A rRNA-mRNA base pairing model for UGA-dependent termination

Construction and analysis of base-paired regions of the 16S rRNA in the 30S ribosomal subunit determined by constraint satisfaction molecular modelling

Structure models for each of the secondary structure regions from the Escherichia coli 16S rRNA (58 separate elements) were constructed using a constraint satisfaction modelling program to determine which helices deviated from classic A-form geometry. Constraints for each rRNA element included the comparative secondary structure, H-bonding conformations predicted from patterns of base-pair covariation, tertiary interactions predicted from covariation analysis, chemical probing data, rRNA-rRNA crosslinking information, and coordinates from solved structures. Models for each element were built using the MC-SYM modelling algorithm and subsequently were subjected to energy minimization to correct unfavorable geometry. Approximately two-thirds of the structures that result from the input data are very similar to A-form geometry. In the remaining instances, the presence of internal loops and bulges, some sequences (and sequence covariants) and accessory information require deviation from A-form geometry. The structures of regions containing more complex base-pairing arrangements including the central pseudoknot, the 530 region, and the pseudoknot involving base-pairing between G570-U571/A865-C866 and G861-C862/G867-C868 were predicted by this approach. These molecular models provide insight into the connection between patterns of H-bonding, the presence of unpaired nucleotides, and the overall geometry of each element.

Interaction between a mutant release factor one and P-site peptidyl-tRNA is influenced by the identity of the two bases downstream of the stop codon UAG

Termination efficiency of a mutant form of RF (release facor) 1, as compared to the wild-type enzyme, is influenced by the P-site peptidyl-tRNA if the termination signal is UAGA. This effect is weaker at the stronger termination signal UAGU. Similarly, low efficiency of the mutant RF1, together with certain peptidyl-tRNAs, can be increased by changing the second base of the 3'-flanking codon from C to G. The data suggest that the mutant RF1 interacts with the P-site peptidyl-tRNA in conjunction with the context at the 3'-side of the termination codon.

The selection in vivo and characterization of an RNA recognition motif for spectinomycin

Ribonucleoprotein (RNP) complexes participate in almost all macromolecular processes, including RNA processing, protein synthesis, and the signal recognition of proteins targeted for export. An understanding of these processes requires detailed knowledge of interactions at the molecular level, which has evidently been difficult due to the size and complexity of the particles. Fragmentation of large RNP complexes into functional subdomains is proven to be a successful in vitro strategy to probe ligand interactions at the molecular level. We reasoned that RNA molecules expressed in vivo may fold in such a manner as to mimic a drug binding site present on the intact ribosome. If expressed at sufficient levels, the RNA would sequester the antibiotic thereby permitting the continued function of the ribosome and consequently allow the cell to survive in the presence of the drug. Evidence is presented here in support of this RNA fragment-rescue concept following the selection and characterization of RNA fragments that confer resistance to the antibiotic spectinomycin.

Phenotypic heterogeneity of mutational changes at a conserved nucleotide in 16 S ribosomal RNA

RNA sites that contain unpaired or mismatched nucleotides can be interaction sites for other macromolecules. C1054, a virtually universally conserved nucleotide in the 16 S (small subunit) ribosomal RNA of Escherichia coli, is part of a highly conserved bulge in helix 34, which has been located at the decoding site of the ribosome. This helix has been implicated in several translational events, including peptide chain termination and decoding accuracy. Here, we observed interesting differences in phenotype associated with the three base substitutions at, and the deletion of, nucleotide C1054. The phenotypes examined include suppression of nonsense codons on different media and at different temperatures, lethality conditioned by temperature and level of expression of the mutant rRNA, ribosome profiles upon centrifugation through sucrose density gradients, association of mutant 30 S subunits with 50 S subunits, and effects on the action of tRNA suppressor mutants. Some of our findings contradict previously reported properties of individual mutants. Particularly notable is our finding that the first reported 16 S rRNA suppressor of UGA mutations was not a C1054 deletion but rather the base substitution C1054A. After constructing deltaC1054 by site-directed mutagenesis, we observed, among other differences, that it does not suppress any of the trpA mutations previously reported to be suppressed by the original UGA suppressor. In general, our results are consistent with the suggestion that the termination codon readthrough effects of mutations at nucleotide 1054 are the result of defects in peptide chain termination rather than of decreases in general translational accuracy. The phenotypic heterogeneity associated with different mutations at this one nucleotide position may be related to the mechanisms of involvement of this nucleotide, the two-nucleotide bulge, and/or helix 34 in particular translational events. In particular, previous indications from other laboratories of conformational changes associated with this region are consistent with differential effects of 1054 mutations on RNA-RNA or RNA-protein interactions. Finally, the association of a variety of phenotypes with different changes at the same nucleotide may eventually shed light on speculations about the coevolution of parts of ribosomal RNA with other translational macromolecules.

rRNA-like sequences occur in diverse primary transcripts: implications for the control of gene expression

Many eukaryotic mRNAs contain sequences that resemble segments of 28S and 18S rRNAs, and these rRNA-like sequences are present in both the sense and antisense orientations. Some are similar to highly conserved regions of the rRNAs, whereas others have sequence similarities to expansion segments. In particular, four 18S rRNA-like sequences are found in several hundred different genes, and the location of these four sequences within the various genes is not random. One of these rRNA-like sequences is preferentially located within protein coding regions immediately upstream of the termination codon of a number of genes. Northern blot analysis of poly(A)+ RNA from different vertebrates (chicken, cattle, rat, mouse, and human) revealed that a large number of discrete RNA molecules hybridize at high stringency to cloned probes prepared from the 28S or 18S rRNA sequences that were found to match those in mRNAs. Inhibition of polymerase II activity, which prevents the synthesis of most mRNAs, abolished most of the hybridization to the rRNA probes. We consider the hypotheses that rRNA-like sequences may have spread throughout eukaryotic genomes and that their presence in primary transcripts may differentially affect gene expression.

The translational function of nucleotide C1054 in the small subunit rRNA is conserved throughout evolution: genetic evidence in yeast

Mutations at position C1054 of 16S rRNA have previously been shown to cause translational suppression in Escherichia coli. To examine the effects of similar mutations in a eukaryote, all three possible base substitutions and a base deletion were generated at the position of Saccharomyces cerevisiae 18S rRNA corresponding to E. coli C1054. In yeast, as in E. coli, both C1054A (rdn-1A) and C1054G (rdn-1G) caused dominant nonsense suppression. Yeast C1054U (rdn-1T) was a recessive antisuppressor, while yeast C1054-delta (rdn-1delta) led to recessive lethality. Both C1054U and two previously described yeast 18S rRNA antisuppressor mutations, G517A (rdn-2) and U912C (rdn-4), inhibited codon-nonspecific suppression caused by mutations in eukaryotic release factors, sup45 and sup35. However, among these only C1054U inhibited UAA-specific suppressions caused by a UAA-decoding mutant tRNA-Gln (SLT3). Our data implicate eukaryotic C1054 in translational termination, thus suggesting that its function is conserved throughout evolution despite the divergence of nearby nucleotide sequences.

Two regions of the Escherichia coli 16S ribosomal RNA are important for decoding stop signals in polypeptide chain termination

Two regions of the 16S rRNA, helix 34, and the aminoacyl site component of the decoding site at the base of helix 44, have been implicated in decoding of translational stop signals during the termination of protein synthesis. Antibiotics specific for these regions have been tested to see how they discriminate the decoding of UAA, UAG, and UGA by the two polypeptide chain release factors (RF-1 and RF-2). Spectinomycin, which interacts with helix 34, stimulated RF-1 dependent binding to the ribosome and termination. It also stimulated UGA dependent RF-2 termination at micromolar concentrations but inhibited UGA dependent RF-2 binding at higher concentrations. Alterations at position C1192 of helix 34, known to confer spectinomycin resistance, reduced the binding of f[3H]Met-tRNA to the peptidyl-tRNA site. They also impaired termination in vitro, with both factors and all three stop codons, although the effect was greater with RF-2 mediated reactions. These alterations had previously been shown to inhibit EF-G mediated translocation. As perturbations in helix 34 effect both termination and elongation reactions, these results indicate that helix 34 is close to the decoding site on the bacterial ribosome. Several antibiotics, hygromycin, neomycin and tetracycline, specific for the aminoacyl site, were shown to inhibit the binding and function of both RFs in termination with all three stop codons in vitro. These studies indicate that decoding of all stop signals is likely to occur at a similar site on the ribosome to the decoding of sense codons, the aminoacyl site, and are consistent with a location for helix 34 near this site.

Mutations in E.coli 16s rRNA that enhance and decrease the activity of a suppressor tRNA

The in vivo expression of mutations constructed within helix 34 of 16S rRNA has been examined together with a nonsense tRNA suppressor for their action at stop codons. The data revealed two novel results: in contrast to previous findings, some of the rRNA mutations affected suppression at UAA and UAG nonsense codons. Secondly, both an increase and a decrease in the efficiency of the suppressor tRNA were induced by the mutations. This is the first report that rRNA mutations decreased the efficiency of a suppressor tRNA. The data are interpreted as there being competition between the two release factors (RF-1 and RF-2) for an overlapping domain and that helix 34 influences this interaction.