Non-ribosomal nucleotide sequences in 7-S RNA, the immediate precursor of 5.8-S ribosomal RNA in yeast.

The topography and the length of the non-ribosomal sequences present in 7-S RNA, the immediate precursor of 5.8-S ribosomal RNA, from the yeast Saccharomyces carlsbergensis were determined by analyzing the nucleotide sequences of the products obtained after complete digestion of 7-S RNA with RNase T1. The results show that 7-S RNA contains approximately 150 non-ribosomal nucleotides. The majority (90%) of the 7-S RNA molecules was found to have the same 5'-terminal pentadecanucleotide sequence as mature 5.8-S rRNA. The remaining 10% exhibited 5'-terminal sequences identical to those of 5.9-S RNA, which has the same primary structure as 5.8-S rRNA except for a slight extension at the 5' end [Rubin, G.M. (1974) Eur. J. Biochem. 41, 197--202]. These data show that the non-ribosomal nucleotides present in 7-S RNA are all located 3'-distal to the mature 5.8-S rRNA sequence. Moreover, it can be concluded that 5.9-S RNA is a stable rRNA rather than a precursor of 5.8-S rRNA. The 3'-terminal sequence of 5.8-S rRNA (U-C-A-U-U-UOH) is recovered in a much longer oligonucleotide in the T1 RNase digest of 7-S RNA having the sequence U-C-A-U-U-U-(C-C-U-U-C-U-C)-A-A-A-C-A-(U-U-C-U)-Gp. The sequences enclosed in brackets are likely to be correct but could not be established with absolute certainty. The arrow indicates the bond cleaved during processing. The octanucleotide sequence -A-A-A-C-A-U-U-C- located near the cleavage site shows a remarkable similarity to the 5'-terminal octanucleotide sequence of 7-S RNA (-A-A-A-C-U-U-U-C-). We suggest that these sequences may be involved in determining the specificity of the cleavages resulting in the formation of the two termini of 5.8-S rRNA.     

The nucleotide sequences of 5.8-S ribosomal RNA from Xenopus laevis and Xenopus borealis

1. The nucleotide sequence of 5.8-S rRNA from Xenopus laevis is given; it differs by a C in equilibrium U transition at position 140 from the 5.8-S rRNA of Xenopus borealis. 2. The sequence contains two completely modified and two partially modified residues. 3. Three different 5' nucleotides are found: pU-C-G (0.4) pC-G (0.2) and pG (0.4). 4. The 3' terminus is C not U as in all other 5.8-S sequences so far determined. 5. The X. laevis sequence differs from the mammalian and turtle sequences by five and six residue changes respectively. 6. A ribonuclease-resistant hairpin loop is a principle feature of secondary structure models proposed for this molecule. 7. Sequence heterogeneity may occur at one position at a very low level (approximately 0.01) in X. laevis 5.8-S rRNA, while none was detected in X. borealis or HeLa cell 5.8-S rRNA.     

Terminal nucleotide sequences of 17-S ribosomal RNA and its immediate precursor 18-S RNA in yeast.

The 5' and 3'-terminal nucleotide sequences of 17-S rRNA and its immediate precursor 18-S RNA from the yeast Saccharomyces carlsbergensis have been analysed. Identification of the terminal oligonucleotides, as present in Ti ribonuclease digests, was performed by diagonal procedures. The major (molar yield 0.9) 5'-terminal oligonucleotide (molar yield 0.15) with the overall composition pU (U2,C2)G was observed. 18-S precursor RNA was found to contain the same 5'-terminal sequences as 17-S rRNA. However, the 3'-terminal sequences of the two types of RNA appeared to be different. The 17-S rRNA yields the oligonucleotide A-U-C-A-U-U-AOH while at least half of the 18-S RNA molecules contain the sequence U-U-U-C-A-A-U-AOH. In addition 18-S RNA yields several minor 3'-terminal oligonucleotides which appear to be structurally related to the major 3'-terminal sequence. These results demonstrate that the extra nucleotides in 18-S RNA relative to 17-S RNA are located exclusively at the 3'-terminus of the 18-S RNA molecule. The possibility that the 3'-terminal nucleotide sequence of 18-S RNA plays a role in the maturation process is discussed.     

Inhibition of protein synthesis by anti-5.8 S rRNA oligodeoxyribonucleotides

To examine the role of the 5.8 S rRNA in ribosome function, oligodeoxyribonucleotides, complementary to chemically accessible sequences, were incubated with rabbit reticulocyte or wheat germ extracts undergoing protein synthesis in vitro. Significant and reproducible inhibitions were observed with several different oligonucleotides, the most inhibitory being specific for the universally conserved GAAC sequence. Mutant or heterologous sequences were substantially less inhibitory, results which clearly implicate the 5.8 S rRNA in the inhibitory process and are consistent with the possibility that the 5.8 S rRNA plays an important role in the binding of tRNA.     

Nucleotide sequences of Acanthamoeba castellanii 5S and 5.8S ribosomal ribonucleic acids: phylogenetic and comparative structural analyses.

Sequences of 5S and 5.8S rRNAs of the amoeboid protist Acanthamoeba castellanii have been determined by gel sequencing of terminally-labeled RNAs which were partially degraded with chemical reagents or ribonucleases. The sequence of the 5S rRNA is (formula, see text). This sequence is compared to eukaryotic 5S rRNA sequences previously published and fitted to a secondary structure model which incorporates features of several previously proposed models. All reported eukaryotic 5S rRNAs fit this model. The sequence of the 5.8S rRNA is (formula, see text). This sequence does not fit parts of existing secondary structure models for 5.8S rRNA, and we question the significance of such models.     

The complete nucleotide sequence of a 23-S rRNA gene from tobacco chloroplasts

The nucleotide sequence of a tobacco chloroplast 23-S rRNA gene, including the spacer between it and the 4.5-S rRNA gene, has been determined. The 23-S rRNA coding region is 2804-base-pairs long. A comparison with the 23-S rRNA sequence of Escherichia coli reveals strong homology and further shows a similarity between the chloroplast 4.5-S rRNA and the 3'-terminal region of E. coli 23-S rRNA. However, the 101-base-pair spacer sequence between the 23-S and 4.5-S rRNA genes has little homology with E. coli 23-S rRNA.     

Reconstitution of active 30-S ribosomal subunits in vitro using heat-denatured 16-S rRNA.

30-S ribosomal subunits which have been reconstituted using heat-denatured 16-S rRNA can participate in the synthesis of lysosyme in vitro. Therefore all the information contributed by 16-S rRNA to the reconstitution process is carried in the primary sequence of this RNA. The specific protein-synthesizing activity of 30-S subunits reconstituted from 30-S subunit proteins and heat-denatured 16-S rRNA is about one third of that observed if unheated 16-S rRNA is used and is comparable to the activity of 30-S particles isolated after dissociation of 70-S ribosomes in the presence of 0.1 mM Mg2+.     

Wheat embryo mitochondrial 18S ribosomal RNA: evidence for its prokaryotic nature.

We present a catalog of sequences of oligonucleotides produced by T1 ribonuclease digestion of 32P-labeled small-ribosomal-subunit RNA ("18S rRNA) isolated from purified wheat embryo mitochondria. This catalog is compared to catalogs published for prokaryotic and chloroplast 16S rRNAs and to preliminary results for wheat cytosol 18S rRNA. These comparisons indicate that: (1) wheat mitochondrial 18S rRNA is clearly prokaryotic in nature, showing significantly more sequence homology with 16S rRNAs than can be expected to arise by chance (p less than 0.000001); (2) shared oligonucleotide sequences include an especially high proportion of those identified as conserved in the evolution of prokaryotic rRNAs; and (3) wheat embryo mitochondrial and cytosol 18S rRNAs retain no more, and perhaps less, than the minimum sequence homology detectable by this sensitive method. These results argue in favor of an endosymbiotic origin for mitochondria.     

Primary structure of the 5.8S gene of rRNA and internal transcribed spacers of rDNA in diploid wheat Triticum urartu thum. ex. gandil

Nucleotide sequences of 5.8S rRNA gene and rDNA internal transcribed spacers ITS-1 and ITS-2 were determined in diploid wheat Triticum urartu. It was shown that 5.8S rRNA gene of this wheat species consists of 163 base pairs and GC-content is 59.5%. When comparing 5.8S rRNA sequences in diploid wheat, rice and lupine and also 5.8S rRNA in hexaploid wheat and horse beans a high evolutional conservatism of its structure was revealed. The size of ITS-1 and ITS-2 in Tr. urartu is 219 and 225 base pairs long correspondingly. While comparing structures of similar rDNA regions of Tr. urartu, rice and maize a high level of homology was found only between nucleotides adjoining genes of high molecular rRNAs. In ITS-1 of Tr. urartu an insertion of 5'-GACGACGACATTGTCCGTC-3' was found, which is absent in maize and rice.     

Studies on the conformation of the 3' terminus of 18-S rRNA

We have studied the conformation of the 3' end of 18-S RNA from human, hamster and Xenopus laevis cells. The 3'-terminal oligonucleotide in a T1 ribonuclease digest of 18-S RNA from HeLa cells was identified, using a standard fingerprinting method. The sequence (G)-A-U-C-A-U-U-A, established by Eladari and Galibert for HeLa 18-S rRNA, was confirmed. An identical 3' terminus is present in hamster fibroblasts and Xenopus laevis cells. The ease of identification of this oligonucleotide has enabled us to quantify its molar yield relative to several other oligonucleotides, and hence to analyse the 3' terminus by several conformation probes. Its sensitivity to S1 nuclease, limited T1 ribonuclease digestion, bisulphite modification and carbodiimide modification was consistent with the terminal oligonucleotide being in a highly exposed conformation. The m6/2A-m6/2A-C-containing sequence of 18-S rRNA also appears to be in an exposed location on the basis of three of these probes.     

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.     

The role of 5-S RNA in temperature-sensitive ribosomal RNA maturation.

The synthesis of 5-S RNA was found to be unchanged at both the permissive (33.5 degrees C) and non-permissive (38.5 degrees C) temperatures in a temperature-sensitive Baby Hamster Kidney cell line (BHK 21 ts 422 E) as measured relative to synthesis of 18-S rRNA. The 5-S RNA is shown to be associated with nucleolar ribonucleoprotein particles even though rRNA processing does not yield a functional 28-S rRNA at the non-permissive temperature. The amount of 5-S RNA found associated with the 80-S ribonucleoprotein particles was the same at the permissive and non-permissive temperatures, indicating that an aberrant 5-S RNA contribution to rRNA processing is not a primary cause for the temperature-sensitive lesion of rRNA maturation in this mutant cell line. The amount of 5-S RNA in nucleolar 80-S RNA particles indicated that the association of 5-S RNA with the rRNA precursor particle occurs before the cleavage step at which 32-S precursor RNA is produced.     

Molecular organization of dinoflagellate ribosomal DNA: evolutionary implications of the deduced 5.8 S rRNA secondary structure

The 5.8 S rRNA gene of Prorocentrum micans, a primitive dinoflagellate, has been cloned and its 159 base pairs (bp) have been sequenced along with the two flanking internal transcribed spacers (ITS 1 and 2), respectively, 212 and 195 bp long. Nucleotide sequence homologies between several previously published 5.8 S rRNA gene sequences including those from another dinoflagellate, an ascomycetous yeast, protozoans, a higher plant and a mammal have been determined by sequence alignment. Two prokaryotic 5'-ends of the 23 S rRNA gene have been compared owing to their probable common origin with eucaryotic 5.8 S rRNA genes. Several nucleotides are distinctive for dinoflagellates when compared with either typical eucaryotes or procaryotes. This is consistent with an early divergence of the dinoflagellate lineage from the typical eucaryotes. The secondary structure of dinoflagellate 5.8 S rRNA molecules fits the model of Walker et al. (1983). Conserved nucleotides which distinguish dinoflagellate 5.8 S rRNA from that of other eucaryotes are located in specific loops which are assumed to play a structural role in the ribosome. A 5.8 S rRNA phylogenetic tree which is proposed, based on sequence data, supports our initial assumption of the dinoflagellates.     

The hemolytic properties of the membrane modifying peptide antibiotics alamethicin, suzukacillin and trichotoxin (author's transl)

1. Using hybridisation techniques nuclei from both amoebae and plasmodia of Physarum polycephalum were found to contain 275 genes each coding for 5.8-S, 19-S and 26-S rRNA, 685 genes for 5-S rRNA and 1050 genes for tRNA. 2. Hybridisation of these RNA species to both amoebal and plasmodial DNA fractionated on CsCl gradients reveal that the 5.8-S, 19-S and 26-S rRNA genes are located at a satellite position (formula: see text) with respect to the main band of DNA, whereas 4-S RNA genes are located exclusively in the main band of DNA (formula: see text). 3. This result was confirmed by demonstrating that only the 5.8-S, 19-S and 26-S rRNA species hybridise to purified plasmodial ribosomal DNA. 4. The 19-S and 26-S rRNA genes of amoebae are located on extrachromosomal DNA molecules of a discrete size (Mr = 38 X 10(6)) with identical properties to plasmodial ribosomal DNA.     

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.     

Microheterogeneity of the primary structure of the short repeated 5S DNA unit in diploid wheat Triticum monococcum L

Nucleotide sequences of two 5S rRNA genes located in repeated 327 bp long units were determined in diploid wheat Triticum monococcum. They were compared with sequences of 5S rRNA genes of Tr. monococcum and Tr. aestivum which were earlier determined. The differences were revealed in two localizations of the nucleotide sequence in 5S DNA coding regions of Tr. monococcum and - in nine localizations in nontranscribed spacer. It was established that the nucleotide sequence of 5S rRNA gene cloned in pTm5S9 plasmid and 5S DNA coding region in Tr. aestivum have significant homology. Diploid wheat Tr. monococcum was supposed to have 5S rRNA genes with different functional activity within one multigene family.     

Primary and secondary structure of 5.8S rRNA from the silkgland of Bombyx mori.

Nucleotide sequence of 5.8S rRNA of the silkworm, Bombyx mori has been determined by gel sequencing methods. The 5.8S rRNA was the longest so far reported, with the 5'-terminal sequence several nucleotides longer than those of the other organisms. Upon constructing the secondary structure in accordance with the "burp gun" model (12), the Bombyx 5.8S rRNA formed a wide-open "muzzle" due to several unpaired bases at the ends. The overall structure also appeared less stable with less G . C pairs and more unpaired bases than that of the HeLa 5.8S rRNA. These structural features may be essential for those 5.8S rRNAs which interact with 28S rRNAs containing the hidden break to form a stable complex.