Messenger RNA movement on the ribosome

Recent X-ray and cryo-EM studies of 70S ribosome complexes containing different types of messenger RNAs (mRNA) and transfer RNA (tRNA) have been reviewed. Changes of the mRNA path on the ribosome at initiation and elongation states have been described. Authors suggested, that the specific region of ribosomal 30S subunit ("platform") is a ribosome binding site of regulatory domains of mRNA which locates on the non-translated 5'-end of the mRNA.     

Ribosome binding to inosine-substituted mRNAs in the absence of ATP and mRNA factors

Incubating ribosomes and eukaryotic initiation factor eIF3 with an inosine-substituted mRNA (where the mRNA secondary structure is strongly reduced) in the absence of ATP and other protein synthesis factors produces a 40 S ribosome.mRNA complex. When Met-tRNAMeti and eIF2 are added, a 60 S ribosome subunit attaches forming an 80 S ribosome.mRNA complex. ATP and the three mRNA factors, eIF4B, cap-site factor, and eIF4A, strongly stimulate the attachment of the 60 S subunit. In the absence of Met-tRNAMeti, the 60-S subunit does not attach, and adding ATP and the mRNA factors inhibits the accumulation of 40 S ribosome.inosine mRNA complexes. These results indicate that a 40 S ribosome, probably in a complex with eIF3, has an intrinsic capacity to attach to mRNA. Further, they suggest that Met-tRNAMeti may interact in a subsequent step to stabilize the 40 S ribosome.mRNA complex and allow the attachment of a 60 S ribosome subunit. Although seen most clearly with the inosine-substituted mRNAs, the 40 S ribosome reaction is also obtained with "guanosine" mRNA. A 40 S ribosome attaches to guanosine mRNA without ATP and mRNA factors when an incubation mixture containing ribosomes, eIF3, and mRNA is fixed with glutaraldehyde. In addition, a 40 S ribosome.guanosine mRNA complex can be obtained without glutaraldehyde in incubations containing ATP and the three mRNA factors in the absence of Met-tRNAMeti. The latter reaction is limited because of the instability of the 40 S ribosome.mRNA complex in the absence of Met-tRNA. Nevertheless, its authenticity is indicated by its full dependence upon ATP and the three mRNA factors. The lack of factor requirement for the formation of 40 S ribosome complexes with inosine-substituted mRNAs indicates that ATP and the three mRNA factors function primarily to unwind the secondary structure of a guanosine mRNA. Data relevant to a role for ATP in facilitating ribosome migration on an mRNA are also discussed.     

Structural elements of rps0 mRNA involved in the modulation of translational initiation and regulation of E. coli ribosomal protein S15.

Previous experiments showed that S15 inhibits its own translation by binding to its mRNA in a region overlapping the ribosome loading site. This binding was postulated to stabilize a pseudoknot structure that exists in equilibrium with two stem-loops and to trap the ribosome on its mRNA loading site in a transitory state. In this study, we investigated the effect of mutations in the translational operator on: the binding of protein S15, the formation of the 30S/mRNA/tRNA(fMet) ternary initiation complex, the ability of S15 to inhibit the formation of this ternary complex. The results were compared to in vivo expression and repression rates. The results show that (1) the pseudoknot is required for S15 recognition and translational control; (2) mRNA and 16S rRNA efficiently compete for S15 binding and 16S rRNA suppresses the ability of S15 to inhibit the formation of the active ternary complex; (3) the ribosome binds more efficiently to the pseudoknot than to the stem-loop; (4) sequences located between nucleotides 12 to 47 of the S15 coding phase enhances the efficiency of ribosome binding in vitro; this is correlated with enhanced in vivo expression and regulation rates.     

RNase catalyzed hydrolysis of ribosomes in several functional states

The RNase A catalyzed hydrolysis of rRNA in ribosomes has been studied for nonwashed 50S and 70S ribosomes, for washed 50S and 70S ribosomes, for runoff 50S ribosomes and for 70S ribosomes in polysomes. The regions available to hydrolysis in the 50S ribosome remain available when the 50S ribosomes become a part of a 70S ribosome or a polysome. The regions available to hydrolysis in the 30S ribosome become unavailable when the 30S ribosome becomes part of a 70S ribosome or a polysome. Removal of tRNA, mRNA and factors from the 50S and 70S ribosome lowers the rate of hydrolysis of one site in the 23S rRNA. This shows that the conformation of one region of the 23S RNA changes for ribosomes in different functional states.     

How does the mRNA pass through the ribosome?

A working model of the mRNA path through the ribosome is proposed. According to the model, the template goes around the small ribosomal subunit along the region where its 'head' is separated from other parts of the subunit. The 5'-end of the mRNA fragment covered by the ribosome is located near the 3'-terminus of 16S rRNA, whereas the 3'-terminal residues of the fragment are situated on the outer surface of the subunit, opposite its 'side ledge'. When associated with the 50S subunit, the 30S subunit is oriented in such a manner that the decoding center faces the L7/L12 stalk. Implications of the proposed working model of the mRNA topography for the function of the ribosome are discussed.     

Structured mRNAs regulate translation initiation by binding to the platform of the ribosome

Gene expression can be regulated at the level of initiation of protein biosynthesis via structural elements present at the 5' untranslated region of mRNAs. These folded mRNA segments may bind to the ribosome, thus blocking translation until the mRNA unfolds. Here, we report a series of cryo-electron microscopy snapshots of ribosomal complexes directly visualizing either the mRNA structure blocked by repressor protein S15 or the unfolded, active mRNA. In the stalled state, the folded mRNA prevents the start codon from reaching the peptidyl-tRNA (P) site inside the ribosome. Upon repressor release, the mRNA unfolds and moves into the mRNA channel allowing translation initiation. A comparative structure and sequence analysis suggests the existence of a universal stand-by site on the ribosome (the 30S platform) dedicated for binding regulatory 5' mRNA elements. Different types of mRNA structures may be accommodated during translation preinitiation and regulate gene expression by transiently stalling the ribosome.     

Insights into protein biosynthesis from structures of bacterial ribosomes

Understanding the structural basis of protein biosynthesis on the ribosome remains a challenging problem for cryo-electron microscopy and X-ray crystallography. Recent high-resolution structures of the Escherichia coli 70S ribosome without ligands, and of the Thermus thermophilus and E. coli 70S ribosomes with bound mRNA and tRNAs, reveal many new features of ribosome dynamics and ribosome-ligand interactions. In addition, the first high-resolution structures of the L7/L12 stalk of the ribosome, responsible for translation factor binding and GTPase activation, reveal the structural basis of the high degree of flexibility in this region of the ribosome. These structures provide groundbreaking insights into the mechanism of protein synthesis at the level of ribosome architecture, ligand binding and ribosome dynamics.     

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

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

Spatial organization of template polynucleotides on the ribosome determined by fluorescence methods.

The spatial organization of template polynucleotides on the ribosome and the dynamics of their interaction with 30 S subunits have been studied by fluorescence spectroscopy. The topography of the mRNA in the ribosome has been determined using singlet-singlet energy transfer. This method has allowed us to estimate distances between donors and acceptors of energy which have been linked to the terminal residues of template polynucleotides (poly- and oligo(U) and oligo(A] and 16 S RNA or to SH-groups of ribosomal proteins S1 and S8. The dynamics of mRNA-ribosome interaction have been investigated by the fluorescence stopped-flow technique. It has been shown that the binding to the 30 S subunit of poly(U) with length much shorter (16 nucleotides) than that covered by the ribosome is greatly enhanced by protein S1. However, the final position of oligo(U)16 on the 30 S subunit, which probably includes the ribosomal decoding site, proves to be quite different from that occupied by oligo(U)16 on a free protein S1. Interaction of oligo- and poly(U) with the 30 S subunit occurs in at least two steps: the first one is as fast as the interaction of poly(U) with free S1, whereas the second step represents a first-order reaction. Therefore, the second step may reflect some rearrangement of the template in the ribosome after its primary binding. It is suggested that protein S1 in some cases may fulfill the role of a transient binding site for mRNA in the course of its interaction with the ribosome. The general shape of the template in the mRNA binding region of the ribosome has been studied using various synthetic ribopolynucleotides and has been shown to be similar. It can be represented by a loop(s) or "U-turn(s)". On the basis of estimation of distances from the ends of poly(U) to some well-localized points on the 30 S ribosomal surface, a tentative model of mRNA path through the ribosome is proposed.     

Influence of duplexes 3' to the mRNA initiation codon on the efficiency of monosome formation

The structural features of mRNA molecules that determine their relative translational rates are at present poorly defined. An early and potentially rate-limiting step in this process is the assembly of an intact 80S ribosome at the translational initiation codon. It is generally assumed that the efficiency of this reaction is controlled by structures in the 5' nontranslated region and in the immediate proximity of the AUG initiation codon. In this paper, we present an assay of initial monosome formation and measure the effects of hybridizing mRNA to complementary DNA fragments on the efficiency of this reaction. This hybridization serves to block specific regions of the mRNA from sequence-specific and intramolecular (secondary structure) interactions. We find that cDNAs that block the 5' nontranslated region, the initiation codon, or regions immediately 3' to the initiation codon markedly inhibit 80S ribosome attachment. These results are consistent with previous studies by ourselves and others which suggest that the introduction of secondary structures into this region can result in decreased translational efficiency. In addition, however, we note that cDNAs that hybridize to segments of the coding region significant distances (as many as several hundred bases) 3' to the initiation codon can also inhibit initial ribosome binding. This effect appears to be limited to duplexes within the mRNA coding region since a cDNA hybridizing exclusively within the 3' nontranslated region does not inhibit, and may actually stimulate, monosome formation. The results of this monosome formation assay therefore suggest that mRNA structures remote from the 5' terminus and initiation codon may also be important in determining the efficiency of translational initiation.     

Kinetic checkpoint at a late step in translation initiation

The translation initiation efficiency of a given mRNA is determined by its translation initiation region (TIR). mRNAs are selected into 30S initiation complexes according to the strengths of the secondary structure of the TIR, the pairing of the Shine-Dalgarno sequence with 16S rRNA, and the interaction between initiator tRNA and the start codon. Here, we show that the conversion of the 30S initiation complex into the translating 70S ribosome constitutes another important mRNA control checkpoint. Kinetic analysis reveals that 50S subunit joining and dissociation of IF3 are strongly influenced by the nature of the codon used for initiation and the structural elements of the TIR. Coupling between the TIR and the rate of 70S initiation complex formation involves IF3- and IF1-induced rearrangements of the 30S subunit, providing a mechanism by which the ribosome senses the TIR and determines the efficiency of translational initiation of a particular mRNA.     

Interactions of translational factor EF-G with the bacterial ribosome before and after mRNA translocation

A conserved translation factor, known as EF-G in bacteria, promotes the translocation of tRNA and mRNA in the ribosome during protein synthesis. Here, EF-G.ribosome complexes in two intermediate states, before and after mRNA translocation, have been probed with hydroxyl radicals generated from free Fe(II)-EDTA. Before mRNA translocation and GTP hydrolysis, EF-G protected a limited set of nucleotides in both subunits of the ribosome from cleavage by hydroxyl radicals. In this state, an extensive set of nucleotides, in the platform and head domains of the 30S subunit and in the L7/L12 stalk region of the 50S subunit, became more exposed to hydroxyl radical attack, suggestive of conformational changes in these domains. Following mRNA translocation, EF-G protected a larger set of nucleotides (23S rRNA helices H43, H44, H89, and H95; 16S rRNA helices h5 and h15). No nucleotide with enhanced reactivity to hydroxyl radicals was detected in this latter state. Both before and after mRNA translocation, EF-G protected identical nucleotides in h5 and h15 of the 30S subunit. These results suggest that h5 and h15 may remain associated with EF-G during the dynamic course of the translocation mechanism. Nucleotides in H43 and H44 of the 50S subunit were protected only after translocation and GTP hydrolysis, suggesting that these helices interact dynamically with EF-G. The effects in H95 suggest that EF-G interacts weakly with H95 before mRNA translocation and strongly and more extensively with this helix following mRNA translocation.     

S4-alpha mRNA translation regulation complex. II. Secondary structures of the RNA regulatory site in the presence and absence of S4

The secondary structure of the Escherichia coli alpha mRNA leader sequence has been determined using nucleases specific for single- or double-stranded RNA. Three different length alpha RNA fragments were studied at 0 degrees C and 37 degrees C. A very stable eight base-pair helix forms upstream from the ribosome initiation site, defining a 29 base loop. There is evidence for base-pairing between nucleotides within this loop and for a "pseudo-knot" interaction of some loop bases with nucleotides just 3' to the initiation codon, forming a region of complex structure. A weak helix also pairs sequences near the 5' terminus of the alpha mRNA with bases near the Shine-Dalgarno sequence. Affinity constants for the translational repressor S4 binding different length alpha mRNA fragments indicate that most of the S4 recognition features must be contained within the main helix and hairpin regions. Binding of S4 to the alpha mRNA alters the structure of the 29 base hairpin region, and probably melts the weak pairing between the 5' and 3' termini of the leader. The pseudo-knot structure and the conformational changes associated with it provide a link between the structures of the S4 binding site and the ribosome binding site. The alpha mRNA may therefore play an active role in mediating translational repression.     

Translation of the leaderless Caulobacter dnaX mRNA.

The expression of the Caulobacter crescentus homolog of dnaX, which in Escherichia coli encodes both the gamma and tau subunits of the DNA polymerase III holoenzyme, is subject to cell cycle control. We present evidence that the first amino acid in the predicted DnaX protein corresponds to the first codon in the mRNA transcribed from the dnaX promoter; thus, the ribosome must recognize the mRNA at a site downstream of the start codon in an unusual but not unprecedented fashion. Inserting four bases in front of the AUG at the 5' end of dnaX mRNA abolishes translation in the correct frame. The sequence upstream of the translational start site shows little homology to the canonical Shine-Dalgarno ribosome recognition sequence, but the region downstream of the start codon is complementary to a region of 16S rRNA implicated in downstream box recognition. The region downstream of the dnaX AUG, which is important for efficient translation, exhibits homology with the corresponding region from the Caulobacter hemE gene adjacent to the replication origin. The hemE gene also appears to be translated from a leaderless mRNA. Additionally, as was found for hemE, an upstream untranslated mRNA also extends into the dnaX coding sequence. We propose that translation of leaderless mRNAs may provide a mechanism by which the ribosome can distinguish between productive and nonproductive templates.     

A region rich in aspartic acid, arginine, tyrosine, and glycine (DRYG) mediates eukaryotic initiation factor 4B (eIF4B) self-association and interaction with eIF3.

The binding of mRNA to the ribosome is mediated by eukaryotic initiation factors eukaryotic initiation factor 4F (eIF4F), eIF4B, eIF4A, and eIF3, eIF4F binds to the mRNA cap structure and, in combination with eIF4B, is believed to unwind the secondary structure in the 5' untranslated region to facilitate ribosome binding. eIF3 associates with the 40S ribosomal subunit prior to mRNA binding. eIF4B copurifies with eIF3 and eIF4F through several purification steps, suggesting the involvement of a multisubunit complex during translation initiation. To understand the mechanism by which eIF4B promotes 40S ribosome binding to the mRNA, we studied its interactions with partner proteins by using a filter overlay (protein-protein [far Western]) assay and the two-hybrid system. In this report, we show that eIF4B self-associates and also interacts directly with the p170 subunit of eIF3. A region rich in aspartic acid, arginine, tyrosine, and glycine, termed the DRYG domain, is sufficient for self-association of eIF4B, both in vitro and in vivo, and for interaction with the p170 subunit of eIF3. These experiments suggest that eIF4B participates in mRNA-ribosome binding by acting as an intermediary between the mRNA and eIF3, via a direct interaction with the p170 subunit of eIF3.     

The initiation region of the SV40 VP1 gene.

The sequence of 15 nucleotides located at the 5' terminus of the plus strand of the SV40 Hind K fragment has been determined as (5') A-G-C-T-T-A-T-G-A-A-G-A-T-G-G (3'). The 3' on OH terminal G of this segment is part of the G-C-C codeword for the N terminal alanine of the VP1 protein. This region therefore presumably corresponds to a ribosome binding site on the 16S late mRNA. Complementarily to the 3' OH of eucaryotic 18S ribosomal RNA and homology with the BMV coat ribosome binding site are discussed.     

Model of ribosome translation and mRNA unwinding

A ribosome is an enzyme that catalyzes translation of the genetic information encoded in messenger RNA (mRNA) into proteins. Besides translation through the single-stranded mRNA, the ribosome is also able to translate through the duplex region of mRNA via unwinding the duplex. Here, based on our proposed ribosome translation model, we study analytically the dynamics of Escherichia coli ribosome translation through the duplex region of mRNA, and compare with the available single molecule experimental data. It is shown that the ribosome uses only one active mechanism (mechanical unwinding), rather than two active mechanisms (open-state stabilization and mechanical unwinding), as proposed before, to unwind the duplex. The reduced rate of translation through the duplex region is due to the occurrence of futile transitions, which are induced by the energy barrier from the duplex unwinding to the forward translocation along the single-stranded mRNA. Moreover, we also present predicted results of the average translation rate versus the external force acting on the ribosome translating through the duplex region and through the single-stranded region of mRNA, which can be easily tested by future experiments.