Structural and functional characterization of the bacterial translocation inhibitor GE82832

The structure of GE82832, a translocation inhibitor produced by a soil microorganism, is shown to be highly related to that of dityromycin, a bicyclodecadepsipeptide antibiotic discovered long ago whose characterization had never been pursued beyond its structural elucidation. GE82832 and dityromycin were shown to interfere with both aminoacyl-tRNA and mRNA movement and with the Pi release occurring after ribosome- and EF-G-dependent GTP hydrolysis. These findings and the unusual ribosomal localization of GE82832/dityromycin near protein S13 suggest that the mechanism of inhibition entails an interference with the rotation of the 30S subunit “head” which accompanies the ribosome-unlocking step of translocation.     

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.     

Meanderings of the mRNA through the ribosome

A map of how mRNA travels through the ribosome is critical for any detailed understanding of the process of translation. This feat has recently been achieved using X-ray crystallography. The structure reveals, for the first time, details of the interactions between the mRNA and the 30S subunit beyond those at the tRNA binding sites. Elements of both 16S rRNA and ribosomal proteins contribute to mRNA binding. This work also identifies two tunnels that the mRNA passes through as it wraps around the 30S subunit. The mechanisms and mechanics of reading frame selection, translational fidelity, and translocation can now be informed by the structure.     

Locking and unlocking of ribosomal motions

During the ribosomal translocation, the binding of elongation factor G (EF-G) to the pretranslocational ribosome leads to a ratchet-like rotation of the 30S subunit relative to the 50S subunit in the direction of the mRNA movement. By means of cryo-electron microscopy we observe that this rotation is accompanied by a 20 A movement of the L1 stalk of the 50S subunit, implying that this region is involved in the translocation of deacylated tRNAs from the P to the E site. These ribosomal motions can occur only when the P-site tRNA is deacylated. Prior to peptidyl-transfer to the A-site tRNA or peptide removal, the presence of the charged P-site tRNA locks the ribosome and prohibits both of these motions.     

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 β-hairpin of ribosomal protein S7. This mutation (S7ΔR77–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 S7ΔR77–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 S7ΔR77–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.     

Observation of intersubunit movement of the ribosome in solution using FRET

Protein synthesis is believed to be a dynamic process, involving structural rearrangements of the ribosome. Cryo-EM reconstructions of certain elongation factor G (EF-G)-containing complexes have led to the proposal that translocation of tRNA and mRNA through the ribosome, from the A to P to E sites, is accompanied by a rotational movement between the two ribosomal subunits. Here, we have used F?rster resonance energy transfer (FRET) to monitor changes in the relative orientation of the ribosomal subunits in different complexes trapped at intermediate stages of translocation in solution. Binding of EF-G to the ribosome in the presence of the non-hydrolyzable GTP analogue GDPNP or GTP plus fusidic acid causes an increase in the efficiency of energy transfer between fluorophores introduced into proteins S11 in the 30 S subunit and L9 in the 50 S subunit, and a decrease in energy transfer between S6 and L9. Similar anti-correlated changes in energy transfer occur upon binding the GTP-requiring release factor RF3. These changes are consistent with the counter-clockwise rotation of the 30 S subunit relative to the 50 S subunit observed in cryo-EM studies. Reaction of ribosomal complexes containing the peptidyl-tRNA analogues N-Ac-Phe-tRNAPhe, N-Ac-Met-tRNAMet or f-Met-tRNAfMet with puromycin, conditions favoring movement of the resulting deacylated tRNAs into the P/E hybrid state, leads to similar changes in FRET. Conversely, treatment of a ribosomal complex containing deacylated and peptidyl-tRNAs bound in the A/P and P/E states, respectively, with EF-G.GTP causes reversal of the FRET changes. The use of FRET has enabled direct observation of intersubunit movement in solution, provides independent evidence that formation of the hybrid state is coupled to rotation of the 30 S subunit and shows that the intersubunit movement is reversed during the second step of translocation.     

GTP hydrolysis by EF‐G synchronizes tRNA movement on small and large ribosomal subunits

Elongation factor G (EF‐G) promotes the movement of two tRNAs and the mRNA through the ribosome in each cycle of peptide elongation. During translocation, the tRNAs transiently occupy intermediate positions on both small (30S) and large (50S) ribosomal subunits. How EF‐G and GTP hydrolysis control these movements is still unclear. We used fluorescence labels that specifically monitor movements on either 30S or 50S subunits in combination with EF‐G mutants and translocation‐specific antibiotics to investigate timing and energetics of translocation. We show that EF‐G–GTP facilitates synchronous movements of peptidyl‐tRNA on the two subunits into an early post‐translocation state, which resembles a chimeric state identified by structural studies. EF‐G binding without GTP hydrolysis promotes only partial tRNA movement on the 50S subunit. However, rapid 30S translocation and the concomitant completion of 50S translocation require GTP hydrolysis and a functional domain 4 of EF‐G. Our results reveal two distinct modes for utilizing the energy of EF‐G binding and GTP hydrolysis and suggest that coupling of GTP hydrolysis to translocation is mediated through rearrangements of the 30S subunit.     

Structural aspects of RbfA action during small ribosomal subunit assembly

Ribosome binding factor A (RbfA) is a bacterial cold shock response protein, required for an efficient processing of the 5' end of the 16S ribosomal RNA (rRNA) during assembly of the small (30S) ribosomal subunit. Here we present a crystal structure of Thermus thermophilus (Tth) RbfA and a three-dimensional cryo-electron microscopic (EM) map of the Tth 30S*RbfA complex. RbfA binds to the 30S subunit in a position overlapping the binding sites of the A and P site tRNAs, and RbfA's functionally important C terminus extends toward the 5' end of the 16S rRNA. In the presence of RbfA, a portion of the 16S rRNA encompassing helix 44, which is known to be directly involved in mRNA decoding and tRNA binding, is displaced. These results shed light on the role played by RbfA during maturation of the 30S subunit, and also indicate how RbfA provides cells with a translational advantage under conditions of cold shock.     

The central pseudoknot in 16S ribosomal RNA is needed for ribosome stability but is not essential for 30S initiation complex formation.

To examine the function of the central pseudoknot in 16S rRNA, we have studied Escherichia coli 30S subunits with the A18 mutation in this structure element. Previously, this mutation, which changes the central base pair of helix 2, C18--G917, to an A18xG917 mismatch, was shown to inhibit translation in vivo and a defect in initiation was suggested. Here, we find that the mutant 30S particles are impaired in forming 70S tight couples and predominantly accumulate as free 30S subunits. Formation of a 30S initiation complex, as measured by toeprinting, was almost as efficient for mutant 30S subunits, derived from the tight couple fraction, as for the wild-type control. However, the A18 mutation has a profound effect on the overall stability of the subunit. The mutant ribosomes were inactivated by affinity chromatography and high salt treatment, due to easy loss of ribosomal proteins. Accordingly, the particles could be reactivated by partial in vitro reconstitution with 30S ribosomal proteins. Mutant 30S subunits from the free subunit fraction were already inactive upon isolation, but could also be reactivated by reconstitution. Apparently, the inactivity in initiation of these mutant 30S subunits is, at least in part, also due to the lack of essential ribosomal proteins. We conclude that disruption of helix 2 of the central pseudoknot by itself does not affect the formation of a 30S initiation complex. We suggest that the in vivo translational defect of the mutant ribosomes is caused by their inability to form 70S initiation complexes.     

Functional interaction of neomycin B and related antibiotics with 30S and 50S ribosomal subunits.

Antibiotics of the neomycin, kanamycin and gentamicin, but not streptomycin, groups stabilize the GDP·elongation factor (EF) G·50S subunit·fusidic acid complex. Treatment of 30S subunits, but not of 50S subunits, with neomycin B or kanamycin B, followed by removal of excess unbound antibiotic and supplementation with untreated complementary subunits, promotes poly(U)-dependent binding of Tyr-tRNA to the reassociated ribosomes (misreading). A similar treatment of either ribosomal subunit with neomycin B inhibits the EF-G-dependent translocation of Ac-Phe-tRNA. These results suggest that interaction of neomycin B and related antibiotics with the 30S subunit induces misreading and inhibits translocation, and interaction with the 50S subunit stabilizes EF-G on the ribosome and also inhibits translocation.     

Multiple effects of S13 in modulating the strength of intersubunit interactions in the ribosome during translation

The ribosomal protein S13 is found in the head region of the small subunit, where it interacts with the central protuberance of the large ribosomal subunit and with the P site-bound tRNA through its extended C terminus. The bridging interactions between the large and small subunits are dynamic, and are thought to be critical in orchestrating the molecular motions of the translation cycle. S13 provides a direct link between the tRNA-binding site and the movements in the head of the small subunit seen during translocation, thereby providing a possible pathway of signal transduction. We have created and characterized an rpsM(S13)-deficient strain of Escherichia coli and have found significant defects in subunit association, initiation and translocation through in vitro assays of S13-deficient ribosomes. Targeted mutagenesis of specific bridge and tRNA contact elements in S13 provides evidence that these two interaction domains play critical roles in maintaining the fidelity of translation. This ribosomal protein thus appears to play a non-essential, yet important role by modulating subunit interactions in multiple steps of the translation cycle.     

The plastid-specific ribosomal proteins of Arabidopsis thaliana can be divided into non-essential proteins and genuine ribosomal proteins

Plastid translation occurs on bacterial-type 70S ribosomes consisting of a large (50S) subunit and a small (30S) subunit. The vast majority of plastid ribosomal proteins have orthologs in bacteria. In addition, plastids also possess a small set of unique ribosomal proteins, so-called plastid-specific ribosomal proteins (PSRPs). The functions of these PSRPs are unknown, but, based on structural studies, it has been proposed that they may represent accessory proteins involved in translational regulation. Here we have investigated the functions of five PSRPs using reverse genetics in the model plant Arabidopsis thaliana. By analyzing T-DNA insertion mutants and RNAi lines, we show that three PSRPs display characteristics of genuine ribosomal proteins, in that down-regulation of their expression led to decreased accumulation of the 30S or 50S subunit of the plastid ribosomes, resulting in plastid translational deficiency. In contrast, two other PSRPs can be knocked out without visible or measurable phenotypic consequences. Our data suggest that PSRPs fall into two types: (i) PSRPs that have a structural role in the ribosome and are bona fide ribosomal proteins, and (ii) non-essential PSRPs that are not required for stable ribosome accumulation and translation under standard greenhouse conditions.     

Conformation of 4.5S RNA in the signal recognition particle and on the 30S ribosomal subunit

The signal recognition particle (SRP) from Escherichia coli consists of 4.5S RNA and protein Ffh. It is essential for targeting ribosomes that are translating integral membrane proteins to the translocation pore in the plasma membrane. Independently of Ffh, 4.5S RNA also interacts with elongation factor G (EF-G) and the 30S ribosomal subunit. Here we use a cross-linking approach to probe the conformation of 4.5S RNA in SRP and in the complex with the 30S ribosomal subunit and to map the binding site. The UV-activatable cross-linker p-azidophenacyl bromide (AzP) was attached to positions 1, 21, and 54 of wild-type or modified 4.5S RNA. In SRP, cross-links to Ffh were formed from AzP in all three positions in 4.5S RNA, indicating a strongly bent conformation in which the 5' end (position 1) and the tetraloop region (including position 54) of the molecule are close to one another and to Ffh. In ribosomal complexes of 4.5S RNA, AzP in both positions 1 and 54 formed cross-links to the 30S ribosomal subunit, independently of the presence of Ffh. The major cross-linking target on the ribosome was protein S7; minor cross-links were formed to S2, S18, and S21. There were no cross-links from 4.5S RNA to the 50S subunit, where the primary binding site of SRP is located close to the peptide exit. The functional role of 4.5S RNA binding to the 30S subunit is unclear, as the RNA had no effect on translation or tRNA translocation on the ribosome.     

Selection of tRNA by the ribosome requires a transition from an open to a closed form

A structural and mechanistic explanation for the selection of tRNAs by the ribosome has been elusive. Here, we report crystal structures of the 30S ribosomal subunit with codon and near-cognate tRNA anticodon stem loops bound at the decoding center and compare affinities of equivalent complexes in solution. In ribosomal interactions with near-cognate tRNA, deviation from Watson-Crick geometry results in uncompensated desolvation of hydrogen-bonding partners at the codon-anticodon minor groove. As a result, the transition to a closed form of the 30S induced by cognate tRNA is unfavorable for near-cognate tRNA unless paromomycin induces part of the rearrangement. We conclude that stabilization of a closed 30S conformation is required for tRNA selection, and thereby structurally rationalize much previous data on translational fidelity.     

The 30S ribosomal P site: a function of 16S rRNA

The 30S ribosomal P site serves several functions in translation. It must specifically bind initiator tRNA during formation of the 30S initiation complex; bind the anticodon stem-loop of peptidyl-tRNA during the elongation phase; and help to maintain the translational reading frame when the A site is unoccupied. Early experiments provided evidence that 16S rRNA was an important component of the 30S P site. Footprinting and crosslinking studies later implicated specific nucleotides in interactions with tRNA. The crystal structures of the 30S subunit and 70S ribosome-tRNA complexes confirmed the interactions between 16S rRNA and tRNA, but also revealed contacts between tRNA and the C-terminal tails of proteins S9 and S13. Deletion of these tails now shows that the 16S rRNA contacts alone are sufficient to support protein synthesis in living cells.     

A novel single amino acid change in small subunit ribosomal protein S5 has profound effects on translational fidelity

S5 is a small subunit ribosomal protein (r-protein) linked to the functional center of the 30S ribosomal subunit. In this study we have identified a unique amino acid mutation in Escherichia coli S5 that produces spectinomycin-resistance and cold sensitivity. This mutation significantly alters cell growth, folding of 16S ribosomal RNA, and translational fidelity. While translation initiation is not affected, both +1 and -1 frameshifting and nonsense suppression are greatly enhanced in the mutant strain. Interestingly, this S5 ribosome ambiguity-like mutation is spatially remote from previously identified S5 ribosome ambiguity (ram) mutations. This suggests that the mechanism responsible for ram phenotypes in the novel mutant strain is possibly distinct from those proposed for other known S5 (and S4) ram mutants. This study highlights the importance of S5 in ribosome function and cell physiology, and suggests that translational fidelity can be regulated in multiple ways.     

Three-dimensional localization of the NH2- and carboxyl-terminal domain of ribosomal protein S1 on the surface of the 30 S subunit from Escherichia coli.

Antibodies were raised against Escherichia coli ribosomal protein S1 and its NH2- and COOH-terminal fragments, and their specificity was demonstrated by a variety of immunological techniques. These antibodies were then used to investigate the location of protein S1 and its NH2- and COOH-terminal domains on the surface of the 30 S ribosomal subunit by immunoelectron microscopy. In order to prevent dissociation of the protein during the experiments, S1 was cross-linked to 30 S subunits with dithiobis(succinimidyl-propionate); cross-linking yield was 100%. Epitopes of the NH2-terminal domain of S1 were localized at the large lobe of the 30 S ribosomal subunit, close to the one-third/two-thirds partition on the side which in the 70 S ribosome faces the cytoplasm. Experiments with monovalent Fab fragments specific for the COOH-terminal part of S1 provide evidence that the COOH-terminal domain forms an elongated structure extending at least 10 nm from the large lobe of the small subunit into the cytoplasmic space.     

Ribosomal protein S15 represses its own translation via adaptation of an rRNA-like fold within its mRNA

The 16S rRNA-binding ribosomal protein S15 is a key component in the assembly of the small ribosomal subunit in bacteria. We have shown that S15 from the extreme thermophile Thermus thermophilus represses the translation of its own mRNA in vitro, by interacting with the leader segment of its mRNA. The S15 mRNA-binding site was characterized by footprinting experiments, deletion analysis and site-directed mutagenesis. S15 binding triggers a conformational rearrangement of its mRNA into a fold that mimics the conserved three-way junction of the S15 rRNA-binding site. This conformational change masks the ribosome entry site, as demonstrated by direct competition between the ribosomal subunit and S15 for mRNA binding. A comparison of the T.thermophilus and Escherichia coli regulation systems reveals that the two regulatory mRNA targets do not share any similarity and that the mechanisms of translational inhibition are different. Our results highlight an astonishing plasticity of mRNA in its ability to adapt to evolutionary constraints, that contrasts with the extreme conservation of the rRNA-binding site.     

Interactions of the non-coding RNA DsrA and RpoS mRNA with the 30 S ribosomal subunit

Expression of sigma(s), the gene product of rpoS, is controlled translationally in response to many environmental stresses. DsrA, a small 87-nucleotide non-coding RNA molecule, acts to increase translational efficiency of RpoS mRNA under some growth conditions. In this work, we demonstrate that DsrA binds directly to the 30 S ribosomal subunit with an observed equilibrium affinity of 2.8 x 10(7) m(-1). DsrA does not compete with RpoS mRNA or tRNA(f)(Met) for binding to the 30 S subunit. The 5' end of DsrA binds to 30 S subunits with an observed equilibrium association constant of 2.0 x 10(6) m(-1), indicating that the full affinity of the interaction requires the entire DsrA sequence. In order to investigate translational efficiency of RpoS mRNA, we examined both ribosome-binding site accessibility and the binding of RpoS mRNA to 30 S ribosomal subunits. We find that that ribosome-binding site accessibility is modulated as a function of divalent cation concentration during mRNA renaturation and by the presence of an antisense sequence that binds to nucleotides 1-16 of the RpoS mRNA fragment. The ribosome-binding site accessibility correlates with the amount of RpoS mRNA participating in 30 S-mRNA "pre-initiation" translational complex formation and provides evidence that regulation follows a competitive model of regulation.