The two main states of the elongating ribosome and the role of the alpha-sarcin stem-loop structure of 23S RNA.

According to the allosteric three-site model of the elongation cycle the ribosome oscillates between two main-functional states, viz the pre-translocational state with occupied A and P sites (E site with low affinity) and the post-translocational state with occupied P and E sites (A site with low affinity). This proposition could be confirmed by a determination of the thermodynamic parameters. High activation-energy barriers were found between both states, namely about 90 kJ mol-1 at 15 mM Mg2+ for either transition (post----pre transition = A-site binding and pre----post transition = translocation). The various A-site states (binding of ternary complex, EF-Tu dependent GTP cleavage, peptide-bond formation) are not separated by significant activation-energy barriers. The rate-limiting step of the elongation cycle is A-site binding, and not translocation as assumed previously. The principal role of both elongation factors is the reduction of the respective activation-energy barrier, thus accelerating the rate of the elongation cycle by several orders of magnitude. Cleavage of a single phosphodiester bond after G2661 of 23S rRNA by the RNase alpha-sarcin abolishes the functions of both elongation factors on the ribosome. This observation implies that the alpha-sarcin stem-loop structure plays an important role in the ribosomal conformational changes involved in the allosteric transitions. Indeed we could demonstrate that suitable oligodeoxynucleotide probes complementary to the alpha-sarcin region induce a conformational change in the 50S subunits; this conformational change causes an irreversible dissociation of tightly coupled ribosomes upon sucrose-gradient centrifugation.(ABSTRACT TRUNCATED AT 250 WORDS)     

The function of the translating ribosome: allosteric three-site model of elongation.

During the last decade, a new model for the ribosomal elongation cycle has emerged. It is based on the finding that eubacterial ribosomes possess 3 tRNA binding sites. More recently, this has been confirmed for archaebacterial and eukaryotic ribosomes as well, and thus appears to be a universal feature of the protein synthetic machinery. Ribosomes from organisms of all 3 kingdoms harbor, in addition to the classical P and A sites, an E site (E for exit), into which deacylated tRNA is displaced during translocation, and from which it is expelled by the binding of an aminoacyl-tRNA to the A site at the beginning of the subsequent elongation round. The main features of the allosteric 3-site model of ribosomal elongation are the following: first, the third tRNA binding site is located 'upstream' adjacent to the P site with respect to the messenger, ie on the 5'-side of the P site. Second, during translocation, deacylated tRNA does not leave the ribosome from the P site, but co-translocates from the P site to the E site--when peptidyl-tRNA translocates from the A site to the P site. Third, deacylated tRNA is tightly bound to the E site in the post-translocational state, where it undergoes codon--anticodon interaction. Fourth, the elongating ribosome oscillates between 2 main conformations: (i), the pre-translocational conformer, where aminoacyl-tRNA (or peptidyl-tRNA) and peptidyl-tRNA (or deacylated tRNA) are firmly bound to the A and P sites, respectively; and (ii), the post-translocational conformer, where peptidyl-tRNA and deacylated tRNA are firmly bound to the P and E sites, respectively. The transition between the 2 states is regulated in an allosteric manner via negative cooperatively. It is modulated in a symmetrical fashion by the 2 elongation factors Tu and G. An elongating ribosome always maintains 2 high-affinity tRNA binding sites with 2 adjacent codon--anticodon interactions. The allosteric transition from the post- to the pre-translocational state is involved in the accuracy of aminoacyl-tRNA selection, and the maintenance of 2 codon--anticodon interactions helps to keep the messenger in frame during translation.     

Kinetic and thermodynamic parameters for tRNA binding to the ribosome and for the translocation reaction.

Kinetic analyses of tRNA binding to the ribosome and of the translocation reaction showed the following results. 1) The activation energy for the P site binding of AcPhe-tRNA to poly(U)-programmed ribosomes is relatively high (Ea = 72 kJ mol-1; 15 mM Mg2+). If only the P site is occupied with deacylated tRNA(Phe), then the E site can be filled more easily with tRNA(Phe) (no activation energy measurable) than the A site with AcPhe-tRNA (Ea = 47 kJ mol-1; 15 mM Mg2+). 2) A ribosome with blocked P and E sites represents a standard state of the elongation cycle, in contrast to a ribosome with only a filled P site. The two states differ in that AcPhe-tRNA binding to the A site of a ribosome with prefilled P and E sites requires much higher activation energy (87 versus 47 kJ mol-1). The latter reaction simulates the allosteric transition from the post- to the pretranslocational state, whereby the tRNA(Phe) is released from the E site upon occupation of the A site (Rheinberger, H.-J., and Nierhaus, K. H. (1986) J. Biol. Chem. 261, 9133-9139). The reversed transition from the pre- to the posttranslocational state (translocation reaction) requires about the same activation energy (90 kJ mol-1). 3) Both elongation factors EF-Tu and EF-G drastically reduce the respective activation energies. 4) The rate of the A site occupation is slower than the rate of translocation in the presence of the respective elongation factors. The data suggest that the A site occupation rather than, as generally assumed, the translocation reaction is the rate-limiting step of the elongation cycle.     

Allosteric interactions between the ribosomal transfer RNA-binding sites A and E

We have previously proposed a three-site model for the elongation cycle. The model is characterized by the presence of two tRNAs on the ribosome before and after translocation. We have already shown a first consequence of the model, namely that the translocation reaction is not coupled with a release of deacylated tRNA. Here we demonstrate the following conclusions. Occupation of the A site triggers the tRNA release from the E site, i.e. the A site occupation induces a drastic decrease in the affinity of the E site for deacylated tRNA. In the concentration range of deacylated tRNA in which a ribosome binds a second tRNA in addition to that one already present at the P site the deacylated tRNA does not compete for one and the same binding site with an A site ligand (AcPhe-tRNA) at 37 degrees C. It follows that the second deacylated tRNA binds to a site, the E site, which is physically distinct from the A site. When the ribosome binds a deacylated tRNA at the E site (in addition to a tRNA at the P site), the A site cannot be occupied by AcPhe-tRNA at 0 degree C and only poorly by the ternary complex elongation factor Tu . Phe-tRNA . guanyl-5'-yl imidodiphosphate. At 37 degrees C a significant A site binding is observed, with a corresponding tRNA release from the E site. In contrast, if the E site is free and only the P site occupied, the A site can bind significant amounts of charged tRNA already at 0 degree C. It follows that an occupied E site induces a low-affinity state of the A site. Thus, the ribosome always contains two high-affinity binding sites, which are A and P sites before and P and E sites after translocation. A and E sites are allosterically linked in a bidirectional manner.     

Crystal structure of the ribosome recycling factor bound to the ribosome

In bacteria, disassembly of the ribosome at the end of translation is facilitated by an essential protein factor termed ribosome recycling factor (RRF), which works in concert with elongation factor G. Here we describe the crystal structure of the Thermus thermophilus RRF bound to a 70S ribosomal complex containing a stop codon in the A site, a transfer RNA anticodon stem-loop in the P site and tRNA(fMet) in the E site. The work demonstrates that structures of translation factors bound to 70S ribosomes can be determined at reasonably high resolution. Contrary to earlier reports, we did not observe any RRF-induced changes in bridges connecting the two subunits. This suggests that such changes are not a direct requirement for or consequence of RRF binding but possibly arise from the subsequent stabilization of a hybrid state of the ribosome.     

Is the three-site model for the ribosomal elongation cycle sound?

The release of deacylated tRNA from the ribosome as a result of translocation has been studied. Translating ribosomes prepared with poly(U)-S-S-Sepharose columns have been used. It has been shown that deacylated tRNA released from the ribosomal P site as a result of translocation rebinds with the vacated A site. Consistent with the known properties of the A site of the ribosome, this interaction is reversible, Mg2+-dependent, codon-specific and is inhibited by the antibiotic tetracycline. It has been concluded that the proposed three-site model of the ribosomal elongation cycle (Rheinberger and Nierhaus (1983) Proc. Natl. Acad. Sci. USA 80, 4213-4217) is not sound: the experimentally observed 'retention' of the deacylated tRNA on the ribosome after translocation can be explained by a codon-dependent rebinding to the A site, rather than by its transition to the 'E site', i.e., in terms of the classical two-site model.     

Visualizing the transfer-messenger RNA as the ribosome resumes translation

Bacterial ribosomes stalled by truncated mRNAs are rescued by transfer-messenger RNA (tmRNA), a dual-function molecule that contains a tRNA-like domain (TLD) and an internal open reading frame (ORF). Occupying the empty A site with its TLD, the tmRNA enters the ribosome with the help of elongation factor Tu and a protein factor called small protein B (SmpB), and switches the translation to its own ORF. In this study, using cryo-electron microscopy, we obtained the first structure of an in vivo-formed complex containing ribosome and the tmRNA at the point where the TLD is accommodated into the ribosomal P site. We show that tmRNA maintains a stable 'arc and fork' structure on the ribosome when its TLD moves to the ribosomal P site and translation resumes on its ORF. Based on the density map, we built an atomic model, which suggests that SmpB interacts with the five nucleotides immediately upstream of the resume codon, thereby determining the correct selection of the reading frame on the ORF of tmRNA.     

Elongation factor G stabilizes the hybrid-state conformation of the 70S ribosome

Following peptide bond formation, transfer RNAs (tRNAs) and messenger RNA (mRNA) are translocated through the ribosome, a process catalyzed by elongation factor EF-G. Here, we have used a combination of chemical footprinting, peptidyl transferase activity assays, and mRNA toeprinting to monitor the effects of EF-G on the positions of tRNA and mRNA relative to the A, P, and E sites of the ribosome in the presence of GTP, GDP, GDPNP, and fusidic acid. Chemical footprinting experiments show that binding of EF-G in the presence of the non-hydrolyzable GTP analog GDPNP or GDP.fusidic acid induces movement of a deacylated tRNA from the classical P/P state to the hybrid P/E state. Furthermore, stabilization of the hybrid P/E state by EF-G compromises P-site codon-anticodon interaction, causing frame-shifting. A deacylated tRNA bound to the P site and a peptidyl-tRNA in the A site are completely translocated to the E and P sites, respectively, in the presence of EF-G with GTP or GDPNP but not with EF-G.GDP. Unexpectedly, translocation with EF-G.GTP leads to dissociation of deacylated tRNA from the E site, while tRNA remains bound in the presence of EF-G.GDPNP, suggesting that dissociation of tRNA from the E site is promoted by GTP hydrolysis and/or EF-G release. Our results show that binding of EF-G in the presence of GDPNP or GDP.fusidic acid stabilizes the ribosomal intermediate hybrid state, but that complete translocation is supported only by EF-G.GTP or EF-G.GDPNP.     

Mapping the rRNA neighborhood of the acceptor end of tRNA in the ribosome.

In order to map the rRNA environment of the acceptor end of tRNA in th e ribosome, hydroxyl radicals were generated in situ from Fe(II) attached via an EDTA linker to the 5' end of tRNA. Nucleotides in rRNA cleaved by the radicals were identified by primer extension, and assigned to the ribosomal A, P and E sites by standard criteria. In the A site, cleavages were found in the 2555-2573 region of 23S rRNA, around bases previously shown to be protected by A site tRNA, and in the alpha-sarcin loop, the site of interaction of elongation factors EF-Tu and EF-G. P site cleavages occurred in the 2250 loop, where a base pair is made with C74 of tRNA; and around the 2493 region in domain V. Interestingly, two clusters of nucleotides in 23S rRNA are accessible to both A site and P site tRNA probes. The first cluster is in the 1940-1965 region of domain IV, around the site of affinity labeling by the 3' end of tRNA, and the second cluster is around the bulged adenosine A2602, whose accessibility to chemical probes is enhanced by P site tRNA and decreased by A site tRNA. From the E site, cleavages occur in the 2390-2440 region, surrounding C2394, a base protected from dimethyl sulfate by E site tRNA, and in the phylogenetically variable stem at positions 1860/1880 of domain IV. Unexpectedly, no cleavages were detected in the central loop of domain V of 23S rRNA.     

Alteration in location of a conserved GTPase-associated center of the ribosome induced by mutagenesis influences the structure of peptidyltransferase center and activity of elongation factor G

Translocation catalyzed by elongation factor G occurs after the peptidyltransferase reaction on the large ribosomal subunit. Deacylated tRNA in the P-site stimulates multiple turnover GTPase activity of EF-G. We suggest that the allosteric signal from the peptidyltransferase center that activates EF-G may involve the alteration in the conformation of elongation factor binding center of the ribosome. The latter consists of the moveable GTPase-associated center and the sarcin-ricin loop that keeps its position on the ribosome during translation elongation. The position of the GTPase-associated center was altered by mutagenesis. An insertion of additional base pair at positions C1030/G1124 was lethal and affected function of EF-G, but not that of EF-Tu. Structure probing revealed a putative allosteric signal pathway connecting the P-site with the binding site of the elongation factors. The results are consistent with the different structural requirements for EF-G and EF-Tu function, where the integrity of the path between the peptidyltransferase center and both GTPase-associated center and sarcin-ricin loop is important for EF-G binding.     

The third ribosomal tRNA-binding site, the E site, is occupied in native polysomes

The nucleic acids of Escherichia coli cells were uniformly labelled with 32P by growing the cells in [32P]orthophosphoric acid for about four generations. The cells were harvested in the logarithmic phase, resuspended in a buffer containing 6 mM Mg2+, 150 mM NH4+ and polyamines and incubated for 3 min at 37 degrees C in the presence of 3H-labelled amino acids. This procedure preferentially labels growing peptidyl chains. Polysomes were isolated, the fraction in the post-translocational state was assessed by a puromycin reaction and the tRNA content/70S ribosome was quantified in comparison to the amount of 5S rRNA determined after separation by gel electrophoresis. The data revealed that at least 75% of post-translocational ribosomes in isolated native polysomes carry a tRNA in their E site. The results are consistent with the allosteric three-site model for the elongation cycle but disagree with the two-site model.     

Localization of the ribosomal protection protein Tet(O) on the ribosome and the mechanism of tetracycline resistance

Tet(O) belongs to a class of ribosomal protection proteins that mediate tetracycline resistance. It is a G protein that shows significant sequence similarity to elongation factor EF-G. Here we present a cryo-electron microscopic reconstruction, at 16 A resolution, of its complex with the E. coli 70S ribosome. Tet(O) was bound in the presence of a noncleavable GTP analog to programmed ribosomal complexes carrying fMet-tRNA in the P site. Tet(O) is directly visible as a mass close to the A-site region, similar in shape and binding position to EF-G. However, there are important differences. One of them is the different location of the tip of domain IV, which in the Tet(O) case, does not overlap with the ribosomal A site but is directly adjacent to the primary tetracycline binding site. Our findings give insights into the mechanism of tetracycline resistance.     

Engaging the ribosome: universal IFs of translation

Eukaryotic initiation factor 1A (eIF1A) and the GTPase IF2/eIF5B are the only universally conserved translation initiation factors. Recent structural, biochemical and genetic data indicate that these two factors form an evolutionarily conserved structural and functional unit in translation initiation. Based on insights gathered from studies of the translation elongation factor GTPases, we propose that these factors occupy the aminoacyl-tRNA site (A site) on the ribosome, and promote initiator tRNA binding and ribosomal subunit joining. These processes yield a translationally competent ribosome with Met-tRNA in the ribosomal peptidyl-tRNA site (P site), base-paired to the AUG start codon of a mRNA.     

Progression of the ribosome recycling factor through the ribosome dissociates the two ribosomal subunits

After the termination step of translation, the posttermination complex (PoTC), composed of the ribosome, mRNA, and a deacylated tRNA, is processed by the concerted action of the ribosome-recycling factor (RRF), elongation factor G (EF-G), and GTP to prepare the ribosome for a fresh round of protein synthesis. However, the sequential steps of dissociation of the ribosomal subunits, and release of mRNA and deacylated tRNA from the PoTC, are unclear. Using three-dimensional cryo-electron microscopy, in conjunction with undecagold-labeled RRF, we show that RRF is capable of spontaneously moving from its initial binding site on the 70S Escherichia coli ribosome to a site exclusively on the large 50S ribosomal subunit. This movement leads to disruption of crucial intersubunit bridges and thereby to the dissociation of the two ribosomal subunits, the central event in ribosome recycling. Results of this study allow us to propose a model of ribosome recycling.     

Significance of the third tRNA binding site, the E site, on E. coli ribosomes for the accuracy of translation: an occupied E site prevents the binding of non-cognate aminoacyl-tRNA to the A site.

The E site (exit site for deacyl-tRNA) has been shown to be allosterically linked to the A site (aminoacyl-tRNA binding site), in that occupation of the E site reduces the affinity of the A site, and vice versa, whereas the intervening peptidyl-tRNA binding site (P site) keeps its high affinity. Here the question is analysed of whether or not the low affinity state of the A site caused by an occupied E site is of importance for the ribosomal accuracy of the aminoacyl-tRNA selection. In a poly(U) dependent system with high accuracy in poly(Phe) synthesis, the acceptance of the cognate ternary complex Phe-tRNA--EF-Tu--GTP (which has the correct anticodon with respect to the codon at the A site) was compared with the competing acceptance of ternary complexes with near-cognate Leu-tRNA(Leu) (which has a similar anticodon) or non-cognate Asp-tRNA(Asp) (which has a dissimilar anticodon), by monitoring the formation of AcPhePhe, AcPheLeu or AcPheAsp, respectively. Cognate (but not near-cognate) occupation of the E site reduced synthesis of the 'wrong' dipeptide AcPheLeu only marginally relative to that of the cognate AcPhe2, whereas the formation of AcPheAsp was decreased as much as 14-fold, thereby reducing it to the background level. It follows that the allosteric interplay between E and A sites, i.e. the low affinity of the A site induced by the occupation of the E site, excludes the interference of non-cognate complexes in the decoding process and thus reduces the number of aminoacyl-tRNA species competing for A site binding by an order of magnitude.(ABSTRACT TRUNCATED AT 250 WORDS)     

The ribosomal E site at low Mg2+: coordinate inactivation of ribosomal functions at Mg2+ concentrations below 10 mM and its prevention by polyamines

Under standard conditions (Mg2+/150 mM NH4+) ribosomes can quantitatively participate in tRNA binding at Mg2+ concentrations of 12 to 15 mM. The overall poly(U)-directed Phe incorporation and the extent of tRNA binding to either P, E or A sites decrease in a parallel manner when the Mg2+ concentration is lowered below 10 mM. At 4 mM the inactivation amounts to about 80%. The coordinate inactivation of all three binding sites is accompanied by an increasing impairment of the ability to translocate A-site bound AcPhe-tRNA to the P site. The translocation efficiency is already reduced at 10 mM Mg2+, and is completely blocked at 6-8 mM. The severe inactivation seen at 6 mM Mg2+ vanishes when the polyamines spermine (0.6 mM) and spermidine (0.4 mM) are present in the assay; tRNA binding again becomes quantitative, the total Phe synthesis even exceeds that observed in the absence of polyamines by a factor of 4. In the presence of polyamines and low Mg2+ (3 and 6 mM) two essential features of the allosteric three-site model (Rheinberger and Nierhaus, J. Biol. Chem. 261, 9133 (1986] are demonstrated. 1) Deacylated tRNA is not released from the P site, but moves to the E site during the course of translocation. 2) Occupation of the E site reduces the A site affinity and vice versa (allosteric interactions between E and A sites). The quality of an in vitro system for protein synthesis can be assessed by two criteria. First, the incubation conditions must allow a near quantitative tRNA binding. Secondly, protein synthesis should proceed with near in vivo rate and accuracy. The 3 mM Mg2+/NH4+/polyamine-system seems to be the best compromise at present between these two requirements.     

Functions and interplay of the tRNA-binding sites of the ribosome

The ribosome translates the genetic information of an mRNA molecule into a sequence of amino acids. The ribosome utilizes tRNAs to connect elements of the RNA and protein worlds during protein synthesis, i.e. an anticodon as a unit of genetic information with the corresponding amino acid as a building unit of proteins. Three tRNA-binding sites are located on the ribosome, termed the A, P and E sites. In recent years the tRNA-binding sites have been localized on the ribosome by three different techniques, small-angle neutron scattering, cryo-electron microscopy and X-ray analyses of 70 S crystals. These high-resolution glimpses into various ribosomal states together with a large body of biochemical data reveal an intricate interplay between the tRNAs and the three ribosomal binding sites, providing an explanation for the remarkable features of the ribosome, such as the ability to select the correct ternary complex aminoacyl-tRNA.EF-Tu.GTP out of more than 40 extremely similar tRNA complexes, the precise movement of the tRNA(2).mRNA complex during translocation and the maintenance of the reading frame.