Mitochondrial DNA of Hydra attenuata (Cnidaria): a sequence that includes an end of one linear molecule and the genes for l-rRNA, tRNA(f-Met), tRNA(Trp), COII, and ATPase8.

The 3231-nucleotide-pair (ntp) sequence of one end of one of the two linear mitochondrial (mt) DNA molecules of Hydra attenuata (phylum Cnidaria, class Hydrozoa, order Anthomedusae) has been determined. This segment contains complete genes for tRNA(f-Met), l-rRNA, tRNA(Trp), subunit 2 of cytochrome c oxidase (COII), subunit 8 of ATP synthetase (ATPase8), and the 5' 136 ntp of ATPase6. These genes are arranged in the order given and are transcribed from the same strand of the molecule. As in two other cnidarians, the hexacorallian anthozoan Metridium senile and the octocorallian anthozoan Sarcophyton glaucum, the mt-genetic code of H. attenuata is near standard. The only modification appears to be that TGA specifies tryptophan rather than termination. Also as in M. senile and S. glaucum, the encoded H. attenuata mt-tRNA(f-Met) has primary and secondary structural features resembling those of Escherichia coli initiator tRNA(t-Met). As the encoded mt-tRNA(Trp) cannot be folded into a totally orthodox secondary structure, two alternative forms are suggested. The encoded H. attenuata mt-l-rRNA is 1738 nt, which is 451 nt shorter than the M. senile mt-l-rRNA. Comparisons of secondary structure models of these two mt-l-rRNAs indicate that most of the size difference results from loss of nucleotides in the H. attenuata molecule at a minimum of 46 locations, which includes elimination of six distinct helical elements.

Mytilus mitochondrial DNA contains a functional gene for a tRNASer(UCN) with a dihydrouridine arm-replacement loop and a pseudo-tRNASer(UCN) gene.

A 2500-nucleotide pair (ntp) sequence of F-type mitochondrial (mt) DNA of the Pacific Rim mussel Mytilus californianus (class Bivalvia, phylum Mollusca) that contains two complete (ND2 and ND3) and two partial (COI and COIII) protein genes and nine tRNA genes is presented. Seven of the encoded tRNAs (Ala, Arg, His, Met(AUA), Pro, Ser(UCN), and Trp) have the potential to fold into the orthodox four-armed tRNA secondary structure, while two [tRNASer(AGN) and a second tRNASer(UCN)] will fold only into tRNAs with a dihydrouridine (DHU) arm-replacement loop. Comparison of these mt-tRNA gene sequences with previously published, corresponding M. edulis F-type mtDNA indicates that similarity between the four-armed tRNASer(UCN) genes is only 63.8% compared with an average of 92.1% (range 86.2-98. 5%) for the remaining eight tRNA genes. Northern blot analysis indicated that mature tRNAs encoded by the DHU arm-replacement loop-containing tRNASer(UCN), tRNASer(AGN), tRNAMet(AUA), tRNATrp, and tRNAPro genes occur in M. californianus mitochondria, strengthening the view that all of these genes are functional. However, Northern blot and 5' RACE (rapid amplification of cDNA ends) analyses indicated that the four-armed tRNASer(UCN) gene is transcribed into a stable RNA that includes the downstream COI sequence and is not processed into a mature tRNA. On the basis of these observations the M. californianus and M. edulis four-armed tRNASer(UCN) sequences are interpreted as pseudo-tRNASer(UCN) genes.

Mitochondrial DNA of the coral Sarcophyton glaucum contains a gene for a homologue of bacterial MutS: a possible case of gene transfer from the nucleus to the mitochondrion.

The nucleotide sequences of two segments of 6,737 ntp and 258 nto of the 18.4-kb circular mitochondrial (mt) DNA molecule of the soft coral Sarcophyton glaucum (phylum Cnidaria, class Anthozoa, subclass Octocorallia, order Alcyonacea) have been determined. The larger segment contains the 3' 191 ntp of the gene for subunit 1 of the respiratory chain NADH dehydrogenase (ND1), complete genes for cytochrome b (Cyt b), ND6, ND3, ND4L, and a bacterial MutS homologue (MSH), and the 5' terminal 1,124 ntp of the gene for the large subunit rRNA (1-rRNA). These genes are arranged in the order given and all are transcribed from the same strand of the molecule. The smaller segment contains the 3' terminal 134 ntp of the ND4 gene and a complete tRNA(f-Met) gene, and these genes are transcribed in opposite directions. As in the hexacorallian anthozoan, Metridium senile, the mt-genetic code of S. glaucum is near standard: that is, in contrast to the situation in mt-genetic codes of other invertebrate phyla, AGA and AGG specify arginine, and ATA specifies isoleucine. However, as appears to be universal for metazoan mt-genetic codes, TGA specifies tryptophan rather than termination. Also, as in M. senile the mt-tRNA(f-Met) gene has primary and secondary structural features resembling those of Escherichia coli initiator tRNA, including standard dihydrouridine and T psi C loop sequences, and a mismatched nucleotide pair at the top of the amino-acyl stem. The presence of a mutS gene homologue, which has not been reported to occur in any other known mtDNA, suggests that there is mismatch repair activity in S. glaucum mitochondria. In support of this, phylogenetic analysis of MutS family protein sequences indicates that the S. glaucum mtMSH protein is more closely related to the nuclear DNA-encoded mitochondrial mismatch repair protein (MSH1) of the yeast Saccharomyces cerevisiae than to eukaryotic homologues involved in nuclear function, or to bacterial homologues. Regarding the possible origin of the S. glaucum mtMSH gene, the phylogenetic analysis results, together with comparative base composition considerations, and the absence of an MSH gene in any other known mtDNA best support the hypothesis that S. glaucum mtDNA acquired the mtMSH gene from nuclear DNA early in the evolution of octocorals. The presence of mismatch repair activity in S. glaucum mitochondria might be expected to influence the rate of evolution of this organism's mtDNA.

The mitochondrial genome of the sea anemone Metridium senile (Cnidaria): introns, a paucity of tRNA genes, and a near-standard genetic code.

The circular, 17,443 nucleotide-pair mitochondrial (mt) DNA molecule of the sea anemone, Metridium senile (class Anthozoa, phylum Cnidaria) is presented. This molecule contains genes for 13 energy pathway proteins and two ribosomal (r) RNAs but, relative to other metazoan mtDNAs, has two unique features: only two transfer RNAs (tRNA(f-Met) and tRNA(Trp)) are encoded, and the cytochrome c oxidase subunit I (COI) and NADH dehydrogenase subunit 5 (ND5) genes each include a group I intron. The COI intron encodes a putative homing endonuclease, and the ND5 intron contains the molecule's ND1 and ND3 genes. Most of the unusual characteristics of other metazoan mtDNAs are not found in M. senile mtDNA: unorthodox translation initiation codons and partial translation termination codons are absent, the use of TGA to specify tryptophan is the only genetic code modification, and both encoded tRNAs have primary and secondary structures closely resembling those of standard tRNAs. Also, with regard to size and secondary structure potential, the mt-s-rRNA and mt-1-rRNA have the least deviation from Escherichia coli 16S and 23S rRNAs of all known metazoan mt-rRNAs. These observations indicate that most of the genetic variations previously reported in metazoan mtDNAs developed after Cnidaria diverged from the common ancestral line of all other Metazoa.

Gender-associated diverse mitochondrial DNA molecules of the mussel Mytilus californianus.

The Pacific-rim, dioecious bivalve Mytilus californianus contains two distinct sequence types of mitochondrial (mt) DNA that are gender-limited in their occurrence. One type (F) is found in both females and males, but the second type (M) is strictly limited to males. Although F- and M-type mtDNAs occur in approximately equal proportion in testes, there is a preponderance of M-type in sperm. Segments of the COI and ND5 genes of F-type and M-type mtDNAs differ in nucleotide sequence by 21.1% and 31.6%, and in predicted amino-acid sequence by 7.9% and 27.1%, respectively. These latter observations raise hitherto unconsidered questions regarding the number of different variants of cytochrome c oxidase and NADH dehydrogenase that may occur in Mytilus non-gametic male cells.

Two mitochondrial group I introns in a metazoan, the sea anemone Metridium senile: one intron contains genes for subunits 1 and 3 of NADH dehydrogenase.

Mitochondrial genes for cytochrome c oxidase subunit I (COI) and NADH dehydrogenase subunit 5 (ND5) of the sea anemone Metridium senile (phylum Cnidaria) each contain a group I intron. This is in contrast to the reported absence of introns in all other metazoan mtDNAs so far examined. The ND5 intron is unusual in that it ends with A and contains two genes (ND1 and ND3) encoding additional subunits of NADH dehydrogenase. Correctly excised ND5 introns are not circularized but are precisely cleaved near their 3' ends and polyadenylylated to provide bicistronic transcripts of ND1 and ND3. COI introns, which encode a putative homing endonuclease, circularize, but in a way that retains the entire genome-encoded intron sequence (other group I introns are circularized with loss of a short segment of the intron 5' end). Introns were detected in the COI and ND5 genes of other sea anemones, but not in the COI and ND5 genes of other cnidarians. This suggests that the sea anemone mitochondrial introns may have been acquired relatively recently.

RNA editing of mat-r transcripts in maize and soybean increases similarity of the encoded protein to fungal and bryophyte group II intron maturases: evidence that mat-r encodes a functional protein.

We present evidence that transcripts of the mat-r (maturase-related) genes of maize and soybean contain 15 and 14 uridines (U), respectively, at positions occupied by cytosines (C) in the mat-r gene sequences. Eleven and twelve of these C-->U edits result in an amino acid replacement. Ten C-->U edits are at corresponding nucleotides in the maize and soybean transcripts and, except for a single silent edit, the remainder are at positions in one species that are Us in the other species. This results in an increase in amino acid sequence similarity of the maize and soybean MAT-R proteins. Further, of those amino acids in maize and soybean MAT-R proteins specified by edited codons, ten are conserved in the reverse transcriptase-associated and RNA splicing-associated sequences of the cox1-I2 and/or the cox1-I1 maturases of the fungus Saccharomyces cerevisiae and the bryophyte, Marchantia polymorpha, respectively. The implied strong selection for amino acid sequence conservation indicates that the MAT-R protein is functional. The possibility is discussed that initiation of translation of the mat-r transcripts is at a four nucleotide codon, ATAA or ATGA.

The mitochondrial ribosomal RNA genes of the nematodes Caenorhabditis elegans and Ascaris suum: consensus secondary-structure models and conserved nucleotide sets for phylogenetic analysis.

The small- and large-subunit mitochondrial ribosomal RNA genes (mt-s-rRNA and mt-l-rRNA) of the nematode worms Caenorhabditis elegans and Ascaris suum encode the smallest rRNAs so far reported for metazoa. These size reductions correlate with the previously described, smaller, structurally anomalous mt-tRNAs of C. elegans and A. suum. Using primer extension analysis, the 5' end nucleotides of the mt-s-rRNA and mt-l-rRNA genes were determined to be adjacent to the 3' end nucleotides of the tRNA(Glu) and tRNA(His) genes, respectively. Detailed, consensus secondary-structure models were constructed for the mt-s-rRNA genes and the 3' 64% of mt-l-rRNA genes of the two nematodes. The mt-s-rRNA secondary-structure model bears a remarkable resemblance to the previously defined universal core structure of E. coli 16S rRNA: most of the nucleotides that have been classified as variable or semiconserved in the E. coli model appear to have been eliminated from the C. elegans and A. suum sequences. Also, the secondary structure model constructed for the 3' 64% of the mt-l-rRNA is similar to the corresponding portion of the previously defined E. coli 23S rRNA core secondary structure. The proposed C. elegans/A. suum mt-s-rRNA and mt-l-rRNA models include all of the secondary-structure element-forming sequences that in E. coli rRNAs contain nucleotides important for A-site and P-site (but not E-site) interactions with tRNAs. Sets of apparently homologous sequences within the mt-s-rRNA and mt-l-rRNA core structures, derived by alignment of the C. elegans and A. suum mt-rRNAs to the corresponding mt-rRNAs of other eukaryotes, and E. coli rRNAs were used in maximum-likelihood analyses. The patterns of divergence of metazoan phyla obtained show considerable agreement with the most prevalent metazoan divergence patterns derived from more classical, morphological, and developmental data.

Mitochondrial DNA of the sea anemone, Metridium senile (Cnidaria): prokaryote-like genes for tRNA(f-Met) and small-subunit ribosomal RNA, and standard genetic code specificities for AGR and ATA codons.

The nucleotide sequence of a segment of the mitochondrial DNA (mtDNA) molecule of the sea anemone Metridium senile (phylum Cnidaria, class Anthozoa, order Actiniaria) has been determined, within which have been identified the genes for respiratory chain NADH dehydrogenase subunit 2 (ND2), the small-subunit rRNA (s-rRNA), cytochrome c oxidase subunit II (COII), ND4, ND6, cytochrome b (Cyt b), tRNA(f-Met), and the large-subunit rRNA (1-rRNA). The eight genes are arranged in the order given and are all transcribed from the same strand of the molecule. The overall order of the M. senile mt-genes differs from that of other metazoan mtDNAs. In M. senile mt-protein genes, AGA and AGG codons appear to have the standard genetic code specification of arginine, rather than serine as found for other invertebrate mt-genetic codes. Also, ATA has the standard genetic code specification of isoleucine. TGA occurs in three M. senile mt-protein genes and may specify tryptophan as in other metazoan, protozoan, and some fungal mt-genetic codes. The M. senile mt-rRNA(f-Met) gene has primary and secondary structure features closely resembling those of the Escherichia coli initiator tRNA, including standard dihydrouridine and T psi C loop sequences and a mismatch pair at the top of the aminoacyl stem. Determinations of the 5' and 3' end nucleotides of the M. senile mt-s-rRNAs indicated that these molecules have a homogenous size of 1,081 ntp, larger than any other known metazoan mt-s-rRNAs. Consistent with its larger size, the M. senile mt-s-rRNA can be folded into a secondary structure that more closely resembles that of the E. coli 16S rRNA than can any other metazoan mt-s-rRNA. These findings concerning M. senile mtDNA indicate that most of the unusual features regarding metazoan mt-genetic codes, rRNAs, and probably tRNAs developed after divergence of the Cnidarian line from the ancestral line common to other metazoa.

Nucleotide correlations that suggest tertiary interactions in the TV-replacement loop-containing mitochondrial tRNAs of the nematodes, Caenorhabditis elegans and Ascaris suum.

In the predicted secondary structures of 20 of the 22 tRNAs encoded in mitochondrial DNA (mtDNA) molecules of the nematodes, Caenorhabditis elegans and Ascaris suum, the T psi C arm and variable loop are replaced with a loop of 6 to 12 nucleotides: the TV-replacement loop. From considerations of patterns of nucleotide correlations in the central regions of these tRNAs, it seems highly likely that tertiary interactions occur within five sets of binary and ternary combinations of nucleotides that correspond in location to nucleotides known to be involved in tertiary interactions in yeast tRNA(Phe) and other standard tRNAs. These observations are consistent with the nematode TV-replacement loop-containing mt-tRNAs being folded into a similar L-shaped functional form to that demonstrated for standard tRNAs, and for the bovine DHU (dihydrouridine) arm replacement-loop-containing mt-tRNA(Ser(AGY)). However, the apparent occurrence in nematode mt-tRNAs of tertiary bonds common to standard tRNAs contrasts with the situation in bovine mt-tRNA(Ser(AGY)) where the functional form is dependent on an almost unique set of tertiary interactions. Because three of the proposed conserved tertiary interactions in the nematode mt-tRNAs involve nucleotides that occur in the variable loop in standard tRNAs, it seems more likely that in nematode mt-tRNAs it is the T psi C arm rather than the variable loop that has undergone the greatest proportional decrease in nucleotide number.

Low, but strongly structured mitochondrial DNA diversity in root knot nematodes (Meloidogyne).

Root-knot nematodes (genus Meloidogyne) have been the subject of recent and numerous studies of genetic variation because of the need to develop molecular diagnostics for the four globally distributed, parthenogenetic species that are significant agricultural pests. Our analysis of Meloidogyne mtDNA improves on previous studies: (i) by examining restriction site polymorphism among a large number of isolates also characterized for standard morphological, host range and allozyme phenotypes; (ii) by using higher resolution electrophoretic techniques; and (iii) by mapping variable restriction sites with reference to the complete nucleotide sequence. This revealed fivefold less sequence divergence (< 0.6%) between variants than estimated in previous restriction fragment length polymorphism (RFLP) studies, but perfect correspondence between mtDNA haplotype and allozyme (esterase) phenotypes. The mtDNA variation, although limited, is strongly structured with as much divergence between two lineages of Meloidogyne arenaria as between either of these and Meloidogyne javanica. The low diversity of mtDNAs suggests that these parthenogenetic lineages arose from distinct but closely related sexual females, a pattern seen in other parthenogenetic complexes. In contrast to the concordance between mtDNA and allozyme markers, there were several discrepancies between the traditional methods of identification. We suggest that further studies of these nematodes should focus on well defined genetic groups, whether or not these coincide with existing taxonomic units.

A tRNA(Ser)(UCN) gene in Artemia salina mitochondrial DNA: a case of mistaken identity.

We have sequenced a segment of mitochondrial DNA (mtDNA) of a crustacean, the brine shrimp, Artemia salina, that includes 3' end-proximal regions of the genes for subunit 1 of the NADH dehydrogenase complex (ND1) and cytochrome b (Cyt b). From our data we conclude that in this mtDNA, as in the mtDNAs of Drosophila species, a tRNA(Ser)(UCN) gene separates the ND1 and Cyt b genes. This is contrary to an earlier report that the A. salina ND1 and Cyt b genes are immediately adjacent to each other.

Genetic novelties in mitochondrial genomes of multicellular animals.

Mitochondrial genomes of multicellular animals are mostly small, circular molecules in which 13 protein genes, two ribosomal-RNA genes and 22 transfer-RNA genes are closely packed. Substantial rearrangements of genes have only occurred between phylogenetically distant organisms. However, a wealth of genetic novelties are found among these genomes that include modified genetic codes, unorthodox translation initiation codons, and structurally modified RNA components of the mitochondrion's translation system.

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.

Repeated sequence sets in mitochondrial DNA molecules of root knot nematodes (Meloidogyne): nucleotide sequences, genome location and potential for host-race identification.

Within a 7 kb segment of the mtDNA molecule of the root knot nematode, Meloidogyne javanica, that lacks standard mitochondrial genes, are three sets of strictly tandemly arranged, direct repeat sequences: approximately 36 copies of a 102 ntp sequence that contains a TaqI site; 11 copies of a 63 ntp sequence, and 5 copies of an 8 ntp sequence. The 7 kb repeat-containing segment is bounded by putative tRNAasp and tRNAf-met genes and the arrangement of sequences within this segment is: the tRNAasp gene; a unique 1,528 ntp segment that contains two highly stable hairpin-forming sequences; the 102 ntp repeat set; the 8 ntp repeat set; a unique 1,068 ntp segment; the 63 ntp repeat set; and the tRNAf-met gene. The nucleotide sequences of the 102 ntp copies and the 63 ntp copies have been conserved among the species examined. Data from Southern hybridization experiments indicate that 102 ntp and 63 ntp repeats occur in the mtDNAs of three, two and two races of M.incognita, M.hapla and M.arenaria, respectively. Nucleotide sequences of the M.incognita Race-3 102 ntp repeat were found to be either identical or highly similar to those of the M.javanica 102 ntp repeat. Differences in migration distance and number of 102 ntp repeat-containing bands seen in Southern hybridization autoradiographs of restriction-digested mtDNAs of M.javanica and the different host races of M.incognita, M.hapla and M.arenaria are sufficient to distinguish the different host races of each species.

Evidence for the frequent use of TTG as the translation initiation codon of mitochondrial protein genes in the nematodes, Ascaris suum and Caenorhabditis elegans.

Data obtained from alignments of nucleotide sequences of mitochondrial (mt) DNA molecules of the nematode worms Ascaris suum and Caenorhabditis elegans indicate that in six of the mt-protein genes of A. suum and three of the mt-protein genes of C. elegans TTG is used as the translation initiation codon. Also, GTT seems to be the translation initiation codon of the A. suum COIII gene. All of the five remaining A. suum mt-protein genes appear to begin with ATT and the remaining nine C. elegans mt-protein genes appear to begin with either ATT or ATA. Therefore, in contrast to all other metazoan mtDNAs sequenced so far, it is likely that none of the nematode mt-protein genes use the standard ATG translation initiation codon. Some A. suum and C. elegans mt-protein genes end in T or TA, suggesting that, as found in other metazoan mitochondria, 3'-terminal polyadenylation is occasionally necessary to generate complete translation termination codons in transcripts of nematode mt-protein genes.

A set of tRNAs that lack either the T psi C arm or the dihydrouridine arm: towards a minimal tRNA adaptor.

The mitochondrial DNA (mtDNA) molecules of the nematode worms, Caenorhabditis elegans and Ascaris suum contain 22 putative genes for non-standard forms of tRNAs. The inferred transcripts can be folded into 20 separate structures each resembling a tRNA whose T psi C arm and variable loop are replaced with a simple loop of 6-12 nucleotides. In two further structures [that resemble tRNAs for ser(UCN) and ser(AGN)], the dihydrouridine arm is replaced by a loop of 5-8 nucleotides. By hybridizing mt-tRNA gene-specific oligonucleotide probes to nematode RNAs, we have obtained evidence for transcription of at least nine C.elegans and three A.suum mt-tRNA genes. Each transcript (tRNA) is the exact size predicted from the respective DNA sequence, to which three nucleotides, presumably CCA, have been added following transcription. An exception was C.elegans mt-tRNAasn, most molecules of which had one nucleotide (plus CCA) more than predicted from the gene. The data presented strongly support the conclusion that the functional mt-tRNAs of nematode worms are direct transcripts (with only CCA addition) of the structurally unusual mt-tRNA genes. There is no evidence of trans-splicing or RNA editing to add the sequences missing from these nonstandard tRNAs. We presume, therefore, that the non-standard forms are active in mitochondrial protein synthesis.

A broad bean mitochondrial atp6 gene with an unusually simple, non-conserved 5' region.

A nucleotide sequence of broad bean mitochondrial DNA (mtDNA) that contains an atp6 gene of 876 ntp is presented. Relative to other plant atp6 genes, this broad bean gene comprises a 90 ntp non-conserved 5' region, a 759 ntp highly conserved central region and a 27 ntp non-conserved 3' region. The non-conserved, 5' region of the broad bean atp6 gene differs from the corresponding regions of most other plant atp6 genes in that it contains only one potential translation initiation codon and, following this codon, a 63 ntp segment that predicts an amino acid sequence with a predominance of alternating leucines.