Paramecium mitochondrial genes. I. Small subunit rRNA gene sequence and microevolution

The sequences of the small subunit mitochondrial rRNA genes from two divergent species of Paramecium (primaurelia and tetraurelia) were determined. The gene lies near the center of the linear mitochondrial genome, on the same strand as are all other currently identified genes. The sequences generally resemble their counterparts found in cytoplasmic, procaryotic, and other mitochondrial sources. The rDNA gene boundaries were located by nuclease S1 protection. Small subunit rDNA spans about 1680 nucleotides, including an extraneous 83-base pair sequence very near the 3' end which is unique to Paramecium mitochondria. This "insert" occurs at the apex of the highly variable in length penultimate helix, according to proposed models for small subunit rRNA secondary structure. A discontinuity occurs in isolated rRNA near the start of the insert, resulting in a stable 13 S RNA species and a small segment containing the remaining 3' portion of the gene. The overall rRNA gene sequence was 94% conserved between the two species, and the nucleotide differences consisted of 53% transitions, 37% transversions, and 9% insertions plus deletions. These substitutions were somewhat clustered, and the two most divergent regions coincided with the gene boundaries. The sequence was aligned with Escherichia coli 16 S rRNA for direct comparison of sequence and structure.     

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.     

Characterization of a separate small domain derived from the 5' end of 23S rRNA of an alpha-proteobacterium.

We demonstrate the presence of a separate processed domain derived from the 5' end of 23S rRNA in ribosomes of Rhodopseudomonas palustris, a member of the alpha-++proteobacteria. Previous sequencing studies predicted intervening sequences (IVS) at homologous positions within the 23S rRNA genes of several alpha-proteobacteria, including R.palustris, and we find a processed 23S rRNA 5' domain in unfractionated RNA from several species. 5.8S rRNA from eukaryotic cytoplasmic large subunit ribosomes and the bacterial processed 23S rRNA 5' domain share homology, possess similar structures and are both derived by processing of large precursors. However, the internal transcribed spacer regions or IVSs separating them from the main large subunit rRNAs are evolutionarily unrelated. Consistent with the difference in sequence, we find that the site and mechanism of IVS processing also differs. Rhodopseudomonas palustris IVS-containing RNA precursors are cleaved in vitro by Escherichia coli RNase III or a similar activity present in R.palustris extracts at a processing site distinct from that found in eukaryotic systems and this results in only partial processing of the IVS. Surprisingly, in a reaction unlike characterized cases of eubacterial IVS processing, an RNA segment larger than the corresponding DNA insertion is removed which contains conserved sequences. These sequences, by analogy, serve to link the 23S rRNA 5' rRNA domains or 5.8S rRNAs to the main portion of other prokaryotic 23S rRNAs or to eukaryotic 28S rRNAs, respectively.     

Mitochondrial L-rRNA from Aspergillus nidulans: potential secondary structure and evolution.

The alignment of gene sequences coding for A. nidulans mitochondrial L-rRNA and E. coli 23S rRNA indicates a strong conservation of primary and potential secondary structure of both rRNA molecules, except that homologies to the 5'-terminal 5.8S-like region and the 3'-terminal 4.5S-like region of bacterial rRNA are not detectable on mtDNA. The structural organization of the A. nidulans mt L-rRNA gene corresponds to that of yeast omega + strains: both genes are interrupted by a large intron sequence (1678 and 1143 bp, respectively) and by another smaller insert (91 and 66 bp) at homologous positions within domain V. An evolutionary tree derived from conserved L-rRNA gene sequences of yeast nuclei, E. coli, maize chloroplasts and six mitochondrial species exhibits a common root of organelle and bacterial sequences separating early from the nuclear branch.     

Location of the 5.8S rRNA gene of Saccharomyces cerevisiae.

Direct DNA sequence analysis of Saccharomyces cerevisiae ribosomal DNA cloned in an Escherichia coli plasmid revealed part of the structural gene for 5.8S rRNA at one end of a 700-base-pair EcoRI fragment. Taken with the previously established EcoRI restriction map of the ribosomal repeat unit, this sequence establishes that the yeast 5.8S RNA segment is located between the 18S and 28S segments in the 42S rRNA precursor and in the DNA which codes for it.     

Complete DNA sequence coding for the large ribosomal RNA of yeast mitochondria.

The mitochondrial gene coding for the large ribosomal RNA (21S) has been isolated from a rho- clone of Saccharomyces cerevisiae. A DNA segment of about 5500 base pairs has been sequenced which included the totality of the sequence coding for the mature ribosomal RNA and the intron. The mature RNA sequence corresponds to a length of 3273 nucleotides. Despite the very low guanine-cytosine content (20.5%), many stretches of sequence are homologous to the corresponding Escherichia coli 23S ribosomal RNA. The sequence can be folded into a secondary structure according to the general models for prokaryotic and eukaryotic large ribosomal RNAs. Like the E.coli gene, the mitochondrial gene contains the sequences that look like the eukaryotic 5.8S and the chloroplastic 4.5S ribosomal RNAs. The 5' and 3' end regions show a complementarity over fourteen nucleotides.     

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.     

Sequence and secondary structure of mouse 28S rRNA 5''terminal domain. Organisation of the 5.8S-28S rRNA complex.

We present the sequence of the 5' terminal 585 nucleotides of mouse 28S rRNA as inferred from the DNA sequence of a cloned gene fragment. The comparison of mouse 28S rRNA sequence with its yeast homolog, the only known complete sequence of eukaryotic nucleus-encoded large rRNA (see ref. 1, 2) reveals the strong conservation of two large stretches which are interspersed with completely divergent sequences. These two blocks of homology span the two segments which have been recently proposed to participate directly in the 5.8S-large rRNA complex in yeast (see ref. 1) through base-pairing with both termini of 5.8S rRNA. The validity of the proposed structural model for 5.8S-28S rRNA complex in eukaryotes is strongly supported by comparative analysis of mouse and yeast sequences: despite a number of mutations in 28S and 5.8S rRNA sequences in interacting regions, the secondary structure that can be proposed for mouse complex is perfectly identical with yeast's, with all the 41 base-pairings between the two molecules maintained through 11 pairs of compensatory base changes. The other regions of the mouse 28S rRNA 5'terminal domain, which have extensively diverged in primary sequence, can nevertheless be folded in a secondary structure pattern highly reminiscent of their yeast' homolog. A minor revision is proposed for mouse 5.8S rRNA sequence.     

Localization and structure of endonuclease cleavage sites involved in the processing of the rat 32S precursor to ribosomal RNA.

The initial endonuclease cleavage site in 32 S pre-rRNA (precursor to rRNA) is located within the rate rDNA sequence by S1-nuclease protection mapping of purified nucleolar 28 S rRNA and 12 S pre-rRNA. The heterogeneous 5'- and 3'-termini of these rRNA abut and map within two CTC motifs in tSi2 (internal transcribed spacer 2) located at 50-65 and 4-20 base-pairs upstream from the homogeneous 5'-end of the 28 S rRNA gene. These results show that multiple endonuclease cleavages occur at CUC sites in tSi2 to generate 28 S rRNA and 12 S pre-rRNA with heterogeneous 5'- and 3'-termini, respectively. These molecules have to be processed further to yield mature 28 S and 5.8 S rRNA. Thermal-denaturation studies revealed that the base-pairing association in the 12 S pre-rRNA:28 S rRNA complex is markedly stronger than that in the 5.8 S:28 S rRNA complex. The sequence of about one-quarter (1322 base-pairs) of the 5'-part of the rat 28 S rDNA was determined. A computer search reveals the possibility that the cleavage sites in the CUC motifs are single-stranded, flanked by strongly base-paired GC tracts, involving tSi2 and 28 S rRNA sequences. The subsequent nuclease cleavages, generating the termini of mature rRNA, seem to be directed by secondary-structure interactions between 5.8 S and 28 S rRNA segments in pre-rRNA. An analysis for base-pairing among evolutionarily conserved sequences in 32 S pre-rRNA suggests that the cleavages yielding mature 5.8 S and 28 S rRNA are directed by base-pairing between (i) the 3'-terminus of 5.8 S rRNA and the 5'-terminus of 28 S rRNA and (ii) the 5'-terminus of 5.8 S rRNA and internal sequences in domain I of 28 S rRNA. A general model for primary- and secondary-structure interactions in pre-rRNA processing is proposed, and its implications for ribosome biogenesis in eukaryotes are briefly discussed.     

Nucleotide sequence of Citrus limon 26S rRNA gene and secondary structure model of its RNA

The complete nucleotide sequence of Citrus limon 26S rDNA has been determined. The sequence has been aligned with large ribosomal RNA (L-rRNA) sequences of Escherichia coli, Saccharomyces cerevisiae and Oryza sativa. Nine extensive expansion segments in dicot 26S rRNA relative to E. coli 23S rRNA have been identified and compared with analogous segments of monocot, yeast, amphibian and human L-rRNAs. A secondary structure model for lemon 26S rRNA has been derived based on the refined model of E. coli 23S rRNA. It has been compared with other eukaryotic L-rRNAs models in terms of location of functionally important regions. Origin and evolution of L-rRNA expansion segments are discussed.     

Structural organization of ribosomal RNAs from Novikoff hepatoma. II. Characterization of possible binding sites of 5 S rRNA and 5.8 S rRNA to 28 S rRNA

Interrelationships among 5 S, 5.8 S, and 28 S rRNA were probed by methods employed in the accompanying report (Choi, Y. C. (1985) J. Biol. Chem. 260, 12769-12772). Two complexes were isolated from 20 S ribonucleoprotein (RNP) fraction and 60 S subunit. The 20 S RNP fraction was found to contain the 3'-340 nucleotide fragment (domain VII) in association with 5 S rRNA. The 60 S subunit contained a stable complex consisting of the 5'-upstream portion (4220-4462, domain VI and VII), the 3'-downstream portion (4463-4802, domain VII) of 3'-583 nucleotides fragment, and 5.8 S rRNA. By computer analysis and hybridization, the 5'-upstream portion was found to contain the 5.8 S rRNA contact site. By affinity chromatography, the 3'-downstream portion was found to contain the 5 S rRNA association site. Furthermore, by comparison with the secondary structure of 28 S rRNA proposed by Hadjiolov et al. (Hadjiolov, A. A., Georgiev, O. I., Nosikov, V. V., and Yavachev, L. P. (1984) Nucleic Acids Res. 12, 3677-3693), it was found that domain VII is capable of binding 5.8 S rRNA and 5 S rRNA juxtaposed to each other. Accordingly, a model was proposed to indicate that a possible contact site for 5.8 S rRNA is within the region surrounding the alpha-sarcin site (4333-4350) and is a possible association site of 5 S rRNA within the 3'-downstream portion (4463-4802) of the 3'-583 nucleotide fragment (4220-4802).     

The sequence of the 5.8 S ribosomal RNA of the crustacean Artemia salina. With a proposal for a general secondary structure model for 5.8 S ribosomal RNA.

We report the primary structure of 5.8 S rRNA from the crustacean Artemia salina. The preparation shows length heterogeneity at the 5'-terminus, but consists of uninterrupted RNA chains, in contrast to some insect 5.8 S rRNAs, which consist of two chains of unequal length separated in the gene by a short spacer. The sequence was aligned with those of 11 other 5.8 S rRNAs and a general secondary structure model derived. It has four helical regions in common with the model of Nazar et al. (J. Biol. Chem. 250, 8591-8597 (1975)), but for a fifth helix a different base pairing scheme was found preferable, and the terminal sequences are presumed to bind to 28 S rRNA instead of binding to each other. In the case of yeast, where both the 5.8 S and 26 S rRNA sequences are known, the existence of five helices in 5.8 S rRNA is shown to be compatible with a 5.8 S - 26 S rRNA interaction model.