Tagging ribosomal protein S7 allows rapid identification of mutants defective in assembly and function of 30 S subunits

Eukaryotic Ribosomal Protein S5 of the 40S Subunit: Structure and Function

The ribosomal protein RPS5 is one of the prime proteins to combine with RNA and belongs to the conserved ribosomal protein family. It plays a substantial role in the process of translation and also has some non-ribosome functions. Despite the enormous studies on the relationship between the structure and function of prokaryotic RPS7, the structure and molecular details of the mechanism of eukaryotic RPS5 remain largely unexplored. This article focuses on the structure of RPS5 and its role in cells and diseases, especially the binding to 18S rRNA. The role of RPS5 in translation initiation and its potential use as targets for liver disease and cancer are discussed.

Protein synthesis by ribosomes with tethered subunits

The ribosome is a ribonucleoprotein machine responsible for protein synthesis. In all kingdoms of life it is composed of two subunits, each built on its own ribosomal RNA (rRNA) scaffold. The independent but coordinated functions of the subunits, including their ability to associate at initiation, rotate during elongation, and dissociate after protein release, are an established model of protein synthesis. Furthermore, the bipartite nature of the ribosome is presumed to be essential for biogenesis, since dedicated assembly factors keep immature ribosomal subunits apart and prevent them from translation initiation. Free exchange of the subunits limits the development of specialized orthogonal genetic systems that could be evolved for novel functions without interfering with native translation. Here we show that ribosomes with tethered and thus inseparable subunits (termed Ribo-T) are capable of successfully carrying out protein synthesis. By engineering a hybrid rRNA composed of both small and large subunit rRNA sequences, we produced a functional ribosome in which the subunits are covalently linked into a single entity by short RNA linkers. Notably, Ribo-T was not only functional in vitro, but was also able to support the growth of Escherichia coli cells even in the absence of wild-type ribosomes. We used Ribo-T to create the first fully orthogonal ribosome-messenger RNA system, and demonstrate its evolvability by selecting otherwise dominantly lethal rRNA mutations in the peptidyl transferase centre that facilitate the translation of a problematic protein sequence. Ribo-T can be used for exploring poorly understood functions of the ribosome, enabling orthogonal genetic systems, and engineering ribosomes with new functions.

RNA localization in bacteria

Bacteria localize proteins and DNA regions to specific subcellular sites, and several recent publications show that RNAs are localized within the cell as well. Localization of tmRNA and some mRNAs indicates that RNAs can be sequestered at specific sites by RNA binding proteins, or can be trapped at the location where they are transcribed. Although the functions of RNA localization are not yet completely understood, it appears that one function of RNA localization is to regulate RNA abundance by controlling access to nucleases. New techniques for visualizing RNAs will likely lead to increased examination of spatial control of RNAs and the role this control plays in the regulation of gene expression and bacterial physiology.

Mapping the ribosomal protein S7 regulatory binding site on mRNA of the E. coli streptomycin operon

In this work it is shown by deletion analysis that an intercistronic region (ICR) approximately 80 nucleotides in length is necessary for interaction with recombinant E. coli S7 protein (r6hEcoS7). A model is proposed for the interaction of S7 with two ICR sites-region of hairpin bifurcations and Shine-Dalgarno sequence of cistron S7. A de novo RNA binding site for heterologous S7 protein of Thermus thermophilus (r6hTthS7) was constructed by selection of a combinatorial RNA library based on E. coli ICR: it has only a single supposed protein recognition site in the region of bifurcation. The SERW technique was used for selection of two intercistronic RNA libraries in which five nucleotides of a double-stranded region, adjacent to the bifurcation, had the randomized sequence. One library contained an authentic AG (-82/-20) pair, while in the other this pair was replaced by AU. A serwamer capable of specific binding to r6hTthS7 was selected; it appeared to be the RNA68 mutant with eight nucleotide mutations. The serwamer binds to r6hTthS7 with the same affinity as homologous authentic ICR of str mRNA binds to r6hEcoS7; apparent dissociation constants are 89 +/- 43 and 50 +/- 24 nM, respectively.

Promiscuous substrate recognition in folding and assembly activities of the trigger factor chaperone

Trigger factor (TF) is a molecular chaperone that binds to bacterial ribosomes where it contacts emerging nascent chains, but TF is also abundant free in the cytosol where its activity is less well characterized. In vitro studies show that TF promotes protein refolding. We find here that ribosome-free TF stably associates with and rescues from misfolding a large repertoire of full-length proteins. We identify over 170 members of this cytosolic Escherichia coli TF substrate proteome, including ribosomal protein S7. We analyzed the biochemical properties of a TF:S7 complex from Thermotoga maritima and determined its crystal structure. Thereby, we obtained an atomic-level picture of a promiscuous chaperone in complex with a physiological substrate protein. The structure of the complex reveals the molecular basis of substrate recognition by TF, indicates how TF could accelerate protein folding, and suggests a role for TF in the biogenesis of protein complexes.

The CCA anticodon specifies separate functions inside and outside translation in Bacillus cereus

Bacillus cereus 14579 encodes two tRNAs with the CCA anticodon, tRNA(Trp) and tRNA(Other). tRNA(Trp) was separately aminoacylated by two enzymes, TrpRS1 and TrpRS2, which share only 34% similarity and display different catalytic capacities and specificities. TrpRS1 was 18-fold more proficient at aminoacylating tRNA(Trp) with Trp, while TrpRS2 more efficiently utilizes the Trp analog 5-hydroxy Trp. tRNA(Other) was not aminoacylated by either TrpRS but instead by the combined activity of LysRS1 and LysRS2, which recognized sequence elements absent from tRNA(Trp). Polysomes were found to contain tRNA(Trp), consistent with its role in translation, but not tRNA(Other) suggesting a function outside protein synthesis. Regulation of the genes encoding TrpRS1 and TrpRS2 (trpS1 and trpS2) is dependent on riboswitch-mediated recognition of the CCA anticodon, and the role of tRNA(Other) in this process was investigated. Deletion of tRNA(Other) led to up to a 50 fold drop in trpS1 expression, which resulted in the loss of differential regulation of the trpS1 and trpS2 genes in stationary phase. These findings reveal that sequence-specific interactions with a tRNA anticodon can be confined to processes outside translation, suggesting a means by which such RNAs may evolve non-coding functions.

A role for the 30S subunit E site in maintenance of the translational reading frame

The exit (E) site has been implicated in several ribosomal activities, including translocation, decoding, and maintenance of the translational reading frame. Here, we target the 30S subunit E site by introducing a deletion in rpsG that truncates the beta-hairpin of ribosomal protein S7. This mutation (S7DeltaR77-Y84) increases both -1 and +1 frameshifting but does not increase miscoding, providing evidence that the 30S E site plays a specific role in frame maintenance. Mutation S7DeltaR77-Y84 also stimulates +1 programmed frameshifting during prfB'-lacZ translation in many synthetic contexts. However, no effect is seen when the E codon of the frameshift site corresponds to those found in nature, suggesting that E-tRNA release does not normally limit the rate of prfB frameshifting. Ribosomes containing S7DeltaR77-Y84 exhibit an elevated rate of spontaneous reverse translocation and an increased K (1/2) for E-tRNA. These effects are of similar magnitude, suggesting that both result from destabilization of E-tRNA. Finally, this mutation of the 30S E site does not inhibit EF-G-dependent translocation, consistent with a primary role for the 50S E site in the mechanism.

Roles of the negatively charged N-terminal extension of Saccharomyces cerevisiae ribosomal protein S5 revealed by characterization of a yeast strain containing human ribosomal protein S5

Ribosomal protein (rp) S5 belongs to a family of ribosomal proteins that includes bacterial rpS7. rpS5 forms part of the exit (E) site on the 40S ribosomal subunit and is essential for yeast viability. Human rpS5 is 67% identical and 79% similar to Saccharomyces cerevisiae rpS5 but lacks a negatively charged (pI approximately 3.27) 21 amino acid long N-terminal extension that is present in fungi. Here we report that replacement of yeast rpS5 with its human homolog yielded a viable yeast strain with a 20%-25% decrease in growth rate. This replacement also resulted in a moderate increase in the heavy polyribosomal components in the mutant strain, suggesting either translation elongation or termination defects, and in a reduction in the polyribosomal association of the elongation factors eEF3 and eEF1A. In addition, the mutant strain was characterized by moderate increases in +1 and -1 programmed frameshifting and hyperaccurate recognition of the UAA stop codon. The activities of the cricket paralysis virus (CrPV) IRES and two mammalian cellular IRESs (CAT-1 and SNAT-2) were also increased in the mutant strain. Consistently, the rpS5 replacement led to enhanced direct interaction between the CrPV IRES and the mutant yeast ribosomes. Taken together, these data indicate that rpS5 plays an important role in maintaining the accuracy of translation in eukaryotes and suggest that the negatively charged N-terminal extension of yeast rpS5 might affect the ribosomal recruitment of specific mRNAs.

Potential New Antibiotic Sites in the Ribosome Revealed by Deleterious Mutations in RNA of the Large Ribosomal Subunit

The ribosome is the main target for antibiotics that inhibit protein biosynthesis. Despite the chemical diversity of the known antibiotics that affect functions of the large ribosomal subunit, these drugs act on only a few sites corresponding to some of the known functional centers. We have used a genetic approach for identifying structurally and functionally critical sites in the ribosome that can be used as new antibiotic targets. By using randomly mutagenized rRNA genes, we mapped rRNA sites where nucleotide alterations impair the ribosome function or assembly and lead to a deleterious phenotype. A total of 77 single-point deleterious mutations were mapped in 23 S rRNA and ranked according to the severity of their deleterious phenotypes. Many of the mutations mapped to familiar functional sites that are targeted by known antibiotics. However, a number of mutations were located in previously unexplored regions. The distribution of the mutations in the spatial structure of the ribosome showed a strong bias, with the strongly deleterious mutations being mainly localized at the interface of the large subunit and the mild ones on the solvent side. Five sites where deleterious mutations tend to cluster within discrete rRNA elements were identified as potential new antibiotic targets. One of the sites, the conserved segment of helix 38, was studied in more detail. Although the ability of the mutant 50 S subunits to associate with 30 S subunits was impaired, the lethal effect of mutations in this rRNA element was unrelated to its function as an intersubunit bridge. Instead, mutations in this region had a profound deleterious effect on the ribosome assembly.

Mutational analysis of the ribosome

The ribosome is responsible for protein synthesis, the translation of the genetic code, in all living organisms. Ribosomes are composed of RNA (ribosomal RNA) and protein (ribosomal protein). Soluble protein factors bind to the ribosome and facilitate different phases of translation. Genetic approaches have proved useful for the identification and characterization of the structural and functional roles of specific nucleotides in ribosomal RNA and of specific amino acids in ribosomal proteins and in ribosomal factors. This chapter summarizes examples of mutations identified in ribosomal RNA, ribosomal proteins, and ribosomal factors.

Temperature-dependent RNP conformational rearrangements: analysis of binary complexes of primary binding proteins with 16 S rRNA

Ribonucleoprotein particles (RNPs) are important components of all living systems, and the assembly of these particles is an intricate, often multistep, process. The 30 S ribosomal subunit is composed of one large RNA (16 S rRNA) and 21 ribosomal proteins (r-proteins). In vitro studies have revealed that assembly of the 30 S subunit is a temperature-dependent process involving sequential binding of r-proteins and conformational changes of 16 S rRNA. Additionally, a temperature-dependent conformational rearrangement was reported for a complex of primary r-protein S4 and 16 S rRNA. Given these observations, a systematic study of the temperature-dependence of 16 S rRNA architecture in individual complexes with the other five primary binding proteins (S7, S8, S15, S17, and S20) was performed. While all primary binding r-proteins bind 16 S rRNA at low temperature, not all r-proteins/16 S rRNA complexes undergo temperature-dependent conformational rearrangements. Some RNPs achieve the same conformation regardless of temperature, others show minor adjustments in 16 S rRNA conformation upon heating and, finally, others undergo significant temperature-dependent changes. Some of the architectures achieved in these rearrangements are consistent with subsequent downstream assembly events such as assembly of the secondary and tertiary binding r-proteins. The differential interaction of 16 S rRNA with r-proteins illustrates a means for controlling the sequential assembly pathway for complex RNPs and may offer insights into aspects of RNP assembly in general.

Recognition and positioning of mRNA in the ribosome by tRNAs with expanded anticodons

Mutant tRNAs containing an extra nucleotide in the anticodon loop are known to suppress +1 frameshift mutations, but in no case has the molecular mechanism been clarified. It has been proposed that the expanded anticodon pairs with a complementary mRNA sequence (the frameshift sequence) in the A site, and this quadruplet "codon-anticodon" helix is translocated to the P site to restore the correct reading frame. Here, we analyze the ability of tRNA analogs containing expanded anticodons to recognize and position mRNA in ribosomal complexes in vitro. In all cases tested, 8 nt anticodon loops position the 3' three-quarters of the frameshift sequence in the P site, indicating that the 5' bases of the expanded anticodon (nucleotides 33.5, 34, and 35) pair with mRNA in the P site. We also provide evidence that four base-pairs can form between the P-site tRNA and mRNA, and the fourth base-pair involves nucleotide 36 of the tRNA and lies toward (or in) the 30 S E site. In the A site, tRNA analogs with the expanded anticodon ACCG are able to recognize either CGG or GGU. These data imply a flexibility of the expanded anticodon in the A site. Recognition of the 5' three-quarters of the frameshift sequence in the A site and subsequent translocation of the expanded anticodon to the P site results in movement of mRNA by four nucleotides, explaining how these tRNAs can change the mRNA register in the ribosome to restore the correct reading frame.

Contribution of 16S rRNA nucleotides forming the 30S subunit A and P sites to translation in Escherichia coli

Many contacts between the ribosome and its principal substrates, tRNA and mRNA, involve universally conserved rRNA nucleotides, implying their functional importance in translation. Here, we measure the in vivo translation activity conferred by substitution of each 16S rRNA base believed to contribute to the A or P site. We find that the 30S P site is generally more tolerant of mutation than the 30S A site. In the A site, A1493C or any substitution of G530 or A1492 results in complete loss of translation activity, while A1493U and A1493G decrease translation activity by >20-fold. Among the P-site nucleotides, A1339 is most critical; any mutation of A1339 confers a >18-fold decrease in translation activity. Regarding all other P-site bases, ribosomes harboring at least one substitution retain considerable activity, >10% that of control ribosomes. Moreover, several sets of multiple substitutions within the 30S P site fail to inactivate the ribosome. The robust nature of the 30S P site indicates that its interaction with the codon-anticodon helix is less stringent than that of the 30S A site. In addition, we show that G1338A suppresses phenotypes conferred by m(2)G966A and several multiple P-site substitutions, suggesting that adenine at position 1338 can stabilize tRNA interaction in the P site.

Creating ribosomes with an all-RNA 30S subunit P site

Ribosome crystal structures have revealed that two small subunit proteins, S9 and S13, have C-terminal tails, which, together with several features of 16S rRNA, contact the anticodon stem-loop of P-site tRNA. To test the functional importance of these protein tails, we created genomic deletions of the C-terminal regions of S9 and S13. All of the tail deletions, including double mutants containing deletions in both S9 and S13, were viable, showing that Escherichia coli cells can synthesize all of their proteins by using ribosomes that contain 30S P sites composed only of RNA. However, these mutants have slower growth rates, indicating that the tails may play a supporting functional role in translation. In vitro analysis shows that 30S subunits purified from the S13 deletion mutants have a generally decreased affinity for tRNA, whereas deletion of the S9 tail selectively affects the binding of tRNAs whose anticodon stem sequences are most divergent from that of initiator tRNA.

Interactions of yeast ribosomal protein rpS14 with RNA

Yeast ribosomal protein S14 (rpS14) binds to two different RNA molecules: (1). helix 23 of 18S rRNA during its assembly into 40S ribosomal subunits and (2). a stem-loop structure in RPS14B pre-mRNA to repress expression of the RPS14B gene. We used the three-dimensional structure of Thermus thermophilus ribosomal protein S11, a bacterial homologue of rpS14, as a guide to identify conserved, surface-exposed amino acid residues that are likely to contact RNA. Eight residues that met these criteria were mutated to alanine. Most of these mutations affected interaction of rpS14 with either helix 23 or the RPS14B stem-loop RNA or both. Assembly of 40S ribosomal subunits and repression of RPS14B were also affected. S11 contains an extended carboxy-terminal domain rich in basic amino acids, which interacts with rRNA. We systematically evaluated the importance of each of the last ten amino acid residues in the basic, carboxy-terminal tail of yeast rpS14 for binding to RNA, by mutating each to alanine. Mutations in nine of these residues decreased binding of rpS14 to one or both of its RNA ligands. In addition, we examined the importance of four structural motifs in helix 23 of 18S rRNA for binding to rpS14. Mutations that altered either the terminal loop, the G-U base-pair closing the terminal loop, or the internal loop affected binding of rpS14 to helix 23.

A functional interaction between ribosomal proteins S7 and S11 within the bacterial ribosome

In this study, we used site-directed mutagenesis to disrupt an interaction that had been detected between ribosomal proteins S7 and S11 in the crystal structure of the bacterial 30 S subunit. This interaction, which is located in the E site, connects the head of the 30 S subunit to the platform and is involved in the formation of the exit channel through which passes the 30 S-bound messenger RNA. Neither mutations in S7 nor mutations in S11 prevented the incorporation of the proteins into the 30 S subunits but they perturbed the function of the ribosome. In vivo assays showed that ribosomes with either mutated S7 or S11 were altered in the control of translational fidelity, having an increased capacity for frameshifting, readthrough of a nonsense codon and codon misreading. Toeprinting and filter-binding assays showed that 30 S subunits with either mutated S7 or S11 have an enhanced capacity to bind mRNA. The effects of the S7 and S11 mutations can be related to an increased flexibility of the head of the 30 S, to an opening of the mRNA exit channel and to a perturbation of the proposed allosteric coupling between the A and E sites. Altogether, our results demonstrate that S7 and S11 interact in a functional manner and support the notion that protein-protein interactions contribute to the dynamics of the ribosome.

Accurate translocation of mRNA by the ribosome requires a peptidyl group or its analog on the tRNA moving into the 30S P site

The ribosome must accurately translocate mRNA to maintain the reading frame. Here, we monitor the position of mRNA within the ribosome before and after EF-G-catalyzed translocation near the initiation site. When a deacylated tRNA that is translocated to the 30S P site recognizes other nearby codons, movement of tRNA and mRNA often becomes uncoupled. Instead of moving in the 5' direction by 3 nucleotides, the mRNA slips backward, repositioning the tRNA on an out-of-frame codon more optimally spaced from the Shine-Dalgarno sequence. In contrast, when peptidyl-tRNA or its analog (N-acetyl-aminoacyl-tRNA) is translocated in the same context, translocation of mRNA is highly accurate. If aminoacyl-tRNA is translocated, an intermediate level of translocational accuracy is observed. Thus, translocational accuracy depends on the acylation state of the tRNA entering the 30S P site.

Crystal structure of the 30 S ribosomal subunit from Thermus thermophilus: structure of the proteins and their interactions with 16 S RNA

We present a detailed analysis of the protein structures in the 30 S ribosomal subunit from Thermus thermophilus, and their interactions with 16 S RNA based on a crystal structure at 3.05 A resolution. With 20 different polypeptide chains, the 30 S subunit adds significantly to our data base of RNA structure and protein-RNA interactions. In addition to globular domains, many of the proteins have long, extended regions, either in the termini or in internal loops, which make extensive contact to the RNA component and are involved in stabilizing RNA tertiary structure. Many ribosomal proteins share similar alpha+beta sandwich folds, but we show that the topology of this domain varies considerably, as do the ways in which the proteins interact with RNA. Analysis of the protein-RNA interactions in the context of ribosomal assembly shows that the primary binders are globular proteins that bind at RNA multihelix junctions, whereas proteins with long extensions assemble later. We attempt to correlate the structure with a large body of biochemical and genetic data on the 30 S subunit.

Analysis of mutations at residues A2451 and G2447 of 23S rRNA in the peptidyltransferase active site of the 50S ribosomal subunit

On the basis of the recent atomic-resolution x-ray structure of the 50S ribosomal subunit, residues A2451 and G2447 of 23S rRNA were proposed to participate directly in ribosome-catalyzed peptide bond formation. We have examined the peptidyltransferase and protein synthesis activities of ribosomes carrying mutations at these nucleotides. In Escherichia coli, pure mutant ribosome populations carrying either the G2447A or G2447C mutations maintained cell viability. In vitro, the G2447A ribosomes supported protein synthesis at a rate comparable to that of wild-type ribosomes. In single-turnover peptidyltransferase assays, G2447A ribosomes were shown to have essentially unimpaired peptidyltransferase activity at saturating substrate concentrations. All three base changes at the universally conserved A2451 conferred a dominant lethal phenotype when expressed in E. coli. Nonetheless, significant amounts of 2451 mutant ribosomes accumulated in polysomes, and all three 2451 mutations stimulated frameshifting and readthrough of stop codons in vivo. Furthermore, ribosomes carrying the A2451U transversion synthesized full-length beta-lactamase chains in vitro. Pure mutant ribosome populations with changes at A2451 were generated by reconstituting Bacillus stearothermophilus 50S subunits from in vitro transcribed 23S rRNA. In single-turnover peptidyltransferase assays, the rate of peptide bond formation was diminished 3- to 14-fold by these mutations. Peptidyltransferase activity and in vitro beta-lactamase synthesis by ribosomes with mutations at A2451 or G2447 were highly resistant to chloramphenicol. The significant levels of peptidyltransferase activity of ribosomes with mutations at A2451 and G2447 need to be reconciled with the roles proposed for these residues in catalysis.

Ribosomal protein S7 from Escherichia coli uses the same determinants to bind 16S ribosomal RNA and its messenger RNA

Ribosomal protein S7 from Escherichia coli binds to the lower half of the 3' major domain of 16S rRNA and initiates its folding. It also binds to its own mRNA, the str mRNA, and represses its translation. Using filter binding assays, we show in this study that the same mutations that interfere with S7 binding to 16S rRNA also weaken its affinity for its mRNA. This suggests that the same protein regions are responsible for mRNA and rRNA binding affinities, and that S7 recognizes identical sequence elements within the two RNA targets, although they have dissimilar secondary structures. Overexpression of S7 is known to inhibit bacterial growth. This phenotypic growth defect was relieved in cells overexpressing S7 mutants that bind poorly the str mRNA, confirming that growth impairment is controlled by the binding of S7 to its mRNA. Interestingly, a mutant with a short deletion at the C-terminus of S7 was more detrimental to cell growth than wild-type S7. This suggests that the C-terminal portion of S7 plays an important role in ribosome function, which is perturbed by the deletion.