virilis and D. yakuba strongly support the secondary structure model for the Drosophila small mt-rRNA that we previously proposed.

Specific requirement for ATP at an early step of in vitro transcription of human mitochondrial DNA

The ATP concentrations allowing transcription of both heavy- and light-strand of human mtDNA in a HeLa cell mitochondrial lysate were found to cover a broad range, with a maximum around 2.5 mM, and with reproducible differences in the ATP response curves for the two transcription events. Direct measurements showed that nonspecific ATP degradation during the assay did not account for the high ATP requirement. 5'-Adenylyl imidodiphosphate (p[NH]ppA), an ATP analog with a nonhydrolyzable beta-gamma bond, was unable to substitute for ATP in supporting mtDNA transcription but greatly stimulated this transcription in the presence of a low concentration of exogenous ATP. Evidence was obtained indicating that p[NH]ppA did not support an early event in mtDNA transcription (formation of preinitiation complex or initiation), whereas this analog could substitute effectively for ATP in the subsequent elongation steps. These results pointed to a specific requirement for ATP at an early step of the transcription process.

The excised leader of human cytochrome c oxidase subunit I mRNA which contains the origin of mitochondrial DNA light-strand synthesis accumulates in mitochondria and is polyadenylated

We identified a polyadenylated RNA species which contains the origin of human mitochondrial DNA light-strand synthesis and the surrounding complementary sequences of the four light-strand-encoded tRNAs. This RNA (RNA 9L) is probably derived from the leader portion of RNA 6 which is excised during the formation of the mature cytochrome c oxidase subunit mRNA (RNA 9). The high degree of secondary structure of this RNA is presumably responsible for its anomalous electrophoretic behavior in denaturing polyacrylamide gels.

The excised leader of human cytochrome c oxidase subunit I mRNA which contains the origin of mitochondrial DNA light-strand synthesis accumulates in mitochondria and is polyadenylated

We identified a polyadenylated RNA species which contains the origin of human mitochondrial DNA light-strand synthesis and the surrounding complementary sequences of the four light-strand-encoded tRNAs. This RNA (RNA 9L) is probably derived from the leader portion of RNA 6 which is excised during the formation of the mature cytochrome c oxidase subunit mRNA (RNA 9). The high degree of secondary structure of this RNA is presumably responsible for its anomalous electrophoretic behavior in denaturing polyacrylamide gels.

Identification of primary transcriptional start sites of mouse mitochondrial DNA: accurate in vitro initiation of both heavy- and light-strand transcripts

The major transcriptional control sequences of vertebrate mitochondrial DNA lie within the displacement loop region. Transcription events initiating in the displacement loop sequence of the mouse genome were identified by 5' end mapping of primary transcripts by S1 nuclease protection and primer extension techniques. Light-strand transcription initiates at a single site, 165 nucleotides upstream of the major heavy-strand origin of replication. Transcription of the heavy strand occurs at two distinct sites, 5 and 13 nucleotides upstream of the gene for phenylalanyl-tRNA, the first heavy-strand-encoded gene. This spatial relationship of the two transcriptional start sites with each other and with the origin of heavy-strand replication and the gene for tRNAPhe is quite similar to that for human mitochondrial DNA. The predominant form of primary heavy-strand transcript in mouse is a short, ca. 75-nucleotide, RNA containing the sequences of tRNAPhe and a few additional nucleotides at the 5' end of tRNAPhe, suggesting that the processing of tRNA involves independent cleavages at the 5' and 3' ends of tRNA sequences.

Precise assignment of the light-strand promoter of mouse mitochondrial DNA: a functional promoter consists of multiple upstream domains

Using deletion mutagenesis we localized the promoter for the light strand of mouse mitochondrial DNA to a 97-base-pair region, from -88 to +9 nucleotides of the transcriptional initiation site. Within this region the light-strand promoter could be dissected into at least three different functional domains. The specificity region, a maximum of 19 base pairs between -10 and +9 of the transcriptional initiation site, was essential and sufficient for accurate transcriptional initiation. A second region, extending to -29 nucleotides from the initiation site, facilitated the formation of a preinitiation complex between the template DNA and factor(s) present in the mitochondrial RNA polymerase fraction and was required for efficient transcription. A third, ill-defined upstream region, which extended up to -88 nucleotides from the initiation site, appeared to influence template transcriptional efficiencies in competition assays. Without the specificity domain, the upstream regions were incapable of supporting any transcription. The presence of multiple upstream domains was confirmed by disrupting nucleotide sequences in the upstream region by using linker insertion and linker replacement techniques.

Diverse patterns of expression of the cytochrome c oxidase subunit I gene and unassigned reading frames 4 and 5 during the life cycle of Trypanosoma brucei

Transcription of a maxicircle segment from Trypanosoma brucei 164 that contains nucleotide (nt) sequences corresponding to cytochrome c oxidase subunit I (COI) and unassigned reading frames (URFs) 4 and 5 of other mitochondrial systems was investigated. Two major transcripts that differ in size by ca. 200 nt map to each of the COI and URF4 genes, while a single major transcript maps to URF5. In total RNA, the larger COI transcript is more abundant in procyclic forms (PFs) than in bloodstream forms (BFs), the smaller COI and both URF4 transcripts have similar abundances in both forms, and the single URF5 transcript is more abundant in BF than PF. These patterns of expression differ in poly(A)+ RNA as a result of a higher proportion of poly(A)+ mitochondrial transcripts in PFs than in BFs. In addition, small (300- to 500-nt) RNAs that are transcribed from C-rich sequences located between putative protein-coding genes also exhibit diverse patterns of expression between life cycle stages and differences in polyadenylation in PFs compared with BFs. These observations suggest that multiple processes regulate the differential expression of mitochondrial genes in T. brucei.

Precise assignment of the light-strand promoter of mouse mitochondrial DNA: a functional promoter consists of multiple upstream domains

Using deletion mutagenesis we localized the promoter for the light strand of mouse mitochondrial DNA to a 97-base-pair region, from -88 to +9 nucleotides of the transcriptional initiation site. Within this region the light-strand promoter could be dissected into at least three different functional domains. The specificity region, a maximum of 19 base pairs between -10 and +9 of the transcriptional initiation site, was essential and sufficient for accurate transcriptional initiation. A second region, extending to -29 nucleotides from the initiation site, facilitated the formation of a preinitiation complex between the template DNA and factor(s) present in the mitochondrial RNA polymerase fraction and was required for efficient transcription. A third, ill-defined upstream region, which extended up to -88 nucleotides from the initiation site, appeared to influence template transcriptional efficiencies in competition assays. Without the specificity domain, the upstream regions were incapable of supporting any transcription. The presence of multiple upstream domains was confirmed by disrupting nucleotide sequences in the upstream region by using linker insertion and linker replacement techniques.

RNA mapping on Drosophila mitochondrial DNA: precursors and template strands

Drosophila melanogaster mitochondrial DNA (mtDNA) is closely related to the mammalian and amphibian mtDNA except for gene organization. In Drosophila, genes are distributed in clusters alternatively coded on each strand. Besides the eleven major foreseeable transcripts previously described (MERTEN and PARDUE, 1981, J. Mol. Biol., 153, 1-21), we have characterized two poly A+ transcripts, one major and one minor which could correspond respectively to the ND3 and ND6 reading frames, and 27 poly A+ minor transcripts (0.2 to greater than 3.2 kb) which are distributed along the mtDNA except in the rRNAs, ND 1 and A+ T rich regions. The mapping and length of 25 of these transcripts strongly suggest a precursor role. They would be processed at the level of tRNA or tRNA-like sequences. Most of them are transcribed from the template strand of each gene cluster and their distribution is in agreement with the hypothesis of several transcription origins and terminations located near the extremities of each gene cluster. Quantitatively our results show a large variation in each presumptive mature transcript compared to the other, even in a given gene cluster, suggesting a specific degradation of some of the mature transcripts.

Identification of primary transcriptional start sites of mouse mitochondrial DNA: accurate in vitro initiation of both heavy- and light-strand transcripts

The major transcriptional control sequences of vertebrate mitochondrial DNA lie within the displacement loop region. Transcription events initiating in the displacement loop sequence of the mouse genome were identified by 5' end mapping of primary transcripts by S1 nuclease protection and primer extension techniques. Light-strand transcription initiates at a single site, 165 nucleotides upstream of the major heavy-strand origin of replication. Transcription of the heavy strand occurs at two distinct sites, 5 and 13 nucleotides upstream of the gene for phenylalanyl-tRNA, the first heavy-strand-encoded gene. This spatial relationship of the two transcriptional start sites with each other and with the origin of heavy-strand replication and the gene for tRNAPhe is quite similar to that for human mitochondrial DNA. The predominant form of primary heavy-strand transcript in mouse is a short, ca. 75-nucleotide, RNA containing the sequences of tRNAPhe and a few additional nucleotides at the 5' end of tRNAPhe, suggesting that the processing of tRNA involves independent cleavages at the 5' and 3' ends of tRNA sequences.

Computer prediction of peptide maps: assignment of polypeptides to human and mouse mitochondrial DNA genes by analysis of two-dimensional-proteolytic digest gels

We have prepared a computer program that predicts complete and partial peptide maps from amino acid sequences. The program fragments amino acid sequences at designated cleavage sites and calculates the molecular weight and relative labeling of each peptide. These data are graphed as log molecular weight of the original protein (X-axis) vs. log molecular weight of the component peptides (Y-axis). The program is interactive, permitting adjustment of a number of graphic parameters and alteration of the position of proteins in the first dimension to accommodate aberrations in protein mobility. The program has been used to predict the V8 protease peptide maps of the 13 open reading frames (ORFs) identified in the human and the mouse mitochondrial DNA (mtDNA) sequences. The results were compared to the V8 protease peptide maps obtained for mouse and human mitochondrially synthesized proteins by two-dimensional proteolytic digest gels. A high correlation was observed between the predicted and observed peptide maps. These results suggest the assignment of several proteins to mtDNA genes.

The mitochondrial DNA molecular of Drosophila yakuba: nucleotide sequence, gene organization, and genetic code

The sequence of the 16,019 nucleotide-pair mitochondrial DNA (mtDNA) molecule of Drosophila yakuba is presented. This molecule contains the genes for two rRNAs, 22 tRNAs, six identified proteins [cytochrome b, cytochrome c oxidase subunits I, II, and III (COI-III), and ATPase subunits 6 and 8] and seven presumptive proteins (URF1-6 and URF4L). Replication originates within a region of 1077 nucleotides that is 92.8% A + T and lacks any open reading frame larger than 123 nucleotides. An equivalent to the sequence found in all mammalian mtCDNAs that is associated with initiation of second-strand DNA synthesis is not present in D. yakuba mtDNA. Introns are absent from D. yakuba mitochondrial genes and there are few (0-31) intergenic nucleotides. The genes found in D. yakuba and mammalian mtDNAs are the same, but there are differences in their arrangement and in the relative proportions of the complementary strands of the molecule that serve as templates for transcription. Although the D. yakuba small and large mitochondrial rRNA genes are exceptionally low in G and C and are shorter than any other metazoan rRNA genes reported, they can be folded into secondary structures remarkably similar to the secondary structures proposed for mammalian mitochondrial rRNAs. D. yakuba mitochondrial tRNA genes, like their mammalian counterparts, are more variable in sequence than nonorganelle tRNAs. In mitochondrial protein genes ATG, ATT, ATA, and in one case (COI) ATAA appear to be used as translation initiation codons. The only termination codon found in these genes is TAA. In the D. yakuba mitochondrial genetic code, AGA, ATA, and TGA specify serine, isoleucine, and tryptophan, respectively. Fifty-nine types of sense condon are used in the D. yakuba mitochondrial protein genes, but 93.8% of all codons end in A or T. Codon-anticodon interactions may include both G-A and C-A pairing in the wobble position. Evidence is summarized that supports the hypothesis that A and T nucleotides are favored at all locations in the D. yakuba mtDNA molecule where these nucleotides are compatible with function.

Diverse patterns of expression of the cytochrome c oxidase subunit I gene and unassigned reading frames 4 and 5 during the life cycle of Trypanosoma brucei

Transcription of a maxicircle segment from Trypanosoma brucei 164 that contains nucleotide (nt) sequences corresponding to cytochrome c oxidase subunit I (COI) and unassigned reading frames (URFs) 4 and 5 of other mitochondrial systems was investigated. Two major transcripts that differ in size by ca. 200 nt map to each of the COI and URF4 genes, while a single major transcript maps to URF5. In total RNA, the larger COI transcript is more abundant in procyclic forms (PFs) than in bloodstream forms (BFs), the smaller COI and both URF4 transcripts have similar abundances in both forms, and the single URF5 transcript is more abundant in BF than PF. These patterns of expression differ in poly(A)+ RNA as a result of a higher proportion of poly(A)+ mitochondrial transcripts in PFs than in BFs. In addition, small (300- to 500-nt) RNAs that are transcribed from C-rich sequences located between putative protein-coding genes also exhibit diverse patterns of expression between life cycle stages and differences in polyadenylation in PFs compared with BFs. These observations suggest that multiple processes regulate the differential expression of mitochondrial genes in T. brucei.

Effect of hypothyroidism on the biogenesis of free mitochondria in the cerebral hemispheres and in cerebellum of rat during postnatal development

The effect of propylthiouracil-induced neonatal hypothyroidism on some aspects of the biogenesis of free (non-synaptosomal) mitochondria in the cerebral hemispheres and in the cerebellum of developing rat has been studied. The results obtained show that in hypothyroid rats mitochondrial DNA synthesis is delayed, mitochondrial RNA synthesis is not affected and cytochrome aa3 content of mitochondria is lower than in controls. Furthermore ultrathin sections of 14- and 21-day old hypothyroid rat cerebella show mitochondria with an altered ultrastructural organization and large intracristal spaces.