Structure and replication of mitochondrial DNA from Paramecium aurelia

Co-evolution in the Jungle: From Leafcutter Ant Colonies to Chromosomal Ends

Biological entities are multicomponent systems where each part is directly or indirectly dependent on the others. In effect, a change in a single component might have a consequence on the functioning of its partners, thus affecting the fitness of the entire system. In this article, we provide a few examples of such complex biological systems, ranging from ant colonies to a population of amino acids within a single-polypeptide chain. Based on these examples, we discuss one of the central and still challenging questions in biology: how do such multicomponent consortia co-evolve? More specifically, we ask how telomeres, nucleo-protein complexes protecting the integrity of linear DNA chromosomes, originated from the ancestral organisms having circular genomes and thus not dealing with end-replication and end-protection problems. Using the examples of rapidly evolving topologies of mitochondrial genomes in eukaryotic microorganisms, we show what means of co-evolution were employed to accommodate various types of telomere-maintenance mechanisms in mitochondria. We also describe an unprecedented runaway evolution of telomeric repeats in nuclei of ascomycetous yeasts accompanied by co-evolution of telomere-associated proteins. We propose several scenarios derived from research on telomeres and supported by other studies from various fields of biology, while emphasizing that the relevant answers are still not in sight. It is this uncertainty and a lack of a detailed roadmap that makes the journey through the jungle of biological systems still exciting and worth undertaking.

Population Genetics of Paramecium Mitochondrial Genomes: Recombination, Mutation Spectrum, and Efficacy of Selection

The evolution of mitochondrial genomes and their population-genetic environment among unicellular eukaryotes are understudied. Ciliate mitochondrial genomes exhibit a unique combination of characteristics, including a linear organization and the presence of multiple genes with no known function or detectable homologs in other eukaryotes. Here we study the variation of ciliate mitochondrial genomes both within and across 13 highly diverged Paramecium species, including multiple species from the P. aurelia species complex, with four outgroup species: P. caudatum, P. multimicronucleatum, and two strains that may represent novel related species. We observe extraordinary conservation of gene order and protein-coding content in Paramecium mitochondria across species. In contrast, significant differences are observed in tRNA content and copy number, which is highly conserved in species belonging to the P. aurelia complex but variable among and even within the other Paramecium species. There is an increase in GC content from ∼20% to ∼40% on the branch leading to the P. aurelia complex. Patterns of polymorphism in population-genomic data and mutation-accumulation experiments suggest that the increase in GC content is primarily due to changes in the mutation spectra in the P. aurelia species. Finally, we find no evidence of recombination in Paramecium mitochondria and find that the mitochondrial genome appears to experience either similar or stronger efficacy of purifying selection than the nucleus.

Structural and functional analysis of the origin of replication of mitochondrial DNA from Paramecium aurelia : I. Inverted complements form the terminal loop

Initiation of replication of the linear mitochondrial DNA from Paramecium occurs at a unique cross-linked terminus of the monomer molecule. Dimer length molecules, containing head-to-head monomers, are replicative intermediates. Previous studies have been with cloned dimer initiation region fragments but here we have isolated and sequenced isomeric forms of restriction fragments located at the initiation end of the monomer. The sequence isomers are inverted complements of each other in the region identified as the single-stranded DNA terminal loop. The unusual electrophoretic behaviour of these terminal restriction fragments supports the sequence data result that the loop is single stranded. These structural features are discussed in regard to mechanisms for the processing of dimer to monomer molecules.

The Oxytricha trifallax mitochondrial genome

The Oxytricha trifallax mitochondrial genome contains the largest sequenced ciliate mitochondrial chromosome (~70 kb) plus a ~5-kb linear plasmid bearing mitochondrial telomeres. We identify two new ciliate split genes (rps3 and nad2) as well as four new mitochondrial genes (ribosomal small subunit protein genes: rps- 2, 7, 8, 10), previously undetected in ciliates due to their extreme divergence. The increased size of the Oxytricha mitochondrial genome relative to other ciliates is primarily a consequence of terminal expansions, rather than the retention of ancestral mitochondrial genes. Successive segmental duplications, visible in one of the two Oxytricha mitochondrial subterminal regions, appear to have contributed to the genome expansion. Consistent with pseudogene formation and decay, the subtermini possess shorter, more loosely packed open reading frames than the remainder of the genome. The mitochondrial plasmid shares a 251-bp region with 82% identity to the mitochondrial chromosome, suggesting that it most likely integrated into the chromosome at least once. This region on the chromosome is also close to the end of the most terminal member of a series of duplications, hinting at a possible association between the plasmid and the duplications. The presence of mitochondrial telomeres on the mitochondrial plasmid suggests that such plasmids may be a vehicle for lateral transfer of telomeric sequences between mitochondrial genomes. We conjecture that the extreme divergence observed in ciliate mitochondrial genomes may be due, in part, to repeated invasions by relatively error-prone DNA polymerase-bearing mobile elements.

Evolution of linear chromosomes and multipartite genomes in yeast mitochondria

Mitochondrial genome diversity in closely related species provides an excellent platform for investigation of chromosome architecture and its evolution by means of comparative genomics. In this study, we determined the complete mitochondrial DNA sequences of eight Candida species and analyzed their molecular architectures. Our survey revealed a puzzling variability of genome architecture, including circular- and linear-mapping and multipartite linear forms. We propose that the arrangement of large inverted repeats identified in these genomes plays a crucial role in alterations of their molecular architectures. In specific arrangements, the inverted repeats appear to function as resolution elements, allowing genome conversion among different topologies, eventually leading to genome fragmentation into multiple linear DNA molecules. We suggest that molecular transactions generating linear mitochondrial DNA molecules with defined telomeric structures may parallel the evolutionary emergence of linear chromosomes and multipartite genomes in general and may provide clues for the origin of telomeres and pathways implicated in their maintenance.

A linear molecule with two large inverted repeats: the mitochondrial genome of the stramenopile Proteromonas lacertae

Mitochondrial evolution has given rise to a complex array of organelles, ranging from classical aerobic mitochondria to mitochondrial remnants known as hydrogenosomes and mitosomes. The latter are found in anaerobic eukaryotes, and these highly derived organelles often retain only scant evidence of their mitochondrial origins. Intermediate evolutionary stages have also been reported as facultatively or even strictly anaerobic mitochondria, and hydrogenosomes that still retain some mitochondrial features. However, the diversity among these organelles with transitional features remains rather unclear and barely studied. Here, we report the sequence, structure, and gene content of the mitochondrial DNA of the anaerobic stramenopile Proteromonas lacertae. It has a linear genome with a unique central region flanked by two identical large inverted repeats containing numerous genes and “telomeres” with short inverted repeats. Comparison with the organelle genome of the strictly anaerobic human parasite Blastocystis reveals that, despite the close similarity of the sequences, features such as the genome structure display striking differences. It remains unclear whether the virtually identical gene repertoires are the result of convergence or descent.

Mitochondrial genome diversity: evolution of the molecular architecture and replication strategy

Mitochondrial genomes in organisms from diverse phylogenetic groups vary in both size and molecular form. Although the types of mitochondrial genome appear very dissimilar, several lines of evidence argue that they do not differ radically. This would imply that interconversion between different types of mitochondrial genome might have occurred via relatively simple mechanisms. We exemplify this scenario on patterns accompanying evolution of mitochondrial telomeres. We propose that mitochondrial telomeres are derived from mobile elements (transposons or plasmids) that invaded mitochondria, integrated into circular or polydisperse linear mitochondrial DNAs (mtDNAs) and subsequently enabled precise resolution of the linear genophore. Simply, the selfish elements generated a problem - how to maintain the ends of a linear DNA - and, at the same time, made themselves essential by providing its solution. This scenario implies that insertion or deletion of such resolution elements may represent relatively simple routes for interconversion between different forms of the mitochondrial genome.

Linear mitochondrial genomes: 30 years down the line

At variance with the earlier belief that mitochondrial genomes are represented by circular DNA molecules, a large number of organisms have been found to carry linear mitochondrial DNA. Studies of linear mitochondrial genomes might provide a novel view on the evolutionary history of organelle genomes and contribute to delineating mechanisms of maintenance and functioning of telomeres. Because linear mitochondrial DNA is present in a number of human pathogens, its replication mechanisms might become a target for drugs that would not interfere with replication of human circular mitochondrial DNA.

Rolling-circle replication of mitochondrial DNA in the higher plant Chenopodium album (L.)

The mitochondrial genomes of higher plants are larger and more complex than those of all other groups of organisms. We have studied the in vivo replication of chromosomal and plasmid mitochondrial DNAs prepared from a suspension culture and whole plants of the dicotyledonous higher plant Chenopodium album (L.). Electron microscopic studies revealed sigma-shaped, linear, and open circular molecules (subgenomic circles) of variable size as well as a minicircular plasmid of 1.3 kb (mp1). The distribution of single-stranded mitochondrial DNA in the sigma structures and the detection of entirely single-stranded molecules indicate a rolling-circle type of replication of plasmid mp1 and subgenomic circles. About half of the sigma-like molecules had tails exceeding the lengths of the corresponding circle, suggesting the formation of concatemers. Two replication origins (nicking sites) could be identified on mpl by electron microscopy and by a new approach based on the mapping of restriction fragments representing the identical 5' ends of the tails of sigma-like molecules. These data provide, for the first time, evidence for a rolling-circle mode of replication in the mitochondria of higher plants.

Electron microscopic investigation of mitochondrial DNA from Chenopodium album (L.)

DNA molecules from mitochondria of whole plants and a suspension culture of Chenopodium album were prepared, by a gentle method, for analysis by electron microscopy. Mitochondrial (mt) DNA preparations from both sources contained mostly linear molecules of variable sizes (with the majority of molecules ranging from 40 to 160 kb). Open circular molecules with contour lengths corresponding to 0. 3-183 kb represented 23-26% of all mtDNA molecules in the preparations from the suspension culture and 13-15% in the preparations from whole plants. More than 90% of the circular DNA was smaller than 30 kb. Virtually no size classes of the mtDNA molecules could be identified, and circular or linear molecules of the genome size (about 270 kb) were not observed. In contrast, plastid (pt) DNA preparations from the suspension culture contained linear and circular molecules falling into size classes corresponding to monomers, dimers and trimers of the chromosome. About 23% of the ptDNA molecules were circular. DNA preparations from mitochondria contained a higher percentage of more complex molecules (rosette-like structures, catenate-like molecules) than preparations of ptDNA. Sigma-like molecules (putative intermediates of rolling-circle replication) were observed in mtDNA preparations from the suspension culture (18% of the circles), and in much lower amount (1%) in preparations from whole plants. The results are compared with data obtained previously by pulsed-field gel electrophoresis and discussed in relation to the structural organization and replication of the mt genome of higher plants.

Linear mitochondrial genome organization in vivo in the genus Pythium

Pulsed-field gel electrophoresis (PFGE) of isolates of Pythium oligandrum with linear mitochondrial genomes revealed a distinct band in ethidium bromide-stained gels similar in size to values estimated by restriction mapping of mitochondrial DNA (mtDNA). Southern analysis confirmed that these bands were mtDNA and indicated that linear genomes were present in unit-length size as well as multimers. Isolates of this species with circular mtDNA restriction maps also had low levels of linear mono- and multimers visualized by Southern analysis of PFGE gels. Examination of 17 additional species revealed similar results; three species had distinct linear mtDNA bands in ethidium bromide-stained gels while the remainder had linear mono- and multi-mers in lower amounts detected only by Southern analysis. Sequence analysis of an isolate of P. oligandrum with a primarily circular mitochondrial genomic map and a low amount of linear molecules revealed that the small unique region of the circular map (which corresponded to the terminal region of linear genomes) was flanked by palindromic intrastrand complementary sequences separated by a unique 194-bp sequence. Sequences with similarity to ATPase9 coding regions from other organisms were located adjacent to this region. Sequences with similarity to mitochondrial origins of replication and autonomously replicating sequences were also located in this region: their potential involvement in the generation of linear molecules is discussed.

Linear mitochondrial DNAs from yeasts: telomeres with large tandem repetitions

The terminal structure of the linear mitochondrial DNA (mtDNA) from the yeast Candida parapsilosis was investigated. This mtDNA, 30 kb long, has symmetrical ends forming inverted terminal repeats. These repeats are made up of a variable number of tandemly repeating units of 738 bp each; the terminal nucleotide corresponds to a precise position within the last repeat unit sequence. The ends had an open structure accessible to enzymes, with a 5' single-stranded extension of about 110 nucleotides. No circular forms were detected in the DNA preparations. Two other unrelated species, Pichia philodendra and Candida salmanticensis also appear to have a linear mtDNA of similar organization. These linear DNAs (which we name Type 2 linear mtDNAs) are distinct from the previously described linear mtDNAs of yeasts whose termini are formed by a closed hairpin loop (Type 1 linear mtDNA). The terminal structure of C. parapsilosis mtDNA is reminiscent of the linear mitochondrial genomes of the ciliate Tetrahymena although, in the latter, the telomeric tandem repeat unit is considerably shorter.

Hairpin and dimer structures of linear plasmid-like DNAs in mitochondria of Paramecium caudatum

The molecular structure of plasmid-like DNAs (designated type-II) which were isolated from mitochondria in the ciliated protozoan Paramecium caudatum was characterized. These type-II DNAs are always detected as a set of four kinds with sizes of 8.2, 4.1, 2.8 and 1.4 kb. The DNAs of 8.2 and 2.8 kb exist as dimers consisting of 4.1- and 1.4-kb monomer molecules, respectively. Electron microscopic observations indicated configurations of a hairpin structure that had a protruding end of single-stranded DNA in one terminus and a loop in the other terminus. The monomers stick together with base-pairing in opposite directions at the protruding end to form the dimers, suggesting the presence of inverted repeats. These unusual dimers may have a role in replication of the DNAs in which the monomers can serve as a primer for each other.

Mitochondrial DNA of Chlamydomonas reinhardtii: the structure of the ends of the linear 15.8-kb genome suggests mechanisms for DNA replication

The mitochondrial genome of Chlamydomonas reinhardtii is a linear double-stranded DNA of 15.8 kb. With the exception of the termini its DNA sequence has been published. Here we describe the unique structure of the two termini determined from cloned fragments or, for the very terminal sequences, by the Maxam and Gilbert method after 5' labeling of uncloned terminal fragments. The 15.8-kb DNA is characterized by terminal inverted repeats of 531 or 532 bp in length including long 3' extensions. The 3' single-stranded extensions of the left and right ends are non-complementary, identical in sequence, and comprise 39 to 41 nucleotides. Remarkably, the linear genome possesses in addition an internal 86-bp repeat of the two outermost sequences. The unusual structure of the 15.8-kb DNA termini is compared with those of other linear mitochondrial DNAs. Possible mechanisms of 15.8-kb DNA replication are discussed.

Linear mitochondrial DNAs of yeasts: frequency of occurrence and general features

In most yeast species, the mitochondrial DNA (mtDNA) has been reported to be a circular molecule. However, two cases of linear mtDNA with specific termini have previously been described. We examined the frequency of occurrence of linear forms of mtDNA among yeasts by pulsed-field gel electrophoresis. Among the 58 species from the genera Pichia and Williopsis that we examined, linear mtDNA was found with unexpectedly high frequency. Thirteen species contained a linear mtDNA, as confirmed by restriction mapping, and labeling, and electron microscopy. The mtDNAs from Pichia pijperi, Williopsis mrakii, and P. jadinii were studied in detail. In each case, the left and right terminal fragments shared homologous sequences. Between the terminal repeats, the order of mitochondrial genes was the same in all of the linear mtDNAs examined, despite a large variation of the genome size. This constancy of gene order is in contrast with the great variation of gene arrangement in circular mitochondrial genomes of yeasts. The coding sequences determined on several genes were highly homologous to those of the circular mtDNAs, suggesting that these two forms of mtDNA are not of distant origins.

Linear mitochondrial DNAs of yeasts: closed-loop structure of the termini and possible linear-circular conversion mechanisms

The terminal structure of the linear mitochondrial DNA (mtDNA) from three yeast species has been examined. By enzymatic digestion, alkali denaturation, and sequencing of cloned termini, it was shown that in Pichia pijperi and P. jadinii, both termini of the linear mtDNA were made of a single-stranded loop covalently joining the two strands, as in the case of vaccinia virus DNA. The left and right loop sequences were in either of two orientations, suggesting the existence of a flip-flop inversion mechanism. Contiguous to the terminal loops, inverted terminal repeats were present. The mtDNA from Williopsis mrakii seems to have an analogous structure, although terminal loops could not be directly demonstrated. Electron microscopy revealed the presence, among linear molecules, of a small number of circular DNAs, mostly of monomer length. Linear and circular models of replication are considered, and possible conversion mechanisms between linear and circular forms are discussed. A flip-flop inversion mechanism between the inverted repeat sequences within a circular intermediate may be involved in the generation of the linear form of mtDNA.

Linear mitochondrial DNAs of yeasts: frequency of occurrence and general features

In most yeast species, the mitochondrial DNA (mtDNA) has been reported to be a circular molecule. However, two cases of linear mtDNA with specific termini have previously been described. We examined the frequency of occurrence of linear forms of mtDNA among yeasts by pulsed-field gel electrophoresis. Among the 58 species from the genera Pichia and Williopsis that we examined, linear mtDNA was found with unexpectedly high frequency. Thirteen species contained a linear mtDNA, as confirmed by restriction mapping, and labeling, and electron microscopy. The mtDNAs from Pichia pijperi, Williopsis mrakii, and P. jadinii were studied in detail. In each case, the left and right terminal fragments shared homologous sequences. Between the terminal repeats, the order of mitochondrial genes was the same in all of the linear mtDNAs examined, despite a large variation of the genome size. This constancy of gene order is in contrast with the great variation of gene arrangement in circular mitochondrial genomes of yeasts. The coding sequences determined on several genes were highly homologous to those of the circular mtDNAs, suggesting that these two forms of mtDNA are not of distant origins.

Linear mitochondrial DNAs of yeasts: closed-loop structure of the termini and possible linear-circular conversion mechanisms

The terminal structure of the linear mitochondrial DNA (mtDNA) from three yeast species has been examined. By enzymatic digestion, alkali denaturation, and sequencing of cloned termini, it was shown that in Pichia pijperi and P. jadinii, both termini of the linear mtDNA were made of a single-stranded loop covalently joining the two strands, as in the case of vaccinia virus DNA. The left and right loop sequences were in either of two orientations, suggesting the existence of a flip-flop inversion mechanism. Contiguous to the terminal loops, inverted terminal repeats were present. The mtDNA from Williopsis mrakii seems to have an analogous structure, although terminal loops could not be directly demonstrated. Electron microscopy revealed the presence, among linear molecules, of a small number of circular DNAs, mostly of monomer length. Linear and circular models of replication are considered, and possible conversion mechanisms between linear and circular forms are discussed. A flip-flop inversion mechanism between the inverted repeat sequences within a circular intermediate may be involved in the generation of the linear form of mtDNA.

Linear plasmids of Borrelia burgdorferi have a telomeric structure and sequence similar to those of a eukaryotic virus

Spirochetes of the genus Borrelia have double-stranded linear plasmids with covalently closed ends. The physical nature of the terminal connections was determined for the 16-kb linear plasmid of the B31 strain of the Lyme disease agent Borrelia burgdorferi. Native telomeric fragments representing the left and right ends of this plasmid were isolated and subjected to Maxam-Gilbert sequence analysis. At the plasmid ends the two DNA strands formed an uninterrupted, perfectly palindromic, AT-rich sequence. This Borrelia linear plasmid consisted of a continuous polynucleotide chain that is fully base paired except for short single-stranded hairpin loops at each end. The left and right telomeres of the 16-kb plasmid were identical for 16 of the first 19 nucleotide positions and constituted an inverted terminal repeat with respect to each other. The left telomere of the 49-kb plasmid of strain B31 was identical to the corresponding telomere of the 16-kb plasmid. Different-sized plasmids of other strains of B. burgdorferi also contained sequences homologous to the left end of the 16-kb plasmid. When the borrelia telomeres were compared with telomeric sequences of other linear double-stranded DNA replicons, sequence similarities were noted with poxviruses and particularly with the iridovirus agent of African swine fever. The latter virus and a Borrelia sp. share the same tick vector. These findings suggest that the novel linear plasmids of Borrelia originated through a horizontal genetic transfer across kingdoms.

Genes of Acanthamoeba: DNA, RNA and protein sequences (a review)

This review summarizes knowledge about the structure of nuclear genes and mitochondrial DNA in Acanthamoeba. The information about nuclear genes is derived from studies of DNA, RNA and protein sequences. The genes considered are those for 5S, 5.8S and 18S rRNA, actin I, profilins Ia/b and II, myosins IB, IC and II, and calmodulin. All of the sequences show strong similarities to comparable sequences from other organisms. Introns have been found in the actin and myosin genes. The location of the actin intron is unique, but many of the myosin introns occur at the same sites as introns in myosins of other organisms. Sequence comparisons, especially of 5S and 5.8S rRNA and actin, support previous evidence, based primarily on 18S rRNA, that Acanthamoeba genes are at least as closely related to those of higher plants and animals as they are to various other protistan genera. The functional organization of the promoter region for the nuclear rDNA transcription unit has been studied extensively, but there is a need for information about the functional organization of regulatory sequences for other genes. Restriction fragment length profile (RFLP) studies of mitochondrial DNA reveal relatively high levels of overall sequence diversity, but information on the structure and function of individual genes is needed. The RFLP appear to have potential as tools for taxonomic studies of this genus.

Mitochondrial DNA of Physarum polycephalum: physical mapping, cloning and transcription mapping

Mitochondrial DNA (mtDNA) has been isolated from four strains of Physarum polycephalum and a restriction site map has been determined using nine restriction enzymes. The restriction site maps of the four strains are similar but each strain is distinguished by insertions, deletions and restriction enzyme site polymorphisms. The sum of the restriction fragments gives mitochondrial genome sizes which vary from about 56 kb to 62 kb. In all four strains the composite map of the restriction enzyme sites for the mtDNA is circular. Knowledge of the restriction enzyme map has enabled cloning of mtDNA fragments representing the entire mtDNA of strain M3. The cloned fragments have been used to create a transcription map of the mtDNA.

Sequences similar to genes for two mitochondrial proteins and portions of ribosomal RNA in tandemly arrayed 6-kilobase-pair DNA of a malarial parasite

Erythrocytic stages of mammalian malarial parasites contain acristate mitochondria whose functions are not well understood. Moreover, little is known about the genome of these organelles. We have previously reported that all species of malarial parasites examined contain highly conserved, tandemly arrayed DNA with a unit length of about 6.0 kb that is transcribed into discrete RNA molecules in erythrocytic stages. We now report the complete DNA sequence of the 5984-bp repeating unit of Plasmodium yoelii, a rodent parasite. Two slightly overlapping regions transcribed into large RNA molecules were found to have significant DNA and protein sequence similarity with mitochondrion-coded proteins, cytochrome c oxidase subunit I and cytochrome b. Significant sequence similarity with other mitochondrial protein genes could not be detected. Ribosomal RNA (rRNA)-like genes were not detected in this sequence either. However, two regions, 82 and 50 nucleotides long, specified by different strands, were found to have extensive similarity with the highly conserved central loop of the peptidyl transferase domain of the large rRNA of Escherichia coli, mitochondria, and chloroplasts. Compensatory nucleotide substitutions were present in these regions, so that the predicted secondary structure was not affected. Functional utilization of these regions, if it exists, could argue for a trans-associative origin of rRNA. In organization, size and sequence, the tandem arrays of 6.0 kb malarial DNA appear to be a very unusual form of mitochondrial DNA.

Some physicochemical properties of rice mitochondrial DNA

Certain physicochemical properties of rice mitochondrial DNA (mtDNA) were determined. Certain low-molecular-weight mtDNA bands were found in addition to the major mtDNA band. Rice mtDNA appeared in the electron microscope as a collection of linear molecules with heterogeneous length in the range of 1-156 kb. The major distribution area was 60-105 kb. A small fraction (less than 5%) of rice mtDNA was found in the form of a circular molecule. Some molecules had the appearance of being supercoiled. Replication fork structures were found in both circular and linear mtDNA molecules. In one rice species, Jin Nante, 15 different circular molecules were found. Rice mtDNA was digested with different restriction enzymes. The total molecular weight of rice mtDNA was calculated to be about 300 kb according to the data of restriction enzyme digestion and electron microscopy.

Mitochondrial telomeres: surprising diversity of repeated telomeric DNA sequences among six species of Tetrahymena

The DNA sequences at the ends of the linear mtDNA of 6 species of Tetrahymena encompassing 13 strains were determined. All the strains have variable numbers of a tandemly repeated DNA sequence, 31 bp to 53 bp in size, at their mtDNA termini. Based upon the size and nucleotide sequence of the terminal repeats, the telomeres can be separated into four classes. T. pigmentosa, hyperangularis, and hegewischi have different telomeric repeats on the two ends of their mtDNAs. The only conserved feature of the mtDNA termini is the presence of tandem repeats. The function of the repeats might be to promote unequal crossing over during recombination, thereby overcoming the problem of telomere replication for these linear DNAs.

Linear mitochondrial deoxyribonucleic acid from the yeast Hansenula mrakii

The mitochondrial deoxyribonucleic acid (mtDNA) from a petite-negative yeast, Hansenula mrakii, was studied. A linear restriction map was constructed with 11 restriction enzymes. The linearity of the genome was confirmed by direct end labeling of the molecule, followed by restriction analysis. The molecular weight of the DNA was found to be 55,000 base pairs. This is the first linear mtDNA found in yeast species. Using specific gene probes obtained from Saccharomyces cerevisiae mtDNA, we have constructed a gene map of H. mrakii mtDNA. The arrangement of genes in this linear genome was very different from the circular mtDNA of other known yeasts.

Phylogenetic relationships and altered genome structures among Tetrahymena mitochondrial DNAs

Tetrahymena thermophila mitochondrial DNA is a linear molecule with two tRNAs, large subunit beta (LSU beta) rRNA (21S rRNA) and LSU alpha rRNA (5.8S-like RNA) encoded near each terminus. The DNA sequence of approximately 550 bp of this region was determined in six species of Tetrahymena. In three species the LSU beta rRNA and tRNA(leu) genes were not present on one end of the DNA, demonstrating a mitochondrial genome organization different from that of T. thermophila. The DNA sequence of the LSU alpha rRNA was used to construct a mitochondrial phylogenetic tree, which was found to be topologically equivalent to a phylogenetic tree based on nuclear small subunit rRNA sequences (Sogin et al. (1986) EMBO J. 5, 3625-3630). The mitochondrial rRNA gene was found to accumulate base-pair substitutions considerably faster than the nuclear rRNA gene, the rate difference being similar to that observed for mammals.

Transformation of Paramecium by microinjection of a cloned serotype gene

Paramecia of a given serotype express only one of several possible surface proteins called immobilization antigens (i-antigens). A 16-kilobase plasmid containing the gene for immobilization antigen A from Paramecium tetraurelia, stock 51, was injected into the macronucleus of deletion mutant d12, which lacks that gene. Approximately 40% of the injected cells acquired the ability to express serotype A at 34 degrees C. Expression appeared to be regulated normally. The transformed cells, like wild type, could be switched to serotype B by antiserum treatment and culture at 19 degrees C; on transfer to 34 degrees C, they switched back to serotype A expression. Many of the lines retained the ability to express serotype A until autogamy, when the old macronucleus is replaced by a new one derived from the micronucleus. DNA from transformants contained the injected plasmid sequences, which were replicated within the paramecia. No evidence for integration was obtained. The majority of replicated plasmid DNA comigrated with a linearized form of the input plasmid. Nonetheless, the pattern of restriction fragments generated by transformant DNA and that generated by input plasmid DNA are identical and consistent with a circular rather than a linear map. These conflicting observations can be reconciled by assuming that a mixture of different linear fragments is present in the transformants, each derived from the circular plasmid by breakage at a different point. Copy-number determinations suggest the presence of 45,000-135,000 copies of the injected plasmid per transformed cell. These results suggest that the injected DNA contains information sufficient for both controlled expression and autonomous replication in Paramecium.

The telomeres of the linear mitochondrial DNA of Tetrahymena thermophila consist of 53 bp tandem repeats

We have cloned and sequenced the telomeric DNA of the linear mitochondrial DNA (mtDNA) of T. thermophila BVII. The mtDNA telomeres consist of a 53 bp sequence tandemly repeated from 4 to 30 times, with most molecules having 15 +/- 4 repetitions. The previously recognized terminal heterogeneity of the mtDNA is completely accounted for by the variability in the number of repeats. The 53 bp repeat does not resemble known telomeric DNA in sequence, repeat size, or number of repetitions. The termini occur at heterogeneous positions within the 53 bp repeat. The junction of the telomeric repeat with the internal DNA is at a different position within the telomeric repeat on each end of the mtDNA. We propose a model for the maintenance of the mtDNA ends involving unequal homologous recombination.

Paramecium mitochondrial DNA sequences and RNA transcripts for cytochrome oxidase subunit I, URF1, and three ORFs adjacent to the replication origin

A 2-kb region adjacent to the replication origin (ori) and a 3-kb region located between the small and large ribosomal RNAs of Paramecium mitochondrial (mt) DNA have been sequenced and the locations of their transcripts determined. The ori segment contains four transcripts, some of which are overlapping, which encode a known protein and two other open reading frames. The other segment encodes, on separate transcripts, the cytochrome c oxidase subunit one gene (COI) and the URF1 gene (ND1) common to most mt genomes. All these genes have the same orientation and do not contain introns. The COI gene is the most divergent of those known and has an internal 108 amino acid 'insert' not found in COI genes from other organisms. With these data it is possible to define a probable Paramecium mt genetic code. With the exception that TGA codes for tryptophan and the use of different start codons, Paramecium mtDNA appears to follow the universal code. GTA possibly can be used as a start codon.

Identification of Paramecium mitochondrial proteins using antibodies raised against fused mitochondrial gene products

Paramecium aurelia mitochondrial (mt) DNA fragments carrying the coding regions for two proteins, P1 (in the region adjacent to the origin of replication) and COII (subunit II of cytochrome oxidase), were used to study mt gene expression. The sequence for the portion of mtDNA containing P1 has already been described [Pritchard et al., Gene 44 (1986) 243-253]. The complete nucleotide sequence of the portion containing the COII gene is presented here. An 18.5-kDa protein was produced in maxicells when a fragment containing a major portion of the sequence coding for P1 was used. This fragment and a fragment carrying the COII gene were cloned into the expression vector pTRPLE', and antibodies were raised against the resulting fusion proteins in an Escherichia coli lysate. Western blots of Paramecium mt extracts identified two proteins, one 21 kDa (COII) and the other 23.5 kDa (P1). The size of the P1 protein is in agreement with the size of the open reading frame in that region of mitochondrial DNA. Based on extensive amino acid homology to the Paramecium gene and limited homology to COII genes from other organisms, the COII gene in another ciliate, Tetrahymena pyriformis, was identified just upstream of the small subunit rDNA in previously published sequences (Schnare et al., 1986). The size of the COII gene and the homology with the COII gene from Tetrahymena suggest that ATC, ATT, GTG and GTC could be used as translational initiators in Paramecium mitochondria.

A fine restriction map of the linear mitochondrial DNA of Tetrahymena pyriformis: genome size, map locations of rRNA and tRNA genes, terminal inversion repeat, and restriction site polymorphism

A fine restriction map of the linear mitochondrial DNA of Tetrahymena pyriformis strain ST is presented. 1. Based on agarose gel electrophoresis data together with limited nucleotide sequences available on some restriction fragments, we estimate the actual size of this genome to be about 55,000 base pairs. 2. Seven tRNA gene locations have been assigned, which are scattered along the genome length. Six of these locations encode the genes for tRNA(phe), tRNA(his), tRNA(trp), and tRNA(glu), and the duplicate tRNA(tyr) genes which are located at the inverted terminal repeat segments. The tRNA gene(s) encoded in one location has not been identified. We have not yet found the tRNA(leu) and tRNA(met) genes, which were previously shown to be encoded in the genome (Chiu et al. 1974; Suyama 1982). 3. We have mapped the 14S rRNA gene by sequencing the 170 bp segment of EcoRI fragment 8 and by aligning its sequence with E. coli 16S rRNA. From our recent complete sequence data the gene size was found to be about 1,650 bp, which is unexpectedly large for the 14S rRNA which has an estimated size of 1,300 bp. The 14S rRNA is probably a cleavage product of the larger primary transcript of which 200-300 bases of the 5' end are missing. 4. The duplicate copies of the 21S rRNA gene at the terminal duplication inversion segments were analyzed. ClaI fragment 7 (1,500 bp) corresponds in sequence from base position 850 to 2,390 of the 20S rRNA gene of Paramecium mitochondrial DNA (Seilhamer et al. 1984b). The 21S gene is approximately 2,500 bp long. The presence of some restriction site polymorphism is apparent in this segment. 5. Each of the 21S gene copies precedes the tRNA(tyr) gene, but the space flanking one tRNA(tyr) gene differs in size and restriction sites from the space flanking another tRNA(tyr) gene. Thus, this space corresponds to the segment of an imperfect match in the terminal duplication inversion of Goldbach et al. (1978a). 6. Saccharomyces cerevisiae mitochondrial probes including Cob, ATPase VI and IX, and cytochrome oxidase I gene sequences, 21S and 15S rRNAs, and mouse mitochondrial DNA showed no significant hybridization with any restriction fragments of Tetrahymena mitochondrial DNA. The results are in accordance with an extensive sequence divergence previously found in the Tetrahymena mitochondrial genome (Goldbach et al. 1977).

Inter-species sequence diversity in the replication initiation region of Paramecium mitochondrial DNA

Mitochondrial DNA from Paramecium aurelia is a linear molecule. Replication is initiated at a unique cross-linked molecular terminus. During replication dimer length molecules, consisting of two head-to-head monomers, are generated. We have cloned the head-to-head dimer initiation region from five different species and several stocks (or races) within species and determined its DNA sequence. For all species, this dimer initiation region consists of a central non-palindromic sequence containing almost exclusively A and T, arranged in an array of direct tandem repeats. In an intra-species comparison, the sequences of the repeat units are relatively homogeneous; inter-species comparisons, however, show diversity except for a conserved "Goldberg-Hogness box", T-A-T-A-A-A-T-A. The size of a repeat unit and the number of repeats within a molecule can vary over a wide range, even in an intra-species comparison. Because of these wide inter-species variations observed, it is likely that the function of this region imposes few constraints on the sequence other than its high A + T content and possibly a Goldberg-Hogness box. The array of direct tandem repeats may have arisen from unequal recombination or crossover within this region. Adjacent to the non-palindromic region is a transcribed sequence which is highly conserved for all species and presumably represents a gene coding region.

Organization and closing of mitochondrial deoxyribonucleic acid from Paramecium tetraaurelia and Paramecium primaurelia

Previously we showed that the mitochondrial deoxyribonucleic acid (DNA) from Paramecium aurelia consists of a linear genome and that replication of this genome is initiated at one terminus and proceeds unidirectionally to the other terminus. Analyses of mitochondria from four closely related species (1, 4, 5, and 7) indicated that the species 1, 5, and 7 DNAs are essentially completely homologous but that the species 4 mitochondrial DNA is only 40 to 50% homologous with that from species 1. The major regions of homology are those containing the genes for ribosomal ribonucleic acid (RNA). To understand the replication and organization of the linear mitochondrial genome better, we compared species 1 (Paramecium primaurelia) and 4 (Paramecium tetraaurelia) DNAs with regard to restriction fragment mapping and homology between initiation regions; we also identified the sites of the genes for ribosomal RNA. In general, the structures of the species 1 and 4 mitochondrial genomes were quite similar. Each ribosomal RNA gene was present in one copy per genome, with the large ribosomal RNA gene located near the terminal region of replication and the small ribosomal RNA gene located more centrally. These two genes were separated by about 10 kilobases in the species 1 genome and by about 12 kilobases in the species 4 genome. In contrast to our previous findings, by using nonstringent hybridization conditions we detected homology between the species 1 and 4 DNA fragments containing the initiation regions. We constructed recombinant DNA clones for many fragments, especially those containing the initiation region and the ribosomal RNA genes. We also constructed restriction enzyme maps for six enzymes for both P. primaurelia and P. tetraaurelia.

Structure and sequence of the mitochondrial 20S rRNA and tRNA tyr gene of Paramecium primaurelia

The sequence and structure of the large (20s) mitochondrial (mt) rRNA gene and flanking regions from Paramecium primaurelia have been determined. The gene contains two regions of strong homology with other large mt rRNAs: one 44-base region near the 5' end and a 321-base region near the 3' end. Another region of strong homology to both ends of E. coli 23s RNA exists at loci consistent with these regions. The Paramecium gene appears to be 2204 bases in length and contains slightly more homology to E. coli rRNA than its mammalian or fungal counterparts. The gene, located about 1200 bp from the replicative terminal end of the linear mt DNA, is transcribed in the same polarity as replication. Previous R-looping studies detected no large introns within the gene. Here we describe sequences resembling degenerate rRNAs, one of which could represent a small intron. A tRNA tyr gene was found on the same DNA strand, 127 bp downstream from the large rRNA presumptive 3' end. The tRNA is flanked on both sides by short DNA regions of approximately 90% A + T content.

Replication of linear mitochondrial DNA from Paramecium: sequence and structure of the initiation-end crosslink

Replication of the 14-micrometer linear Paramecium mitochondrial DNA is initiated by a crosslinking of the duplex strands at the initiation end of the molecule. As a consequence of the crosslink, a head-to-head dimer molecule, or palindrome, is a replicative intermediate. The central region of the dimer molecules of two species was cloned and sequenced, In the distal regions, the sequence is palindromic as expected; however, in the central region, there is a nonpalindromic sequence that is rich in A + T and contains direct tandem repeats. It is proposed that the nonpalindromic sequence constitutes the crosslink. Implications for the replication scheme are discussed. The model is unlike any other for a linear DNA.

Organization and closing of mitochondrial deoxyribonucleic acid from Paramecium tetraaurelia and Paramecium primaurelia

Previously we showed that the mitochondrial deoxyribonucleic acid (DNA) from Paramecium aurelia consists of a linear genome and that replication of this genome is initiated at one terminus and proceeds unidirectionally to the other terminus. Analyses of mitochondria from four closely related species (1, 4, 5, and 7) indicated that the species 1, 5, and 7 DNAs are essentially completely homologous but that the species 4 mitochondrial DNA is only 40 to 50% homologous with that from species 1. The major regions of homology are those containing the genes for ribosomal ribonucleic acid (RNA). To understand the replication and organization of the linear mitochondrial genome better, we compared species 1 (Paramecium primaurelia) and 4 (Paramecium tetraaurelia) DNAs with regard to restriction fragment mapping and homology between initiation regions; we also identified the sites of the genes for ribosomal RNA. In general, the structures of the species 1 and 4 mitochondrial genomes were quite similar. Each ribosomal RNA gene was present in one copy per genome, with the large ribosomal RNA gene located near the terminal region of replication and the small ribosomal RNA gene located more centrally. These two genes were separated by about 10 kilobases in the species 1 genome and by about 12 kilobases in the species 4 genome. In contrast to our previous findings, by using nonstringent hybridization conditions we detected homology between the species 1 and 4 DNA fragments containing the initiation regions. We constructed recombinant DNA clones for many fragments, especially those containing the initiation region and the ribosomal RNA genes. We also constructed restriction enzyme maps for six enzymes for both P. primaurelia and P. tetraaurelia.