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.     

The involvement of base 1054 in 16S rRNA for UGA stop codon dependent translational termination.

The deletion of the highly conserved cytidine nucleotide at position 1054 in E. coli 16S rRNA has been characterized to confer an UGA stop codon specific suppression activity which suggested a functional participation of small subunit rRNA in translational termination. Based on this structure-function correlation we constructed the three point mutations at site 1054, changing the wild-type C residue to an A, G or U base. The mutations were expressed from a complete plasmid encoded rRNA operon (rrnB) using a conditional expression system with the lambda PL-promoter. All three altered 16S rRNA molecules were expressed and incorporated into 70S ribosomal particles. Structural analysis of the protein and 16S rRNA moieties of the mutant ribosomes showed no differences when compared to wild-type particles. The phenotypic analysis revealed that only the 1054G base change led to a significantly reduced generation time of transformed cells, which could be correlated with the inability of the mutant ribosomes to specifically stop at UGA stop codons in vivo. The response towards UAA and UAG termination codons was not altered. Furthermore, in vitro RF-2 termination factor binding experiments indicated that the association behaviour of mutant ribosomes was not changed, enforcing the view that the UGA stop codon suppression is a direct consequence of the rRNA mutation. Taken together, these results argue for a direct participation of that 16S rRNA motif in UGA dependent translational termination and furthermore, suggest that termination factor binding and stop codon recognition are two separate steps of the termination event.     

Interaction between the ribosomal subunits: 16S rRNA suppressors of the lethal ΔA1916 mutation in the 23S rRNA of <Emphasis Type="Italic">Escherichia coli</Emphasis>

A1916 in 23S rRNA is located in one of the major intersubunit bridges of the 70S ribosome. Deletion of A1916 disrupts the intersubunit bridge B2a, promotes misreading of the genetic code and is lethal. In a genetic selection for suppressor mutations, two base substitutions in 16S rRNA were recovered that restored viability and also allowed expression of ΔA1916-associated capreomycin resistance. These mutations were G1048A in helix 34 and U1471C in helix 44. Restoration of function is incomplete, however, and the double mutants are slow-growing, defective in subunit association and support high levels of translational errors. In contrast, none of these parameters is affected by the single 16S suppressor mutations. U1471C likely affects another intersubunit contact, bridge B6, suggesting that interactions between different bridges and cross-talk between subunits contributes to ribosomal function.     

A ribosomal ambiguity mutation in the 530 loop of E. coli 16S rRNA.

A series of base substitution and deletion mutations were constructed in the highly conserved 530 stem and loop region of E. coli 16S rRNA involved in binding of tRNA to the ribosomal A site. Base substitution and deletion of G517 produced significant effects on cell growth rate and translational fidelity, permitting readthrough of UGA, UAG and UAA stop codons as well as stimulating +1 and -1 frameshifting in vivo. By contrast, mutations at position 534 had little or no effect on growth rate or translational fidelity. The results demonstrate the importance of G517 in maintaining translational fidelity but do not support a base pairing interaction between G517 and U534.     

A functional relationship between helix 1 and the 900 tetraloop of 16S ribosomal RNA within the bacterial ribosome

The conserved 900 tetraloop that caps helix 27 of 16S ribosomal RNA (rRNA) interacts with helix 24 of 16S rRNA and also with helix 67 of 23S rRNA, forming the intersubunit bridge B2c, proximal to the decoding center. In previous studies, we investigated how the interaction between the 900 tetraloop and helix 24 participates in subunit association and translational fidelity. In the present study, we investigated whether the 900 tetraloop is involved in other undetected interactions with different regions of the Escherichia coli 16S rRNA. Using a genetic complementation approach, we selected mutations in 16S rRNA that compensate for a 900 tetraloop mutation, A900G, which severely impairs subunit association and translational fidelity. Mutations were randomly introduced in 16S rRNA, using either a mutagenic XL1-Red E. coli strain or an error-prone PCR strategy. Gain-offunction mutations were selected in vivo with a specialized ribosome system. Two mutations, the deletion of U12 and the U12C substitution, were thus independently selected in helix 1 of 16S rRNA. This helix is located in the vicinity of helix 27, but does not directly contact the 900 tetraloop in the crystal structures of the ribosome. Both mutations correct the subunit association and translational fidelity defects caused by the A900G mutation, revealing an unanticipated functional interaction between these two regions of 16S rRNA.     

Ribosomes containing the C1054-deletion mutation in E. coli 16S rRNA act as suppressors at all three nonsense codons.

It was established some time ago that the deletion of base C1054 in E. coli 16S rRNA specifically affects UGA-dependent termination of translation. Based on this observation, a model for the termination event was proposed in which the UGA nonsense codon on the mRNA base-pairs with a complementary motif in 'helix 34' of the 16S rRNA, thus potentially providing a recognition signal for the binding of the release factor. This model has been re-examined here and evidence is presented which demonstrates that ribosomes containing the C1054 delta mutation enhance the activity of suppressors of both UAG and UAA termination codons introduced into the host. The results do not support the nonsense codon-16S rRNA base pairing model, and rather imply a more general involvement of 'helix 34' in the translation termination reactions.     

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.     

The influence of base identity and base pairing on the function of the alpha-sarcin loop of 23S rRNA.

The alpha-sarcin loop of large subunit rRNAs is one of the sites of interaction of elongation factors with the ribosome, and the target of the cytotoxins alpha-sarcin and ricin. Using a genetic selection for increased frameshifting in a reporter gene, we have isolated a C --> U mutation at position 2666 in the alpha-sarcin loop. In the NMR-derived structure of the loop, bases equivalent to 2666 and 2654 are paired via a non-canonical base pairing interaction. Each of the three base substitutions at C2666 and A2654 was constructed by site-directed mutagenesis of a plasmid borne copy of the rrnB operon of Escherichia coli. Only the C2666 --> U and A2654 --> G mutations that resulted in the formation of canonical A-U and C-G base pairs respectively, increased the levels of stop codon readthrough and frameshifting. The effects of different base pair combinations at positions 2666 and 2654 on ribosome function were then tested by constructing and analyzing all possible base combinations at these sites. All A --> G base substitution mutations at position 2654 and C --> U substitutions at position 2666 increased the levels of translational errors. However, these effects were greatest when G2654 and U2666 had the potential to engage in standard Watson-Crick base pairing interactions. These data indicate that base identity as well as base pairing interactions are important for the function of this essential component of the large subunit rRNA.     

Tertiary interactions between helices h13 and h44 in 16S RNA contribute to the fidelity of translation

The A-minor interaction, formed between single-stranded adenosines and the minor groove of a receptor helix, is among the most common motifs found in rRNA. Among the A-minors found in 16S rRNA are a set of interactions between adenosines at positions 1433, 1434 and 1468 in helix 44 (h44) and their receptors in the nucleotide 320-340 region of helix 13 (h13). These interactions have been implicated in the maintenance of translational accuracy, because base substitutions at the adjacent C1469 increase miscoding errors. We have tested their functional significance through mutagenesis of h13 and h44. Mutations at the h44 A residues, or the A-minor receptors in h13, increase a variety of translational errors and a subset of the mutants show decreased association between 30S and 50S ribosomal subunits. These results are consistent with the involvement of h13-h44 interactions in the alignment and packing of these helices in the 30S subunit and the importance of this helical alignment for tRNA selection and subunit-subunit interaction.     

rRNA Suppressor of a Eukaryotic Translation Initiation Factor 5B/Initiation Factor 2 Mutant Reveals a Binding Site for Translational GTPases on the Small Ribosomal Subunit

The translational GTPases promote initiation, elongation, and termination of protein synthesis by interacting with the ribosome. Mutations that impair GTP hydrolysis by eukaryotic translation initiation factor 5B/initiation factor 2 (eIF5B/IF2) impair yeast cell growth due to failure to dissociate from the ribosome following subunit joining. A mutation in helix h5 of the 18S rRNA in the 40S ribosomal subunit and intragenic mutations in domain II of eIF5B suppress the toxic effects associated with expression of the eIF5B-H480I GTPase-deficient mutant in yeast by lowering the ribosome binding affinity of eIF5B. Hydroxyl radical mapping experiments reveal that the domain II suppressors interface with the body of the 40S subunit in the vicinity of helix h5. As the helix h5 mutation also impairs elongation factor function, the rRNA and eIF5B suppressor mutations provide in vivo evidence supporting a functionally important docking of domain II of the translational GTPases on the body of the small ribosomal subunit.     

Study of the functional interaction of the 900 Tetraloop of 16S ribosomal RNA with helix 24 within the bacterial ribosome

The 900 tetraloop that caps helix 27 of 16S ribosomal RNA (rRNA) is amongst the most conserved regions of rRNA. This tetraloop forms a GNRA motif that docks into the minor groove of three base-pairs at the bottom of helix 24 of 16S rRNA in the 30S subunit. Both the tetraloop and its receptor in helix 24 contact the 23S rRNA, forming the intersubunit bridge B2c. Here, we investigated the interaction between the 900 tetraloop and its receptor by genetic complementation. We used a specialized ribosome system in combination with an in vivo instant evolution approach to select mutations in helix 24 compensating for a mutation in the 900 tetraloop (A900G) that severely decreases ribosomal activity, impairing subunit association and translational fidelity. We selected two mutants where the G769-C810 base-pair of helix 24 was substituted with either U-A or C x A. When these mutations in helix 24 were investigated in the context of a wild-type 900 tetraloop, the C x A but not the U-A mutation severely impaired ribosome activity, interfering with subunit association and decreasing translational fidelity. In the presence of the A900G mutation, both mutations in helix 24 increased the ribosome activity to the same extent. Subunit association and translational fidelity were increased to the same level. Computer modeling was used to analyze the effect of the mutations in helix 24 on the interaction between the tetraloop and its receptor. This study demonstrates the functional importance of the interaction between the 900 tetraloop and helix 24.     

The importance of base pairing in the penultimate stem of Escherichia coli 16S rRNA for ribosomal subunit association.

The influence of base pairing in the penultimate stem of Escherichia coli 16S rRNA (defined as nt 1409-1491) on ribosome function has been addressed by the construction of mutations in this region of rRNA. Two sets of mutations were made on either side of a structurally conserved region in the penultimate stem that disrupted base pairing, while a third set of mutations replaced the wild-type sequence with other base pair combinations. The effects of these mutations were analyzed in vivo and in vitro . The mutations that disrupted base pairing caused significant increases in cell doubling times as well as a severe subunit association defect and a modest increase in frame shifting and stop codon read-through. Restoration of base pairing restored wild-type growth rates, decoding and subunit association, indicating that base pairing in this region is essential for proper ribosome function.     

The Shine and Dalgarno hypothesis for termination: the 3' terminus of the 16S rRNA of the Escherichia coli ribosome can be modified or base-paired with a complementary oligonucleotide without affecting termination in vitro

The occurrence of the nucleotides "...CCUUAOH" at the 3' terminus of the 16S rRNA of the small subunit of the Escherichia coli ribosome led to the suggestion that they may have a direct base pairing with the termination codon in the termination event of protein biosynthesis (Shine and Dalgarno 1974). We have examined this concept with two approaches, firstly using a 30S subunit whose 16S rRNA has been modified with a fluorescein moiety on the terminal adenosine together with the antibody against the moiety, and secondly with an oligonucleotide, UAAGG, complementary to the terminal pentanucleotide sequence of the rRNA. Collectively the data suggest that the nucleotides at the 3' terminus of 16S rRNA are not critically involved in base pairing during termination codon recognition.     

Base complementarity in helix 2 of the central pseudoknot in 16S rRNA is essential for ribosome functioning.

Helix 2 of the central pseudoknot structure in Escherichia coli 16S rRNA is formed by a long-distance interaction between nt 17-19 and 918-916, resulting in three base pairs: U17-A918, C18-G917and A19-U916. Previous work has shown that disruption of the central base pair abolishes ribosomal activity. We have mutated the first and last base pairs and tested the mutants for their translational activity in vivo , using a specialized ribosome system. Mutations that disrupt Watson-Crick base pairing result in strongly impaired translational activity. An exception is the mutation U916-->G, creating an A.G pair, which shows almost no decrease in activity. Mutations that maintain base complementarity have little or no impact on translational efficiency. Some of the introduced base pair substitutions substantially alter the stability of helix 2, but this does not influence ribosome functioning, neither at 42 nor at 28 degrees C. Therefore, our results do not support models in which the pseudoknot is periodically disrupted. Rather, the central pseudoknot structure is suggested to function as a permanent structural element necessary for proper organization in the center of the 30S subunit.     

Variable region V1 ofSaccharomyces cerevisiae 18S rRNA participates in biogenesis and function of the small ribosomal subunit

The role of helix 6, which forms the major portion of the most 5′-located expansion segment ofSaccharomyces cerevisiae 18S rRNA, was studied by in vivo mutational analysis. Mutations that increased the size of the helical part and/or the loop, even to a relatively small extent, abolished 18S rRNA formation almost completely. Concomitantly, 35S pre-rRNA and an abnormal 23S precursor species accumulated. rDNA units containing these mutations did not support cell growth. A deletion removing helix 6 almost completely, on the other hand, had a much less severe effect on the formation of 18S rRNA, and cells expressing only the mutant rRNA remained able to grow, albeit at a much reduced rate. Disruption of the apical A·U base pair by a single point mutation did not cause a noticeable reduction in the level of 18S rRNA but did result in a twofold lower growth rate of the cells. This effect could not be reversed by introduction of a second point mutation that restores base pairing. We conclude that both the primary and the secondary structure of helix 6 play an important role in the formation and the biological function of the 40S subunit. Edited by: S.A. Gerbi     

Mutational eidence for a functional connection between two domains of 23S rRNA in translation termination

Nucleotide 1093 in domain II of Escherichia coli 23S rRNA is part of a highly conserved structure historically referred to as the GTPase center. The mutation G1093A was previously shown to cause readthrough of nonsense codons and high temperature-conditional lethality. Defects in translation termination caused by this mutation have also been demonstrated in vitro. To identify sites in 23S rRNA that may be functionally associated with the G1093 region during termination, we selected for secondary mutations in 23S rRNA that would compensate for the temperature-conditional lethality caused by G1093A. Here we report the isolation and characterization of such a secondary mutation. The mutation is a deletion of two consecutive nucleotides from helix 73 in domain V, close to the peptidyltransferase center. The deletion results in a shortening of the CGCG sequence between positions 2045 and 2048 by two nucleotides to CG. In addition to restoring viability in the presence of G1093A, this deletion dramatically decreased readthrough of UGA nonsense mutations caused by G1093A. An analysis of the amount of mutant rRNA in polysomes revealed that this decrease cannot be explained by an inability of G1093A-containing rRNA to be incorporated into polysomes. Furthermore, the deletion was found to cause UGA readthrough on its own, thereby implicating helix 73 in termination for the first time. These results also indicate the existence of a functional connection between the G1093 region and helix 73 during translation termination.     

Base pairing between U3 and the pre-ribosomal RNA is required for 18S rRNA synthesis.

The nucleolus, the site of pre-ribosomal RNA (pre-rRNA) synthesis and processing in eukaryotic cells, contains a number of small nucleolar RNAs (snoRNAs). Yeast U3 snoRNA is required for the processing of 18S rRNA from larger precursors and contains a region complementary to the pre-rRNA. Substitution mutations in the pre-rRNA which disrupt this base pairing potential are lethal and prevent synthesis of 18S rRNA. These mutant pre-rRNAs show defects in processing which closely resemble the effects of genetic depletion of components of the U3 snoRNP. Co-expression of U3 snoRNAs which carry compensatory mutations allows the mutant pre-rRNAs to support viability and synthesize 18S rRNA at high levels. Pre-rRNA processing steps which are blocked by the external transcribed spacer region mutations are largely restored by expression of the compensatory U3 mutants. Pre-rRNA processing therefore requires direct base pairing between snoRNA and the substrate. Base pairing with the substrate is thus a common feature of small RNAs involved in mRNA and rRNA maturation.