Nucleotide sequence of the single ribosomal RNA operon of pea chloroplast DNA

The nucleotide sequence of an 8 kbp region of pea ( Pisum sativum L.) chloroplast DNA containing the rRNA operon and putative promoter sites has been determined and compared to the corresponding sequences from maize, tobacco and the liverwort Marchantia polymorpha . The chloroplast DNA species of all vascular plants investigated, with the exception of a few legumes including pea, and of Marchantia contain an inverted repeat with an rRNA operon. The pea rRNA operon is the first sequenced rRNA operon from a plant with only one copy of the rRNA genes per molecule of chloroplast DNA. The organization of the operon is the same as for maize, tobacco and Marchantia . i.e. tRNA-Val gene/16S rRNA gene/spacer with intron-containing genes for tRNA-Ile and tRNA-Ala/23S rRNA gene/4.5S rRNA gene/5S rRNA gene. Current evidence suggests that the tRNA-Val gene may not be contranscribed with the other genes. For pea 16S, 23S, 4.5S and 5S rRNA have 1488, 2813, 105 and 121 nucleotides, respectively. The homologies of the entire operon (the tRNA-Val gene - 5S rRNA region) to those from tobacco, maize and Marchantia are 88, 82 and 79%, respectively. The corresponding homologies for tobacco/maize, tobacco/ Marchantia and maize/ Marchantia have similar values. The 16S and 23S rRNA genes from pea are more than 90% homologous to those from the 3 other species. We conclude that the fact that pea only has one set of rRNA genes per molecule of chloroplast DNA is apparently not correlated with any significant difference between the pea operon and the rRNA operons from tobacco, maize and Marchantia .     

Nucleotide sequence and evolution of coding and noncoding regions of a quail mitochondrial genome

Summary Segments of the Japanese quail mito-chondrial genome encompassing many tRNA and protein genes, the small and part of the large rRNA genes, and the control region have been cloned and sequenced. Analysis of the relative position of these genes confirmed that the tRNA^Glu and ND6 genes in galliform mitochondrial DNA are located immediately adjacent to the control region of the molecule instead of between the cytochrome b and ND5 genes as in other vertebrates. Japanese quail and chicken display another distinctive characteristic, that is, they both lack an equivalent to the light-strand replication origin found between the tRNA^Cys and tRNA^Asn genes in all vertebrate mitochondrial genomes sequenced thus far. Comparison of the protein-encoding genes revealed that a great proportion of the substitutions are silent and involve mainly transitions. This bias toward transitions also occurs in the tRNA and rRNA genes but is not observed in the control region where transversions account for many of the substitutions. Sequence alignment indicated that the two avian control regions evolve mainly through base substitutions but are also characterized by the occurrence of a 57-bp deletion/addition event at their 5′ end. The overall sequence divergence between the two gallinaceous birds suggests that avian mitochondrial genomes evolve at a similar rate to other vertebrate mitochondrial DNAs.     

Rearrangements of mitochondrial transfer RNA genes in marsupials

Summary The nucleotide sequences of the mitochondrial origin of light-strand replication and the five tRNA genes surrounding it were determined for three marsupials. The region was found to be rearranged, leaving only the tRNA^Tyr gene at the same position as in placental mammals andXenopus. Distribution of the same rearranged genotype among two marsupial families indicates that the events causing the rearrangements took place in an early marsupial ancestor. The putative mitochondrial light-strand origin of replication in marsupials contains a hairpin structure similar to other vertebrate origins and, in addition, extensive flanking sequences that are not found in other vertebrates. Sequence comparisons among the marsupials as well as placentals indicate that the tRNA^Tyr gene has been evolving under more constraints than the other tRNA genes.Deceased July 21, 1991     

Phylogenetic estimation of Mytilidae in the East China Sea inferred from mitochondrial genes and nuclear DNA sequence variation

We performed a phylogenetic estimation of the family Mytilidae in the East China Sea based on nuclear internal transcribed spacer (ITS) genes and two mitochondrial genes (COI and 16S RNA). Analysis of five mytilid species based on each of the three genes resulted in mostly congruent trees, although there were some discrepancies in the classification of these species. We combine the results obtained from the three separate analyses to provide a phylogenetic estimation of Mytilidae. We found that the Mytilidae was divided into two major lineages: in one clade, Mytilus galloprovincialis was grouped with Mytilus coruscus; in the second clade, Septifer bilocularis was placed at the basal position in an individual clade, and Perna viridis and Musculista senhousia were recovered as a monophyletic group. Although these finding provide important insights into the taxonomic relationships among the Mytilidae, many aspects of Mytilidae phylogeny remain unresolved. Further analysis based on more molecular information and extensive taxon sampling is necessary to elucidate the phylogenetic relationships among the major lineages within the Mytilidae.     

DNA sequence,structure, and phylogenetic relationship of the small subunit rRNA coding region of mitochondrial DNA fromPodospora anserina

Summary DNA sequence analysis and the localization of the 5 and 3 termini by S1 mapping have shown that the mitochondrial (mt) small subunit rRNA coding region fromPodospora anserina is 1980 bp in length. The analogous coding region for mt rRNA is 1962 bp in maize, 1686 bp inSaccharomyces cerevisiae, and 956 bp in mammals, whereas its counterpart inEscherichia coli is 1542 bp. TheP. anserina mt 16S-like rRNA is 400 bases longer than that fromE. coli, but can be folded into a similar secondary structure. The additional bases appear to be clustered at specific locations, including extensions at the 5 and 3 termini. Comparison with secondary structure diagrams of 16S-like RNAs from several organisms allowed us to specify highly conserved and variable regions of this gene. Phylogenetic tree construction indicated that this gene is grouped with other mitochondrial genes, but most closely, as expected, with the fungal mitochondrial genes.     

The complete mitochondrial DNA sequence of the crustacean Artemia franciscana

The complete mitochondrial DNA (mtDNA) sequence of the brine shrimp Artemia franciscana has been determined. It extends the present knowledge of mitochondrial genomes to the crustacean class and supplies molecular markers for future comparative studies in this large branch of the arthropod phylum. Artemia mtDNA is 15,822 nucleotides long, and when compared with its Drosophila counterpart, it shows very few gene rearrangements, merely affecting two tRNAs placed 3 downstream of the ND 2 gene. In this position a stem-loop secondary structure with characteristics similar to the vertebrate mtDNA L-strand origin of replication is found. This suggests that, associated with tRNA changes, the diversification of the mitochondrial genome from an ancestor common to crustacea and insects could be explained by errors in the mtDNA replication process. Although the gene content is the same as in most animal mtDNAs, the sizes of the protein coding genes are in some cases considerably smaller. Artemia mtDNA uses the same genetic code as found in insects, ATN and GTG are used as initiation codons, and several genes end in incomplete T or TA codons.Correspondence to: R. Garesse     

Variation in salmonid mitochondrial DNA: Evolutioinary constraints and mechanisms of substitution

Summary Sequence comparisons were made from 2214 bp of mitochondrial DNA cloned from six Pacific salmonid species. These sequences include the genes for ATPase subunit 6, cytochrome oxidase subunit 3, NADH dehydrogenase subunit 3, NADH dehydrogenase subunit 4L, tRNA^GLY, and tRNA^ARG. Variation is found at 338 silent and 12 nonsilent positions of protein coding genes and 10 positions in the two tRNA sequences. A single 3-bp length difference was also detected. In all pairwise comparisons the sequence divergence observed in the fragment was higher than that previously predicted by restriction enzyme analysis of the entire molecule. The inferred evolutionary relationship of these species is consistent between methods. The distribution of silent variation shows a complex pattern with greatly reduced variation at the junctions of genes. The variation in the tRNA sequences is concentrated in the DHU loop. The close relationship of these species and extensive sequence analyzed allows for an analysis of the spectrum of substitutions that includes the frequencies of all 12 possible substitutions. The observed spectrum of substitutions is related to potential pathways of spontaneous substitution. The salmonid sequences show an extremely high ratio of silent to replacement substitutions. In addition the amino acid sequences of the four proteins coded in this fragment show a consistently high level of identity with theXenopus sequences. Taken together these data are consistent with a slower rate of amino acid substitution among the cold-blooded vertebrates when compared to mammals.     

Nucleotide sequence and genome organization of bacteriophage S13 DNA

The complete sequence of bacteriophage S13 DNA has been determined. The molecule has 5386 nucleotides and differs from φX174 by 87 transitions and 24 transversions. All the proteins, A, A^*, B, C, D, E, F, G, H, J and K found in φX174 are also present in S13. Due to changes in the H/A intergenic region of S 13, the start of an additional protein. A′, has been identified. Genes F and H coding for the capsid and spike proteins, respectively, are the least conserved in comparison to φX174. Many of the silent changes, as well as some amino acid changes, are found in the same nucleotide sequence positions in phage G4, confirming the interrelationship between the three phages.     

The mitochondrial DNA of Dictyostelium discoideum: complete sequence, gene content and genome organization

We present an overview of the gene content and organization of the mitochondrial genome of Dictyostelium discoideum. The mitochondria genome consists of 55,564 bp with an A + T content of 72.6%. The identified genes include those for two ribosomal RNAs (rnl and rns), 18 tRNAs, ten subunits of the NADH dehydrogenase complex (nad1, 2, 3, 4, 4L, 5, 6, 7, 9 and 11), apocytochrome b (cytb), three subunits of the cytochrome oxidase (cox1/2 and 3), four subunits of the ATP synthase complex (atp1, 6, 8 and 9), 15 ribosomal proteins, and five other ORFs, excluding intronic ORFs. Notable features of D. discoideum mtDNA include the following. (1) All genes are encoded on the same strand of the DNA and a universal genetic code is used. (2) The cox1 gene has no termination codon and is fused to the downstream cox2 gene. The 13 genes for ribosomal proteins and four ORF genes form a cluster 15.4 kb long with several gene overlaps. (3) The number of tRNAs encoded in the genome is not sufficient to support the synthesis of mitochondrial protein. (4) In total, five group I introns reside in rnl and cox1/2, and three of those in cox1/2 contain four free-standing ORFs. We compare the genome to other sequenced mitochondrial genomes, particularly that of Acanthamoeba castellanii. Received: 5 July 1999 / Accepted: 17 January 2000     

DNA sequence and secondary structures of the large subunit rRNA coding regions and its two class I introns of mitochondrial DNA fromPodospora anserina

Summary DNA sequence analysis has shown that the gene coding for the mitochondrial (mt) large subunit ribosomal RNA (rRNA) fromPodospora anserina is interrupted by two class I introns. The coding region for the large subunit rRNA itself is 3715 bp and the two introns are 1544 (r1) and 2404 (r2) bp in length. Secondary structure models for the large subunit rRNA were constructed and compared with the equivalent structure fromEscherichia coli 23S rRNA. The two structures were remarkably similar despite an 800-base difference in length. The additional bases in theP. anserina rRNA appear to be mostly in unstructured regions in the 3 part of the RNA. Secondary structure models for the two introns show striking similarities with each other as well as with the intron models from the equivalent introns inSaccharomyces cerevisiae, Neurospora crassa, andAspergillus nidulans. The long open reading frames in each intron are different from each other, however, and the nucleotide sequence similarity diverges as it proceeds away from the core structure. Each intron is located within regions of the large subunit rRNA gene that are highly conserved in both sequence and structure. Computer analysis showed that the open reading frame for intron r1 contained a common maturase-like polypeptide. The open reading frames of intron r2 apeared to be chimeric, displaying high sequence similarity with the open reading frames in the r1 and ATPase 6 introns ofN. crassa.