Three-dimensional structure of the mammalian cytoplasmic ribosome

A three-dimensional reconstruction of the 80 S ribosome from rabbit reticulocytes has been calculated from low-dose electron micrographs of a negatively stained single-particle specimen. At 37 A resolution, the precise orientations of the 40 S and 60 S subunits within the monosome can be discerned. The translational domain centered on the upper portion of the subunit/subunit interface is quite open, allowing considerable space between the subunits for interactions with the non-ribosomal macromolecules involved in protein synthesis. Further, the cytosolic side of the monosome is strikingly more open than the membrane-attachment side, suggesting a greater ease of communication with the cytoplasm, which would facilitate the inwards and outwards diffusion of a number of ligands. Although the 60 S subunit portion of the 80 S structure shows essentially all of the major morphological features identified for the eubacterial 50 S large subunit, it appears to possess a region of additional mass that evidently accounts for the more ellipsoidal form of the eukaryotic subunit.     

Three-dimensional reconstruction of the 70S Escherichia coli ribosome in ice: the distribution of ribosomal RNA

A reconstruction, at 40 A, of the Escherichia coli ribosome imaged by cryo-electron microscopy, obtained from 303 projections by a single-particle method of reconstruction, shows the two subunits with unprecedented clarity. In the interior of the subunits, a complex distribution of higher mass density is recognized, which is attributed to ribosomal RNA. The masses corresponding to the 16S and 23S components are linked in the region of the platform of the small subunit. Thus the topography of the rRNA regions responsible for protein synthesis can be described.     

Eukaryotic initiation factor 3 does not prevent association through physical blockage of the ribosomal subunit-subunit interface.

The "native" 40 S ribosomal subunit, in which the protein eukaryotic initiation factor 3 is bound to the 40 S small ribosomal subunit, has been reconstructed to 48 A resolution. Comparison with a previous three-dimensional reconstruction of the "derived" 40 S subunit lacking any non-ribosomal components reveals the attachment site and morphology of the factor. It is a large (approximately 165 to 170 A long), bilobed, elongate structure, attached to the back lobes of the 40 S subunit by two strand-like features. Significantly, the factor is oriented away from the 60 S-subunit-40 S-subunit interface surface of the 40 S particle, suggesting that its anti-association activity is not accomplished via simple physical blockage of that surface.     

Three-dimensional structure of the large ribosomal subunit from Escherichia coli.

The three-dimensional structure of the large (50S) ribosomal subunit from Escherichia coli has been determined from electron micrographs of negatively stained specimens. A new method of three-dimensional reconstruction was used which combines many images of individual subunits recorded at a single high tilt angle. A prominent feature of the reconstruction is a large groove on the side of the subunit that interacts with the small ribosomal subunit. This feature is probably of functional significance as it includes the regions where the peptidyl transferase site and the binding locations of the elongation factors have been mapped previously by immunoelectron microscopy.     

Haloarcula marismortui 50S subunit-complementarity of electron microscopy and X-Ray crystallographic information

The large 50S subunit of the Haloarcula marismortui 70S ribosome was solved to 19 A using cryo-electron microscopy and single particle reconstruction techniques and to 9 A using X-ray crystallography. In the latter case, phases were determined by multiple isomorphous replacement and anomalous scattering from three heavy atom derivatives. The availability of X-ray and electron microscopy (EM) data has made it possible to compare the results of the two experimental methods. In the flexible regions of the 50S subunit, small differences in the mass distribution were detected. These differences can be attributed to the influence of packing in the crystal cell. The rotationally averaged power spectra of X-ray and EM were compared in an overlapping spatial frequency range from 60 to 13 A. The resulting ratio of X-ray to EM power ranges from 1 to 15, reflecting a progressively larger underestimation of the Fourier amplitudes by the electron microscope.     

Characterization of the nuclear export adaptor protein Nmd3 in association with the 60S ribosomal subunit

The nucleocytoplasmic shuttling protein Nmd3 is an adaptor for export of the 60S ribosomal subunit from the nucleus. Nmd3 binds to nascent 60S subunits in the nucleus and recruits the export receptor Crm1 to facilitate passage through the nuclear pore complex. In this study, we present a cryoelectron microscopy (cryo-EM) reconstruction of the 60S subunit in complex with Nmd3 from Saccharomyces cerevisiae. The density corresponding to Nmd3 is directly visible in the cryo-EM map and is attached to the regions around helices 38, 69, and 95 of the 25S ribosomal RNA (rRNA), the helix 95 region being adjacent to the protein Rpl10. We identify the intersubunit side of the large subunit as the binding site for Nmd3. rRNA protection experiments corroborate the structural data. Furthermore, Nmd3 binding to 60S subunits is blocked in 80S ribosomes, which is consistent with the assigned binding site on the subunit joining face. This cryo-EM map is a first step toward a molecular understanding of the functional role and release mechanism of Nmd3.     

Native 3D structure of eukaryotic 80s ribosome: morphological homology with E. coli 70S ribosome

A three-dimensional reconstruction of the eukaryotic 80S monosome from a frozen-hydrated electron microscopic preparation reveals the native structure of this macromolecular complex. The new structure, at 38A resolution, shows a marked resemblance to the structure determined for the E. coli 70S ribosome (Frank, J., A. Verschoor, Y. Li, J. Zhu, R.K. Lata, M. Radermacher, P. Penczek, R. Grassucci, R.K. Agrawal, and Srivastava. 1996b. In press; Frank, J., J. Zhu, P. Penczek, Y. Li, S. Srivastava ., A. Verschoor, M. Radermacher, R. Grassucci, R.K. Lata, and R. Agrawal. 1995. Nature (Lond.).376:441-444.) limited to a comparable resolution, but with a number of eukaryotic elaborations superimposed. Although considerably greater size and intricacy of the features is seen in the morphology of the large subunit (60S vs 50S), the most striking differences are in the small subunit morphology (40S vs 30S): the extended beak and crest features of the head, the back lobes, and the feet. However, the structure underlying these extra features appears to be remarkably similar in form to the 30S portion of the 70S structure. The intersubunit space also appears to be strongly conserved, as might be expected from the degree of functional conservation of the ribosome among kingdoms (Eukarya, Eubacteria, and Archaea). The internal organization of the 80S structure appears as an armature or core of high-density material for each subunit, with the two cores linked by a single bridge between the platform region of the 40S subunit and the region below the presumed peptidyltransferase center of the 60S subunit. This may be equated with a close contact of the 18S and 28S rRNAs in the translational domain centered on the upper subunit:subunit interface.     

Structure and structural variations of the Escherichia coli 30 S ribosomal subunit as revealed by three-dimensional cryo-electron microscopy

A three-dimensional reconstruction of the 30 S subunit of the Escherichia coli ribosome was obtained at 23 A resolution. Because of the improved resolution, many more structural details are seen as compared to those obtained in earlier studies. Thus, the new structure is more suitable for comparison with the 30 S subunit part of the 70 S ribosome, whose structure is already known at a better resolution. In addition, we observe relative and, to some extent, independent movements of three main structural domains of the 30 S subunit, namely head, platform and the main body, which lead to partial blurring of the reconstructed volume. An attempt to subdivide the data set into conformationally defined subsets reveals the existence of conformers in which these domains have different orientations with respect to one another. This result suggests the existence of dynamic properties of the 30 S subunit that might be required for facilitating its interactions with mRNA, tRNA and other ligands during protein biosynthesis.     

Visualization of the eEF2-80S ribosome transition-state complex by cryo-electron microscopy

In an attempt to understand ribosome-induced GTP hydrolysis on eEF2, we determined a 12.6-Å cryo-electron microscopy reconstruction of the eEF2-bound 80S ribosome in the presence of aluminum tetrafluoride and GDP, with aluminum tetrafluoride mimicking the γ-phosphate during hydrolysis. This is the first visualization of a structure representing a transition-state complex on the ribosome. Tight interactions are observed between the factor's G domain and the large ribosomal subunit, as well as between domain IV and an intersubunit bridge. In contrast, some of the domains of eEF2 implicated in small subunit binding display a large degree of flexibility. Furthermore, we find support for a transition-state model conformation of the switch I region in this complex where the reoriented switch I region interacts with a conserved rRNA region of the 40S subunit formed by loops of the 18S RNA helices 8 and 14. This complex is structurally distinct from the eEF2-bound 80S ribosome complexes previously reported, and analysis of this map sheds light on the GTPase-coupled translocation mechanism.     

Structure of a human pre-40S particle points to a role for RACK1 in the final steps of 18S rRNA processing

Synthesis of ribosomal subunits in eukaryotes is a complex and tightly regulated process that has been mostly characterized in yeast. The discovery of a growing number of diseases linked to defects in ribosome biogenesis calls for a deeper understanding of these mechanisms and of the specificities of human ribosome maturation. We present the 19 Å resolution cryo-EM reconstruction of a cytoplasmic precursor to the human small ribosomal subunit, purified by using the tagged ribosome biogenesis factor LTV1 as bait. Compared to yeast pre-40S particles, this first three-dimensional structure of a human 40S subunit precursor shows noticeable differences with respect to the position of ribosome biogenesis factors and uncovers the early deposition of the ribosomal protein RACK1 during subunit maturation. Consistently, RACK1 is required for efficient processing of the 18S rRNA 3′-end, which might be related to its role in translation initiation. This first structural analysis of a human pre-ribosomal particle sets the grounds for high-resolution studies of conformational transitions accompanying ribosomal subunit maturation.     

Ribosome-DnaK interactions in relation to protein folding

Bacterial ribosomes or their 50S subunit can refold many unfolded proteins. The folding activity resides in domain V of 23S RNA of the 50S subunit. Here we show that ribosomes can also refold a denatured chaperone, DnaK, in vitro, and the activity may apply in the folding of nascent DnaK polypeptides in vivo. The chaperone was unusual as the native protein associated with the 50S subunit stably with a 1:1 stoichiometry in vitro. The binding site of the native protein appears to be different from the domain V of 23S RNA, the region with which denatured proteins interact. The DnaK binding influenced the protein folding activity of domain V modestly. Conversely, denatured protein binding to domain V led to dissociation of the native chaperone from the 50S subunit. DnaK thus appears to depend on ribosomes for its own folding, and upon folding, can rebind to ribosome to modulate its general protein folding activity.     

Localization of L11 protein on the ribosome and elucidation of its involvement in EF-G-dependent translocation

L11 protein is located at the base of the L7/L12 stalk of the 50 S subunit of the Escherichia coli ribosome. Because of the flexible nature of the region, recent X-ray crystallographic studies of the 50 S subunit failed to locate the N-terminal domain of the protein. We have determined the position of the complete L11 protein by comparing a three-dimensional cryo-EM reconstruction of the 70 S ribosome, isolated from a mutant lacking ribosomal protein L11, with the three-dimensional map of the wild-type ribosome. Fitting of the X-ray coordinates of L11-23 S RNA complex and EF-G into the cryo-EM maps combined with molecular modeling, reveals that, following EF-G-dependent GTP hydrolysis, domain V of EF-G intrudes into the cleft between the 23 S ribosomal RNA and the N-terminal domain of L11 (where the antibiotic thiostrepton binds), causing the N-terminal domain to move and thereby inducing the formation of the arc-like connection with the G' domain of EF-G. The results provide a new insight into the mechanism of EF-G-dependent translocation.     

Conformational variability in Escherichia coli 70S ribosome as revealed by 3D cryo-electron microscopy

During protein biosynthesis, ribosomes are believed to go through a cycle of conformational transitions. We have identified some of the most variable regions of the E. coli 70S ribosome and its subunits, by means of cryo-electron microscopy and three-dimensional (3D) reconstruction. Conformational changes in the smaller 30S subunit are mainly associated with the functionally important domains of the subunit, such as the neck and the platform, as seen by comparison of heat-activated, non-activated and 50S-bound states. In the larger 50S subunit the most variable regions are the L7/L12 stalk, central protuberance and the L1-protein, as observed in various tRNA-70S ribosome complexes. Difference maps calculated between 3D maps of ribosomes help pinpoint the location of ribosomal regions that are most strongly affected by conformational transitions. These results throw direct light on the dynamic behavior of the ribosome and help in understanding the role of these flexible domains in the translation process.     

The Cryo-EM structure of a complete 30S translation initiation complex from Escherichia coli

Formation of the 30S initiation complex (30S IC) is an important checkpoint in regulation of gene expression. The selection of mRNA, correct start codon, and the initiator fMet-tRNA(fMet) requires the presence of three initiation factors (IF1, IF2, IF3) of which IF3 and IF1 control the fidelity of the process, while IF2 recruits fMet-tRNA(fMet). Here we present a cryo-EM reconstruction of the complete 30S IC, containing mRNA, fMet-tRNA(fMet), IF1, IF2, and IF3. In the 30S IC, IF2 contacts IF1, the 30S subunit shoulder, and the CCA end of fMet-tRNA(fMet), which occupies a novel P/I position (P/I1). The N-terminal domain of IF3 contacts the tRNA, whereas the C-terminal domain is bound to the platform of the 30S subunit. Binding of initiation factors and fMet-tRNA(fMet) induces a rotation of the head relative to the body of the 30S subunit, which is likely to prevail through 50S subunit joining until GTP hydrolysis and dissociation of IF2 take place. The structure provides insights into the mechanism of mRNA selection during translation initiation.     

Large-scale movement of eIF3 domains during translation initiation modulate start codon selection

The eukaryotic initiation factor 3 (eIF3) complex is involved in every step of translation initiation, but there is limited understanding of its molecular functions. Here, we present a single particle electron cryomicroscopy (cryo-EM) reconstruction of yeast 48S ribosomal preinitiation complex (PIC) in an open conformation conducive to scanning, with core subunit eIF3b bound on the 40S interface near the decoding center in contact with the ternary complex eIF2·GTP·initiator tRNA. eIF3b is relocated together with eIF3i from their solvent interface locations observed in other PIC structures, with eIF3i lacking 40S contacts. Re-processing of micrographs of our previous 48S PIC in a closed state also suggests relocation of the entire eIF3b-3i-3g-3a-Cter module during the course of initiation. Genetic analysis indicates that high fidelity initiation depends on eIF3b interactions at the 40S subunit interface that promote the closed PIC conformation, or facilitate the relocation of eIF3b/eIF3i to the solvent interface, on start codon selection.     

Interaction of bovine mitochondrial ribosomes with messenger RNA

The gene for subunit II of cytochrome oxidase (CoII) from bovine mitochondria has been cloned behind a T7 promoter and the corresponding mRNA synthesized in vitro. The RNA transcribed from this vector has a single nucleotide 5' to the start AUG and, thus, corresponds closely to the native mRNA. It binds to the small 28 S ribosomal subunit of bovine mitochondria but not to the large (39 S) subunit or to 55 S ribosomes. The binding occurs readily in the absence of auxiliary initiation factors or initiator tRNA. The complex formed appears to contain 1 mRNA/28 S subunit. The observed binding is specific for mRNA since neither tRNA nor ribosomal RNA can act as competitive inhibitors. The interaction of the mRNA with the 28 S subunit does not require an AUG codon near the 5' end and constructs containing 5' leaders of more than 100 nucleotides still bind efficiently. About 5% of the bound mRNA is protected from digestion by T1 RNase. The protected fragments do not arise from a specific region of the mRNA since they hybridize to several restriction fragments of the cloned CoII gene.     

Stabilization by the 30S ribosomal subunit of the interaction of 50S subunits with elongation factor G and guanine nucleotide.

The role of the 30S ribosomal subunit in the formation of the complex ribosome-guanine nucleotide-elongation factor G (EF-G) has been examined in a great variety of experimental conditions. Our results show that at a large molar excess of EF-G or high concentrations of GTP or GDP, 50S ribosomal subunits are as active alone as with 30S subunits in the formation of the complex, while at lower concentrations of nucleotide or lower amounts of EF-G, addition of the 30S subunit stimulates greatly the reaction. The presence of the 30S ribosomal subunit can also moderate the inhibition of the 50S subunit activity that occurs by increasing moderately the concentrations of K+ and NH4+, and extends upward the concentration range of these monovalent cations in which complex formation is at maximum. The Mg2+ requirement for complex formation with the 50S subunit appears to be slightly less than that needed for association of the 30S and 50S ribosomal subunits. Measurement of the reaction rate constants of the complex formation shows that the 30S ribosomal subunit has only little effect on the initial association of EF-G and guanine nucleotide with the 50S subunit; but once this complex is formed, the 30S subunit increases its stability from 10- to 18-fold. It is concluded that stabilization of the interaction between EF-G and ribosome is a major function of the 30S subunit in the ribosome-EF-G GTPase reaction.     

The formation of a defective small subunit of the mitochondrial ribosomes in petite mutants of Saccharomyces cerevisiae

The involvement of mitochondrial protein synthesis in the assembly of the mitochondrial ribosomes was investigated by studying the extent to which the assembly process can proceed in petite mutants of Saccharomyces cerevisiae which lack mitochondrial protein synthetic activity due to the deletion of some tRNA genes and/or one of the rRNA genes on the mtDNA. Petite strains which retain the 15-S rRNA gene can synthesize this rRNA species, but do not contain any detectable amounts of the small mitochondrial ribosomal subunit. Instead, a ribonucleoparticle with a sedimentation coefficient of 30 S (instead of 37 S) was observed. This ribonucleoparticle contained all the small ribosomal subunit proteins with the exception of the var1 and three to five other proteins, which indicates that the 30-S ribonucleoparticle is related to the small mitochondrial ribosomal subunit (37 S). Reconstitution experiments using the 30-S particle and the large mitochondrial ribosomal subunit from a wild-type yeast strain indicate that the 30-S particle is not active in translating the artificial message poly(U). The large mitochondrial ribosomal subunit was present in petite strains retaining the 21-S rRNA gene. The petite 54-S subunit is biologically active in the translation of poly(U) when reconstituted with the small subunit (37 S) from a wild-type strain. The above results indicate that mitochondrial protein synthetic activity is essential for the assembly of the mature small ribosomal subunit, but not for the large subunit. Since the var1 protein is the only mitochondrial translation product known to date to be associated with the mitochondrial ribosomes, the results suggest that this protein is essential for the assembly of the mature small subunit.     

Kinetics of reaction of Escherichia coli ribosomal proteins toward N-ethylmaleimide

The kinetics of reaction of the exposed ribosomal proteins from Escherichia coli toward N-ethylmaleimide (NEM) have been studied. While most of the proteins from the 30S subunit react rapidly with NEM and plateau levels can be reached, most of the proteins from the 50S subunit show biphasic uptake kinetics. Furthermore, differences have been observed in the reactivity of proteins toward NEM depending on whether the protein is in the free subunit or in the 70S ribosome.