Mutations in conserved regions of ribosomal RNAs decrease the productive association of peptide-chain release factors with the ribosome during translation termination.

Early studies provided evidence that peptide-chain release factors (RFs) bind to both ribosomal subunits and trigger translation termination. Although many ribosomal proteins have been implicated in termination, very few data present direct biochemical evidence for the involvement of rRNA. Particularly absent is direct evidence for a role of a large subunit rRNA in RF binding. Previously we demonstrated in vitro that mutations in Escherichia coli rRNAs, known to cause nonsense codon readthrough in vivo, reduce the efficiency of RF2-driven catalysis of peptidyl-tRNA hydrolysis. This reduction was consistent with the idea that in vivo defective termination at the mutant ribosomes contributes to the readthrough. Nevertheless, other explanations were also possible, because still missing was essential biochemical evidence for that idea, namely, decrease in productive association of RFs with the mutant ribosomes. Here we present such evidence using a new realistic in vitro termination assay. This study directly supports in vivo involvement in termination of conserved rRNA regions that also participate in other translational events. Furthermore, this study provides the first strong evidence for involvement of large subunit rRNA in RF binding, indicating that the same rRNA region interacts with factors that determine both elongation and termination of translation.

Covariance of complementary rRNA loop nucleotides does not necessarily represent functional pseudoknot formation in vivo.

We examined mutationally a two-hairpin structure (nucleotides 57 to 70 and 76 to 110) in a region of domain I of Escherichia coli 23S rRNA that has been implicated in specific functions in protein synthesis by other studies. On the basis of the observed covariance of several nucleotides in each loop in Bacteria, Archaea, and chloroplasts, the two hairpins have been proposed to form a pseudoknot. Here, appropriate loop changes were introduced in vitro by site-directed mutagenesis to eliminate any possibility of base pairing between the loops. The bacterial cells containing each cloned mutant rRNA operon were then examined for cell growth, termination codon readthrough, and assembly of the mutant rRNAs into functional ribosomes. The results show that, under the conditions examined, the two hairpins do not form a pseudoknot structure that is required for the functioning of the ribosome in vivo and therefore that sequence covariance does not necessarily indicate the formation of a functional pseudoknot.

Co-conservation of rRNA tetraloop sequences and helix length suggests involvement of the tetraloops in higher-order interactions.

Terminal loops containing four nucleotides (tetraloops) are common in structural RNAs, and they frequently conform to one of three sequence motifs, GNRA, UNCG, or CUUG. Here we compare available sequences and secondary structures for rRNAs from bacteria, and we show that helices capped by phylogenetically conserved GNRA loops display a strong tendency to be of conserved length. The simplest interpretation of this correlation is that the conserved GNRA loops are involved in higher-order interactions, intramolecular or intermolecular, resulting in a selective pressure for maintaining the lengths of these helices. A small number of conserved UNCG loops were also found to be associated with conserved length helices, consistent with the possibility that this type of tetraloop also takes part in higher-order interactions.

Suppression of nonsense mutations induced by expression of an RNA complementary to a conserved segment of 23S rRNA.

We identified a short RNA fragment, complementary to the Escherichia coli 23S rRNA segment comprising nucleotides 735 to 766 (in domain II), which when expressed in vivo results in the suppression of UGA nonsense mutations in two reporter genes. Neither UAA nor UAG mutations, examined at the same codon positions, were suppressed by the expression of this antisense rRNA fragment. Our results suggest that a stable phylogenetically conserved hairpin at nucleotides 736 to 760 in 23S rRNA, which is situated close to the peptidyl transferase center, may participate in one or more specific interactions during peptide chain termination.

Ribosomal RNAs in translation termination: facts and hypotheses.

It is now well established that ribosomal RNAs (rRNAs) play an active role in every aspect of translation. This review focuses on recent evidence for the involvement of rRNAs from both subunits of the ribosome in translation termination. This evidence comprises data obtained with rRNA mutants both in vivo and in vitro. In particular, mutations in specific regions of rRNAs caused readthrough of nonsense codons in vivo. Consistent with their in vivo characteristics, the mutations decreased the productive association of the ribosome with release factor 2 (RF2) and the efficiency of catalysis of peptidyl-tRNA hydrolysis in the presence of RF2 in realistic in vitro termination systems. It is now evident that genetic selections for termination-defective mutants in vivo and their characterization in realistic in vitro termination assays will rapidly advance our understanding of the mechanism of termination.

An rRNA fragment and its antisense can alter decoding of genetic information.

rRNA plays a central role in protein synthesis and is intimately involved in the initiation, elongation, and termination stages of translation. However, the mode of its participation in these reactions, particularly as to the decoding of genetic information, remains elusive. In this paper, we describe a new approach that allowed us to identify an rRNA segment whose function is likely to be related to translation termination. By screening an expression library of random rRNA fragments, we identified a fragment of the Escherichia coli 23S rRNA (nucleotides 74 to 136) whose expression caused readthrough of UGA nonsense mutations in certain codon contexts in vivo. The antisense RNA fragment produced a similar effect, but in neither case was readthrough of UAA or UAG observed. Since termination at UGA in E. coli specifically requires release factor 2 (RF2), our data suggest that the fragments interfere with RF2-dependent termination.

Mutations in RNAs of both ribosomal subunits cause defects in translation termination.

Mutations in RNAs of both subunits of the Escherichia coli ribosome caused defects in catalysis of peptidyl-tRNA hydrolysis in a realistic in vitro termination system. Assaying the two codon-dependent cytoplasmic proteins that drive termination, RF1 and RF2, we observed large defects with RF2 but not with RF1, a result consistent with the in vivo properties of the mutants. Our study presents the first direct in vitro evidence demonstrating the involvement of RNAs from both the large and the small ribosomal subunits in catalysis of peptidyl-tRNA hydrolysis during termination of protein biosynthesis. The results and conclusions are of general significance since the rRNA nucleotides studied have been virtually universally conserved throughout evolution. Our findings suggest a novel role for rRNAs of both subunits as molecular transmitters of a signal for termination.

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.

Functional effects of mutating the closing GxA base-pair of a conserved hairpin loop in 23 S ribosomal RNA.

Recently, Draper and co-workers solved the structure of a hexanucleotide hairpin loop that is conserved in large subunit ribosomal RNAs. (In Escherichia coli, the hexanucleotide consists of nucleotides 1093 to 1098, in the GTPase center of 23 S rRNA.) A major feature of that structure is a G1093xA1098 base-pair that closes the loop. Our laboratory reported previously the isolation of the mutation G1093A and its characterization as a suppressor of UGA mutations and a cause of temperature-conditional lethality. For the work reported here, we asked whether G1093A causes its phenotypes precisely because it is part of the G1093/A1098 base-pair. Using oligonucleotide-directed site-specific mutagenesis, we introduced base substitutions at nucleotides 1093 and 1098 into a plasmid-borne ribosomal RNA operon (rrnB). Each mutant plasmid was then tested for the two mutant phenotypes, nonsense suppression and temperature-dependent growth inhibition. Our results indicate that mutations at 1093 do not cause the mutant phenotypes because G1093 is part of the G1093xA1098 base-pair. We discuss alternative avenues to the observed mutant phenotypes and, in particular, present a model in which a specific interaction of the loop is involved in peptide chain termination.

A base substitution in the amino acid acceptor stem of tRNA(Lys) causes both misacylation and altered decoding.

In 1984, our laboratory reported the characterization of the first misacylated tRNA missense suppressor, a mutant Escherichia coli lysine tRNA with a C70 to U base change in the amino acid acceptor stem. We suggested then that the suppressor tRNA, though still acylated to a large extent with lysine, is partially misacylated with alanine. The results reported in this article demonstrate that is the case both in vitro and in vivo. For the in vitro studies, the mutant tRNA species was isolated from the appropriate RPC-5 column fractions and shown to be acylatable with both lysine and alanine. For the in vivo demonstration, use was made of a temperature-sensitive alaS mutation, which results in decreasing acylation with Ala as the temperature is increased, resulting ultimately in lethality at 42 degrees C. The alaSts mutation was also used to demonstrate that the ability of the same missense suppressor, lysT(U70), to suppress a trpA frameshift mutation is not affected by the Ala-acylation deficiency. We conclude that the misacylation and altered decoding are two independent effects of the C70 to U mutation in tRNA(Lys). The influence of an alteration in the acceptor stem, which is in contact with the large (50S) ribosomal subunit, on decoding, which involves contact between the anticodon region of tRNA and the small (30S) ribosomal subunit, may occur intramolecularly, through the tRNA molecule. Alternatively, the U70 effect may be accomplished intermolecularly; for example, it may alter the interaction of tRNA with ribosomal RNA in the 50S subunit, which may then influence further interactions between the two subunits and between the 30S subunit and the anticodon region of the tRNA. Preliminary evidence suggesting some form of the latter explanation is presented. The influence of a single nucleotide on both tRNA identity and decoding may be related to the coevolution of tRNAs, aminoacyl-tRNA synthetases, and ribosomes.

UGA suppression by a mutant RNA of the large ribosomal subunit.

A role for rRNA in peptide chain termination was indicated several years ago by isolation of a 168 rRNA (small subunit) mutant of Escherichia coli that suppressed UGA mutations. In this paper, we describe another interesting rRNA mutant, selected as a translational suppressor of the chain-terminating mutant trpA (UGA211) of E. coli. The finding that it suppresses UGA at two positions in trpA and does not suppress the other two termination codons, UAA and UAG, at the same codon positions (or several missense mutations, including UGG, available at one of the two positions) suggests a defect in UGA-specific termination. The suppressor mutation was mapped by plasmid fragment exchanges and in vivo suppression to domain II of the 23S rRNA gene of the rrnB operon. Sequence analysis revealed a single base change of G to A at residue 1093, an almost universally conserved base in a highly conserved region known to have specific interactions with ribosomal proteins, elongation factor G, tRNA in the A-site, and the peptidyltransferase region of 23S rRNA. Several avenues of action of the suppressor mutation are suggested, including altered interactions with release factors, ribosomal protein L11, or 16S rRNA. Regardless of the mechanism, the results indicate that a particular residue in 23S rRNA affects peptide chain termination, specifically in decoding of the UGA termination codon.

Variety of nonsense suppressor phenotypes associated with mutational changes at conserved sites in Escherichia coli ribosomal RNA.

To screen for ribosomal RNA mutants defective in peptide chain termination, we have been looking for rRNA mutants that exhibit different patterns of suppression of nonsense mutations and that do not suppress missense mutations at the same positions in the same reporter gene. The rRNA mutations were induced by segment-directed randomly mutagenic PCR treatment of a cloned rrnB operon, followed by subcloning of the mutagenesis products and transformation of strains containing different nonsense mutations in the Escherichia coli trpA gene. To date, we have repeatedly obtained only two small sets of mutations, one in the 3' domain of 16S rRNA, at five nucleotides out of the 610 mutagenized (two in helix 34 and three in helix 44), and the other in 23S rRNA at only four neighboring nucleotide positions (in a highly conserved hexanucleotide loop) within the 1.4 kb mutagenized segment. There is variety, however, in the suppression patterns of the mutants, ranging from suppression of UAG or UGA, through suppression of UAG and UGA, but not UAA, to suppression of all three termination codons. The two helices in 16S rRNA have previously been associated both physically and functionally with the decoding center of the ribosome. The 23S region is part of the binding site for the large subunit protein L11 and the antibiotic thiostrepton, both of which have been shown to affect peptide chain termination. Finally, we have demonstrated that the 23S mutant A1093, which suppresses trpA UGA mutations very efficiently, is lethal at temperatures above 36 degrees C (when highly expressed). This lethality is overcome by secondary 23S rRNA mutations in domain V. Our results suggest that specific regions of 16S and 23S rRNA are involved in peptide chain termination, that the lethality of A1093 is caused by high-level UGA suppression, and that intramolecular interaction between domains II and V of 23S rRNA may play a role in peptide chain termination at the UGA stop codon.

Mutations at three sites in the Escherichia coli 23S ribosomal RNA binding region for protein L11 cause UGA-specific suppression and conditional lethality.

A single nucleotide change, G to A, at nucleotide position 1093 of E. coli 23S ribosomal RNA was found to cause UGA-specific suppression (D.K. Jemiolo, F.T. Pagel and E.J. Murgola, Proc. Natl. Acad. Sci. USA, in press). To obtain new kinds of UGA-specific suppressors in 23S rRNA, we used segment-directed mutagenic PCR, and targeted first the 1405 nucleotide SnaBI/I-CeuI segment, which includes position 1093, of the rrnB operon cloned into a multicopy plasmid. The mutagenized fragments were subcloned into the plasmid vector and used to transform to ampicillin resistance (Ampr) a recipient strain containing a UGA mutation in trpA. The Ampr transformants were then screened for suppression of UGA. After purification, Trp+ transformants were tested for association of the suppressor phenotype first with the plasmid and then specifically with the SnaBI/I-CeuI fragment. In one screening, four different kinds of mutational change were found, all at three sites within a highly conserved hexanucleotide loop in domain II of 23S rRNA. This region is part of the site for binding of the large subunit protein L11, which has been shown to be involved in peptide chain termination in a specific way. All of the mutants (G1093A, G1093 delta, A1095 delta, and U1097 delta) suppress UGA mutations, but not UAA or UAG mutations, and all four types exhibit high-temperature conditional lethality when highly expressed. Several mechanisms can be suggested for the UGA-specific suppression exhibited by these mutants, including altered interaction with protein L11, Second-site mutations that overcome the conditional lethality of G1093A indicate that intramolecular interactions within 23S rRNA may play a role in peptide chain termination at the UGA stop codon.

Doublet translocation at GGA is mediated directly by mutant tRNA(2Gly).

Members of the sufS class of -1 frameshift suppressors have alterations of the GGA/G-decoding tRNA(2Gly). Suppressor-promoted frameshifting at GGA was shown in this study to be directly mediated by the mutant tRNA(2Gly). We disproved the possibility that, in the presence of the compromised mutant tRNA(2Gly), either wild-type tRNA(1Gly), wild-type tRNA(3Gly), a GGA-reading mutant form of tRNA(3Gly), or any other agent suppresses the frameshift mutation trpE91.

Ribosomal RNA and peptidyl-tRNA hydrolase: a peptide chain termination model for lambda bar RNA inhibition.

We propose here a model to explain the inhibition of bacteriophage lambda (lambda) vegetative growth and the killing of E coli cells defective in peptidyl-tRNA hydrolase (Pth) by lambda bar RNA. The model suggests that bar RNA, which contains a characteristic UGA triplet, base-pairs in an anti-parallel fashion with the 1199-1205 region of E coli 16S rRNA. In doing so, it prevents the required functioning of that region of 16S rRNA in UGA-specific peptide chain termination. Pth is implicated in peptide chain termination because a defect in Pth is required for the achievement of the bar RNA inhibitory effects. We make certain predictions that flow from the model, predictions involving suppression of nonsense mutations, and present preliminary experimental results that demonstrate the fulfillment of those predictions.

Mutations in 16S rRNA that affect UGA (stop codon)-directed translation termination.

Site-directed mutagenesis was performed on a sequence motif within the 3' major domain of Escherichia coli 16S rRNA shown previously to be important for peptide chain termination. Analysis of stop codon suppression by the various mutants showed an exclusive response to UGA stop signals, which was correlated directly with the continuity of one or the other of two tandem complementary UCA sequences (bases 1199-1204). Since no other structural features of the mutated ribosomes were hampered and the translation initiation and elongation events functioned properly, we propose that a direct interaction occurs between the UGA stop codon on the mRNA and the 16S rRNA UCA motif as one of the initial events of UGA-dependent peptide chain termination. These results provide evidence that base pairing between rRNA and mRNA plays a direct role in termination, as it has already been shown to do for initiation and elongation.

Suppression of a double missense mutation by a mutant tRNA(Phe) in Escherichia coli.

We report here the isolation of a mutant tRNAPhe that suppresses a double missense auxotrophic mutation in trpA of Escherichia coli, trpA218. The doubly mutant protein product differs from wild-type TrpA by the replacements of Phe22 by Leu and Gly211 by Ser. A partial revertant TrpA phenotype can be obtained from trpA218 by changing either Leu22 back to Phe or Ser211 back to Gly. Translational suppressors were previously obtained that act at codon 211, replacing the Ser211 in the TrpA218 protein, presumably with Gly. In the present study, we selected for trpA218 suppressors caused by mutation of a cloned tRNAPhe gene, pheV. DNA sequence analysis of the suppressor isolated reveals a singular structural alteration, changing the anticodon from 5'-GAA-3' to 5'-GAG-3'. Sequencing of trpA218 confirmed the likely identity of Leu22 as CUC. The new missense suppressor, designated pheV(SuCUC), is lethal to the cell when highly expressed, as from a high copy number plasmid. This may be due to efficient replacement of Leu by Phe at CUC (and, probably, CUU) codons throughout the genome. We anticipate that pheV(SuCUC) will prove, like other missense suppressors, to be extremely useful in studies on the specificity and accuracy of decoding.

Suppression and the code: beyond codons and anticodons.

Specificity and accuracy in the decoding of genetic information during mRNA-programmed, ribosome-dependent polypeptide synthesis (translation) involves more than just hydrogen bonding between two anti-parallel trinucleotides, the mRNA codon and the tRNA anticodon. Other macromolecules are also involved, and translational suppression has been and continues to be an appropriate and effective way to identify them, as well as other parts of mRNA and tRNA, and to elucidate the structural determinants of their functions and interactions. Experimental results are presented that bear upon codon context effects, the role of tRNA structural features in aminoacyl-tRNA selection and in codon selection (reading-frame maintenance), determinants of tRNA identity, elongation factor suppressor mutants, and termination codon recognition by the ribosomal RNA of the small subunit. The examples presented illustrate the complexity of the decoding process and the interconnectedness of translational macromolecules in achieving specificity and accuracy in polypeptide synthesis.

A radioactive assay for the physiological activity of the tryptophan synthetase alpha subunit in crude extracts of Escherichia coli.

A modified assay has been devised for the physiological reaction, indole-3-glycerol phosphate to Trp, of the enzyme tryptophan synthetase. The assay may be applied to crude bacterial extracts, and is based on the measurement of incorporation of radioactivity from [3H]Ser into Trp. Comparison with previous colorimetric assays indicates an improvement in sensitivity of about 30-fold, and advantages in terms of sample economy and simplified manipulation.