The 3''-terminal region of bacterial 23S ribosomal RNA: structure and homology with the 3''-terminal region of eukaryotic 28S rRNA and with chloroplast 4.5s rRNA.

The sequence of the 110 nucleotide fragment located at the 3'-end of E.coli, P.vulgaris and A.punctata 23S rRNAs has been determined. The homology between the E.coli and P.vulgaris fragments is 90%, whereas that between the E.coli and A.punctate fragments is only 60%. The three rRNA fragments have sequences compatible with a secondary structure consisting of two hairpins. Using chemical and enzymatic methods recently developed for the study of the secondary structure of RNA, we demonstrated that one of these hairpins and part of the other are actually present in the three 3'-terminal fragments in solution. This supports the existence of these two hairpins in the intact molecule. Indeed, results obtained upon limited digestion of intact 23S RNA with T1 RNase were in good agreement with the existence of these two hairpins. We observed that the primary structures of the 3'-terminal regions of yeast 26S rRNA and X.laevis 28S rRNA are both compatible with a secondary structure similar to that found at the 3'-end of bacterial 23S rRNAs. Furthermore, both tobacco and wheat chloroplast 4.5S rRNAs can also be folded in a similar way as the 3'-terminal region of bacterial 23S rRNA, the 3'-end of chloroplast 4.5S rRNAs being complementary to the 5'-end of chloroplast 23S rRNA. This strongly reinforces the hypothesis that chloroplast 4.5S rRNA originates from the 3'-end of bacterial 23S rRNA and suggests that this rRNA may be base-paired with the 5'-end of chloroplast 23S rRNA. Invariant oligonucleotides are present at identical positions in the homologous secondary structures of E.coli 23S, yeast 26S, X.laevis 28S and wheat and tobacco 4.5S rRNAs. Surprisingly, the sequences of these oligonucleotides are not all conserved in the 3'-terminal regions of A.punctata or even P.vulgaris 23S rRNAs. Results obtained upon mild methylation of E.coli 50S subunits with dimethylsulfate strongly suggest that these invariant oligonucleotides are involved in RNA tertiary structure or in RNA-protein interactions.     

Structural analysis of the internal transcribed spacer 2 of the precursor ribosomal RNA from Saccharomyces cerevisiae

Full-length precursor ribosomal RNA molecules (6440 bases) were produced in vitro using a plasmid containing the yeast 35 S pre-rRNA operon under the control of phage T7 promoter. The higher-order structure of the internal transcribed spacer 2 (ITS-2) region (between the 5.8 S and 25 S rRNA sequence) in the pre-rRNA molecule was investigated using a combination of enzymatic and chemical structural probes. The data were used to evaluate several structural models predicted by a minimum free-energy calculation. The results supported a model in which the 3' end of the 5.8 S rRNA and the 5' end of the 25 S rRNA are hydrogen-bonded better than the one in which the ends are not. The model contains a high degree of secondary structure with several stable hairpins. Similar structural models for the ITS-2 regions of Schizosaccharomyces pombe, Saccharomyces carlsbergensis, mung bean and Xenopus laevis were derived. Certain common folding features appear to be conserved, in spite of extensive sequence divergence. The yeast model should be useful as a prototype in future investigations of the structure, function and processing of pre-rRNA.     

A discontinuous small subunit ribosomal RNA in Tetrahymena pyriformis mitochondria

We show here that in the mitochondria of Tetrahymena pyriformis, the small subunit (SSU) rRNA is discontinuous, being comprised of two separate components which we term "alpha" (a novel low molecular weight RNA, approximately equal to 200 nucleotides long) and "beta" (a previously described 14 S RNA). The SSU alpha rRNA has been sequenced in its entirety; it represents the immediate 5'-terminal domain of conventional SSU rRNA. The sequences at the ends of the SSU beta rRNA have also been determined; they show that this molecule corresponds to the 3'-terminal 7/8 of conventional SSU rRNA. A 2.5-kilobase pair XbaI restriction fragment of T. pyriformis mitochondrial DNA which contains the SSU alpha and SSU beta rRNA genes was cloned and its complete nucleotide sequence was determined. This revealed that the genes encoding the two segments of SSU rRNA are separated by a 54-base pair (A + T)-rich spacer. The alpha and beta sequences can be fitted to a generalized secondary structure model for eubacterial 16 S rRNA, with the two RNA species associating through long range interactions to form base-paired regions characteristic of SSU rRNA. In this model, the spacer is situated in a region of pronounced primary and secondary structural variation among SSU rRNAs. The significance of these findings with respect to rRNA biosynthesis and processing and the possible evolutionary relationship between spacers and variable regions in rRNA genes is discussed.     

Study of a cloned ribosomal operon region coding for 5.8S rRNA in the loach Misgurnus fossilis L

A fragment of the loach (Misgurnus fossilis L.) ribosomal operon containing 5.8S rDNA and adjacent regions of the internal transcribed spacer (ITS-1, and ITS-2) was sequenced. The 5'-terminal sequencing in 5.8S rDNA was corrected by analysing the primary structure of the loach 5.8S rRNA. This RNA was shown to be presented by three types of molecules; one of these was shorter by 4 nucleotides at the 5'-end because of the processing site being shifted in the rRNA precursor. The two other types differed in the 5'-terminal nucleotide (UMP or AMP). In the cloned fragment under study, the sequence of 5.8S rDNA has TMP at the 5'-terminus. The known nucleotide sequences of 5.8S rRNAs were compared in eukaryotes; as a result, conservative regions were revealed at the sites of molecule modification. All the 5.8S rRNAs of the vertebrates studied were found to have coincidences in the localization of nucleotide substitutions and other mutations (inversions and deletions). The authors propose a model for the secondary structure of ITS-1 and ITS-2 in the region of 5.8S rRNA processing.     

Evidence for a Competitive-Displacement Model for the initiation of protein synthesis involving the intermolecular hybridization of 5 S rRNA, 18 S rRNA and mRNA.

We have previously shown that a 5'-terminal region of mouse 5 S rRNA can base-pair in vitro with two distinct regions of 18 S rRNA. Further analysis reveals that these 5 S rRNA-complementary sequences in 18 S rRNA also exhibit complementarity to the Kozak consensus sequence surrounding the mRNA translational start site. To test the possibility that these 2 regions in 18 S rRNA may be involved in mRNA binding and translational initiation, we have tested, using an in vitro translation system, the effects of DNA oligonucleotides complementary to these 18 S rRNA sequences on protein synthesis. Results show that an oligonucleotide complementary to one 18 S rRNA region does inhibit translation at the step of initiation. We propose a Competitive-Displacement Model for the initiation of translation involving the intermolecular base-pairing of 5 S rRNA, 18 S rRNA and mRNA.     

Probing the phosphates of the Escherichia coli ribosomal 16S RNA in its naked form, in the 30S subunit, and in the 70S ribosome

Ethylnitrosourea is an alkylating reagent which preferentially modifies phosphates in nucleic acids. It was used to map phosphates in naked Escherichia coli 16S rRNA engaged in tertiary interactions through hydrogen bonds or ion coordination. Of the phosphates, 7% are found involved in such interactions, and 57% of them are located in loops or interhelical regions, where they are involved in maintaining local intrinsic structures or long-distance tertiary interactions. The other phosphates (43%) are found in helical regions. These phosphates often occur at the proximity of bulged nucleotides or in irregular helices containing noncanonical base pairs (and bulges) and are assumed to bind cations in order to neutralize negative charges and to stabilize unusual phosphate backbone folding. In the 30S subunit, ENU allowed mapping of phosphates in contact with proteins. The RNA is not uniformly engaged in RNA/protein interactions. Regions 1-51, 250-310, 567-612, 650-670, and 1307-1382 are particularly buried whereas the 3'-terminal domain and the 5'-proximal region (nucleotides 53-218) are exposed. The conformation of 16S rRNA is not drastically affected by protein binding, but conformational adjustments are detected in several defined regions. They are found in the 5' domain (region 147-172), in the central domain (region 827-872), in the 3' major domain (nucleotides 955-956, 994, 1054, 1181, 1257, and 1262-1263), and in the 3'-terminal domain (around 1400). The 50S subunit shields clusters of phosphates located at the subunit interface. The most extensive protections are observed in the 3'-terminal domain (1490-1542), in the central region of the molecule (770-930), and in the upper 3' major domain.(ABSTRACT TRUNCATED AT 250 WORDS)     

Probable involvement of 3'-terminal segment of 18S rRNA in translation initiation of uncapped mRNAs in plants

A possibility of involvement of 3'-terminal 18S rRNA segment in the cap-independent initiation of translation on plant ribosomes was studied. It was shown that 3-terminal segment (nucleotides 1777-1811) of 18S rRNA including the last hairpin 45 is accessible for complementary interactions in 40S ribosomal subunits. Oligonucleotides complementary to this segment of rRNA when added to wheat germ cell-free protein synthesizing system were found to specifically inhibit translation of uncapped reporter mRNA coding for beta-glucuronidase, which bears in the 5'-untranslated region (UTR) a leader sequence of potato virus Y (PVY) genomic RNA possessing fragments complementary to the region 1777-1811. It was shown that a sequence corresponding to nucleotides 291-316 of PVY, which is complementary to a major portion of the 3-terminal 18S rRNA segment 1777-1808, when placed into 5'-UTR, is able to enhance translational efficiency of the reporter mRNAs. The results obtained suggest that complementary interactions between mRNA 5'-UTR and 18S rRNA 3'-terminal segment can take place in the course of cap-independent translation initiation.     

Studies on the 3′-terminal sequences of the large ribosomal ribonucleic acid of different eukaryotes and those associated with `hidden'' breaks in heat-dissociable insect 26S ribonucleic acid

The 3'-terminal sequences associated with the large rRNA complex from a range of eukaryotes were determined after pancreatic or T(1)-ribonuclease digestion of RNA terminally labelled with [(3)H]isoniazid. In all higher eukaryotes examined except Drosophila melanogaster, the 3'-terminal sequences Y-G-U(OH) and G-C-U(OH) were demonstrated for the large RNA component(s) and for 6S RNA respectively. The 3'-terminal sequence of Saccharomyces cerevisiae 26S RNA was Y-G-U(OH) and that of 6S RNA Y-A-U-U-U(OH). Three 3'-terminal sequences were found in equimolar amounts in the heat-dissociable 26S rRNA characteristic of insect ribosomes. These were Y-G-U-G-U(OH), Y-C-G-U(OH) and G-C-U(OH) for cultured Antheraea eucalypti cells, Y-G-U(OH), Y-G-U(OH) and G-C-U(OH) for Galleria mellonella larvae and Y-C-G-A(OH), Y-G-U-A(OH) and G-Y-U-G(OH) for Drosophila melanogaster flies. Thus the introduction of the central scission in insect 26S rRNA results in the generation of a unique 3'-terminus and does not arise from random cleavage of the polynucleotide chain.     

Comparative Surface Structure of 16S Ribosomal Ribonucleic Acid of 30S Ribosomes of Procaryotic Cells

Ribonuclease T(1) treatment of 30S ribosomes of Escherichia coli converts a large region at the 3' OH end of 16S ribosomal ribonucleic acid (rRNA) to low-molecular-weight RNA. The final 25 nucleotides at the 3' terminus of the molecule emerge relatively intact, whereas most of the region "upstream," for about 150 nucleotides, is converted to oligonucleotides. Identical enzyme treatment generates a fragment of about 60 nucleotides from the middle of 16S rRNA (section D'). To determine whether there are similar sequences in other bacteria, which occupy similar accessible surface locations, we treated 30S ribosomes from Azotobacter vinelandii and Bacillus stearothermophilus with RNase T(1). In each case, a fragment of RNA about 25 nucleotides in length containing the 3' OH end of 16S rRNA and a fragment of about 60 nucleotides in length similar, but not identical, in oligonucleotide composition to section D' of E. coli 16S rRNA were obtained from nuclease-treated 30S ribosomes. These data indicate that, although the primary structure at the 3' end and the middle (section D') of the various 16S rRNA's is not completely conserved, their respective conformations are conserved. A number of identical oligonucleotides were found in the low-molecular-weight fraction obtained from RNase T(1)-treated E. coli, A. vinelandii, and B. stearothermophilus 30S ribosomes. These results show that identical RNase T(1)-sensitive sequences are present in all three bacteria. Hydrolysis of these regions leads to the production of the fragments 25 and 60 nucleotides in length.     

Identical 3′-terminal octanucleotide sequence in 18S ribosomal ribonucleic acid from different eukaryotes. A proposed role for this sequence in the recognition of terminator codons

The 3'-terminal sequence of 18S ribosomal RNA from Drosophila melanogaster and Saccharomyces cerevisiae was determined by stepwise degradation from the 3'-terminus and labelling with [(3)H]isoniazid. The sequence G-A-U-C-A-U-U-A(OH) was found at the 3'-terminus of both 18S rRNA species. Less extensive data for 18S RNA from a number of other eukaryotes are consistent with the same 3'-terminal sequence, and an identical sequence has previously been reported for the 3'-end of rabbit reticulocyte 18S rRNA (Hunt, 1970). These results suggest that the base sequence in this region is strongly conserved and may be identical in all eukaryotes. As the 3'-terminal hexanucleotide is complementary to eukaryotic terminator codons we discuss the possibility that the 3'-end of 18S rRNA may have a direct base-pairing role in the termination of protein synthesis.     

Specific fragmentation of tRNA and rRNA at a 7-methylguanine residue in the presence of methylated carrier RNA

The reaction of site-specific cleavage of tRNA at a 7-methylguanine residue, including subsequent treatment with sodium borohydride and aniline [Wintermeyer, W. and Zachau, H.G. (1975) FEBS Lett. 58, 306-309], was shown to work only within a certain range of tRNA concentrations (higher than 30 microM). The Escherichia coli 16S rRNA, which contained a unique m7G (position 527), could not be split by this method when taken at any concentration. It was found that the presence of statistically methylated carrier RNA in the reaction mixture at the borohydride stage significantly stimulates site-specific fragmentation of 16S rRNA and 32P-labeled tRNAs. Direct sequencing proved that 16S rRNA and tRNA are cleaved by this procedure successfully at the m7G residue. The E. coli 16S rRNA was preparatively cleaved by the described procedure into two fragments. The 5'-terminal fragment (1-526) and the 3'-terminal fragment (528-1542) were isolated in the pure form and their secondary structure investigated by the circular dichroism method. The results of this study showed that the secondary and tertiary structures of the 5'-terminal one-third of the 16S rRNA are at least as ordered as those of intact 16S rRNA or its 3'-terminal two-thirds.     

5' -and 3'-terminal nucleotide sequences of Tetrahymena pyriformis 17S rRNA.

Ribonuclease T1 oligonucleotides arising from the 5' and 3' termini of the 17S rRNA of Tetrahymena pyriformis were isolated by the diagonal method of Dahlberg (Dahlberg, J. E. (1968), Nature (London) 220, 548), and their nucleotide sequences were determined. The base sequence of the 3'-terminal fragment is (G)AUCAUUAoh, which is identical to that found in other 17S-18S eucaryotic rRNA species. The nucleotide sequence of the 5'-terminal oligonucleotide is pAACCUGp, which is identical in length to that found in other eucaryotes and shows a partial but significant sequence homology to the 5' RNase TI oligonucleotides isolated from other eucaryotic species.     

Heterogeneity of nucleotide sequences of 16S ribosomal RNA genes from the Desulfotomaculum kuznetsovii type strain]

Two copies of the 16S rRNA gene, rrnA and rrnB, of the type strain 17T of the thermophilic sulfate-reducing bacterium Desulfotomaculum kuznetsovii were cloned and completely sequenced. The comparison of the determined sequences revealed considerable heterogeneity (8.3%) of the two genes, rrnA and rrnB. The main differences were associated with superlong inserts located at the variable 5'- and 3'-terminal regions of the 16S rRNA genes. Comparative analysis that involved analogous genes from the phylogenetically closest representatives of the genus Desulfotomaculum showed that disregard of the heterogeneity of the two gene copies distorts the position of the bacterium studied in the phylogenetic tree.     

Electron microscopy of secondary structure in partially denatured precursor and mature Escherichia coli 16 S and 23 S rRNA

The secondary structure of 16 S and 23 s rRNA sequences in 30 S preribosomal RNA of Escherichia coli was analyzed by electron microscopy after partial denaturation and compared to mature 16 S and 23 S rRNA examined under the same conditions. The sequences in the pre-rRNA notably lack the specific loops that dominate the 5'-terminal regions of mature 16 S and 23 S rRNA. In other respects, the sizes and locations of loops in the 23 S rRNA sequence are qualitatively very similar in mature and pre-rRNA. Eleven of 12 loops outside of the 5'-terminal domain correspond, with the most frequent features in the 3'-half of the molecule. In contrast, the sizes and locations of loops in the 16 S rRNA sequence differ between precursor and mature forms. In the pre-rRNA, instead of the 370-nucleotide 5'-terminal loop of mature rRNA, some 1000-nucleotide terminal loops are observed. The pre-rRNA also shows a frequent 610-nucleotide central loop and a large 1240-nucleotide loop not seen in the mature rRNA. Also, in the 3'-region of the sequence, the largest loops in pre-rRNA are 120 nucleotides shorter than in mature rRNA. We suggest that the structure of pre-rRNA may promote some alternate conformational features, and that these could be important during ribosome formation or function.