The structure of Tetrahymena pyriformis mitochondrial DNA. I. Strain differences and occurrence of inverted repetitions

Colponemids represent multiple ancient alveolate lineages

The alveolates comprise three well-studied protist lineages of significant environmental, medical, and economical importance: apicomplexans (e.g., Plasmodium), dinoflagellates (e.g., Symbiodinium), and ciliates (e.g., Tetrahymena). These major lineages have evolved distinct and unusual characteristics, the origins of which have proved to be difficult evolutionary puzzles. Mitochondrial genomes are a prime example: all three groups depart from canonical form and content, but in different ways. Reconstructing such ancient transitions is difficult without deep-branching lineages that retain ancestral characteristics. Here we describe two such lineages and how they illuminate the ancestral state of alveolate mitochondrial genomes. We established five clonal cultures of colponemids, predatory alveolates without cultured representatives and molecular data. Colponemids represent at least two independent lineages at the phylum level in multilocus phylogenetic analysis; one sister to apicomplexans and dinoflagellates, and the other at a deeper position. A genome survey from one strain showed that ancestral state of the mitochondrial genomes in the three major alveolate lineages consisted of an unusual linear chromosome with telomeres and a substantially larger gene set than known alveolates. Colponemid sequences also identified several environmental lineages as colponemids, altogether suggesting an untapped potential for understanding the origin and evolution of apicomplexans, dinoflagellates, and ciliates.

Extragenomic double-stranded DNA circles in yeast with linear mitochondrial genomes: potential involvement in telomere maintenance

Although the typical mitochondrial DNA (mtDNA) is portrayed as a circular molecule, a large number of organisms contain linear mitochondrial genomes classified by their telomere structure. The class of mitochondrial telomeres identified in three yeast species, Candida parapsilosis, Pichia philodendra and Candida salmanticensis, is characterized by inverted terminal repeats each consisting of several tandemly repeating units and a 5' single-stranded extension. The molecular mechanisms of the origin, replication and maintenance of this type of mitochondrial telomere remain unknown. While studying the replication of linear mtDNA of C.parapsilosis by 2-D gel electrophoresis distinct DNA fragments composed solely of mitochondrial telomeric sequences were detected and their properties were suggestive of a circular conformation. Electron microscopic analysis of these DNAs revealed the presence of highly supertwisted circular molecules which could be relaxed by DNase I. The minicircles fell into distinct categories based on length, corresponding to n x 0.75 kb (n = 1-7). Similar results were obtained with two other yeast species (P.philodendra and C. salmanticensis) which possess analogous telomeric structure.

Complete sequence of the mitochondrial genome of Tetrahymena pyriformis and comparison with Paramecium aurelia mitochondrial DNA

We report the complete nucleotide sequence of the Tetrahymena pyriformis mitochondrial genome and a comparison of its gene content and organization with that of Paramecium aurelia mtDNA. T. pyriformis mtDNA is a linear molecule of 47,172 bp (78.7 % A+T) excluding telomeric sequences (identical tandem repeats of 31 bp at each end of the genome). In addition to genes encoding the previously described bipartite small and large subunit rRNAs, the T. pyriformis mitochondrial genome contains 21 protein-coding genes that are clearly homologous to genes of defined function in other mtDNAs, including one (yejR) that specifies a component of a cytochrome c biogenesis pathway. As well, T. pyriformis mtDNA contains 22 open reading frames of unknown function larger than 60 codons, potentially specifying proteins ranging in size from 74 to 1386 amino acid residues. A total of 13 of these open reading frames ("ciliate-specific") are found in P. aurelia mtDNA, whereas the remaining nine appear to be unique to T. pyriformis; however, of the latter, five are positionally equivalent and of similar size in the two ciliate mitochondrial genomes, suggesting they may also be homologous, even though this is not evident from sequence comparisons. Only eight tRNA genes encoding seven distinct tRNAs are found in T. pyriformis mtDNA, formally confirming a long-standing proposal that most T. pyriformis mitochondrial tRNAs are nucleus-encoded species imported from the cytosol. Atypical features of mitochondrial gene organization and expression in T. pyriformis mtDNA include split and rearranged large subunit rRNA genes, as well as a split nad1 gene (encoding subunit 1 of NADH dehydrogenase of respiratory complex I) whose two segments are located on and transcribed from opposite strands, as is also the case in P. aurelia. Gene content and arrangement are very similar in T. pyriformis and P. aurelia mtDNAs, the two differing by a limited number of duplication, inversion and rearrangement events. Phylogenetic analyses using concatenated sequences of several mtDNA-encoded proteins provide high bootstrap support for the monophyly of alveolates (ciliates, dinoflagellates and apicomplexans) and slime molds.

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.

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.

The cytochrome oxidase subunit I gene of Tetrahymena: a 57 amino acid NH2-terminal extension and a 108 amino acid insert

The gene sequence for cytochrome oxidase subunit I (COI) in the ciliate Tetrahymena mitochondrial DNA has been determined and shown to be coded by the same strand as codes the genes (in order) for 14S rRNA, tRNA(trp), tRNA(glu), 21S rRNA, tRNA(leu) and tRNA(met). The predicted protein has 698 amino acids, including an NH2-terminal 57 amino acid extension and a 108 amino acid insert originally found in Paramecium COI. These extension and insert segments are not highly hydrophobic but are relatively rich in lysine, arginine and serine. In analogy with the presequence of nuclear-encoded mitochondrial proteins, they might function as a transmembrane signal. The remaining polypeptide segments show a hydrophobicity characteristic of membrane spanning proteins. TCOI shows a 64% amino acid identity with Paramecium COI but less than a 38% amino acid conservation with human COI. The Tetrahymena mitochondrial code is analogous with the mammalian mitochondrial code; but differs from the Tetrahymena nuclear genetic code; TGA is exclusively translated as tryptophan; ATA is used as an initiation codon probably for methionine, and TAA as a stop codon; the arginine codons (CGN) are not used. The use of the leucine codon TTA in TCOI is contradictory to the codon recognition pattern previously obtained from the isolated tRNA(leu) isoacceptors recognizing only the CUN codons, but consistent with the tRNA(leu) (anticodon UAA) gene encoded in the genome. The reason for this inconsistency has not been resolved.

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.

The 5S and 5.8S ribosomal RNA sequences of Tetrahymena thermophila and T. pyriformis

The nucleotide sequences of the 5S rRNAs of Tetrahymena thermophila and two strains of T. pyriformis have been determined to be identical. The 5.8S rRNA sequences have also been determined; these sequences correct several errors in an earlier report. The 5.8S rRNAs of the two species differ at a single position. The sequencing results indicate that the species are of recent common ancestry. Molecular evidence that has been interpreted in the past as suggestive of an ancient divergence has been reviewed and found to be consistent with a T. pyriformis complex radiation beginning approximately 30-40 million years ago.

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).

Size maturation process of nascent DNA intermediates into chromosomal-sized DNA in Tetrahymena pyriformis macronuclear DNA replication

An analysis was made of the size maturation process of nascent DNA intermediates in macronuclear DNA replication of Tetrahymena pyriformis. The first discrete size class of nascent intermediates larger than Okazaki fragments were replicon-sized DNA (about 2 X 10(7) D single-stranded (ss) DNA) and accumulated in cells treated with cycloheximide. On removal of cycloheximide, the replicon-sized intermediates were converted to middle-sized intermediates (about 10 X 10(7) D ssDNA) and then merged into chromosomal-sized DNA. As indicated by either aphidicolin inhibition or the technique of the photolysis of bromodeoxyuridine (BrdU)-substituted DNA with long-wave ultraviolet light, four to eight replicon-sized intermediates were joined together to form a middle-sized intermediate after rapid sealing by DNA synthesis of the late-replicating regions located between adjacent replicon-sized intermediates. The late-replicating regions may represent the short gaps or terminal regions where DNA synthesis was retarded by cycloheximide, since the size of late-replicating regions was suggested to be shorter than the replicon size by DNA fiber autoradiography. Therefore, it is probable that four to eight completed replicons are joined as a group such as a replicon cluster, as has been reported in DNA replication of other eukaryotic cells.

Structural variations and optional introns in the mitochondrial DNAs of Neurospora strains isolated from nature

Mitochondrial DNAs from ten wild-type Neurospora crassa, Neurospora intermedia, and Neurospora sitophila strains collected from different geographical areas were screened for structural variations by restriction enzyme analysis. The different mtDNAs show much greater structural diversity, both within and among species, than had been apparent from previous studies of mtDNA from laboratory N. crassa strains. The mtDNAs range in size from 60 to 73 kb, and both the smallest and largest mtDNAs are found in N. crassa strains. In addition, four strains contain intramitochondrial plasmid DNAs that do not hybridize with the standard mtDNA. All of the mtDNA species have a basically similar organization. A 25-kb region that includes the rRNA genes and most tRNA genes shows very strong conservation of restriction sites in all strains. The 2.3-kb intron found in the large rRNA gene in standard N. crassa mtDNAs is present in all strains examined, including N. intermedia and N. sitophila strains. The size differences between the different mtDNAs are due to insertions or deletions that occur outside of the rRNA-tRNA region. Restriction enzyme and heteroduplex mapping suggest that four of these insertions are optional introns in the gene encoding cytochrome oxidase subunit I. Mitochondrial DNAs from different wild-type strains contain zero, one, three, or four of these introns.

Replication of the linear mitochondrial DNA of Tetrahymena pyriformis

1. Electron micrographs of the linear mtDNA from Tetrahymena pyriformis strain GL show linear molecules with a duplex 'eye' of variable size in the middle. This indicates that replication of this DNA starts near the middle of the molecule and proceeds bidirectionally to the ends, as previously shown for the mtDNA of strain ST (Arnberg, A.C., Van Bruggen, E.F.J., Clegg, R.A., Upholt, W.B. and Borst, P. (1974) Biochim. Biophys. Acta 361, 266-276). The mtDNAs of these two strains have little base sequence homology beyond the ribosomal RNA cistron (Goldbach, R.W., Bollen-De Boer, J.E., Van Bruggen, E.F.J. and Borst, P. (1978) Biochim. Biophys. Acta 521, 187-197). 2. Electron micrographs of mtDNA from strain ST, spread under non-denaturing conditions, contain only molecules with fully duplex ends. mtDNA spread under conditions of early denaturation contains duplex loops on one end (40% of all molecules) or both ends (37%). The loops are stable to partial denaturation and vary in size from 0.15 to approximately 1.0 micron, most loops measuring 0.25--0.40 micron. No loops are formed with single-stranded DNA under analogous conditions and we conclude from this result that loop formation is based on the presence of straight, rather than inverted, duplications near the ends. 3. When full-length 3H-labelled mtDNA from strain ST, 32P-labelled at the 5'-termini with T4 polynucleotide kinase, was sedimented in alkaline sucrose gradients, greater than 70% of the 3H and less than 30% of the 32P cosedimented with full-length molecules; the remaining 32P sedimented heterogeneously and predominantly with the DNA less than 10% the size of intact single strands. Brief incubations of full-length mtDNA with DNA polymerase I from Escherichia coli and labelled dNTPs at 15 degrees C did not lead to preferential labelling of terminal EcoRI fragments of the DNA. From these results we infer that the DNA contains nicks or gaps near the termini and that these are not bordered by free 3'-OH groups. 4. A model is presented in which straight sequence repetitions at the termini of Tetrahymena pyriformis mtDNA are involved in the later stages of replication. This model can also account for the pronounced terminal heterogeneity previously observed in this DNA.

Mitochondrial DNA from Podospora anserina. I. Isolation and characterization

Mitochondrial (Mt) DNA from Podospora anserina was isolated and characterized with respect to density in CsCl, contour length and endonuclease restriction enzymes. The density of Mt DNA for four races examined was 1.694 g/cm3, compared with 1.712 g/cm3 for nuclear DNA. Extraction in the presence of a nuclease inhibitor, aurintricarboxylic acid and isolation in DAPI CsCl gradients allowed us to isolate high molecular weight DNA. Mt DNA isolated by total DNA extraction contained ca. 1% of circular molecules, 31 micron in contour length; Mt DNA isolated from purified mitochondria contained 2--4% of these 31 micron circles. Analysis with Eco RI restriction endonuclease revealed that each of the four races examined, s, A, T and E had a characteristic fragment pattern. Races s and A Mt DNA differed by only one fragment after Eco RI enzymatic digestion; similarly, these two DNA differed by only one or two fragments after Hae III digestion.

Conservation of the sequence and position of the ribosomal RNA genes in Tetrahymena pyriformis mitochondrial DNA

1. We have done cross-hybridizations between the mitochondrial ribosomal RNAs and DNAs from strains ST and PP of Tetrahymena pyriformis. DNA . ribosomal RNA hybrid formation can be completely prevented by an excess of the heterologous ribosomal RNA and the heterologous hybrids melt 6 degrees C below the homologous hybrids. This shows that the ribosomal RNA cistrons can account for the 5% cross-hybridization previously observed between the mtDNAs of strains PP and ST (Goldbach et al. (1977) Biochim. Biophys. Acta 477, 37--50). 2. By electron microscopy of DNA . ribosomal RNA hybrids we have determined the position of the ribosomal RNA cistrons on the mtDNA of strain GL, a mtDNA which we have shown to contain a sub-terminal 1 micron duplication-inversion and a terminal palindrome at one end which varies in length from 0 to 5 micron and which includes the 1 micron duplication-inversion (Arnberg et al. (1977) Biochim. Biophys. Acta 477, 51--69). The 21 S ribosomal RNA cistron overlaps the 1 micron duplication-inversion and as a result two or three cistrons are present, depending on the size of the terminal palindrome. Only one 14 S ribosomal RNA cistron is found, located about 10 000 base pairs away from the nearest 21 S cistron is found, located about 10 000 base pairs away from the nearest 21 S cistron and with the same polarity as this cistron. 3. We conclude from these results and those in the preceding paper that the sequence of the ribosomal RNAs and the position of the ribosomal RNA genes in the mtDNA is strongly conserved in Tetrahymena. Possible reasons for the duplication of 21-S ribosomal RNA genes and the terminal heterogeneity of Tetrahymena mtDNA are discussed.

The organization of ribosomal RNA genes in the mitochondrial DNA of Tetrahymena pyriformis strain ST

1. We have constructed a physical map of the mtDNA of Tetrahymena pyriformis strain ST using the restriction endonucleases EcoRI, PstI, SacI, HindIII and HhaI. 2. Hybridization of mitochondrial 21 S and 14 S ribosomal RNA to restriction fragments of strain ST mtDNA shows that this DNA contains two 21-S and only one 14-S ribosomal RNA genes. By S1 nuclease treatment of briefly renatured single-stranded DNA the terminal duplication-inversion previously detected in this DNA (Arnberg et al. (1975) Biochim. Biophys. Acta 383, 359--369) has been isolated and shown to contain both 21-S ribosomal RNA genes. 14 S ribosomal RNA hybridizes to a region in the central part of the DNA, about 8000 nucleotides or 20% of the total DNA length apart from the nearest 21 S ribosomal RNA gene. 3. We have confirmed this position of the three ribosomal RNA genes by electron microscopical analysis of DNA . RNA hybrid molecules and R-loop molecules. 4. Hybridization of 21 S ribosomal RNA with duplex mtDNA digested either with phage lambda-induced exonuclease or exonuclease III of Escherichia coli, shows that the 21-S ribosomal RNA genes are located on the 5'-ends of each DNA strand. Electron microscopy of denaturated mtDNA hybridized with a mixture of 14-S and 21-S ribosomal RNAs show that the 14 S ribosomal RNA gene has the same polarity as the nearest 21 S ribosomal RNA gene. 5. Tetrahymena mtDNA is (after Saccharomyces mtDNA) the second mtDNA in which the two ribosomal RNA cistrons are far apart and the first mtDNA in which one of the ribosomal RNA cistrons is duplicated.

The structure of Tetrahymena pyriformis mitochondrial DNA. II. The complex structure of strain GL mitochondrial DNA

1. Isolated mtDNA from Tetrahymena pyriformis strain GL is a linear duplex molecule with an average molecular weight of 32.6 - 10(6) and without internal gaps or breaks. Denaturation of this DNA results in single strands with a duplex hairpin at one end. The length of this hairpin varies between 0 and 5 micrometer within one preparation. 2. Uder renaturation conditions the single strands with hairpins are able to circularize in two ways, depending on the length of the hairpin. Circularization is also observed after partial digestion with exonuclease III of native strain GL mtDNA. 3. All these data fit a model (see Fig.2) in which the DNA is heterogeneous in length at both ends. At the left end a 10-micrometer duplication-inversion is present; part of this duplication-inversion is complementary to a region at the right end of the molecule. 4. The analogy between the structural peculiarities of strain GL mtDNA and of some linear viral DNAs is stressed.