mRNA Exit Channel Research Articles

The structure of a human translation initiation complex reveals two independent roles for the helicase eIF4A

Eukaryotic translation initiation involves recruitment of the 43S pre-initiation complex to the 5′ end of mRNA by the cap-binding complex eIF4F, forming the 48S translation initiation complex (48S), which then scans along the mRNA until the start codon is recognized. We have previously shown that eIF4F binds near the mRNA exit channel of the 43S, leaving open the question of how mRNA secondary structure is removed as it enters the mRNA channel on the other side of the 40S subunit. Here we report the structure of a human 48S that shows that, in addition to the eIF4A that is part of eIF4F, there is a second eIF4A helicase bound at the mRNA entry site, which could unwind RNA secondary structures as they enter the 48S. The structure also reveals conserved interactions between eIF4F and the 43S, probaby explaining how eIF4F can promote mRNA recruitment in all eukaryotes.

Abstract P-21: The Investigation of S.aureus Ribosome-Binding Factor A Localization on the 30S Ribosomal Subunit by Cryo-Electron Microscopy

Background: Ribosome biogenesis is a complex process of ribosomal RNA and protein binding. Bacterial ribosome maturation and components involved in it are especially interesting, because they are widespread targets for antibiotics. A number of special protein factors facilitating the maturation of the 30S small ribosomal subunit are known. One of them is a ribosome-binding factor A (RbfA). This is a small (~14 kDa) protein with KH-domain organization distinguishing RNA binding proteins. Recent cryo-EM reconstruction of E.coli 30S-RbfA complex indicates that RbfA binds to 30S subunit on the central decoding region and promotes the switch from the immature state of h28 (neck) to mature state. RbfA interacts with 3`-end of 16S rRNA on mRNA exit channel and stabilizes the conformation of the region between h28, h44/h45 linker and 3`-end. Methods: Pure S.aureus RbfA was obtained by homologous expression in E.coli BL21 strain followed by Ni-NTA and gel filtration. The 30S subunits were obtained by dissociation of the S.aureus 70S ribosomes in a sucrose gradient (0-30%). We performed 30S subunit and RbfA complex reconstitution, sample and grid preparation. Data was collected on Talos Arctica, Falcon 2 detector (FEI Company/Thermo Fisher). Results: The 30S-RbfA complex density map with average resolution ~ 3.5 Å (FSC=0.143) was obtained. In comparison with the free subunit map (EMD 23052) we observed an extra density on the neck region near the decoding center region. Conclusion: Obtained data is correlated with recent structural results of the homologous E.coli RbfA. We consider that S.aureus RbfA binds to the 30S subunit at the same region. The next step of our structural research is building the model of S.aureus 30S-RbfA complex.

Communication between RACK1/Asc1 and uS3 (Rps3) is essential for RACK1/Asc1 function in yeast Saccharomyces cerevisiae

The receptor for activated c-kinase (RACK1, Asc1 in yeast) is a eukaryotic ribosomal protein located in the head region of the 40S subunit near the mRNA exit channel. This WD-repeat β-propeller protein acts as a signaling molecule and is involved in metabolic regulation, cell cycle progression, and translational control. However, the exact details of the RACK1 recruitment and stable association with the 40S ribosomal subunit remain only partially known. X-ray analyses of the yeast, Saccharomyces cerevisiae, ribosome revealed that the RACK1 propeller blade (4–5) interacts with the eukaryote-specific C-terminal domain (CTD) of ribosomal protein S3 (uS3 family). To check the functional significance of this interaction, we generated mutant yeast strains harboring C-terminal deletions of uS3. We found that deletion of the 20 C-terminal residues (interacting with blade 4–5) from the uS3-CTD abrogates RACK1 binding to the ribosome. Strains with truncated uS3-CTD exhibited compromised cellular growth and protein synthesis similar to that of RACK1Δ strain, thus suggesting that the uS3-CTD is crucial not only for the recruitment and association of RACK1 with the ribosome, but also for its intracellular function. We suggest that eukaryote-specific RACK1-uS3 interaction has evolved to act as a link between the ribosome and the cellular signaling pathways.

RACK1 Specifically Regulates Translation through Its Binding to Ribosomes.

The translational capability of ribosomes deprived of specific nonfundamental ribosomal proteins may be altered. Physiological mechanisms are scanty, and it is unclear whether free ribosomal proteins can cross talk with the signaling machinery. RACK1 (receptor for activated C kinase 1) is a highly conserved scaffold protein, located on the 40S subunit near the mRNA exit channel. RACK1 is involved in a variety of intracellular contexts, both on and off the ribosomes, acting as a receptor for proteins in signaling, such as the protein kinase C (PKC) family. Here we show that the binding of RACK1 to ribosomes is essential for full translation of capped mRNAs and efficient recruitment of eukaryotic initiation factor 4E (eIF4E). In vitro, when RACK1 is partially depleted, supplementing the ribosome machinery with wild-type RACK1 restores the translational capability, whereas the addition of a RACK1 mutant that is unable to bind ribosomes does not. Outside the ribosome, RACK1 has a reduced half-life. By accumulating in living cells, free RACK1 exerts an inhibitory phenotype, impairing cell cycle progression and repressing global translation. Here we present RACK1 binding to ribosomes as a crucial way to regulate translation, possibly through interaction with known partners on or off the ribosome that are involved in signaling.

Structures of translationally inactive mammalian ribosomes

The cellular levels and activities of ribosomes directly regulate gene expression during numerous physiological processes. The mechanisms that globally repress translation are incompletely understood. Here, we use electron cryomicroscopy to analyze inactive ribosomes isolated from mammalian reticulocytes, the penultimate stage of red blood cell differentiation. We identify two types of ribosomes that are translationally repressed by protein interactions. The first comprises ribosomes sequestered with elongation factor 2 (eEF2) by SERPINE mRNA binding protein 1 (SERBP1) occupying the ribosomal mRNA entrance channel. The second type are translationally repressed by a novel ribosome-binding protein, interferon-related developmental regulator 2 (IFRD2), which spans the P and E sites and inserts a C-terminal helix into the mRNA exit channel to preclude translation. IFRD2 binds ribosomes with a tRNA occupying a noncanonical binding site, the 'Z site', on the ribosome. These structures provide functional insights into how ribosomal interactions may suppress translation to regulate gene expression.

Critical Role for Saccharomyces cerevisiae Asc1p in Translational Initiation at Elevated Temperatures.

The eukaryotic ribosomal protein RACK1/Asc1p is localized to the mRNA exit channel of the 40S subunit but lacks a defined role in mRNA translation. Saccharomyces cerevisiae deficient in ASC1 exhibit temperature-sensitive growth. Using this null mutant, potential roles for Asc1p in translation and ribosome biogenesis are evaluated. At the restrictive temperature the asc1Δ null mutant has reduced polyribosomes. To test the role of Asc1p in ribosome stability, cryo-EM is used to examine the structure of 80S ribosomes in an asc1Δ yeast deletion mutant at both the permissive and nonpermissive temperatures. CryoEM indicates that loss of Asc1p does not severely disrupt formation of this complex structure. No defect is found in rRNA processing in the asc1Δ null mutant. A proteomic approach is applied to survey the effect of Asc1p loss on the global translation of yeast proteins. At the nonpermissive temperature, the asc1Δ mutant has reduced levels of ribosomal proteins and other factors critical for translation. Collectively, these results are consistent with recent observations suggesting that Asc1p is important for ribosome occupancy of short mRNAs. The results show the Asc1 ribosomal protein is critical in translation during heat stress.

Abstract 1914: Elongation factor 2: A novel target for cancer progression

Abstract Protein translation is one the most energy demanding and highly regulated processes in cells. For this reason, dysregulation of protein synthesis is linked with different types of disease, including cancer. The link between protein synthesis and cancer progression is becoming a central theme among cancer research. Although numerous studies have identified protein synthesis as a process central to cancer progression, further research is required to identify potential novel targets and/or biomarkers. Recently, RACK1 (Receptor for Activated C Kinase 1), a scaffold protein involved in many cell regulatory pathways including cell proliferation and migration, has been found to be part of the ribosomal machinery. Here, RACK1 is able to regulate the synthesis of particular sets of proteins and the translation itself. In fact, RACK1 is located close the mRNA exit channel where is able to recruit kinases, phosphatases and specific mRNA binding proteins. We have identified elongation factor 2 (eEF2) as novel RACK1 interacting protein in our two and three dimensional colon cancer models. Elongation factor 2 is one of the main proteins regulating the elongation phase of protein synthesis, responsible for the translocation of the mRNA along the ribosome. We have confirmed the binding between eEF2 and RACK1 by isolating and purifying a native human form of eEF2 and combining it with a purified human version of RACK1. Interestingly, we have demonstrated that stress conditions and IGF-1 stimulation modulate eEF2 activity in colon cancer cells. Moreover, we have examined the expression of EEF2 and have found that EEF2 gene is dysregulated in our cohort of matched normal and cancer colonic patient tissues. Interestingly, EEF2 expression is upregulated in mucinous cancers (a rare and aggressive type of colorectal cancer) compared to non-mucinous cancers and the expression of EEF2 is as well upregulated in cancers that have recurred within 2 to 3 years after the first surgery. We believe that eEF2 is playing an important role in cancer progression and migration especially by regulating and modulating protein synthesis in certain conditions. A better understanding of the role of this protein will help in the identification of novel targets that can be then translated into therapeutic strategies against colorectal cancer. Citation Format: Beatrice Malacrida, Catríona M. Dowling, Rasmus K. Flygaard, Maeve Kiely, John C. Coffey, Lasse B. Jenner, Patrick A. Kiely. Elongation factor 2: A novel target for cancer progression [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr 1914.

Structural dynamics of protein S1 on the 70S ribosome visualized by ensemble cryo-EM.

Bacterial ribosomal protein S1 is the largest and highly flexible protein of the 30S subunit, and one of a few core ribosomal proteins for which a complete structure is lacking. S1 is thought to participate in transcription and translation. Best understood is the role of S1 in facilitating translation of mRNAs with structured 5' UTRs. Here, we present cryo-EM analyses of the 70S ribosome that reveal multiple conformations of S1. Based on comparison of several 3D maximum likelihood classification approaches in Frealign, we propose a streamlined strategy for visualizing a highly dynamic component of a large macromolecular assembly that itself exhibits high compositional and conformational heterogeneity. The resulting maps show how S1 docks at the ribosomal protein S2 near the mRNA exit channel. The globular OB-fold domains sample a wide area around the mRNA exit channel and interact with mobile tails of proteins S6 and S18. S1 also interacts with the mRNA entrance channel, where an OB-fold domain can be localized near S3 and S5. Our analyses suggest that S1 cooperates with other ribosomal proteins to form a dynamic mesh near the mRNA exit and entrance channels to modulate the binding, folding and movement of mRNA.

Abstract 4485: Identification and characterization of novel RACK1 binding partners that may modulate the elongation phase of protein synthesis

Abstract RACK1 (Receptor for Activated C Kinase 1) is a member of the tryptophan-aspartate (WD-repeat) family of proteins. By functioning as a scaffold protein, RACK1 is involved in regulating many different signalling pathways in cells, including cell proliferation and cell migration. Interestingly, RACK1 has been identified as a central component of the ribosomal machinery, specifically located on the 40S ribosomal subunit close to the mRNA exit channel where it makes contact with other ribosomal proteins. Importantly, it is believed that in this position, RACK1 can recruit a series of kinases and phosphatases as well as functioning to regulate the translation and the synthesis of particular cohorts of proteins. Moreover, RACK1 plays a central role in influencing the location of the translation machinery. Using 2D and 3D models of colon cancer cell lines, together with Click-IT chemistry and Mass Spectrometry analysis, we were able to identify a series of proteins, including newly synthesized proteins, that interact with RACK1. We identified proteins involved in cell cycle control, metabolism and protein synthesis. As expected, we have found a number of proteins that are involved in cell migration and a number of proteins that are mediators of the cell adhesion process. Interestingly, some of the most highly scored interacting proteins were those involved in protein synthesis. Of those, we identified several elongation factors as being novel RACK1 binding partners. Elongation factors are a class of proteins directly involved in the elongation phase of protein synthesis. Along with this primary function, these factors have different important roles in cells, such as influencing cytoskeleton remodelling and activation of growth and proliferation pathways. Elongation factors have been found to be upregulated in many different types of cancer. We have confirmed the interaction between RACK1 and several of these elongation factors and we have determined that many of these are dysregulated in colon cancer. We have established that the activity of these elongation factors is regulated by a combination of stress conditions and growth factor stimulations. We have determined that RACK1 plays a central role in scaffolding these proteins to promote proliferation and migration in our colon cancer cell models. Collectively, these results provide a novel and interesting role for RACK1 in the modulation of the elongation phase of protein synthesis. We are now investigating the subcellular location of these factors in response to different stimuli and asking how is RACK1 involved in their localization downstream of IGF-I and integrin signalling. Characterizing and mapping the interaction between these proteins and RACK1, both in cells and tissue, may lead to the design of novel therapeutic approaches in colon cancer. Citation Format: Beatrice Malacrida, Rasmus K. Flygaard, Catríona M. Dowling, John C. Coffey, Lasse B. Jenner, Patrick A. Kiely. Identification and characterization of novel RACK1 binding partners that may modulate the elongation phase of protein synthesis [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 4485. doi:10.1158/1538-7445.AM2017-4485

The β-hairpin of 40S exit channel protein Rps5/uS7 promotes efficient and accurate translation initiation in vivo.

The eukaryotic 43S pre-initiation complex bearing tRNAi(Met) scans the mRNA leader for an AUG start codon in favorable context. Structural analyses revealed that the β-hairpin of 40S protein Rps5/uS7 protrudes into the 40S mRNA exit-channel, contacting the eIF2∙GTP∙Met-tRNAi ternary complex (TC) and mRNA context nucleotides; but its importance in AUG selection was unknown. We identified substitutions in β-strand-1 and C-terminal residues of yeast Rps5 that reduced bulk initiation, conferred 'leaky-scanning' of AUGs; and lowered initiation fidelity by exacerbating the effect of poor context of the eIF1 AUG codon to reduce eIF1 abundance. Consistently, the β-strand-1 substitution greatly destabilized the 'PIN' conformation of TC binding to reconstituted 43S·mRNA complexes in vitro. Other substitutions in β-hairpin loop residues increased initiation fidelity and destabilized PIN at UUG, but not AUG start codons. We conclude that the Rps5 β-hairpin is as crucial as soluble initiation factors for efficient and accurate start codon recognition.

34 Cyo-EM visualization of Mycobacterium 70S ribosome reveals unique structural components at the function sites

The 3D structures of prokaryotic and eukaryotic ribosomes by crystallography and electron microscopy have revealed that they share an evolutionarily conserved core (Schmeing & Ramakrishnan, 2009), but each of the ribosomes contains its own set of specific proteins (or extensions of conserved proteins) and expansion segments of rRNAs (Melnikov et al., 2012). How these differences correlate to function still remains largely unknown. A 3D cryo-EM map of the 70S ribosome from Mycobacterium smegmatis (Msm70S) unveiled striking new structural features (Shasmal & Sengupta, 2012). The core of the Msm70S shows overall similarity with the core of the Escherichia coli 70S ribosome while containing additional mass in the periphery and solvent exposed sides. Some of the Mycobacterium ribosomal proteins are significantly bigger as compared to the E. coli counter parts. The rRNAs also contain extra helices, also revealed by their secondary structures. Most of the additional density of the Msm70S can be largely attributed to the extra helices present in the rRNAs, and extra domains of homologous proteins. One of the most notable features appears in the large subunit near L1 stalk as a structure forming a long helix with its upper end located in the vicinity of the mRNA exit channel (which we term the ‘steeple’). We propose that the prominent helical structure in mycobacterium 23S rRNA participates in modulating different steps of translation, especially the E site tRNA exit mechanism and propagation of mRNA 5′ end.

Small Ribosomal Protein RPS0 Stimulates Translation Initiation by Mediating 40S-Binding of eIF3 via Its Direct Contact with the eIF3a/TIF32 Subunit

The ribosome translates information encoded by mRNAs into proteins in all living cells. In eukaryotes, its small subunit together with a number of eukaryotic initiation factors (eIFs) is responsible for locating the mRNA's translational start to properly decode the genetic message that it carries. This multistep process requires timely and spatially coordinated placement of eIFs on the ribosomal surface. In our long-standing pursuit to map the 40S-binding site of one of the functionally most complex eIFs, yeast multisubunit eIF3, we identified several interactions that placed its major body to the head, beak and shoulder regions of the solvent-exposed side of the 40S subunit. Among them is the interaction between the N-terminal domain (NTD) of the a/TIF32 subunit of eIF3 and the small ribosomal protein RPS0A, residing near the mRNA exit channel. Previously, we demonstrated that the N-terminal truncation of 200 residues in tif32-Δ8 significantly reduced association of eIF3 and other eIFs with 40S ribosomes in vivo and severely impaired translation reinitiation that eIF3 ensures. Here we show that not the first but the next 200 residues of a/TIF32 specifically interact with RPS0A via its extreme C-terminal tail (CTT). Detailed analysis of the RPS0A conditional depletion mutant revealed a marked drop in the polysome to monosome ratio suggesting that the initiation rates of cells grown under non-permissive conditions were significantly impaired. Indeed, amounts of eIF3 and other eIFs associated with 40S subunits in the pre-initiation complexes in the RPS0A-depleted cells were found reduced; consistently, to the similar extent as in the tif32-Δ8 cells. Similar but less pronounced effects were also observed with the viable CTT-less mutant of RPS0A. Together we conclude that the interaction between the flexible RPS0A-CTT and the residues 200–400 of the a/TIF32-NTD significantly stimulates attachment of eIF3 and its associated eIFs to small ribosomal subunits in vivo.

Structural Diversity in Bacterial Ribosomes: Mycobacterial 70S Ribosome Structure Reveals Novel Features

Here we present analysis of a 3D cryo-EM map of the 70S ribosome from Mycobacterium smegmatis, a saprophytic cousin of the etiological agent of tuberculosis in humans, Mycobacterium tuberculosis. In comparison with the 3D structures of other prokaryotic ribosomes, the density map of the M. smegmatis 70S ribosome reveals unique structural features and their relative orientations in the ribosome. Dramatic changes in the periphery due to additional rRNA segments and extra domains of some of the peripheral ribosomal proteins like S3, S5, S16, L17, L25, are evident. One of the most notable features appears in the large subunit near L1 stalk as a long helical structure next to helix 54 of the 23S rRNA. The sharp upper end of this structure is located in the vicinity of the mRNA exit channel. Although the M. smegmatis 70S ribosome possesses conserved core structure of bacterial ribosome, the new structural features, unveiled in this study, demonstrates diversity in the 3D architecture of bacterial ribosomes. We postulate that the prominent helical structure related to the 23S rRNA actively participates in the mechanisms of translation in mycobacteria.

Bypassing of stems versus linear base-by-base inspection of mammalian mRNAs during ribosomal scanning

Initiation codon selection in eukaryotes involves base-by-base inspection of the 5'-untranslated region of mRNA by scanning ribosomal 43S preinitiation complexes. We employed in vitro reconstitution to investigate factor requirements for this process and report that in the absence of eIF1 and DHX29, eIFs 4A, 4B and 4G promote efficient bypassing of stable stems by scanning 43S complexes and formation of 48S initiation complexes on AUG codons immediately upstream and downstream of such stems, without their unwinding. However, intact stems are not threaded through the entire mRNA Exit channel of the 40S subunit, resulting in incorrect positioning of mRNA upstream of the ribosomal P site in 48S complexes formed on AUG codons following intact stems, which renders them susceptible to dissociation by eIF1. In 48S complexes formed on AUG codons preceding intact stems, the stems are accommodated in the A site. Such aberrant complexes are destabilized by DHX29, which also ensures that mRNA enters the mRNA-binding cleft in a single-stranded form and therefore undergoes base-by-base inspection during scanning.

PKCβII modulates translation independently from mTOR and through RACK1

RACK1 (receptor for activated C kinase 1) is an abundant scaffolding protein, which binds active PKCbetaII (protein kinase C betaII) increasing its activity in vitro. RACK1 has also been described as a component of the small ribosomal subunit, in proximity to the mRNA exit channel. In the present study we tested the hypothesis that PKCbetaII plays a specific role in translational control and verified whether it may associate with the ribosomal machinery. We find that specific inhibition of PKCbetaI/II reduces translation as well as global PKC inhibition, but without affecting phosphorylation of mTOR (mammalian target of rapamycin) targets. These results suggest that PKCbetaII acts as a specific PKC isoform affecting translation in an mTOR-independent fashion, possibly close to the ribosomal machinery. Using far-Western analysis, we found that PKCbetaII binds ribosomes in vitro. Co-immunoprecipitation studies indicate that a small but reproducible pool of PKCbetaII is associated with membranes containing ribosomes, suggesting that in vivo PKCbetaII may also physically interact with the ribosomal machinery. Polysomal profiles show that stimulation of PKC results in an increased polysomes/80S ratio, associated with a shift of PKCbetaII to the heavier part of the gradient. A RACK1-derived peptide that inhibits the binding of active PKCbetaII to RACK1 reduces the polysomes/80S ratio and methionine incorporation, suggesting that binding of PKCbetaII to RACK1 is important for PKC-mediated translational control. Finally, down-regulation of RACK1 by siRNA (small interfering RNA) impairs the PKC-mediated increase of translation. Taken together the results of the present study show that PKCbetaII can act as a specific PKC isoform regulating translation, in an mTOR-independent fashion, possibly close to the ribosomal machinery.

EIF3a cooperates with sequences 5′ of uORF1 to promote resumption of scanning by post-termination ribosomes for reinitiation on GCN4 mRNA

Yeast initiation factor eIF3 (eukaryotic initiation factor 3) has been implicated in multiple steps of translation initiation. Previously, we showed that the N-terminal domain (NTD) of eIF3a interacts with the small ribosomal protein RPS0A located near the mRNA exit channel, where eIF3 is proposed to reside. Here, we demonstrate that a partial deletion of the RPS0A-binding domain of eIF3a impairs translation initiation and reduces binding of eIF3 and associated eIFs to native preinitiation complexes in vivo. Strikingly, it also severely blocks the induction of GCN4 translation that occurs via reinitiation. Detailed examination unveiled a novel reinitiation defect resulting from an inability of 40S ribosomes to resume scanning after terminating at the first upstream ORF (uORF1). Genetic analysis reveals a functional interaction between the eIF3a-NTD and sequences 5' of uORF1 that is critically required to enhance reinitiation. We further demonstrate that these stimulatory sequences must be positioned precisely relative to the uORF1 stop codon and that reinitiation efficiency after uORF1 declines with its increasing length. Together, our results suggest that eIF3 is retained on ribosomes throughout uORF1 translation and, upon termination, interacts with its 5' enhancer at the mRNA exit channel to stabilize mRNA association with post-termination 40S subunits and enable resumption of scanning for reinitiation downstream.

The structure of the 80S ribosome from Trypanosoma cruzi reveals unique rRNA components

We present analysis, by cryo-electron microscopy and single-particle reconstruction, of the structure of the 80S ribosome from Trypanosoma cruzi, the kinetoplastid protozoan pathogen that causes Chagas disease. The density map of the T. cruzi 80S ribosome shows the phylogenetically conserved eukaryotic rRNA core structure, together with distinctive structural features in both the small and large subunits. Remarkably, a previously undescribed helical structure appears in the small subunit in the vicinity of the mRNA exit channel. We propose that this rRNA structure likely participates in the recruitment of ribosome onto the 5' end of mRNA, in facilitating and modulating the initiation of translation that is unique to the trypanosomes.

Identification of the versatile scaffold protein RACK1 on the eukaryotic ribosome by cryo-EM.

RACK1 serves as a scaffold protein for a wide range of kinases and membrane-bound receptors. It is a WD-repeat family protein and is predicted to have a beta-propeller architecture with seven blades like a Gbeta protein. Mass spectrometry studies have identified its association with the small subunit of eukaryotic ribosomes and, most recently, it has been shown to regulate initiation by recruiting protein kinase C to the 40S subunit. Here we present the results of a cryo-EM study of the 80S ribosome that positively locate RACK1 on the head region of the 40S subunit, in the immediate vicinity of the mRNA exit channel. One face of RACK1 exposes the WD-repeats as a platform for interactions with kinases and receptors. Using this platform, RACK1 can recruit other proteins to the ribosome.

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.