The conserved A-site finger of the 23S rRNA: just one of the intersubunit bridges or a part of the allosteric communication pathway?

During the translocation of tRNAs and mRNA relative to the ribosome, the B1a, B1b and B1c bridges undergo the most extensive conformational changes among the bridges between the large and the small ribosomal subunits. The B1a bridge, also called the "A-site finger" (ASF), is formed by the 23S rRNA helix 38, which is located right above the ribosomal A-site. Here, we deleted part of the ASF so that the B1a intersubunit bridge could not be formed (DeltaB1a). The mutation led to a less efficient subunit association. A number of functional activities of the DeltaB1a ribosomes, such as tRNA binding to the P and A-sites, translocation and EF-G-related GTPase reaction were preserved. A moderate decrease in EF-G-related GTPase stimulation by the P-site occupation by deacylated tRNA was observed. This suggests that the B1a bridge is not involved in the most basic steps of the elongation cycle, but rather in the fine-tuning of the ribosomal activity. Chemical probing of ribosomes carrying the ASF truncation revealed structural differences in the 5S rRNA and in the 23S rRNA helices located between the peptidyltransferase center and the binding site of the elongation factors. Interestingly, reactivity changes were found in the P-loop, an important functional region of the 23S rRNA. It is likely that the A-site finger, in addition to its role in subunit association, forms part of the system of allosteric signal exchanges between the small subunit decoding center and the functional centers on the large subunit.     

The A-site finger in 23 S rRNA acts as a functional attenuator for translocation

Helix 38 (H38) in 23 S rRNA, which is known as the "A-site finger (ASF)," is located in the intersubunit space of the ribosomal 50 S subunit and, together with protein S13 in the 30 S subunit, it forms bridge B1a. It is known that throughout the decoding process, ASF interacts directly with the A-site tRNA. Bridge B1a becomes disrupted by the ratchet-like rotation of the 30 S subunit relative to the 50 S subunit. This occurs in association with elongation factor G (EF-G)-catalyzed translocation. To further characterize the functional role(s) of ASF, variants of Escherichia coli ribosomes with a shortened ASF were constructed. The E. coli strain bearing such ASF-shortened ribosomes had a normal growth rate but enhanced +1 frameshift activity. ASF-shortened ribosomes showed normal subunit association but higher activity in poly(U)-dependent polyphenylalanine synthesis than the wild type (WT) ribosome at limited EF-G concentrations. In contrast, other ribosome variants with shortened bridge-forming helices 34 and 68 showed weak subunit association and less efficient translational activity than the WT ribosome. Thus, the higher translational activity of ASF-shortened ribosomes is caused by the disruption of bridge B1a and is not due to weakened subunit association. Single round translocation analyses clearly demonstrated that the ASF-shortened ribosomes have higher translocation activity than the WT ribosome. These observations indicate that the intrinsic translocation activity of ribosomes is greater than that usually observed in the WT ribosome and that ASF is a functional attenuator for translocation that serves to maintain the reading frame.     

An essential function for the phosphate-dependent exoribonucleases RNase PH and polynucleotide phosphorylase.

Escherichia coli cells lacking both polynucleotide phosphorylase (PNPase) and RNase PH, the only known P(i)-dependent exoribonucleases, were previously shown to grow slowly at 37 degrees C and to display a dramatically reduced level of tRNA(Tyr)su3+ suppressor activity. Here we show that the RNase PH-negative, PNP-negative double-mutant strain actually displays a reversible cold-sensitive phenotype and that tRNA biosynthesis is normal. In contrast, ribosome structure and function are severely affected, particularly at lower temperatures. At 31 degrees C, the amount of 50S subunit is dramatically reduced and 23S rRNA is degraded. Moreover, cells that had been incubated at 42 degrees C immediately cease growing and synthesizing protein upon a shift to 31 degrees C, suggesting that the ribosomes synthesized at the higher temperature are defective and unable to function at the lower temperature. These data indicate that RNase PH and PNPase play an essential role that affects ribosome metabolism and that this function cannot be taken over by any of the hydrolytic exoribonucleases present in the cell.     

Mutations in helix 27 of the yeast Saccharomyces cerevisiae 18S rRNA affect the function of the decoding center of the ribosome

A dynamic structural rearrangement in the phylogenetically conserved helix 27 of Escherichia coli 16S rRNA has been proposed to directly affect the accuracy of translational decoding by switching between "accurate" and "error-prone" conformations. To examine the function of helix 27 in eukaryotes, random and site-specific mutations in helix 27 of the yeast Saccharomyces cerevisiae 18S rRNA have been characterized. Mutations at positions of yeast 18S rRNA corresponding to E. coli 886 (rdn8), 888 (rdn6), and 912 (rdn4) increased translational accuracy in vivo and in vitro, and caused a reduction in tRNA binding to the A-site of mutant ribosomes. The double rdn4rdn6 mutation separated the killing and stop-codon readthrough effects of the aminoglycoside antibiotic, paromomycin, implicating a direct involvement of yeast helix 27 in accurate recognition of codons by tRNA or release factor eRF1. Although our data in yeast does not support a conformational switch model analogous to that proposed for helix 27 of E. coli 16S rRNA, it strongly suggests a functional conservation of this region in tRNA selection.     

Molecular dynamics simulations suggest that RNA three-way junctions can act as flexible RNA structural elements in the ribosome

We present extensive explicit solvent molecular dynamics analysis of three RNA three-way junctions (3WJs) from the large ribosomal subunit: the 3WJ formed by Helices 90–92 (H90–H92) of 23S rRNA; the 3WJ formed by H42–H44 organizing the GTPase associated center (GAC) of 23S rRNA; and the 3WJ of 5S rRNA. H92 near the peptidyl transferase center binds the 3′-CCA end of amino-acylated tRNA. The GAC binds protein factors and stimulates GTP hydrolysis driving protein synthesis. The 5S rRNA binds the central protuberance and A-site finger (ASF) involved in bridges with the 30S subunit. The simulations reveal that all three 3WJs possess significant anisotropic hinge-like flexibility between their stacked stems and dynamics within the compact regions of their adjacent stems. The A-site 3WJ dynamics may facilitate accommodation of tRNA, while the 5S 3WJ flexibility appears to be essential for coordinated movements of ASF and 5S rRNA. The GAC 3WJ may support large-scale dynamics of the L7/L12-stalk region. The simulations reveal that H42–H44 rRNA segments are not fully relaxed and in the X-ray structures they are bent towards the large subunit. The bending may be related to L10 binding and is distributed between the 3WJ and the H42–H97 contact.     

Involvement of helix 34 of 16 S rRNA in decoding and translocation on the ribosome

Helix 34 of 16 S rRNA is located in the head of the 30 S ribosomal subunit close to the decoding center and has been invoked in a number of ribosome functions. In the present work, we have studied the effects of mutations in helix 34 both in vivo and in vitro. Several nucleotides in helix 34 that are either highly conserved or form important tertiary contacts in 16 S rRNA (U961, C1109, A1191, and A1201) were mutated, and the mutant ribosomes were expressed in the Escherichia coli MC250 Delta7 strain that lacks all seven chromosomal rRNA operons. Mutations at positions A1191 and U961 reduced the efficiency of subunit association and resulted in structural rearrangements in helix 27 (position 908) and helix 31 (position 974) of 16 S rRNA. All mutants exhibited increased levels of frameshifting and nonsense readthrough. The effects on frameshifting were specific in that -1 frameshifting was enhanced with mutant A1191G and +1 frameshifting with the other mutants. Mutations of A1191 moderately (approximately 2-fold) inhibited tRNA translocation. No significant effects were found on efficiency and rate of initiation, misreading of sense codons, or binding of tRNA to the E site. The data indicate that helix 34 is involved in controlling the maintenance of the reading frame and in tRNA translocation.     

Ribosome assembly in Escherichia coli strains lacking the RNA helicase DeaD/CsdA or DbpA

Ribosome subunit assembly in bacteria is a fast and efficient process. Among the nonribosomal proteins involved in ribosome biogenesis are RNA helicases. We describe ribosome biogenesis in Escherichia coli strains lacking RNA helicase DeaD (CsdA) or DbpA. Ribosome large subunit assembly intermediate particles (40S) accumulate at 25 degrees C and at 37 degrees C in the absence of DeaD but not without DbpA. 23S rRNA is incompletely processed in the 40S and 50S particles of the DeaD(-) strain. Pulse labeling showed that the 40S particles are converted nearly completely into functional ribosomes. The rate of large ribosomal subunit assembly was reduced about four times in DeaD-deficient cells. Functional activity tests of the ribosomal particles demonstrated that the final step of 50S assembly, the activation step, was affected when DeaD was not present. The results are compatible with the model that predicts multiple DeaD-catalyzed structural transitions of the ribosome large subunit assembly.     

Ribosomal Intersubunit Bridge B2a Is Involved in Factor-Dependent Translation Initiation and Translational Processivity

Intersubunit bridges are important for holding together subunits in the 70S ribosome. Moreover, a number of intersubunit bridges have a role in modulating the activity of the ribosome during translation. Ribosomal intersubunit bridge B2a is formed by the interaction between the conserved 23S rRNA helix-loop 69 (H69) and the top of the 16S rRNA helix 44. Within the 70S ribosome, bridge B2a contacts translation factors and the A-site tRNA. In addition to bridging the subunits, bridge B2a has been invoked in a number of other ribosomal functions from initiation to termination. In the present work, single-nucleotide substitutions were inserted at positions 1912 and 1919 of Escherichia coli 23S rRNA (helix 69), which are involved in important intrahelical and intersubunit tertiary interactions in bridge B2a. The resulting ribosomes had a severely reduced activity in a cell-free translation elongation assay, but displayed a nearly wild-type-level peptidyl transferase activity. In vitro reassociation efficiency decreased with all of the H69 variant 50S subunits, but was severest with the A1919C and ΔH69 variants. The mutations strongly affected initiation-factor-dependent 70S initiation complex formation, but exhibited a minor effect on the nonenzymatic initiation process. The mutations decreased ribosomal processivity in vitro and caused a progressive depletion of 50S subunits in polysomal fractions in vivo. Mutations at position 1919 decreased the stability of a dipeptidyl-tRNA in the A-site, whereas the binding of the dipeptidyl-tRNA was rendered more stable with 1912 and ΔH69 mutations. Our results suggest that the H69 of 23S rRNA functions as a control element during enzymatic steps of translation.     

Conserved loop sequence of helix 69 in Escherichia coli 23 S rRNA is involved in A-site tRNA binding and translational fidelity

Ribosomal (r) RNAs play a crucial role in the fundamental structure and function of the ribosome. Helix 69 (H69) (position 1906-1924), a highly conserved stem-loop in domain IV of the 23 S rRNA of bacterial 50 S subunits, is located on the surface for intersubunit association with the 30 S subunit by connecting with helix 44 of 16 S rRNA with the bridge B2a. H69 directly interacts with A/T-, A-, and P-site tRNAs during each translation step. To investigate the functional importance of the highly conserved loop sequence (1912-1918) of H69, we employed a genetic method that we named SSER (systematic selection of functional sequences by enforced replacement). This method allowed us to identify and select from the randomized loop sequences of H69 in Escherichia coli 23 S rRNA functional sequences that are absolutely required for ribosomal function. From a library consisting of 16,384 sequence variations, 13 functional variants were obtained. A1912 and U(Psi)1917 were selected as essential residues in all variants. An E. coli strain having 23 S rRNA with a U to A mutation at position 1915 showed a severe growth phenotype and low translational fidelity. The result could be explained by the fact that the A1915-ribosome variant has weak subunit association, weak A-site tRNA binding, and decreased translational activity. This study proposes that H69 plays an important role in the control of translational fidelity by modulating A-site tRNA binding during the decoding process.     

Antisense oligonucleotides targeting universally conserved 26S rRNA domains of plant ribosomes at different steps of polypeptide elongation

A ribosome undergoes significant conformational changes during elongation of polypeptide chain that are correlated with structural changes of rRNAs. We tested nine different antisense oligodeoxynucleotides complementary to the selected, highly conserved sequences of Lupinus luteus 26S rRNA that are engaged in the interactions with tRNA molecules. The ribosomes were converted either to pre- or to posttranslocational states, with or without prehybridized oligonucleotides, using tRNA or mini-tRNA molecules. The activity of those ribosomes was tested via the so-called binding assay. We observed well-defined structural changes of ribosome's conformation during different steps of the elongation cycle of protein biosynthesis. In this article, we present that (i) before and after translocation, fragments of domain V between helices H70/H71 and H74/H89 do not have to interact with nucleotides 72-76 of the acceptor arm of A-site tRNA; (ii) helix H69 does not have to interact with DHU arm of tRNA in positions 25 and 26 after forming the peptide bond, but before translocation; (iii) helices H69 and H70 interact weakly with nucleotides 11, 12, 25, and 26 of A-site tRNA before forming a peptide bond in the ribosome; (iv) interactions between helices H80, H93 and single-stranded region between helices H92 and H93 and CCAend of P-site tRNA are necessary at all steps of elongation cycle; and (v) before and after translocation, helix H89 does not have to interact with nucleotides in positions 64-65 and 50-53 of A-site tRNA TPsiC arm.     

How are tRNAs and mRNA arranged in the ribosome? An attempt to correlate the stereochemistry of the tRNA-mRNA interaction with constraints imposed by the ribosomal topography.

Two tRNA molecules at the ribosomal A- and P-sites, with a relatively small angle between the planes of the L-shaped molecules, can be arranged in two mutually exclusive orientations. In one (the 'R'-configuration), the T-loop of the A-site tRNA faces the D-loop of the P-site tRNA, whereas in the other (the 'S'-configuration) the D-loop of the A-site tRNA faces the T-loop of the P-site tRNA. A number of stereochemical arguments, based on the crystal structure of 'free' tRNA, favour the R-configuration. In the ribosome, the CCA-ends of the tRNA molecules are 'fixed' at the base of the central protuberance (the peptidyl transferase centre) of the 50S subunit, and the anticodon loops lie in the neck region (the decoding site) of the 30S subunit. The translocation step is essentially a rotational movement of the tRNA from the A- to the P-site, and there is convincing evidence that the A-site must be located nearest to the L7/L12 protuberance of the 50S subunit. The mRNA in the two codon-anticodon duplexes lies on the 'inside' of the 'elbows' of the tRNA molecules (in both the S-type and R-type configurations), and runs up between the two molecules from the A- to the P-site in the 3' to 5'-direction. These considerations have the consequence that in the S-configuration the mRNA in the codon-anticodon duplexes is directed towards the 50S subunit, whereas in the R-configuration it is directed towards the 30S subunit. The results of site-directed cross-linking experiments, in particular cross-links to mRNA at positions within or very close to the codons interacting with A- or P-site tRNA, favour the latter situation. This conclusion is in direct contradiction to other current models for the arrangement of mRNA and tRNA on the ribosome.     

Functional elucidation of a key contact between tRNA and the large ribosomal subunit rRNA during decoding

The selection of cognate tRNAs during translation is specified by a kinetic discrimination mechanism driven by distinct structural states of the ribosome. While the biochemical steps that drive the tRNA selection process have been carefully documented, it remains unclear how recognition of matched codon:anticodon helices in the small subunit facilitate global rearrangements in the ribosome complex that efficiently promote tRNA decoding. Here we use an in vitro selection approach to isolate tRNA^Trp miscoding variants that exhibit a globally perturbed tRNA tertiary structure. Interestingly, the most substantial distortions are positioned in the elbow region of the tRNA that closely approaches helix 69 (H69) of the large ribosomal subunit. The importance of these specific interactions to tRNA selection is underscored by our kinetic analysis of both tRNA and rRNA variants that perturb the integrity of this interaction.     

Ribosome structure and activity are altered in cells lacking snoRNPs that form pseudouridines in the peptidyl transferase center

One of the oldest questions in RNA science is the role of nucleotide modification. Here, the importance of pseudouridine formation (Psi) in the peptidyl transferase center of rRNA was examined by depleting yeast cells of 1-5 snoRNAs that guide a total of six Psi modifications. Translation was impaired substantially with loss of a conserved Psi in the A site of tRNA binding. Depletion of other Psis had subtle or no apparent effect on activity; however, synergistic effects were observed in some combinations. Pseudouridines are proposed to enhance ribosome activity by altering rRNA folding and interactions, with some Psis having greater effects than others. The possibility that modifying snoRNPs might affect ribosome structure in other ways is also discussed.     

Transfer RNA docking pair model in the ribosomal pre- and post-translocational states.

A consensus has been reached that the conformation of the anticodon-codon interactions of two adjacent tRNA molecules on the ribosome is a Sundaralingam-type (S-type). Even if it is kept to the S-type, there are still various possibilities. Various experimental data have been supporting an idea that the conformation of A-site tRNA is different from that of P-site tRNA. Those data as well as the recent result of Brimacombe and co-workers that U20:1 of lupin tRNAmMetbound to the A-site was cross-linked to a region, 875-905, of 23S rRNA in combination with the other recent findings of Nierhaus and co-workers about the spin-contrast method of neutron diffraction of the ribosome and the better accessible nucleotide patterns of phosphorothioated tRNAs on the ribosome have led to a new tRNA docking pair model, in which the highly conserved G18 and G19 of D-loop in A-site tRNA and C56 and C61 of TpsiC-loop in P-site tRNA base pair along with the conventional base pairs of adjacent codon-anticodon interactions. This A-P tRNA pair model can be translocated to the P-E tRNA pair model without changing the conformation except the ACCA termini, keeping the position of the growing nascent polypeptide chain.     

Major rearrangements in the 70S ribosomal 3D structure caused by a conformational switch in 16S ribosomal RNA

Dynamic changes in secondary structure of the 16S rRNA during the decoding of mRNA are visualized by three-dimensional cryo-electron microscopy of the 70S ribosome. Thermodynamically unstable base pairing of the 912-910 (CUC) nucleotides of the 16S RNA with two adjacent complementary regions at nucleotides 885-887 (GGG) and 888-890 (GAG) was stabilized in either of the two states by point mutations at positions 912 (C912G) and 885 (G885U). A wave of rearrangements can be traced arising from the switch in the three base pairs and involving functionally important regions in both subunits of the ribosome. This significantly affects the topography of the A-site tRNA-binding region on the 30S subunit and thereby explains changes in tRNA affinity for the ribosome and fidelity of decoding mRNA.     

Mechanism of translation based on intersubunit complementarities of ribosomal RNAs and tRNAs

A universal rule is found about nucleotide sequence complementarities between the regions 2653-2666 in the GTPase-binding site of 23S rRNA and 1064-1077 of 16S rRNA as well as between the region 1103-1107 of 16S rRNA and GUUCG (or GUUCA) of tRNAs. This rule holds for all species in the living kingdoms except for two protista mitochondrial rRNAs of Trypanosoma brucei and Plasmodium falciparum. We found that quite similar relationships for the two species hold under the assumption presented in the present paper. The complementarity between T-loop of tRNA and the region 1103-1107 of 16S rRNA suggests that the first interaction of a ribosome with aminoacyl-tRNAEF-TuGTP ternary complex or EF-GGDP complex could occur at the region 1103-1107 of 16S rRNA with the T-loop-D-loop contact region of the ternary complex or the domain IV-V bridge region of the EF-GGDP complex. The second interaction should occur between the A-site codon and the anticodon loop or between the anticodon stem/loop of A-site tRNA and the tip of domain IV of EF-G. The above stepwise interactions would facilitate the collision of the region 1064-1077 of 16S rRNA with the region around A2660 at the alpha-sarcin/ricin loop of 23S rRNA. In this way, the universal rule is capable of explaining how spectinomycin-binding region of 16S rRNA takes part in translocation, how GTPases such as EF-Tu and EF-G can be introduced into their binding site on the large subunit ribosome in proper orientation efficiently and also how driving forces for tRNA movement are produced in translocation and codon recognition. The analysis of T-loops of all tRNAs also presents an evolutionary trend from a random and seemingly primitive sequence, as defined to be Y type, to the most developed structure, such as either 5G7 or 5A7 types in the present definition.     

Importance of tRNA interactions with 23S rRNA for peptide bond formation on the ribosome: studies with substrate analogs

The major enzymatic activity of the ribosome is the catalysis of peptide bond formation. The active site -- the peptidyl transferase center -- is composed of ribosomal RNA (rRNA), and interactions between rRNA and the reactants, peptidyl-tRNA and aminoacyl-tRNA, are crucial for the reaction to proceed rapidly and efficiently. Here, we describe the influence of rRNA interactions with cytidine residues in A-site substrate analogs (C-puromycin or CC-puromycin), mimicking C74 and C75 of tRNA on the reaction. Base-pairing of C75 with G2553 of 23S rRNA accelerates peptide bond formation, presumably by stabilizing the peptidyl transferase center in its productive conformation. When C74 is also present in the substrate analog, the reaction is slowed down considerably, indicating a slow step in substrate binding to the active site, which limits the reaction rate. The tRNA-rRNA interactions lead to a robust reaction that is insensitive to pH changes or base substitutions in 23S rRNA at the active site of the ribosome.     

A structural model for the large subunit of the mammalian mitochondrial ribosome

Protein translation is essential for all forms of life and is conducted by a macromolecular complex, the ribosome. Evolutionary changes in protein and RNA sequences can affect the 3D organization of structural features in ribosomes in different species. The most dramatic changes occur in animal mitochondria, whose genomes have been reduced and altered significantly. The RNA component of the mitochondrial ribosome (mitoribosome) is reduced in size, with a compensatory increase in protein content. Until recently, it was unclear how these changes affect the 3D structure of the mitoribosome. Here, we present a structural model of the large subunit of the mammalian mitoribosome developed by combining molecular modeling techniques with cryo-electron microscopic data at 12.1A resolution. The model contains 93% of the mitochondrial rRNA sequence and 16 mitochondrial ribosomal proteins in the large subunit of the mitoribosome. Despite the smaller mitochondrial rRNA, the spatial positions of RNA domains known to be involved directly in protein synthesis are essentially the same as in bacterial and archaeal ribosomes. However, the dramatic reduction in rRNA content necessitates evolution of unique structural features to maintain connectivity between RNA domains. The smaller rRNA sequence also limits the likelihood of tRNA binding at the E-site of the mitoribosome, and correlates with the reduced size of D-loops and T-loops in some animal mitochondrial tRNAs, suggesting co-evolution of mitochondrial rRNA and tRNA structures.