Mutations in the Escherichia coli 23S rRNA increase the rate of peptidyl-tRNA dissociation from the ribosome

We have studied in vivo the phenotypes of 23S rRNA mutations G2582A, G2582U, G2583C, and U2584C, which are located at the A site of Escherichia coli 50S ribosomal subunit. All mutant rRNAs incorporated into 50S ribosomal subunits. Upon sucrose gradient fraction of cell lysates, 23S rRNAs mutated at G2582 to A and G2583 to C accumulated in the 50S and 70S fractions and were under-represented in the polysome fraction. Induction of 23S rRNAs mutated at G2582 and G2583 lead to a drastic reduction in cell growth. In addition, mutations G2582A and G2583C reduced to one-third the total protein synthesis but not the RNA synthesis. Finally, we show that 23S rRNA mutations G2582A, G2582U, and G2583C cause a significant increase in peptidyl-tRNA drop-off from ribosomes, thereby reducing translational processivity. The results clearly show that tRNA-23S rRNA interaction has an essential role in maintaining the processivity of translation.     

Mutations in the Escherichia coli23S rRNA Increase the Rate of Peptidyl-tRNA Dissociation from the Ribosome

We have studied in vivothe phenotypes of 23S rRNA mutations G2582A, G2582U, G2583C, and U2584C, which are located at the A site of Escherichia coli50S ribosomal subunit. All mutant rRNAs incorporated into 50S ribosomal subunits. Upon sucrose gradient fractionation of cell lysates, 23S rRNAs mutated at G2582 to A and G2583 to C accumulated in the 50S and 70S fractions and were underrepresented in the polysome fraction. Induction of 23S rRNAs mutated at G2582 and G2583 lead to a drastic reduction in cell growth. In addition, mutations G2582A and G2583C reduced to one-third the total protein synthesis but not the RNA synthesis. Finally, we show that 23S rRNA mutations G2582A, G2582U, and G2583C cause a significant increase in peptidyl-tRNA drop-off from ribosomes, thereby reducing translational processivity. The results clearly show that tRNA–23S rRNA interaction has an essential role in maintaining the processivity of translation.     

Base-pairing between 23S rRNA and tRNA in the ribosomal A site

The aminoacyl (A site) tRNA analog 4-thio-dT-p-C-p-puromycin (s4TCPm) photochemically cross-links with high efficiency and specificity to G2553 of 23S rRNA and is peptidyl transferase reactive in its cross-linked state, establishing proximity between the highly conserved 2555 loop in domain V of 23S rRNA and the universally conserved CCA end of tRNA. To test for base-pairing interactions between 23S rRNA and aminoacyl tRNA, site-directed mutations were made at the universally conserved nucleotides U2552 and G2553 of 23S rRNA in both E. coli and B. stearothermophilus ribosomal RNA and incorporated into ribosomes. Mutations at G2553 resulted in dominant growth defects in E. coli and in decreased levels of peptidyl transferase activity in vitro. Genetic analysis in vitro of U2552 and G2553 mutant ribosomes and CCA end mutant tRNA substrates identified a base-pairing interaction between C75 of aminoacyl tRNA and G2553 of 23S rRNA.     

Interactions between 23S rRNA and tRNA in the ribosomal E site

Interactions between tRNA or its analogs and 23S rRNA in the large ribosomal subunit were analyzed by RNA footprinting and by modification-interference selection. In the E site, tRNA protected bases G2112, A2392, and C2394 of 23S rRNA. Truncated tRNA, lacking the anticodon stem-loop, protected A2392 and C2394, but not G2112, and tRNA derivatives with a shortened 3' end protected only G2112, but not A2392 or C2394. Modification interference revealed C2394 as the only accessible nucleotide in 23S rRNA whose modification interferes with binding of tRNA in the large ribosomal subunit E site. The results suggest a direct contact between A76 of tRNA A76 and C2394 of 23S rRNA. Protections at G2112 may reflect interaction of this 23S rRNA region with the tRNA central fold.     

Binding of the 3'' terminus of tRNA to 23S rRNA in the ribosomal exit site actively promotes translocation.

A key event in ribosomal protein synthesis is the translocation of deacylated tRNA, peptidyl tRNA and mRNA, which is catalyzed by elongation factor G (EF-G) and requires GTP. To address the molecular mechanism of the reaction we have studied the functional role of a tRNA exit site (E site) for tRNA release during translocation. We show that modifications of the 3' end of tRNAPhe, which considerably decrease the affinity of E-site binding, lower the translocation rate up to 40-fold. Furthermore, 3'-end modifications lower or abolish the stimulation by P site-bound tRNA of the GTPase activity of EF-G on the ribosome. The results suggest that a hydrogen-bonding interaction of the 3'-terminal adenine of the leaving tRNA in the E site, most likely base-pairing with 23S rRNA, is essential for the translocation reaction. Furthermore, this interaction stimulates the GTP hydrolyzing activity of EF-G on the ribosome. We propose the following molecular model of translocation: after the binding of EF-G.GTP, the P site-bound tRNA, by a movement of the 3'-terminal single-stranded ACCA tail, establishes an interaction with 23S rRNA in the adjacent E site, thereby initiating the tRNA transfer from the P site to the E site and promoting GTP hydrolysis. The co-operative interaction between the E site and the EF-G binding site, which are distantly located on the 50S ribosomal subunit, is probably mediated by a conformational change of 23S rRNA.     

Periodic conformational changes in rRNA: monitoring the dynamics of translating ribosomes

In protein synthesis, a tRNA transits the ribosome via consecutive binding to the A (acceptor), P (peptidyl), and E (exit) site; these tRNA movements are catalyzed by elongation factor G (EF-G) and GTP. Site-specific Pb2+ cleavage was applied to trace tertiary alterations in tRNA and all rRNAs on pre- and posttranslocational ribosomes. The cleavage pattern of deacylated tRNA and AcPhe-tRNA changed individually upon binding to the ribosome; however, these different conformations were unaffected by translocation. On the other hand, translocation affects 23S rRNA structure. Significantly, the Pb2+ cleavage pattern near the peptidyl transferase center was different before and after translocation. This structural rearrangement emerged periodically during elongation, thus providing evidence for a dynamic and mobile role of 23S rRNA in translocation.     

Interaction of translation initiation factor IF1 with the E. coli ribosomal A site

Initiation Factor 1 (IF1) is required for the initiation of translation in Escherichia coli. However, the precise function of IF1 remains unknown. Current evidence suggests that IF1 is an RNA-binding protein that sits in the A site of the decoding region of 16 S rRNA. IF1 binding to 30 S subunits changes the reactivity of nucleotides in the A site to chemical probes. The N1 position of A1408 is enhanced, while the N1 positions of A1492 and A1493 are protected from reactivity with dimethyl sulfate (DMS). The N1-N2 positions of G530 are also protected from reactivity with kethoxal. Quantitative footprinting experiments show that the dissociation constant for IF1 binding to the 30 S subunit is 0.9 microM and that IF1 also alters the reactivity of a subset of Class III sites that are protected by tRNA, 50 S subunits, or aminoglycoside antibiotics. IF1 enhances the reactivity of the N1 position of A1413, A908, and A909 to DMS and the N1-N2 positions of G1487 to kethoxal. To characterize this RNA-protein interaction, several ribosomal mutants in the decoding region RNA were created, and IF1 binding to wild-type and mutant 30 S subunits was monitored by chemical modification and primer extension with allele-specific primers. The mutations C1407U, A1408G, A1492G, or A1493G disrupt IF1 binding to 30 S subunits, whereas the mutations G530A, U1406A, U1406G, G1491U, U1495A, U1495C, or U1495G had little effect on IF1 binding. Disruption of IF1 binding correlates with the deleterious phenotypic effects of certain mutations. IF1 binding to the A site of the 30 S subunit may modulate subunit association and the fidelity of tRNA selection in the P site through conformational changes in the 16 S rRNA.     

The side-by-side model of two tRNA molecules allowing the alpha-helical conformation of the nascent polypeptide during the ribosomal transpeptidation.

Lim and Spirin [25] proposed a preferable conformation of the nascent peptide during the ribosomal transpeptidation. Spirin and Lim [26] excluded the possibilities of the side-by-side model proposed by Johnson et al [13] and the three-tRNA binding model (A, P and E sites) of Rheinberger and Nierhaus [3]. However, a slight conformational change at the 3' end regions of both A and P site tRNA molecules can enable the three different tRNA binding models to converge. With a modification of the angles of the ribose rings of both anticodon and mRNA this model can also be related to the model of Sundaralingam et al [19]. In this model of E coli rRNA the 3' end sequence ACCA76 or GCCA76 of P site tRNA is base-paired to UGGU810 of 23S rRNA, while the ACC75 or GCC75 of A site tRNA are base-paired to GGU1621 23S rRNA. The conformation of the A76 of A site tRNA is necessarily different from that of P site tRNA, at least during the course of the transpeptidation. The A76 of A site tRNA overlaps the binding region of puromycin. The C1400 of 16S rRNA in this model is located at a distance of 4 A from the 5' end of the anticodon of P site tRNA [14] and 17 A from the 5' end of the anticodon of A site tRNA [15]. It is also shown that a considerable but reasonable modification in the conformation of the anticodon loops could lead to accommodation of three deacylated tRNA(Phe) molecules at a time on 70S ribosome in the presence of poly(U) as observed experimentally [6]. A sterochemical explanation for the negatively-linked allosteric interactions between the A and E sites is also shown in the present model.     

Gene mutations of 23S rRNA associated with clarithromycin resistance in Helicobacter pylori strains isolated from Korean patients

Although resistance of Helicobacter pylori to clarithromycin is a major cause of failure of eradication therapies, little information is available regarding gene mutations of clarithromycin-resistant primary and secondary H. pylori isolates in Korea. In the present study, we examined gene mutations of H. pylori 23S rRNA responsible for resistance to clarithromycin. DNA sequences of the 23S rRNA gene in 21 primary clarithromycin-resistant and 64 secondary clarithromycin-resistant strains were determined by PCR amplification and nucleotide sequence analyses. Two mutations of the 23S rRNA gene, A2143G and T2182C, were observed in primary clarithromycin-resistant isolates. In secondary isolates, dual mutation of A2143G+T2182C was frequently observed. In addition, A2143G+T2182C+ T2190C, A2143G+T2182C+C2195T, and A2143G+T2182C +A2223G were observed in secondary isolates. Furthermore, macrolide binding was tested on purified ribosomes isolated from T2182C or A2143C mutant strains with [14C]erythromycin. Erythromycin binding increased in a dose-dependent manner for the susceptible strain but not for the mutant strains. These results indicate that secondary isolates show a greater variety of 23S rRNA gene mutation types than primary isolates, and triple mutations of secondary isolates are associated with A2143G+T2182C in H. pylori isolated from Korean patients.     

Binding of tRNA to the ribosomal A and P sites protects two distinct sets of nucleotides in 16 S rRNA

Transfer RNA protects a characteristic set of bases in 16 S rRNA from chemical probes when it binds to ribosomes. We used several criteria, based on construction of well-characterized in vitro ribosome-tRNA complexes, to assign these proteins to A or P-site binding. All of these approaches lead to similar conclusions. In the A site, tRNA caused protection of G529, G530, A1492 and A1493 (strongly), and A1408 and G1494 (weakly). In the P site, the protected bases are G693, A794, C795, G926 and G1401 (strong), and A532, G966, G1338 and G1339 (weak). In contrast to what is observed for 23 S rRNA, blocking the release of EF-Tu.GDP from the ribosome by kirromycin has no detectable effect on the protection of bases in 16 S rRNA.     

Contribution of ribosomal residues to P-site tRNA binding

Structural studies have revealed multiple contacts between the ribosomal P site and tRNA, but how these contacts contribute to P-tRNA binding remains unclear. In this study, the effects of ribosomal mutations on the dissociation rate (k_off) of various tRNAs from the P site were measured. Mutation of the 30S P site destabilized tRNAs to various degrees, depending on the mutation and the species of tRNA. These data support the idea that ribosome-tRNA interactions are idiosyncratically tuned to ensure stable binding of all tRNA species. Unlike deacylated elongator tRNAs, N-acetyl-aminoacyl-tRNAs and tRNA^fMet dissociated from the P site at a similar low rate, even in the presence of various P-site mutations. These data provide evidence for a stability threshold for P-tRNA binding and suggest that ribosome-tRNA^fMet interactions are uniquely tuned for tight binding. The effects of 16S rRNA mutation G1338U were suppressed by 50S E-site mutation C2394A, suggesting that G1338 is particularly important for stabilizing tRNA in the P/E site. Finally, mutation C2394A or the presence of an N-acetyl-aminoacyl group slowed the association rate (k_on) of tRNA dramatically, suggesting that deacylated tRNA binds the P site of the ribosome via the E site.     

Protected nucleotide G2608 in 23S rRNA confers resistance to oxazolidinones in E. coli

The oxazolidinones are a new class of potent antibiotics that are active against a broad spectrum of Gram-positive bacterial pathogens including those resistant to other antibiotics. These drugs specifically inhibit protein biosynthesis whereas DNA and RNA synthesis are not affected. Although biochemical and genetic studies indicate that oxazolidinones target the ribosomal peptidyltransferase center, other investigations suggest that they interact with different regions of ribosomes. Thus, the exact binding site and mechanism of action have remained elusive. Here, we study, by use of base-specific reagents, the effect of the oxazolidinones on the chemical protection footprinting patterns of the 23S rRNA. We report: (i) reproducible protection of G2607 and G2608 of 23S rRNA by a potent oxazolidinone on a ribosome.tRNA.mRNA complex; (ii) no protections were observed on 70S ribosomes devoid of tRNA and mRNA; (iii) EF-G also weakly protected G2607 and G2608; (iv) mutations at G2608 conferred resistance to the oxazolidinones in Escherichia coli cells; and (v) G2607 and G2608 occur near the exit to the peptide tunnel on the 50S subunit. A mechanism for the pleiotropic action of the oxazolidinones is discussed.     

Evidence that the G2661 region of 23S rRNA is located at the ribosomal binding sites of both elongation factors

Alpha-sarcin cleaves one phosphodiester bond of 23S rRNA within 70S ribosomes or 50S subunits derived from E. coli. The resulting fragment was isolated and sequenced. The cleavage site was identified as being after G2661 and is located within a universally conserved dodecamer. Cleavage after G2661 specifically blocked the binding of both elongation factors, i.e. that of the ternary complex Phe-tRNA*EF-Tu*GMPPNP and of EF-G*GMPPNP, whereas all elongation-factor independent functions of the ribosome, such as association of the ribosomal subunits, tRNA binding to A and P sites, the accuracy of tRNA selection at both sites, the peptidyl transferase activity, and the EF-G independent, spontaneous translocation, were not affected at all. Control experiments with wheat germ ribosomes yielded an equivalent inhibition pattern. The data suggest that the universally conserved dodecamer containing the cleavage site G2661 is located at the presumably overlapping region of the binding sites of both elongation factors.     

Structure and function of the conserved 690 hairpin in Escherichia coli 16 S ribosomal RNA. II. NMR solution structure

The solution structure of the conserved 690 hairpin from Escherichia coli 16 S rRNA was determined by NMR spectroscopy. The 690 loop is located at the surface of the 30 S subunit in the platform region and has been implicated in interactions with P-site bound tRNA, E-site mRNA, S11 binding, IF3 binding, and in RNA-RNA interactions with the 790 loop of 16 S rRNA and domain IV of 23 S rRNA. The structure reveals a novel sheared type G690.U697 base-pair with a single hydrogen bond from the G690 amino to U697-04. G691 and A696 also form a sheared pair and U692 forms a U-turn with an H-bond to the A695 non-bridging phosphate oxygen. The sheared pairs and U-turn result in the continuous single-stranded stacking of five residues from 6693 to U697 with their Watson-Crick functional groups exposed in the minor groove. The overall fold of the 690 hairpin is similar to the anticodon loop of tRNA. The structure provides an explanation for chemical protection patterns in the loop upon interaction with tRNA, the 50 S subunit, and S11. In vivo genetic studies demonstrate the functional importance of the motifs observed in the solution structure of the 690 hairpin.     

Mutations in domain V of the 23S ribosomal RNA of Bacillus subtilis that inactivate its protein folding property in vitro

The active site of a protein folding reaction is in domain V of the 23S rRNA in the bacterial ribosome and its homologs in other organisms. This domain has long been known as the peptidyl transferase center. Domain V of Bacillus subtilis is split into two segments, the more conserved large peptidyl transferase loop (RNA1) and the rest (RNA2). These two segments together act as a protein folding modulator as well as the complete domain V RNA. A number of site-directed mutations were introduced in RNA1 and RNA2 of B.subtilis, taking clues from reports of these sites being involved in various steps of protein synthesis. For example, sites like G2505, U2506, U2584 and U2585 in Escherichia coli RNA1 region are protected by deacylated tRNA at high Mg²⁺ concentration and A2602 is protected by amino acyl tRNA when the P site remains occupied already. Mutations A2058G and A2059G in the RNA1 region render the ribosome Ery^r in E.coli and Lnc^r in tobacco chloroplast. Sites in P loop G2252 and G2253 in E.coli are protected against modification by the CCA end of the P site bound tRNA. Mutations were introduced in corresponding nucleotides in B.subtilis RNA1 and RNA2 of domain V. The mutants were tested for refolding using unfolded protein binding assays with unfolded carbonic anhydrase. In the protein folding assay, the mutants showed partial to complete loss of this activity. In the filter binding assay for the RNA–refolding protein complex, the mutants showed an extent of protein binding that agreed well with their protein folding activity.     

Function of the ribosomal E-site: a mutagenesis study

Ribosomes synthesize proteins according to the information encoded in mRNA. During this process, both the incoming amino acid and the nascent peptide are bound to tRNA molecules. Three binding sites for tRNA in the ribosome are known: the A-site for aminoacyl-tRNA, the P-site for peptidyl-tRNA and the E-site for the deacylated tRNA leaving the ribosome. Here, we present a study of Escherichia coli ribosomes with the E-site binding destabilized by mutation C2394G of the 23S rRNA. Expression of the mutant 23S rRNA in vivo caused increased frameshifting and stop codon readthrough. The progression of these ribosomes through the ribosomal elongation cycle in vitro reveals ejection of deacylated tRNA during the translocation step or shortly after. E-site compromised ribosomes can undergo translocation, although in some cases it is less efficient and results in a frameshift. The mutation affects formation of the P/E hybrid site and leads to a loss of stimulation of the multiple turnover GTPase activity of EF-G by deacylated tRNA bound to the ribosome.     

Non-bridging phosphate oxygen atoms within the tRNA anticodon stem-loop are essential for ribosomal A site binding and translocation

The conformation of the anticodon stem-loop of tRNAs required for correct decoding by the ribosome depends on intramolecular and intermolecular interactions that are independent of the tRNA nucleotide sequence. Non-bridging phosphate oxygen atoms have been shown to be critical for the structure and function of several RNAs. However, little is known about the role they play in ribosomal A site binding and translocation of tRNA to the P site. Here, we show that non-bridging phosphate oxygen atoms within the tRNA anticodon stem-loop at positions 33, 35, and 37 are important for A site binding. Those at positions 34 and 36 are not necessary for binding, but are essential for translocation. Our results correlate with structural data, indicating that position 34 interacts with the highly conserved 16S rRNA base G966 and position 36 interacts with the universally conserved tRNA base U33 during translocation to the P site.