Mutant 16S ribosomal RNA: a codon-specific translational suppressor

Phenotypic effects of targeted mutations in the small subunit rRNA gene of Tetrahymena thermophila

Tetrahymena thermophila is an ideal organism with which to study functional aspects of the rRNAs in vivo since the somatic rRNA genes of T. thermophila can be totally replaced by cloned copies introduced via microinjection. In this study, we made small insertions into seven sites within the small subunit rRNA gene and observed their phenotypic effects on transformed cells. Two mutated genes coding for rRNA (rDNAs), both of which bear insertions in highly conserved sequences, failed to transform and are therefore believed to produce nonfunctional rRNAs. Three other altered rDNAs produce functional rRNAs that can substitute for most or all of the cellular rRNA. Two of these bear insertions in highly variable regions, and, surprisingly, the other has an insertion in a region that is well conserved for both sequence and secondary structure among eucaryotes. In addition, two other insertions appear to destabilize rRNAs that contain them. Our findings make predictions concerning the positions of some of these sites within the tertiary structure of the small ribosomal subunit and thus serve as an in vivo test of the existing tertiary structure models for the small subunit rRNA. Our results are in good agreement with expectations based on sequence comparison and in vitro work.

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.

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.

Codon context effect in virus translational readthrough. A study in vitro of the determinants of TMV and Mo-MuLV amber suppression

To assess the role of codon context on the efficiency of eukaryotic suppression of termination codons, we have compared, in a rabbit cell-free translation system, the readthrough efficiency related to two synthetic transcripts differing by the codon context around an amber codon. The codon contexts are derived from tobacco mosaic virus (TMV) and Moloney murine leukemia virus (Mo-MuLV) RNAs. The Mo-MuLV-like codon context does not promote suppression. Substituting TMV-derived triplets in the Mo-MuLV-like codon context shows that the two codons downstream from the TMV UAG signal are important determinants of suppression, as recently demonstrated in vivo.

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.

Use of single-stranded DNA oligonucleotides in programming ribosomes for translation

Single-stranded DNA (ssDNA) oligomers were compared to synthetic RNA oligomers in their ability to program E. coli ribosomes in vitro. AUG and dATG-containing oligomers promoted the non-enzymatic binding of fmet-tRNA to ribosomes, with similar dependence on time and magnesium concentration; only at 10 mM Mg++ or at low oligomer concentration was RNA slightly preferred in complex formation. These initiation complexes were biologically active in that fmet-tRNA, bound in response to ssDNA or RNA, was fully reactive with puromycin. While dAUG could not function as an initiation codon, p-dAUG functioned as well as AUG or dATG. However, dUAA and p-dUAA could not replace UAA in directing release-factor (RF) activity, and dTAA functioned only to a slight extent. Release factors had specificity for termination complexes containing dATGTAA, dATGTAG, or dATGTGA. At Mg++ concentrations of 15 mM or higher, these hexamers directed peptidyl transferase-dependent fmet-tRNA hydrolysis in the absence of RF. We suggest this RF-independent activation of peptidyl transferase as a unique system for studying the mechanism of termination. Overall, these results indicate that ssDNA can be used in place of RNA for certain studies of protein synthesis.

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.

Evidence that a downstream pseudoknot is required for translational read-through of the Moloney murine leukemia virus gag stop codon

Approximately 5% of the ribosomes translating the gag gene of murine leukemia viruses read through the UAG terminator and translate the in-frame pol gene to produce the gag-pol fusion polyprotein, the sole source of the pol gene products. We show that a pseudoknot located eight nucleotides 3' of the UAG codon in the Moloney murine leukemia virus is required for read-through. This requirement is markedly different from that known to be involved in other cases of read-through but surprisingly similar to some stimulatory sequences known to promote ribosomal frameshifting.

Mutations in 16S rRNA in Escherichia coli at methyl-modified sites: G966, C967, and G1207

Mutations were constructed at three sites in 16S rRNA in E. coli by oligonucleotide-directed mutagenesis, and cloned into the rrnB operon on either pKK3535 or pNO2680. The mutated bases, G966, C967, and G1207, are located in the 3' major domain of 16S rRNA and are sites post-transcriptionally modified by methylation. We constructed a deletion mutation at C967 (delta 967) and three substitution mutations at each of the following sites: G966, C967, and G1207. By maxicell analysis, we found that all of the mutations were processed normally and incorporated into 30S subunits and 70S ribosomes. We found that delta 967 was a dominant lethal mutation while the substitution mutations at G966 and C967 had no effects on cell growth rate. The mutants C1207 and U1207 were shown to have dominant lethal phenotypes while A1207 had no effect on cell growth rate. These results help to establish the importance of methyl-modified regions to ribosome function.

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.

Salmonella typhimurium prfA mutants defective in release factor 1

Mutations have been characterized that map in the prfA gene of Salmonella typhimurium. These weak amber suppressors show increased readthrough of UAG but not UAA or UGA codons. Some hemA mutants exhibit a similar suppressor activity due to transcriptional polarity on prfA. All of the suppressors mapping in prfA are recessive to the wild type. Two mutant prfA genes were cloned onto plasmids, and their DNA sequences were determined. A method was devised for transferring the sequenced mutant alleles back to their original location in S. typhimurium via an Escherichia coli recD strain that carries the entire S. typhimurium hemA-prfA operon as a chromosomal insertion in trp. This reconstruction experiment showed that the mutations sequenced are sufficient to confer the suppressor phenotype.

Eukaryotic start and stop translation sites

Sequences flanking translational initiation and termination sites have been compiled and statistically analyzed for various eukaryotic taxonomic groups. A few key similarities between taxonomic groups support conserved mechanisms of initiation and termination. However, a high degree of sequence variation at these sites within and between various eukaryotic groups suggest that translation may be modulated for many mRNAs. Multipositional analysis of di-, tri-, and quadrinucleotide sequences flanking start/stop sites indicate significant biases. In particular, strong tri-nucleotide biases are observed at the -3, -2, and -1 positions upstream of the start codon. These biases and the interspecific variation in nucleotide preferences at these three positions have lead us to propose a revised model of the interaction of the 18S ribosomal RNA with the mRNA at the site of translation initiation. Unusually strong biases against the CG dinucleotide immediately downstream of termination codons suggest that they may lead to faulty termination and/or failure of the ribosome to disassociate from the mRNA.

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.

Codon context

The analysis of coding sequences reveals nonrandomness in the context of both sense and stop codons. Part of this is related to nucleotide doublet preference, seen also in non-coding sequences and thought to arise from the dependence of mutational events on surrounding sequence. Another nonrandom context element, relating the wobble nucleotides of successive codons, is observed even when doublet preference, codon usage and bias in amino acid doublets are all allowed for. Several phenomena related to protein synthesis have been shown in vivo to be affected by the nucleotide sequence around codons. Thus, nonsense and missense suppression, elongation rate, precision of tRNA selection and polypeptide chain termination are all affected by codon context. At present, it remains unclear how these phenomena may influence the evolution of nonrandomness in the context of codons in natural sequences.

Overproduction of release factor reduces spontaneous frameshifting and frameshift suppression by mutant elongation factor Tu

Mutant forms of elongation factor Tu encoded by tufA8 and tufB103 in Salmonella typhimurium cause suppression of some but not all frameshift mutations. All of the suppressed mutations in S. typhimurium have frameshift windows ending in the termination codon UGA. Because both tufA8 and tufB103 are moderately efficient UGA suppressors, we asked whether the efficiency of frameshifting is influenced by the level of misreading at UGA. We introduced plasmids synthesizing either one of the release factors into strains in which the tuf mutations suppress a test frameshift mutation. We found that overproduction of release factor 2 (which catalyzes release at UGA and UAA) reduced frameshifting promoted by the tuf mutations at all sites tested. However, at one of these sites, trpE91, overproduction of release factor 1 also reduced suppression. The spontaneous level of frameshift "leakiness" at three sites in trpE, each terminating in UGA, was reduced in strains carrying the release factor 2 plasmid. We conclude that both spontaneous and suppressor-enhanced reading-frame shifts are influenced by the activity of peptide chain release factors. However, the data suggest that the effect of release factor on frameshifting does not necessarily depend on the presence of the normal triplet termination signal.

Codon recognition in polypeptide chain termination: site directed crosslinking of termination codon to Escherichia coli release factor 2

An RNA synthesized in vitro was positioned on the Escherichia coli ribosome at the P site with tRNAala, and with a termination codon, UAA, as the next codon in the A site. Such a complex bound stoichiometric amounts of release factor 2 (RF-2); a corresponding RNA with UAC in place of UAA was not a template for the factor. An RNA containing 4-thio-UAA in place of the UAA supported binding of RF-2, and this has allowed site-directed crosslinking from the first position of the termination codon to answer two long standing questions about the termination of protein biosynthesis, the position of the termination codon and its proximity to the release factor during codon recognition. An RF-2.mRNA crosslinked product was detected, indicating the release factor and the termination codon are in close physical contact during the codon recognition event of termination. The 4-thio-U crosslinked also to the ribosome but only to the 30S subunit, and the proteins and the rRNA site concerned were identified. RF-2 decreased significantly the crosslinking to the ribosomal components, but no new crosslink sites were found. If the stop codon was deliberately displaced from the decoding site by one codon's length then a different pattern of crosslinking in particular to the rRNA resulted. These observations are consistent with a model of codon recognition by RF-2 at the decoding site, without a major shift in position of the codon.

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.

Analysis of leaky viral translation termination codons in vivo by transient expression of improved beta-glucuronidase vectors

Plant RNA viruses commonly exploit leaky translation termination signals in order to express internal protein coding regions. As a first step to elucidate the mechanism(s) by which ribosomes bypass leaky stop codons in vivo, we have devised a system in which readthrough is coupled to the transient expression of beta-glucuronidase (GUS) in tobacco protoplasts. GUS vectors that contain the stop codons and surrounding nucleotides from the readthrough regions of several different RNA viruses were constructed and the plasmids were tested for the ability to direct transient GUS expression. These studies indicated that ribosomes bypass the leaky termination sites at efficiencies ranging from essentially 0 to ca. 5% depending upon the viral sequence. The results suggest that the efficiency of readthrough is determined by the sequence surrounding the stop codon. We describe improved GUS expression vectors and optimized transfection conditions which made it possible to assay low-level translational events.

Recent advances in peptide chain termination

Peptide chain termination occurs when a stop codon is decoded by a release factor. In Escherichia coli two codon-specific release factors (RF1 and RF2) direct the termination of protein synthesis, while in eukaryotes a single factor is required. The E. coli factors have been purified and their genes isolated. A combination of protein and DNA sequence data reveal that the RFs are structurally similar and that RF2 is encoded in two reading frames. Frame-shifting from one reading frame to the next occurs at a rate of 50%, is regulated by the RF2-specific stop codon UGA, and involves the direct interaction of the RF2 mRNA with the 3' end of the 16S rRNA. The RF genes are located in two separate operons, with the RF1 gene located at 26.7 min and the RF2 gene at 62.3 min on the chromosome map. Ribosomal binding studies place the RF-binding region at the interface between the ribosomal subunits. A possible mechanism of stop-codon recognition is reviewed.

Features of the formate dehydrogenase mRNA necessary for decoding of the UGA codon as selenocysteine

The fdhF gene encoding the 80-kDa selenopolypeptide subunit of formate dehydrogenase H from Escherichia coli contains an in-frame TGA codon at amino acid position 140, which encodes selenocysteine. We have analyzed how this UGA "sense codon" is discriminated from a UGA codon signaling polypeptide chain termination. Deletions were introduced from the 3' side into the fdhF gene and the truncated 5' segments were fused in-frame to the lacZ reporter gene. Efficient read-through of the UGA codon, as measured by beta-galactosidase activity and incorporation of selenium, was dependent on the presence of at least 40 bases of fdhF mRNA downstream of the UGA codon. There was excellent correlation between the results of the deletion studies and the existence of a putative stem-loop structure lying immediately downstream of the UGA in that deletions extending into the helix drastically reduced UGA translation. Similar secondary structures can be formed in the mRNAs coding for other selenoproteins. Selenocysteine insertion cartridges were synthesized that contained this hairpin structure and variable portions of the fdhF gene upstream of the UGA codon and inserted into the lacZ gene. Expression studies showed that upstream sequences were not required for selenocysteine insertion but that they may be involved in modulating the efficiency of read-through. Translation of the UGA codon was found to occur with high fidelity since it was refractory to ribosomal mutations affecting proofreading and to suppression by the sup-9 gene product.

Identification of the mutations in the prfB gene of Escherichia coli K12, which confer UGA suppressor activity

By DNA sequencing and gene dissection, it has been revealed that Su+UGA#11, the mutant prfB of E. coli (Chang et al., 1990) has a double mutation compared with the wild-type LS653: one is a base substitution from T to C at the codon 63 and the other is from G to A at the codon 79. Both mutations cause amino acid substitution, Leu63----Phe63 (L63F) and Asp79----Gly79 (D79G), and are necessary to confer the efficient UGA suppressor activity.

Novel UGA-suppressors in Escherichia coli K-12

UGA-specific nonsense suppressors from Escherichia coli K-12 were isolated and characterized. One of them (Su+UGA-11) was identified as a mutant of the prfB gene for the peptide releasing factor RF2. It appears that in this strain, while peptide release at sites of UGA mutations is retarded, the UGA stop codon is read through even in the absence of a tRNA suppressor, exhibiting a novel type of passive nonsense suppression. Three suppressors (Su+UGA-12, -16 and -34) were capable of restoring the streptomycin sensitive phenotype in resistant bacteria (strAr). Because of their drug-related phenotype, these are possibly mutations in the components of the ribosomal machinery, particularly those concerned with peptide release at UGA nonsense codons. A tRNA suppressor was also obtained which was derived from the tRNA(Trp) gene. In this strain, a long region between rrnC (84.5 min) and rrnB (89.5 min) was duplicated and one of the duplicated genes of tRNA(Trp) was mutated to the suppressor. The mechanism of UGA-suppression is discussed in terms of translation termination at the nonsense codon in both active and passive fashions.

A single base change at 726 in 16S rRNA radically alters the pattern of proteins synthesized in vivo

A single base change in 16S rRNA (C-726 to G) was constructed by site-directed mutagenesis and cloned into the multicopy plasmid pKK3535 (generating pKK726G) which contains the complete rrnB operon from Escherichia coli. The mutant 16S rRNA was found predominantly in the 30S subunit fraction but was present in the 70S ribosomes. Protein analyses of the free 30S subunits revealed a decrease in the levels of ribosomal proteins S2 and S21 while the composition of the 70S ribosomes was as the wild-type. Transformants of pKK726G were temperature sensitive for growth, although the mutant ribosomes themselves were translationally active in vivo at 37 and 42 degrees C. Two-dimensional gel electrophoresis of the proteins translated in vivo revealed an altered protein profile which included novel proteins, changes in the levels of normal proteins, and the presence of heat shock proteins (HSPs) at 30 degrees C. Inactivation of the host encoded wild-type ribosomes coincided with a significant decrease in the synthesis of the HSPs. We therefore believe the induction of the HSPs to be a secondary response by the cells to the presence of the abnormal proteins.

Developmental regulation of stage-specific ribosome populations in Plasmodium

The Plasmodium parasites are so far unique in biology in possessing developmentally regulated ribosomal RNA gene units. Two different genes encode their small subunit rRNAs: one gene (A) yields transcripts predominant in the asexual blood-stage parasites, and the other (C) is mainly transcribed in the sporozoite forms that develop in the mosquito. Developmental control of events allowing a switch in the complement of ribosomes must coordinate the production of the new class with selective inactivation and removal of the old. We show here that in P. falciparum the switch, from A to C gene expression involves the control of rRNA processing, allowing accumulation of precursor C-gene transcripts in gametocytes. These precursor molecules are processed to mature size in the zygote and the early ookinete, where both transcription and processing of the C-gene rRNA seem to be accelerated. As the C-gene precursor rRNA appears, a defined and limited pattern of breakdown of the dominant A-gene rRNA occurs, in which conserved, functionally active sequences involved in the termination of translation and elongation are targeted. By the late oocyst stage, the A-gene transcripts are virtually replaced by mature C-gene transcripts.

Substitution of an invariant nucleotide at the base of the highly conserved '530-loop' of 15S rRNA causes suppression of yeast mitochondrial ochre mutations

We have determined the nucleotide sequence alteration in the 15S rRNA gene of a Saccharomyces cerevisiae strain carrying the previously described mitochondrial ochre suppressor, MSUI. The suppressor contains an A residue at position 633 of the yeast mitochondrial sequence, in place of the wild-type G. This position, located in the highly conserved region forming the stem of the '530-loop', corresponds to G517 of the Escherichia coli 16S rRNA and is occupied by G in all other known small rRNA sequences. This finding strongly supports the previous conclusions of others that the 530-loop region plays an important role in enhancing translational accuracy.

Translation of chloroplast-encoded mRNA: potential initiation and termination signals

A survey of 196 protein-coding chloroplast DNA sequences demonstrated the preference for AUG and UAA codons for initiation and termination of translation, respectively. As in prokaryotes at every nucleotide position from -25 to +25 (AUG is +1 to +3) and for 25 nucleotides 5' and 3' to the termination codon an A or U is predominant, except for C at +5 and G at +22. A Shine-Dalgarno (SD) sequence (GGAGG or tri- or tetranucleotide variant) was found within 100 bp 5' to the AUG codon in 92% of the genes. In 40% of these cases, the location of the SD sequence was similar to that of the consensus for prokaryotes (-12 to -7 5' to AUG), presumed to be optimal for translation initiation. A SD sequence could not be located in 6% of the chloroplast sequences. We propose that mRNA secondary structures may be required for the relocation of a distal SD sequences to within the optimal region (-12 to -7) for initiation of translation. We further suggest that termination at UGA codons in chloroplast genes may occur by a mechanism, involving 16S rRNA secondary structure, which has been proposed for UGA termination in E. coli.

Suppression of the Escherichia coli rpoH opal mutation by ribosomes lacking S15 protein

Several suppressors (suhD) that can specifically suppress the temperature-sensitive opal rpoH11 mutation of Escherichia coli K-12 have been isolated and characterized. Unlike the parental rpoH11 mutant deficient in the heat shock response, the temperature-resistant pseudorevertants carrying suhD were capable of synthesizing sigma 32 and exhibiting partial induction of heat shock proteins. These strains were also cold sensitive and unable to grow at 25 degrees C. Genetic mapping and complementation studies permitted us to localize suhD near rpsO (69 min), the structural gene for ribosomal protein S15. Ribosomes and polyribosomes prepared from suhD cells contained a reduced level (ca. 10%) of S15 relative to that of the wild type. Cloning and sequencing of suhD revealed that an IS10-like element had been inserted at the attenuator-terminator region immediately downstream of the rpsO coding region. The rpsO mRNA level in the suhD strain was also reduced to about 10% that of wild type. Apparently, ribosomes lacking S15 can actively participate in protein synthesis and suppress the rpoH11 opal (UGA) mutation at high temperature but cannot sustain cell growth at low temperature.