Prediction of the recognition sites on 16S and 23S rRNAs from E. coli for the formation of 16S-23S rRNA complex

Interactions between RNA molecules have been postulated to play an important role in the assembly of ribosomes. Using the sequence analysis and the search of continuous complementary regions on 16S rRNA and 23S rRNA, the recognition sites involved in the formation of ribosome of E. coli are postulated. The number of postulated sites was narrowed down by taking available experimental data. The suggestive evidence for correct postulation is obtained from sequence comparison studies of 16S and 23S rRNAs from various species. The sites 891-899 and 1195-1203 on 16S rRNA along with the corresponding complementary sites 1904-1912 and 760-768 on 23S rRNA are predicted to be the most probable candidates for the sites of recognition between 16S and 23S rRNAs. The possibility of the involvement of the additional site 630-638 on 16S rRNA with its complementary site 2031-2039 on 23S rRNA cannot be ruled out.     

Prediction of secondary structures of 16S and 23S rRNA fromEscherichia coli

Small and large subunits ofEscherichia coli ribosome have three different rRNAs, the sequences of which are known. However, attempts by three groups to predict secondary structures of 16S and 23S rRNAs have certain common limitations namely, these structures are predicted assuming no interactions among various domains of the molecule and only 40% residues are involved in base pairing as against the experimental observation of 60 % residues in base paired state. Recent experimental studies have shown that there is a specific interaction between naked 16S and 23S rRNA molecules. This is significant because we have observed that the regions (oligonucleotides of length 9–10 residues), in 16S rRNA which are complementary to those in 23S rRNA do not have internal complementary sequences. Therefore, we have developed a simple graph theoretical approach to predict secondary structures of 16S and 23S rRNAs. Our method for model building not only uses complete sequence of 16S or 23S rRNA molecule along with other experimental observations but also takes into account the observation that specific recognition is possible through the complementary sequences between 16S and 23S rRNA molecules and, therefore, these parts of the molecules are not used for internal base pairing. The method used to predict secondary structures is discussed. A typical secondary structure of the complex between 16S and 23S rRNA molecules, obtained using our method, is presented and compared Briefly with earlier model Building studies.     

Composite structure of the chloroplast 23 S ribosomal RNA genes of Chlamydomonas reinhardii: Evolutionary and functional implications

The chloroplast ribosomal unit of Chlamydomonas reinhardii displays two features which are not shared by other chloroplast ribosomal units. These include the presence of an intron in the 23 S ribosomal RNA gene and of two small genes coding for 3 S and 7 S rRNA in the spacer between the 16 S and 23 S rRNA genes (Rochaix & Malnoë, 1978). Sequencing of the 7 S and 3 S rRNAs as well as their genes and neighbouring regions has shown that: (1) the 7 S and 3 S rRNA genes are 282 and 47 base-pairs long, respectively, and are separated by a 23 base-pair A + T-rich spacer. (2) A sequence microheterogeneity exists within the 3 S RNA genes. (3) The sequences of the 7 S and 3 S rRNAs are homologous to the 5′ termini of prokaryotic and other chloroplast 23 S rRNAs, indicating that the C. reinhardii counterparts of 23 S rRNA have a composite structure. (4) The sequences of the 7 S and 3 S rRNAs are related to that of cytoplasmic 5.8 S rRNA, suggesting that these RNAs may perform similar functions in the ribosome. (5) Partial nucleotide sequence complementarity is observed between the 5′ ends of the 7 S and 3 S RNAs on one hand and the 23 S rRNA sequences which flank the ribosomal intron on the other. These data are compatible with the idea that these small rRNAs may play a role in the processing of the 23 S rRNA precursor.     

tRNA genes are found between 16S and 23S rRNA genes in Bacillus subtilis.

There are at least nine, and probably ten, ribosomal RNA gene sets in the genome of Bacillus subtilis. Each gene set contains sequences complementary to 16S, 23S and 5S rRNAs. We have determined the nucleotide sequences of two DNA fragments which each contain 165 base pairs of the 16S rRNA gene, 191 base pairs of the 23S rRNA gene, and the spacer region between them. The smaller space region is 164 base pairs in length and the larger one includes an additional 180 base pairs. The extra nucleotides could be transcribed in tRNAIIe and tRNA Ala sequences. Evidence is also presented for the existence of a second spacer region which also contains tRNAIIe and tRNA Ala sequences. No other tRNAs appear to be encoded in the spacer regions between the 16S and 23S rRNA genes. Whereas the nucleotide sequences corresponding to the 16S rRNA, 23S rRNA and the spacer tRNAs are very similar to those of E. coli, the sequences between these structural genes are very different.     

Ribotyping of 16S and 23S rRNA genes and organization of rrn operons in members of the bacterial genera Gemmata,Planctomyces, Thermotoga,Thermus, and Verrucomicrobium

The number of organization of rrn genes of two members of the order Planctomycetales, Planctomyces limnophilus and Gemmata obscuriglobus, as well as three species from other bacterial phyla, namely Thermotoga maritima, Thermus aquaticus and Verrucomicrobium spinosum were examined by Southern blot hybridization analysis of restricted DNA with labeled 16S- and 23S rRNAs. Ribotyping analysis revealed that two species contain unlinked 16S- and 23S rRNA genes. Planctomyces limnophilus possessed two unlinked rrn genes which were separated from each other by at least 4.3 kb, and Thermus aquaticus had to unlinked 16S and 23S rRNA genes, separated from each other by at least 2.5 kb. Gemmata obscuriglobus exhibited five genes for which the organization could as yet not be determined because of the complex hybridization patterns. In the other two species, rrn genes clustered in operons. Thermotoga maritima had a single gene for each rRNA species which were separated by not more than 1.5 kb, while Verrucomicrobium spinosum had four copies of probably linked 16S and 23S rRNA genes with a maximal distance between 16S and 23S rRNA genes of 1.3 kb.     

The secondary structure of the protein L1 binding region of ribosomal 23S RNA. Homologies with putative secondary structures of the L11 mRNA and of a region of mitochondrial 16S rRNA.

An heterologous complex was formed between E. coli protein L1 and P. vulgaris 23S RNA. We determined the primary structure of the RNA region which remained associated with protein L1 after RNase digestion of this complex. We also identified the loci of this RNA region which are highly susceptible to T1, S1 and Naja oxiana nuclease digestions respectively. By comparison of these results with those previously obtained with the homologous regions of E. coli and B. stearothermophilus 23S RNAs, we postulate a general structure for the protein L1 binding region of bacterial 23S RNA. Both mouse and human mit 16S rRNAs and Xenopus laevis and Tetrahymena 28S rRNAs contain a sequence similar to the E. coli 23s RNS region preceding the L1 binding site. The region of mit 16S rRNA which follows this sequence has a potential secondary structure bearing common features with the L1-associated region of bacterial 23S rRNA. The 5'-end region of the L11 mRNA also has several sequence potential secondary structures displaying striking homologies with the protein L1 binding region of 23S rRNA and this probably explains how protein L1 functions as a translational repressor. One of the L11 mRNA putative structures bears the features common to both the L1-associated region of bacterial 23S rRNA and the corresponding region of mit 16S rRNA.     

Sequence of the 16S rRNA gene from the thermoacidophilic archaebacteriumSulfolobus solfataricus and its evolutionary implications

Summary The sequence of the small-subunit rRNA from the thermoacidophilic archaebacteriumSulfolobus solfataricus has been determined and compared with its counterparts from halophilic and methanogenic archaebacteria, eukaryotes, and eubacteria. TheS. solfataricus sequence is specifically related to those of the other archaebacteria, to the exclusion of the eukaryotic and eubacterial sequences, when examined either by evolutionary distance matrix analyses or by the criterion of minimum change (maximum parsimony). The archaebacterial 16S rRNA sequences all conform to a common secondary structure, with theS. solfataricus structure containing a higher proportion of canonical base pairs and fewer helical irregularities than the rRNAs from the mesophilic archaebacteria.S. solfataricus is unusual in that its 16S rRNA-23S rRNA intergenic spacer lacks a tRNA gene.     

Analysis of DNA encoding 23S rRNA and 16S–23S rRNA intergenic spacer regions from Plesiomonas shigelloides

Amplification of the gene encoding 23S rRNA of Plesiomonas shigelloides by polymerase chain reaction (PCR), with primers complementary to conserved regions of 16S and the 3' end of 23S rRNA genes, resulted in a DNA fragment of approximately 3 kb. This fragment was cloned in Escherichia coli and its nucleotide sequence determined. The region encoding 23S rRNA shows high homology with the published sequences of 23S rRNA from other members of the gamma division of Proteobacteria. The sequence of the intergenic spacer region, between the 16S and 23S rRNA genes, was determined in a further two clones. In one the sequence of a single tRNA(Glu) was found which was absent from the other two. This variation in sequence suggests that the different clones may be derived from different ribosomal RNA operons.     

Mutations in the Escherichia coli23S rRNA Increase the Rate of Peptidyl-tRNA Dissociation from the Ribosome

We have studied in vivothe phenotypes of 23S rRNA mutations G2582A, G2582U, G2583C, and U2584C, which are located at the A site of Escherichia coli50S ribosomal subunit. All mutant rRNAs incorporated into 50S ribosomal subunits. Upon sucrose gradient fractionation of cell lysates, 23S rRNAs mutated at G2582 to A and G2583 to C accumulated in the 50S and 70S fractions and were underrepresented in the polysome fraction. Induction of 23S rRNAs mutated at G2582 and G2583 lead to a drastic reduction in cell growth. In addition, mutations G2582A and G2583C reduced to one-third the total protein synthesis but not the RNA synthesis. Finally, we show that 23S rRNA mutations G2582A, G2582U, and G2583C cause a significant increase in peptidyl-tRNA drop-off from ribosomes, thereby reducing translational processivity. The results clearly show that tRNA–23S rRNA interaction has an essential role in maintaining the processivity of translation.     

Sequence Studies on Precursor 16S Ribosomal RNA of <Emphasis Type="Italic">Escherichia coli</Emphasis>

THE 16S and 23S rRNAs of E. coli are known to be synthesized through intermediates of marginally. higher S values (about 17S and 24S). Although various authors^1–3 have reported the presence of these precursors, no sequence studies have been presented. Nevertheless, there is strong but indirect evidence³ that the precursor 16S rRNA (p16) is about 200 residues longer than 16S rRNA (ml6). In contrast, the evidence suggests that the precursor 23S rRNA has few or no further residues.     

'boxA'-like sequence between the 16 S/23 S spacer in rRNA operon of mycoplasmas.

We have found that a boxA-like sequence is conserved in the 16 S and 23 S rRNA intergenic spacer regions of mycoplasmas, and that it always locates on loop regions of the hypothetical secondary stem-loop structures. A nucleotide sequence similar to the '-10' box of prokaryotic promoters was identified at upstream sites of the boxA-like sequence in the 16 S/23 S spacer regions. These structures may represent an internal promoter between the 16 S and 23 S rRNA genes in mycoplasmas.     

Cytological localization of the genes for the four classes of ribosomal RNA (25S, 18S, 5.8S and 5S) in polytene chromosomes of Phaseolus coccineus

Homologous tritiated 25S, 18S and 5.8S rRNAs were used separately for in situ hybridization to the polytene chromosomes of the embryo suspensor cells of Phaseolus coccineus. Hybridization occurred at the same chromosomal sites which were labeled in previous in situ hybridization experiments with 25+18S rRNAs in the same material (Avanzi et al., 1972), namely: nucleolus organizing system (satellite, nucleolar constriction and organizer) of chromosome pairs I (S₁) and V (S₂), proximal heterochromatic segment of the long arm of chromosome pair I, and terminal heterochromatic segment of chromosome pair II. Competition hybridization experiments confirmed for P. coccineus the high sequence homology between 25S and 18S rRNA already known for other plants.Homologous ¹²⁵I-5S rRNA was found to hybridize to three sites in the polytene chromosomes of P. cocdneus: the proximal heterochromatic segment in the long arm of chromosome pair I (which also bears the sequences complementary to 25S, 18S and 5.8S RNAs), most of the proximal heterochromatic segment plus a small portion of adjoining euchromatin in the long arm of chromosome pair VI and the large intercalary heterochromatic segment in the same chromosome pair. Simultaneous labeling of the two 5S RNA sites in chromosome VI was quite rare (3%), the rule being labelling of one site to the exclusion of the other, with a labeling frequency of 43.7% and 53.3% for sites no. 1 and no. 2 respectively. These results are interpreted as being due to differential hybridizability of chromosomal sites such as described in other materials.     

Reading frame switch caused by base-pair formation between the 3'' end of 16S rRNA and the mRNA during elongation of protein synthesis in Escherichia coli.

Watson-Crick base pairing is shown to occur between the mRNA and nucleotides near the 3' end of 16S rRNA during the elongation phase of protein synthesis in Escherichia coli. This base-pairing is similar to the mRNA-rRNA interaction formed during initiation of protein synthesis between the Shine and Dalgarno (S-D) nucleotides of ribosome binding sites and their complements in the 1540-1535 region of 16S rRNA. mRNA-rRNA hybrid formation during elongation had been postulated to explain the dependence of an efficient ribosomal frameshift on S-D nucleotides precisely spaced 5' on the mRNA from the frameshift site. Here we show that disruption of the postulated base pairs by single nucleotide substitutions, either in the S-D sequence required for shifting or in nucleotide 1538 of 16S rRNA, decrease the amount of shifting, and that this defect is corrected by restoring complementary base pairing. This result implies that the 3' end of 16S rRNA scans the mRNA very close to the decoding sites during elongation.     

Selection for intragenic suppressors of lethal 23S rRNA mutations in Escherichia coli identifies residues important for ribosome assembly and function

Mutations in several functionally important regions of the 23S rRNA of E. coli increase the levels of frameshifting and readthrough of stop codons. These mutations include U2555A, U2555G, ΔA1916 and U2493C. The mutant rRNAs are lethal when expressed at high levels from a plasmid, in strains also expressing wild type rRNA from chromosomal rrn operons. The lethal phenotype can be suppressed by a range of second-site mutations in 23S rRNA. However, analysis of the functionality of the double mutant rRNAs in heterogeneous ribosome populations shows that in general, the second site mutations do not restore function. Instead, they prevent the assembly, or entry of the mutant 50S subunits into the functioning 70S ribosome and polysome pools, by affecting the competitiveness of the mutant subunits for association with 30S particles. The second-site mutations lie in regions of the 23S rRNA involved in subunit assembly, intersubunit bridge formation and interactions of the ribosome with tRNAs and factors. These second site suppressor mutations thus define functionally important rRNA nucleotides and this approach may be of general use in the functional mapping of large RNAs.