A mutation in the 530 loop of Escherichia coli 16S ribosomal RNA causes resistance to streptomycin.

Oligonucleotide-directed mutagenesis was used to introduce an A to C transversion at position 523 in the 16S ribosomal RNA gene of Escherichia coli rrnB operon cloned in plasmid pKK3535. E. coli cells transformed with the mutated plasmid were resistant to streptomycin. The mutated ribosomes isolated from these cells were not stimulated by streptomycin to misread the message in a poly(U)-directed assay. They were also restrictive to the stimulation of misreading by other error-promoting related aminoglycoside antibiotics such as neomycin, kanamycin or gentamicin, which do not compete for the streptomycin binding site. The 530 loop where the mutation in the 16S rRNA is located has been mapped at the external surface of the 30S subunit, and is therefore distal from the streptomycin binding site at the subunit interface. Our results support the conclusion that the mutation at position 523 in the 16S rRNA does not interfere with the binding of streptomycin, but prevents the drug from inducing conformational changes in the 530 loop which account for its miscoding effect. Since this effect primarily results from a perturbation of the translational proofreading control, our results also provide evidence that the 530 loop of the 16S rRNA is involved in this accuracy control.     

Modulation of 16S rRNA function by ribosomal protein S12

Ribosomal protein S12 is a critical component of the decoding center of the 30S ribosomal subunit and is involved in both tRNA selection and the response to streptomycin. We have investigated the interplay between S12 and some of the surrounding 16S rRNA residues by examining the phenotypes of double-mutant ribosomes in strains of Escherichia coli carrying deletions in all chromosomal rrn operons and expressing total rRNA from a single plasmid-borne rrn operon. We show that the combination of S12 and otherwise benign mutations at positions C1409-G1491 in 16S rRNA severely compromises cell growth while the level and range of aminoglycoside resistances conferred by the G1491U/C substitutions is markedly increased by a mutant S12 protein. The G1491U/C mutations in addition confer resistance to the unrelated antibiotic, capreomycin. S12 also interacts with the 912 region of 16S rRNA. Genetic selection of suppressors of streptomycin dependence caused by mutations at proline 90 in S12 yielded a C912U substitution in 16S rRNA. The C912U mutation on its own confers resistance to streptomycin and restricts miscoding, properties that distinguish it from a majority of the previously described error-promoting ram mutants that also reverse streptomycin dependence.     

Mutations in eukaryotic 18S ribosomal RNA affect translational fidelity and resistance to aminoglycoside antibiotics.

Mutations have been created in the Saccharomyces cerevisiae 18S rRNA gene that correspond to those known to be involved in the control of translational fidelity or antibiotic resistance in prokaryotes. Yeast strains, in which essentially all chromosomal rDNA repeats are deleted and all cellular rRNAs are encoded by plasmid, have been constructed that contain only mutant 18S rRNA. In Escherichia coli, a C-->U substitution at position 912 of the small subunit rRNA causes streptomycin resistance. Eukaryotes normally carry U at the corresponding position and are naturally resistant to streptomycin. We show that a U-->C transition (rdn-4) at this position of the yeast 18S rRNA gene decreases resistance to streptomycin. The rdn-4 mutation also increases resistance to paromomycin and G-418, and inhibits nonsense suppression induced by paromomycin. The same phenotypes, as well as a slow growth phenotype, are also associated with rdn-2, whose prokaryotic counterpart, 517 G-->A, manifests itself as a suppressor rather than an antisuppressor. Neither rdn-2- nor rdn-4-related phenotypes could be detected in the presence of the normal level of wild-type rDNA repeats. Our data demonstrate that eukaryotic rRNA is involved in the control of translational fidelity, and indicate that rRNA features important for interactions with aminoglycosides have been conserved throughout evolution.     

The interaction between streptomycin and ribosomal RNA

The present study shows that a mutation in the 530 loop of 16S rRNA impairs the binding of streptomycin to the bacterial ribosome, thereby restricting the misreading effect of the drug. Previous reports demonstrated that proteins S4, S5 and S12 as well as the 915 region of 16S rRNA are involved in the binding of streptomycin, and indicated that the drug not only interacts with the 30S subunit but also with the 50S subunit. The relationship between the target of streptomycin and its known interference with the proofreading control of translational accuracy is examined in light of these results.     

Positions 13 and 914 in Escherichia coli 16S ribosomal RNA are involved in the control of translational accuracy.

Using a conditional expression system with the temperature-inducible lambda PL promoter, we previously showed that the single mutations 13U-->A and 914A-->U, and the double mutation 13U-->A and 914A-->U in Escherichia coli 16S ribosomal RNA impair the binding of streptomycin (Pinard et al., The FASEB Journal, 1993, 7, 173-176). In this study, we found that the two single mutations and the double mutation increase translational fidelity, reducing in vivo readthrough of nonsense codons and frameshifting, and decreasing in vitro misincorporation in a poly(U)-directed system. Using oligodeoxyribonucleotide probes which hybridize to the 530 loop and to the 1400 region of 16S rRNA, two regions involved in the control of tRNA binding to the A site, we observed that the mutations in rRNA increase the binding of the probe to the 530 loop but not to the 1400 region. We suggest that the mutations at positions 13 and 914 of 16S rRNA induce a conformational rearrangement in the 530 loop, which contributes to the increased accuracy of the ribosome.     

Dissociation rates of peptidyl-tRNA from the P-site of E.coli ribosomes.

We studied the dissociation rates of peptidyl-tRNA from the P-site of poly(U)-programmed wild-type Escherichia coli ribosomes, hyperaccurate variants altered in S12 (SmD, SmP) and error-prone variants (Ram) altered in S4 or S5. The experiments were carried out in the presence and absence of streptomycin, and the effects of neomycin were tested in the wild-type ribosomes. Binding of peptidyl-tRNA to the P-site of wild-type ribosomes is much stronger than to their A-site. Addition of streptomycin dramatically reduces its affinity for the P-site. The S12 alternations make the P-site binding of peptidyl-tRNA much tighter, and the S4, S5 alterations make it weaker than in the case of the wild-type. We find that when binding of peptidyl-tRNA to the A-site is weak, then the affinity for the P-site is stronger, and vice versa. From these results, we formulate a hypothesis for the actions of streptomycin and neomycin based on deformations of the 16S rRNA tertiary structure. The results are also used to interpret some in vivo experiments on translational processivity.     

Formation of the central pseudoknot in 16S rRNA is essential for initiation of translation.

The postulated central pseudoknot formed by regions 9-13/21-25 and 17-19/916-918 of 16S rRNA of Escherichia coli is phylogenetically conserved in prokaryotic as well eukaryotic species. This pseudoknot is located at the center of the secondary structure of the 16S rRNA and connects the three major domains of this molecule. We have introduced mutations into this pseudoknot by changing the base-paired residues C18 and G917, and the effect of such mutations on the ribosomal activity was studied in vivo, using a 'specialized' ribosome system. As compared with ribosomes having the wild-type pseudoknot, the translational activity of ribosomes containing an A, G or U residue at position 18 was dramatically reduced, while the activity of mutant ribosomes having complementary bases at positions 18 and 917 was at the wild-type level. The reduced translational activity of those mutants that are incapable of forming a pseudoknot was caused by their inability to form 70S ribosomal complexes. These results demonstrate that the potential formation of a central pseudoknot in 16S rRNA with any base-paired residues at positions 18 and 917 is essential to complete the initiation process.     

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.     

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.     

The downstream box: an efficient and independent translation initiation signal in Escherichia coli.

The downstream box (DB) was originally described as a translational enhancer of several Escherichia coli and bacteriophage mRNAs located just downstream of the initiation codon. Here, we introduced nucleotide substitutions into the DB and Shine-Dalgarno (SD) region of the highly active bacteriophage T7 gene 10 ribosome binding site (RBS) to examine the possibility that the DB has an independent and functionally important role. Eradication of the SD sequence in the absence of a DB abolished the translational activity of RBS fragments that were fused to a dihydrofolate reductase reporter gene. In contrast, an optimized DB at various positions downstream of the initiation codon promoted highly efficient protein synthesis despite the lack of a SD region. The DB was not functional when shifted upstream of the initiation codon to the position of the SD sequence. Nucleotides 1469-1483 of 16S rRNA ('anti-downstream box') are complementary to the DB, and optimizing this complementarity strongly enhanced translation in the absence and presence of a SD region. We propose that the stimulatory interaction between the DB and the anti-DB places the start codon in close contact with the decoding region of 16S rRNA, thereby mediating independent and efficient initiation of translation.     

Interaction between 16S ribosomal RNA and ribosomal protein S12: differential effects of paromomycin and streptomycin.

Strains containing a series of restrictive and non-restrictive mutations in ribosomal protein S12 have been transformed with plasmids carrying the rrnB operon with mutations at positions 1409 and 1491 in 16S rRNA. The effects of the double-mutant constructs have been measured by growth rate, paromomycin and streptomycin sensitivity, resistance and dependence. The results demonstrate a functional interaction between the 1409-1491 region of rRNA and ribosomal protein S12.     

Interactions of elongation factor EF-P with the Escherichia coli ribosome

EF-P (eubacterial elongation factor P) is a highly conserved protein essential for protein synthesis. We report that EF-P protects 16S rRNA near the G526 streptomycin and the S12 and mRNA binding sites (30S T-site). EF-P also protects domain V of the 23S rRNA proximal to the A-site (50S T-site) and more strongly the A-site of 70S ribosomes. We suggest that EF-P: (a) may play a role in translational fidelity and (b) prevents entry of fMet-tRNA into the A-site enabling it to bind to the 50S P-site. We also report that EF-P promotes a ribosome-dependent accommodation of fMet-tRNA into the 70S P-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.     

The role of RbfA in 16S rRNA processing and cell growth at low temperature in Escherichia coli

RbfA, a 30S ribosome-binding factor, is a multicopy suppressor of a cold-sensitive C23U mutation of the 16S rRNA and is required for efficient processing of the 16S rRNA. At 37 degrees C, DeltarbfA cells show accumulation of ribosomal subunits and 16S rRNA precursor with a significantly reduced polysome profile in comparison with wild-type cells. RbfA is also a cold-shock protein essential for Escherichia coli cells to adapt to low temperature. In this study, we examined its association with the ribosome and its role in 16S rRNA processing and ribosome profiles at low temperature. In wild-type cells, following cold shock at 15 degrees C, the amount of free RbfA remained largely stable, while that of its 30S subunit-associated form became several times greater than that at 37 degrees C and a larger fraction of total 30S subunits was detected to be RbfA-containing. In DeltarbfA cells, the pre-16S rRNA amount increased after cold shock with a concomitant reduction of the mature 16S rRNA amount and the formation of polysomes was further reduced. A closer examination revealed that 30S ribosomal subunits of DeltarbfA cells at low temperature contained primarily pre-16S rRNA and little mature 16S rRNA. Our results indicate that the cold sensitivity of DeltarbfA cells is directly related to their lack of translation initiation-capable 30S subunits containing mature 16S rRNA at low temperature. Importantly, when the C-terminal 25 residue sequence was deleted, the resulting RbfADelta25 lost the abilities to stably associate with the 30S subunit and to suppress the dominant-negative, cold-sensitive phenotype of the C23U mutation in 16S rRNA but was able to suppress the 16S rRNA processing defect and the cold-sensitive phenotype of the DeltarbfA cells, suggesting that RbfA may interact with the 30S ribosome at more than one site or function in more than one fashion in assisting the 16S rRNA maturation at low temperature.     

Ribosomes of the extremely thermophilic eubacterium Thermotoga maritima are uniquely insensitive to the miscoding-inducing action of aminoglycoside antibiotics.

Poly(U)- and poly(UG)-programmed cell-free systems were developed from the extreme thermophilic, anaerobic eubacterium Thermotoga maritima, and their susceptibility to aminoglycoside and other antibiotics was assayed at a temperature (75 degrees C) close to the physiological optimum (80 degrees C) for cell growth and in vitro polypeptide synthesis, using a Bacillus stearothermophilus system as the reference. The synthetic capacity of the Thermotoga assay mixture was abolished by the eubacterium-targeted drugs chloramphenicol, thiostrepton, and kirromycin. However, streptomycin, the disubstituted 2-deoxystreptamines (kanamycin, gentamicin, neomycin, and paromomycin), and the monosubstituted 2-deoxystreptamine (hygromycin) all failed to promote translational misreading of poly(U) on Thermotoga ribosomes; they also failed to block polyphenylalanine synthesis at a low (less than 10(-4) M) concentration and did not inhibit Thermotoga cell growth at a high (10 micrograms/ml) concentration even though Thermotoga ribosomes possess the 16S rRNA sequences required for aminoglycoside action. In contrast to the other eubacteria, Thermotoga elongation factor G was also refractory to the steroid inhibitor of peptidyl-tRNA translocation fusidic acid.     

Analysis of streptomycin-resistance of Escherichia coli mutants.

We previously reported about Escherichia coli transformation experiments yielding streptomycin-resistant cells carrying a C912 to T transition in a plasmid-born 16S rRNA gene. These experiments were based on results obtained with streptomycin-resistant Euglena chloroplasts bearing an equivalent mutation in the single chloroplast 16S rRNA gene. We extended this study and transformed E. coli with plasmid constructs having a mutated 16S rRNA gene at position 914 (A to C) or a double mutation at positions 912 and 888 (C to T:G to A) or a mutation in the S12 gene (Lys-42 to Thr). We tested the transformed cells before and after a screening procedure in the presence of streptomycin. We find that the plasmid-born mutations protect colonies against a short streptomycin exposure, but ribosomes carrying mutated 16S rRNA do not significantly reduce codon misreading in vitro. However, ribosomes isolated from transformed cells after the screening procedure resist misreading. These ribosomes have acquired a second mutation in the S12 protein as shown in one case by sequencing and by transformation experiments. Furthermore, we show that the A914 to C mutation prevents (strongly reduces) base methylation in the central domain of 16S rRNA.