Complete modification maps for the cytosolic small and large subunit rRNAs of Euglena gracilis: functional and evolutionary implications of contrasting patterns between the two rRNA components

In the protist Euglena gracilis, the cytosolic small subunit (SSU) rRNA is a single, covalently continuous species typical of most eukaryotes; in contrast, the large subunit (LSU) rRNA is naturally fragmented, comprising 14 separate RNA molecules instead of the bipartite (28S + 5.8S) eukaryotic LSU rRNA typically seen. We present extensively revised secondary structure models of the E. gracilis SSU and LSU rRNAs and have mapped the positions of all of the modified nucleosides in these rRNAs (88 in SSU rRNA and 262 in LSU rRNA, with only 3 LSU rRNA modifications incompletely characterized). The relative proportions of ribose-methylated nucleosides and pseudouridine (∼ 60% and ∼ 35%, respectively) are closely similar in the two rRNAs; however, whereas the Euglena SSU rRNA has about the same absolute number of modifications as its human counterpart, the Euglena LSU rRNA has twice as many modifications as the corresponding human LSU rRNA. The increased levels of rRNA fragmentation and modification in E. gracilis LSU rRNA are correlated with a 3-fold increase in the level of mispairing in helical regions compared to the human LSU rRNA. In contrast, no comparable increase in mispairing is seen in helical regions of the SSU rRNA compared to its homologs in other eukaryotes. In view of the reported effects of both ribose-methylated nucleoside and pseudouridine residues on RNA structure, these correlations lead us to suggest that increased modification in the LSU rRNA may play a role in stabilizing a ‘looser’ structure promoted by elevated helical mispairing and a high degree of fragmentation.     

Phenotypic effects of targeted mutations in the small subunit rRNA gene of Tetrahymena thermophila.

Tetrahymena thermophila is an ideal organism with which to study functional aspects of the rRNAs in vivo since the somatic rRNA genes of T. thermophila can be totally replaced by cloned copies introduced via microinjection. In this study, we made small insertions into seven sites within the small subunit rRNA gene and observed their phenotypic effects on transformed cells. Two mutated genes coding for rRNA (rDNAs), both of which bear insertions in highly conserved sequences, failed to transform and are therefore believed to produce nonfunctional rRNAs. Three other altered rDNAs produce functional rRNAs that can substitute for most or all of the cellular rRNA. Two of these bear insertions in highly variable regions, and, surprisingly, the other has an insertion in a region that is well conserved for both sequence and secondary structure among eucaryotes. In addition, two other insertions appear to destabilize rRNAs that contain them. Our findings make predictions concerning the positions of some of these sites within the tertiary structure of the small ribosomal subunit and thus serve as an in vivo test of the existing tertiary structure models for the small subunit rRNA. Our results are in good agreement with expectations based on sequence comparison and in vitro work.     

DISCONTINUOUS MITOCHONDRIAL AND CHLOROPLAST LARGE SUBUNIT RIBOSOMAL RNAs AMONG GREEN ALGAE: PHYLOGENETIC IMPLICATIONS1

To provide insights into the occurrence, evolution, and phylogenetic distribution of discontinuous mitochondrial and chloroplast large subunit ribosomal RNAs (LSU rRNAs) among green algae, we surveyed 12 taxa representing three classes of green algae: the Chlorophyceae, Pleurastrophyceae, and Micromonadophyceae (sensu Mattox and Stewart 1984). We present evidence that discontinuous mitochondrial and chloroplast LSU rRNAs are quite widespread among green algae. Mitochondrial LSU rRNAs appear discontinuous in zoosporic chlorophycean lineages displaying a clockwise or directly opposed configuration in their flagellar apparatus, as well as in chlorococcalean autosporic taxa phylogenetically related to them, but are continuous among zoosporic green algal lineages with a counterclockwise flagellar apparatus configuration, as well as among chlorococcalean autosporic taxa phylogenetically related to them. Chloroplast LSU rRNAs appear discontinuous in all of the lineages investigated. Discontinuous mitochondrial LSU rRNA represents a molecular trait that might have originated at or near the base of Chlorophyceae, whereas discontinuous chloroplast LSU rRNA might have developed very early in the evolutionary history of the green algal group itself. We suggest, therefore, that the presence of discontinuous mitochondrial but not chloroplast LSU rRNA can be used as an additional character in assessing phylogenetic affiliations among green algae.     

A minor 9.8 kb rDNA unit of rice variety IR-20

A clone bearing a 9.8 kb EcoRI fragment of rice DNA containing the genes for the rRNAs and the intergenic spacer was identified by screening a rice genomic library in lambda Charon 4 phage with rRNAs. The 9.8 kb EcoRIDNA fragment was found to be a minor rDNA unit of rice variety IR-20. The rRNA genes and the intergenic spacer were mapped by hybridization and nucleotide sequence analyses. The DNAs in the intergenic spacer of the minor rDNA unit of 9.8 kb and the major rDNA unit of 8.9 kb cross-hybridized showing that those regions are homologous.     

Characterization of mitochondrial ribosomal RNA genes in gadiformes: sequence variations,secondary structural features,and phylogenetic implications

Secondary structure features of mitochondrial ribosomal RNAs (mt-rRNAs) of bony fishes were investigated by a DNA sequence alignment approach. The small subunit (SSU) and large subunit (LSU) mt-rRNA genes were found to contain several additional variable regions compared to their mammalian counterparts. Fish mt-LSU rRNA genes were found to be longer than the mammalians due to increased length of some of the variable regions. The 5' and 3' ends of Atlantic cod mt-rRNAs were precisely mapped. The 3' ends of mt-SSU rRNAs were found to be homogenous and mono-adenylated, whereas that of the mt-LSU rRNAs were heterogenous and oligo-adenylated. The 5' ends of mt-SSU rRNAs appeared to be heterogenous, corresponding to the presumed first and second positions of the gene. Sequences of the central domain and the D-domain of the mt-SSU and mt-LSU rRNA genes, respectively, were determined and characterized for 11 gadiform species (representing the families Gadidae, Lotidae, Ranicipitidae, Merlucciidae, Phycidae, and Macrouridae) and one Lophiidae species. Detailed secondary structure models of the RNA regions are presented for the Atlantic cod (Gadus morhua) and Roundnose grenadier (Coryphaeonides rupestris). Saturation plots revealed that DNA nucleotide positions corresponding to unpaired RNA regions become saturated with transitions at sequence divergence levels about 0.15. Phylogenetic analyses revealed some aspects of gadiform relationships. Gadidae was identified as the most derived of the gadiform families. Lotidae was found to be the family closest related to Gadidae, and Ranicipitidae was also recognized as a derived gadiform taxon.     

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.     

Complete sequence and structure of ribosomal RNA gene of Heterosporis anguillarum

The ribosomal RNA (rRNA) gene region of the microsporidium Heterosporis anguillarum has been examined. Complete DNA sequence data (4060 bp, GenBank Accession No. AF402839) of the rRNA gene of H. anguillarum are presented for the small subunit gene (SSU rRNA: 1359 bp), the internal transcribed spacer (ITS: 37 bp), and the large subunit gene (LSU rRNA: 2664 bp). The secondary structures of the H. anguillarum SSU and LSU rRNA genes are constructed and described. This is the first complete sequence of an rRNA gene published for a fish-infecting microsporidian species. In the phylogenetic analysis, the sequences, including partial SSU rRNA, ITS, and partial LSU rRNA sequences of the fish-infecting microsporidia, were aligned and analysed. The taxonomic position of H. anguillarum as suggested by Lom et al. (2000; Dis Aquat Org 43:225-231) is confirmed in this paper.     

Physical Mapping of Recombinant Plasmids Containing Broad Bean Chloroplast Ribosomal RNA Genes

Two BamHl fragments containing broad bean chloroplast rRNA genes were cloned using the bacterial plasmid pBR322 as a vector and Escherichia coli HB101 as host bacterial. Physical maps of the two cloned ct DNA BamHI fragments containing rRNA genes were constructed by cleavage with several restriction endonucleases and Southern blot hybridization with E. coli 16S-23S rRNAs. Recombinant plasmids pVFBI6 and pVFB32 contain a 16S rRNA sequence on the 4.70 kb BamHl fragment, a 23S rRNA sequence and 4.5S/5S rRNA sequences on the 5.65 kb BamHl fragment, respectively.     

Highly conserved gene arrangement of the mitochondrial genomes of 23 Plasmodium species

Mitochondrial (mt) genomes from diverse phylogenetic groups vary considerably in size, structure and organization. The genus Plasmodium, the causative agent of malaria, has the smallest mt genome in the form of a tandemly repeated, linear element of 6 kb. The Plasmodium mt genome encodes only three protein genes (cox1, cox3 and cob) and large- and small-subunit ribosomal RNA (rRNA) genes, which are highly fragmented with 19 identified rRNA pieces. The complete mt genome sequences of 21 Plasmodium species have been published but a thorough investigation of the arrangement of rRNA gene fragments has been undertaken for only Plasmodium falciparum, the human malaria parasite. In this study, we determined the arrangement of mt rRNA gene fragments in 23 Plasmodium species, including two newly determined mt genome sequences from P. gallinaceum and P. vinckei vinckei, as well as Leucocytozoon caulleryi, an outgroup of Plasmodium. Comparative analysis reveals complete conservation of the arrangement of rRNA gene fragments in the mt genomes of all the 23 Plasmodium species and L. caulleryi. Surveys for a new rRNA gene fragment using hidden Markov models enriched with recent mt genome sequences led us to suggest the mtR-26 sequence as a novel candidate LSU rRNA fragment in the mt genomes of the 24 species. Additionally, we found 22-25 bp-inverted repeat sequences, which may be involved in the generation of lineage-specific mt genome arrangements after divergence from a common ancestor of the genera Eimeria and Plasmodium/Leucocytozoon.     

Complete sequence and secondary structure of the large subunit ribosomal RNA from the harmful unarmored dinoflagellate Akashiwo sanguinea.

This is the first report of the complete DNA sequence of the gene encoding the ribosomal large subunit (LSU rDNA, 3336 bp) from the naked gymnodinioid dinoflagellate Akashiwo sanguinea. No introns were found in the LSU rDNA coding region and secondary structures were predicted for both the LSU and 5.8S rRNAs. The predicted LSU structure showed most of the features seen in the consensus secondary structure model proposed for the eukaryotic nuclear LSU rRNAs. However, six helices (C1_1, C1_2, C1_3, D10, D20_1 and H1_2) are not present in the A. sanguinea LSU structure. Particularly, the C branch area (or D2 domain), was extremely reduced compared to the eukaryotic consensus sequence due to nucleotide deletion. Phylogenetic resolution against 12 divergent (D) domains and cores in LSU rDNA showed that the D1, D2 and D12 domains were highly variable and could be used as genetic markers within low taxonomic levels, particularly in the gymnodinioid complex.