A snapshot of the 30S ribosomal subunit capturing mRNA via the Shine-Dalgarno interaction

In the initiation phase of bacterial translation, the 30S ribosomal subunit captures mRNA in preparation for binding with initiator tRNA. The purine-rich Shine-Dalgarno (SD) sequence, in the 5' untranslated region of the mRNA, anchors the 30S subunit near the start codon, via base pairing with an anti-SD (aSD) sequence at the 3' terminus of 16S rRNA. Here, we present the 3.3 A crystal structure of the Thermus thermophilus 30S subunit bound with an mRNA mimic. The duplex formed by the SD and aSD sequences is snugly docked in a "chamber" between the head and platform domains, demonstrating how the 30S subunit captures and stabilizes the otherwise labile SD helix. This location of the SD helix is suitable for the placement of the start codon AUG in the immediate vicinity of the mRNA channel, in agreement with reported crosslinks between the second position of the start codon and G1530 of 16S rRNA.     

Unusual ribosome binding properties of mRNA encoding bacteriophage lambda repressor.

The mRNA encoding repressor cI of phage lambda is the only known E. coli message which starts directly with the initiation AUG codon. The ability of in vitro synthesized cI mRNA fragments (150 or 400 nts) to form ternary initiation complexes has been studied using the toeprint method. In the presence of tRNA(Met)f, these fragments are capable of forming the ternary complexes at the 5'-terminal AUG codon not only with 30S subunits but also with undissociated 70S ribosomes (70S tight couples). In the latter case, no binding at other positions of cI mRNA can be detected at all. The starting region of cI mRNA has a single stranded conformation and is highly enriched in A-residues. This feature of cI mRNA RBS is suggested to be the main factor which allows cI mRNA to form the initiation complex with the ribosome. Unlike 30S subunits, the binding to 70S tight couples is not affected by any of the initiation factors, although it is as efficient as that to 30S subunits supplemented with the factors. 30S subunits prefer to associate with the internal RBSs of the preformed mRNA molecules, provided that they are not sequestered by the secondary structure. In contrast, 70S tight couples tend to avoid extra sequences upstream of the codon directed to the P site and occupy a position as close as possible to the 5'-end of the message. This has been found to be the case both for tRNA(Met)f and for elongator tRNA(Glu)2. The structural features of mRNA RBSs which influence their different binding for 30S subunits and 70S ribosomes are discussed.     

Translational repression of the Escherichia coli alpha operon mRNA: importance of an mRNA conformational switch and a ternary entrapment complex

Ribosomal protein S4 represses synthesis of the four ribosomal proteins (including itself) in the Escherichia coli alpha operon by binding to a nested pseudoknot structure that spans the ribosome binding site. A model for the repression mechanism previously proposed two unusual features: (i) the mRNA switches between conformations that are "active" or "inactive" in translation, with S4 as an allosteric effector of the inactive form, and (ii) S4 holds the 30 S subunit in an unproductive complex on the mRNA ("entrapment"), in contrast to direct competition between repressor and ribosome binding ("displacement"). These two key points have been experimentally tested. First, it is found that the mRNA pseudoknot exists in an equilibrium between two conformers with different electrophoretic mobilities. S4 selectively binds to one form of the RNA, as predicted for an allosteric effector; binding of ribosomal 30 S subunits is nearly equal in the two forms. Second, we have used S4 labeled at a unique cysteine with either of two fluorophores to characterize its interactions with mRNA and 30 S subunits. Equilibrium experiments detect the formation of a specific ternary complex of S4, mRNA pseudoknot, and 30 S subunits. The existence of this ternary complex is unambiguous evidence for translational repression of the alpha operon by an entrapment mechanism.     

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.     

A competition mechanism regulates the translation of the Escherichia coli operon encoding ribosomal proteins L35 and L20

Escherichia coli ribosomal protein (r-protein) L20 is essential for the assembly of the 50S ribosomal subunit and is also a translational regulator of its own rpmI-rplT operon, encoding r-proteins L35 and L20 in that order. L20 directly represses the translation of the first cistron and, through translational coupling, that of its own gene. The translational operator of the operon is 450 nt in length and includes a long-range pseudoknot interaction between two RNA sequences separated by 280 nt. L20 has the potential to bind both to this pseudoknot and to an irregular hairpin, although only one site is occupied at a time during regulation. This work shows that the rpmI-rplT operon is regulated by competition between L20 and the ribosome for binding to mRNA in vitro and in vivo. Detailed studies on the regulatory mechanisms of r-protein synthesis have only been performed on the rpsO gene, regulated by r-protein S15, and on the alpha operon, regulated by S4. Both are thought to be controlled by a trapping mechanism, whereby the 30S ribosomal subunit, the mRNA, and the initiator tRNA are blocked as a nonfunctional preternary complex. This alternative mode of regulation of the rpmI-rplT operon raises the possibility that control is kinetically and not thermodynamically limited in this case. We show that the pseudoknot, which is known to be essential for L20 binding and regulation, also enhances 30S binding to mRNA as if this structure is specifically recognised by the ribosome.     

Alternative mRNA structures of the cIII gene of bacteriophage lambda determine the rate of its translation initiation

The bacteriophage lambda cIII gene product has a regulatory function in the lysis-lysogeny decision following infection. The availability of a set of cIII expression mutants allowed us to establish the structure-function relationship of the cIII mRNA. We demonstrate, using defined in vitro systems, that the cIII mRNA is present in two conformations at equilibrium. Mutations that have been shown to lead to cIII overexpression were found to freeze the RNA in one conformation (structure B), and permit efficient binding to the 30 S ribosomal subunit. Mutations that have been shown to prevent cIII translation cause the mRNA to assume the alternative conformation (structure A). In this structure, the translation initiation region is occluded, thereby preventing 30 S ribosomal subunit binding. By varying the temperature or Mg2+ concentration it was possible to alter the relative proportion of the alternative structures in wild-type mRNA. We suggest that the regulation of the equilibrium between the two mRNA conformations provides a mechanism for the control of cIII gene expression.     

Isolation and characterization of ribosomes and translation initiation factors from the gram-positive soil bacterium Streptomyces lividans

A primer extension inhibition (toeprint) assay was developed using ribosomes and ribosomal subunits from Streptomyces lividans. This assay allowed the study of ribosome binding to streptomycete leaderless and leadered mRNA. Purified 30S subunits were unable to form a ternary complex on aph leaderless mRNA, whereas 70S ribosomes could form ternary complexes on this mRNA. 30S subunits formed ternary complexes on leadered aph and malE mRNA. The translation initiation factors (IF1, IF2, and IF3) from S. lividans were isolated and included in toeprint and filter binding assays with leadered and leaderless mRNA. Generally, the IFs reduced the toeprint signal on leadered mRNA; however, incubation of IF1 and IF2 with 30S subunits that had been washed under high-salt conditions promoted the formation of a ternary complex on aph leaderless mRNA. Our data suggest that, as reported for Escherichia coli, initiation complexes with leaderless mRNAs might use a novel pathway involving 70S ribosomes or 30S subunits bound by IF1 and IF2 but not IF3. Some mRNA-ribosome-initiator tRNA reactions that yielded weak or no toeprint signals still formed complexes in filter binding assays, suggesting the occurrence of interactions that are not stable in the toeprint assay.     

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.     

Sequences of a hairpin structure in the 3'-untranslated region mediate regulation of human pulmonary surfactant protein B mRNA stability

The ability of pulmonary surfactant to reduce alveolar surface tension requires adequate expression of surfactant protein B (SP-B). Dexamethasone (DEX, 10(-7) M) increases human SP-B mRNA stability by a mechanism that requires a 126-nt-long segment (the 7.6S region) of the 3'-untranslated region (3'-UTR). The objective of this study was to identify sequences in the 7.6S region that mediate regulation of SP-B mRNA stability. The 7.6S region was found to be sufficient for DEX-mediated stabilization of mRNA. Sequential substitution mutagenesis of the 7.6S region indicates that a 90-nt region is required for DEX-mediated stabilization and maintenance of intrinsic stability. In this region, one 30-nt-long element (002), predicted to form a stem-loop structure, is sufficient for DEX-mediated stabilization of mRNA and intrinsic mRNA stability. Cytosolic proteins specifically bind element 002, and binding activity is unaffected whether proteins are isolated from cells incubated in the absence or presence of DEX. While loop sequences of element 002 have no role in regulation of SP-B mRNA stability, the proximal stem sequences are required for DEX-mediated stabilization and specific binding of proteins. Mutation of the sequences that comprise the proximal or distal arm of the stem negates the destabilizing activity of element 002 on intrinsic SP-B mRNA stability. These results indicate that cytosolic proteins bind a single hairpin structure that mediates intrinsic and hormonal regulation of SP-B mRNA stability via mechanisms that involve sequences of the stems of the hairpin structure.     

Identification of three 30S proteins contributing to the ribosomal A site

Summary When 30S ribosomal subunits from E. coli are incubated with unfractionated 30S protein, the protein synthetic activity of the ribosomes is enhanced. Part of this effect is due to the stimulation of mRNA binding by S1 (Van Duin and Kurland, 1970). In addition, three other proteins (S2, S3 and S14) increase the number of tRNA binding sites. The enhancing effect of S2, S3 and S14 on the tRNA binding capacity of the ribosomes is seen both in the presence and absence of T factor. S2, S3 and S14 do not seem to stimulate mRNA binding. The aminoacyl-tRNA bound in response to S2, S3 and S14 is associated with the 70S ribosome and it can donate amino acid residues for polypeptide synthesis. We conclude that S2, S3 and S14 are part of the 30S A site.     

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.     

Conformational change in the 16S rRNA in the Escherichia coli 70S ribosome induced by P/P- and P/E-site tRNAPhe binding

The effects of P/P- and P/E-site tRNA(Phe) binding on the 16S rRNA structure in the Escherichia coli 70S ribosome were investigated using UV cross-linking. The identity and frequency of 16S rRNA intramolecular cross-links were determined in the presence of deacyl-tRNA(Phe) or N-acetyl-Phe-tRNA(Phe) using poly(U) or an mRNA analogue containing a single Phe codon. For N-acetyl-Phe-tRNA(Phe) with either poly(U) or the mRNA analogue, the frequency of an intramolecular cross-link C967 x C1400 in the 16S rRNA was decreased in proportion to the binding stoichiometry of the tRNA. A proportional effect was true also for deacyl-tRNA(Phe) with poly(U), but the decrease in the C967 x C1400 frequency was less than the tRNA binding stoichiometry with the mRNA analogue. The inhibition of the C967 x C1400 cross-link was similar in buffers with, or without, polyamines. The exclusive participation of C967 with C1400 in the cross-link was confirmed by RNA sequencing. One intermolecular cross-link, 16S rRNA (C1400) to tRNA(Phe)(U33), was made with either poly(U) or the mRNA analogue. These results indicate a limited structural change in the small subunit around C967 and C1400 during tRNA P-site binding sensitive to the type of mRNA that is used. The absence of the C967 x C1400 cross-link in 70S ribosome complexes with tRNA is consistent with the 30S and 70S crystal structures, which contain tRNA or tRNA analogues; the occurrence of the cross-link indicates an alternative arrangement in this region in empty ribosomes.     

Using a targeted chemical nuclease to elucidate conformational changes in the E. coli 30S ribosomal subunit

Determining the detailed tertiary structure of 16S rRNA within 30S ribosomal subunits remains a challenging problem. The particular structure of the RNA which allows tRNA to effectively interact with the associated mRNA during protein synthesis remains particularly ambiguous. This study utilizes a chemical nuclease, 1, 10-o-phenanthroline-copper, to localize regions of 16S rRNA proximal to the decoding region under conditions in which tRNA does not readily associate with the 30S subunit (inactive conformation), and under conditions which optimize tRNA binding (active conformation). By covalently attaching 1,10-phenanthroline-copper to a DNA oligomer complementary to nucleotides in the decoding region (1396-1403), we have determined that nucleotides 923-929, 1391-1396, and 1190-1192 are within approximately 15 A of the nucleotide base-paired to nucleotide 1403 in inactive subunits, but in active subunits only cleavages (1404-1405) immediately proximal to the 5' end of the hybridized probe remain. These results provide evidence for dynamic movement in the 30S ribosomal subunit, reported for the first time using a targeted chemical nuclease.     

Interaction of the Escherichia coli fdhF mRNA hairpin promoting selenocysteine incorporation with the ribosome.

The codon UGA located 5' adjacent to an mRNA hairpin within fdhF mRNA promotes the incorporation of the amino acid selenocysteine into formate dehydrogenase H of Escherichia coli. The loop region of this mRNA hairpin has been shown to bind to the special elongation factor SELB, which also forms a complex with selenocysteinyl-tRNA(Sec) and GTP. We designed seven different mRNA constructs derived from the fdhF mRNA which contain a translation initiation region including an AUG initiation codon followed by no, one, two, three, four, five or six UUC phenylalanine codon(s) and the UGA selenocysteine codon 5' adjacent to the fdhF mRNA hairpin. By binding these different mRNA constructs to 30S ribosomal subunits in vitro we attempted to mimic intermediate steps of elongation of a structured mRNA approaching the ribosome by one codon at a time. Toeprint analysis of the mRNA-ribosome complexes showed that the presence of the fdhF mRNA hairpin strongly interferes with binding of the fdhF mRNA to 30S ribosomal subunits as soon as the hairpin is placed closer than 16 bases to the ribosomal P-site. Binding is reduced up to 25-fold compared with mRNA constructs where the hairpin is located outside the ribosomal mRNA track. Surprisingly, no toeprint signals were observed in any of our mRNA constructs when tRNA(Sec) was used instead of tRNA(fMet). Lack of binding of selenocysteinyl-tRNA(Sec) to the UGA codon was attributed to steric hindrance by the fdhF mRNA hairpin. By chemical probing of the shortest mRNA construct (AUG-UGA-fdhF hairpin) bound to 30S ribosomal subunits we demonstrate that the hairpin structure is not unfolded in the presence of ribosomes in vitro; also, this mRNA is not translated in vivo when fused in-frame 5' of the lacZ gene. Therefore, our data indicate that the fdhF mRNA hairpin has to be unfolded during elongation prior to entering the ribosomal mRNA track and we propose that the SELB binding domain within the fdhF mRNA is located outside the ribosomal mRNA track during decoding of the UGA selenocysteine codon by the SELB-selenocysteinyl-tRNA(Sec)-GTP complex.     

Evidence for allosteric coupling between the ribosome and repressor binding sites of a translationally regulated mRNA

Escherichia coli ribosomal protein S4 is a translational repressor regulating the expression of four ribosomal genes in the alpha operon. In vitro studies have shown that the protein specifically recognizes an unusual mRNA pseudoknot secondary structure which links sequences upstream and downstream of the ribosome binding site for rpsM (S13) [Tang, C. K., & Draper, D. E. (1989) Cell 57, 531]. We have prepared fusions of the rpsM translational initiation site and lacZ that allows us to detect repression in cells in which overproduction of S4 repressor can be induced. Twenty-five mRNA sequence variants have been introduced into the S13-lacZ fusions and the levels of translational repression measured. Sets of compensating base changes confirm the importance of the pseudoknot secondary structure for translational repression. An A residue in a looped, single-stranded sequence is also required for S4 recognition and may contact S4 directly. Comparison of translational repression levels and S4 binding constants for the set of mRNA mutations show that nine mutants are repressed much more weakly than predicted from their affinity for S4; in extreme cases no repression can be detected for variants with unchanged S4 binding. We suggest that the mRNA contains functionally distinct ribosome and repressor binding sites that are allosterically coupled. Mutations can relieve translational repression by disrupting the linkage between the two sites without altering S4 binding. This proposal assigns to the mRNA a more active role in mediating translational repression than found in other translational repression systems.     

A study of the thermophilic ribosomal protein S7 binding to the truncated S12-S7 intercistronic region provides more insight into the mechanism of regulation of the str operon of E. coli(1).

A study of the ability of His6-tagged ribosomal protein S7 of Thermus thermophilus to interact with the truncated S12-S7 intercistronic region of str mRNA of Escherichia coli has been described. A minimal S7 binding mRNA fragment is a part of the composite hairpin, with the termination codon of the S12 cistron on one side and the initiation codon of the next S7 cistron on the other. It has a length in the range of 63-103 nucleotides. The 63 nucleotide mRNA fragment, which corresponds to a putative S7 binding site, binds very poorly with S7. Tight RNA structure models, which behave as integral systems and link the S7 binding site with the translational regulation region of the hairpin, are suggested. This observation provides more insight into the mechanism of S7-directed autogenous control of translational coupling of str mRNA.     

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

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

Translational standby sites: how ribosomes may deal with the rapid folding kinetics of mRNA

We have previously shown that stable base-pairing at a translational initiation site in Escherichia coli can inhibit translation by competing with the binding of ribosomes. When the base-pairing is not too strong, this competition is won by the ribosomes, resulting in efficient translation from a structured ribosome binding site (RBS). We now re-examine these results in the light of RNA folding kinetics and find that the window during which a folded RBS is open is generally much too short to recruit a 30S ribosomal subunit from the cytoplasm. We argue that to achieve efficient expression, a 30S subunit must already be in contact with the mRNA while this is still folded, to shift into place as soon as the structure opens. Single-stranded regions flanking the structure may constitute a standby site, to which the 30S subunit can attach non-specifically. We propose a steady-state kinetic model for the early steps of translational initiation and use this to examine various quantitative aspects of standby binding. The kinetic model provides an explanation of why the earlier equilibrium competition model predicted implausibly high 30S-mRNA affinities. Because all RNA is structured to some degree, standby binding is probably a general feature of translational initiation.