Formation of the central pseudoknot in 16S rRNA is essential for initiation of translation.

The postulated central pseudoknot formed by regions 9-13/21-25 and 17-19/916-918 of 16S rRNA of Escherichia coli is phylogenetically conserved in prokaryotic as well eukaryotic species. This pseudoknot is located at the center of the secondary structure of the 16S rRNA and connects the three major domains of this molecule. We have introduced mutations into this pseudoknot by changing the base-paired residues C18 and G917, and the effect of such mutations on the ribosomal activity was studied in vivo, using a 'specialized' ribosome system. As compared with ribosomes having the wild-type pseudoknot, the translational activity of ribosomes containing an A, G or U residue at position 18 was dramatically reduced, while the activity of mutant ribosomes having complementary bases at positions 18 and 917 was at the wild-type level. The reduced translational activity of those mutants that are incapable of forming a pseudoknot was caused by their inability to form 70S ribosomal complexes. These results demonstrate that the potential formation of a central pseudoknot in 16S rRNA with any base-paired residues at positions 18 and 917 is essential to complete the initiation process.     

Yeast ribosomal protein L25 binds to an evolutionary conserved site on yeast 26S and E. coli 23S rRNA.

The binding site of the yeast 60S ribosomal subunit protein L25 on 26S rRNA was determined by RNase protection experiments. The fragments protected by L25 originate from a distinct substructure within domain IV of the rRNA, encompassing nucleotides 1465-1632 and 1811-1861. The protected fragments are able to rebind to L25 showing that they constitute the complete protein binding site. This binding site is remarkably conserved in all 23/26/28S rRNAs sequenced to date including Escherichia coli 23S rRNA. In fact heterologous complexes between L25 and E. coli 23S rRNA could be formed and RNase protection studies on these complexes demonstrated that L25 indeed recognizes the conserved structure. Strikingly the L25 binding site on 23S rRNA is virtually identical to the previously identified binding site of E. coli ribosomal protein EL23. Therefore EL23 is likely to be the prokaryotic counterpart of L25 in spite of the limited homology displayed by the amino acid sequences of the two proteins.     

The primary and secondary structure of yeast 26S rRNA.

We present the sequence of the 26S rRNA of the yeast Saccharomyces carlsbergensis as inferred from the gene sequence. The molecule is 3393 nucleotides long and consists of 48% G+C; 30 of the 43 methyl groups can be located in the sequence. Starting from the recently proposed structure of E. coli 23S rRNA (see ref. 25) we constructed a secondary structure model for yeast 26S rRNA. This structure is composed of 7 domains closed by long-range base pairings as n the bacterial counterpart. Most domains show considerable conservation of the overall structure; unpaired regions show extended sequence homology and the base-paired regions contain many compensating base pair changes. The extra length of the yeast molecule is due to a number of insertions in most of the domains, particularly in domain II. Domain VI, which is extremely conserved, is probably part of the ribosomal A site. alpha-Sarcin, which apparently inhibits the EF-1 dependent binding of aminoacyl-tRNA, causes a cleavage between position 3025 and 3026 in a conserved loop structure, just outside domain VI. Nearly all of the located methyl groups, like in E. coli, are present in domain II, V and VI and clustered to a certain extent mainly in regions with a strongly conserved primary structure. The only three methyl groups of 26S rRNA which are introduced relatively late during the processing are found in single stranded loops in domain VI very close to positions which have been shown in E. coli 23S rRNA to be at the interface of the ribosome.     

Covariance of complementary rRNA loop nucleotides does not necessarily represent functional pseudoknot formation in vivo

We examined mutationally a two-hairpin structure (nucleotides 57 to 70 and 76 to 110) in a region of domain I of Escherichia coli 23S rRNA that has been implicated in specific functions in protein synthesis by other studies. On the basis of the observed covariance of several nucleotides in each loop in Bacteria, Archaea, and chloroplasts, the two hairpins have been proposed to form a pseudoknot. Here, appropriate loop changes were introduced in vitro by site-directed mutagenesis to eliminate any possibility of base pairing between the loops. The bacterial cells containing each cloned mutant rRNA operon were then examined for cell growth, termination codon readthrough, and assembly of the mutant rRNAs into functional ribosomes. The results show that, under the conditions examined, the two hairpins do not form a pseudoknot structure that is required for the functioning of the ribosome in vivo and therefore that sequence covariance does not necessarily indicate the formation of a functional pseudoknot.     

Double molecular mimicry in Escherichia coli: binding of ribosomal protein L20 to its two sites in mRNA is similar to its binding to 23S rRNA

Escherichia coli ribosomal L20 is one of five proteins essential for the first reconstitution step of the 50S ribosomal subunit in vitro. It is purely an assembly protein, because it can be withdrawn from the mature subunit without effect on ribosome activity. In addition, L20 represses the translation of its own gene by binding to two sites in its mRNA. The first site is a pseudoknot formed by a base-pairing interaction between nucleotide sequences separated by more than 280 nucleotides, whereas the second site is an irregular helix formed by base-pairing between neighbouring nucleotide sequences. Despite these differences, the mRNA folds in such a way that both L20 binding sites share secondary structure similarity with the L20 binding site located at the junction between helices H40 and H41 in 23S rRNA. Using a set of genetic, biochemical, biophysical, and structural experiments, we show here that all three sites are recognized similarly by L20.     

A cluster of methylations in the domain IV of 25S rRNA is required for ribosome stability

In all three domains of life ribosomal RNAs are extensively modified at functionally important sites of the ribosome. These modifications are believed to fine-tune the ribosome structure for optimal translation. However, the precise mechanistic effect of modifications on ribosome function remains largely unknown. Here we show that a cluster of methylated nucleotides in domain IV of 25S rRNA is critical for integrity of the large ribosomal subunit. We identified the elusive cytosine-5 methyltransferase for C2278 in yeast as Rcm1 and found that a combined loss of cytosine-5 methylation at C2278 and ribose methylation at G2288 caused dramatic ribosome instability, resulting in loss of 60S ribosomal subunits. Structural and biochemical analyses revealed that this instability was caused by changes in the structure of 25S rRNA and a consequent loss of multiple ribosomal proteins from the large ribosomal subunit. Our data demonstrate that individual RNA modifications can strongly affect structure of large ribonucleoprotein complexes.     

Structural analysis of the peptidyl transferase region in ribosomal RNA of the eukaryote Xenopus laevis

Accessible single-strand bases in Xenopus laevis 28 S ribosomal RNA (rRNA) Domain V, the peptidyl transferase region, were determined by chemical modification with dimethylsulfate, 1-cyclohexyl-3-(2-morpholinoethyl-carbodiimide metho-p-toluene sulfonate and kethoxal, followed by primer extension. The relative accessibilities of three rRNA substrates were compared: deproteinized 28 S rRNA under non-denaturing conditions (free 28 S rRNA), 60 S subunits and 80 S ribosomes. Overall, our experimental results support the theoretical secondary structure model of Domain V derived by comparative sequence analysis and compensatory base-pair changes, and support some theoretical tertiary interactions previously suggested by covariation. The 60 S subunits and 80 S ribosomes generally show increasing resistance to chemical modification. Bases which are sensitive in free 28 S rRNA but protected in 60 S subunits may be sites for ribosomal protein binding or induced structural rearrangements. Another class of nucleotides is distinguished by its sensitivity in 60 S subunits but protection in 80 S ribosomes; these nucleotides may be involved in subunit-subunit interactions or located at the interface of the ribosome. We found a third class of bases, which is protected in free 28 S rRNA but sensitive in 60 S subunits and/or 80 S ribosomes, suggesting that structural changes occur in Domain V as a result of subunit assembly and ribosome formation. One such region is uniquely hypersensitive in eukaryotic ribosomes but is absent in Escherichia coli ribosomes. Sites that we determined to be accessible on empty 80 S ribosomes could serve as recognition sites for translation components.     

L22 ribosomal protein and effect of its mutation on ribosome resistance to erythromycin

The ribosomal protein L22 is a core protein of the large ribosomal subunit interacting with all domains of the 23S rRNA. The triplet Met82-Lys83-Arg84 deletion in L22 from Escherichia coli renders cells resistant to erythromycin which is known as an inhibitor of the nascent peptide chain elongation. The crystal structure of the Thermus thermophilus L22 mutant with equivalent triplet Leu82-Lys83-Arg84 deletion has been determined at 1.8A resolution. The superpositions of the mutant and the wild-type L22 structures within the 50S subunits from Haloarcula marismortui and Deinococcus radiodurans show that the mutant beta-hairpin is bent inward the ribosome tunnel modifying the shape of its narrowest part and affecting the interaction between L22 and 23S rRNA. 23S rRNA nucleotides of domain V participating in erythromycin binding are located on the opposite sides of the tunnel and are brought to those positions by the interaction of the 23S rRNA with the L22 beta-hairpin. The mutation in the L22 beta-hairpin affects the orientation and distances between those nucleotides. This destabilizes the erythromycin-binding "pocket" formed by 23S rRNA nucleotides exposed at the tunnel surface. It seems that erythromycin, while still being able to interact with one side of the tunnel but not reaching the other, is therefore unable to block the polypeptide growth in the drug-resistant ribosome.     

Do mRNA and rRNA binding sites of E.coli ribosomal protein S15 share common structural determinants?

Escherichia coli ribosomal protein S15 recognizes two RNA targets: a three-way junction in 16S rRNA and a pseudoknot structure on its own mRNA. Binding to mRNA occurs when S15 is expressed in excess over its rRNA target, resulting in an inhibition of translation start. The sole apparent similarity between the rRNA and mRNA targets is the presence of a G-U/G-C motif that contributes only modestly to rRNA binding but is essential for mRNA. To get more information on the structural determinants used by S15 to bind its mRNA target as compared to its rRNA site, we used site-directed mutagenesis, substitution by nucleotide analogs, footprinting experiments on both RNA and protein, and graphic modeling. The size of the mRNA-binding site could be reduced to 45 nucleotides, without loss of affinity. This short RNA preferentially folds into a pseudoknot, the formation of which depends on magnesium concentration and temperature. The size of the loop L2 that bridges the two stems of the pseudoknot through the minor groove could not be reduced below nine nucleotides. Then we showed that the pseudoknot recognizes the same side of S15 as 16S rRNA, although shielding a smaller surface area. It turned out that the G-U/G-C motif is recognized from the minor groove in both cases, and that the G-C pair is recognized in a very similar manner. However, the wobble G-U pair of the mRNA is not directly contacted by S15, as in rRNA, but is most likely involved in building a precise conformation of the RNA, essential for binding. Otherwise, unique specific features are utilized, such as the three-way junction in the case of 16S rRNA and the looped out A(-46) for the mRNA pseudoknot.     

Electron microscopic mapping of secondary structures in bacterial 16S and 23S ribosomal ribonucleic acid and 30S precursor ribosomal ribonucleic acid

Electron microscopy revealed reproducible secondary structure patterns within partially denatured 16S and 23S ribosomal ribonucleic acid (rRNA) from Escherichia coli. When prepared with 50% formamide-100 mM ammonium acetate, 16S rRNA included two small hairpins that appeared in over 50% of all molecules. Three open loops were observed with frequencies of less than 25%. In contrast, 23S rRNA included a terminal open loop and two additional large structures in over 75% of all molecules. These secondary structure patterns were conserved in the 16S and 23S rRNA from Pseudomonas aeruginosa. The secondary structure of the 30S precursor rRNA from the ribonclease III-deficient E. coli mutant AB105 was mapped after partial denaturation in 70% formamide-100 mM ammonium acetate. Two large open loops were superimposed on the 16S and 23S rRNA secondary structure patterns. These loops were the most frequent structures found on the precursor, and their stems coincided with ribonuclease III cleavage sites. A tentative 5'-3 orientation was determined for the secondary structure patterns of 16S and 23S rRNA from their relative locations within 30S precursor rRNA. The relation of secondary structure to ribosomal protein binding and ribonuclease III cleavage is discussed.     

Crucial elements that maintain the interactions between the regulatory TnaC peptide and the ribosome exit tunnel responsible for Trp inhibition of ribosome function

Translation of the TnaC nascent peptide inhibits ribosomal activity in the presence of l-tryptophan, inducing expression of the tnaCAB operon in Escherichia coli. Using chemical methylation, this work reveals how interactions between TnaC and the ribosome are affected by mutations in both molecules. The presence of the TnaC-tRNA(Pro) peptidyl-tRNA within the ribosome protects the 23S rRNA nucleotide U2609 against chemical methylation. Such protection was not observed in mutant ribosomes containing changes in 23S rRNA nucleotides of the A748-A752 region. Nucleotides A752 and U2609 establish a base-pair interaction. Most replacements of either A752 or U2609 affected Trp induction of a TnaC-regulated LacZ reporter. However, the single change A752G, or the dual replacements A752G and U2609C, maintained Trp induction. Replacements at the conserved TnaC residues W12 and D16 also abolished the protection of U2609 by TnaC-tRNA(Pro) against chemical methylation. These data indicate that the TnaC nascent peptide in the ribosome exit tunnel interacts with the U2609 nucleotide when the ribosome is Trp responsive. This interaction is affected by mutational changes in exit tunnel nucleotides of 23S rRNA, as well as in conserved TnaC residues, suggesting that they affect the structure of the exit tunnel and/or the nascent peptide configuration in the tunnel.     

Following the dynamics of changes in solvent accessibility of 16 S and 23 S rRNA during ribosomal subunit association using synchrotron-generated hydroxyl radicals

We have probed the structure and dynamics of ribosomal RNA in the Escherichia coli ribosome using equilibrium and time-resolved hydroxyl radical (OH) RNA footprinting to explore changes in the solvent-accessible surface of the rRNA with single-nucleotide resolution. The goal of these studies is to better understand the structural transitions that accompany association of the 30 S and 50 S subunits and to build a foundation for the quantitative analysis of ribosome structural dynamics during translation. Clear portraits of the subunit interface surfaces for 16 S and 23 S rRNA were obtained by constructing difference maps between the OH protection maps of the free subunits and that of the associated ribosome. In addition to inter-subunit contacts consistent with the crystal structure, additional OH protections are evident in regions at or near the subunit interface that reflect association-induced conformational changes. Comparison of these data with the comparable difference maps of the solvent-accessible surface of the rRNA calculated for the Thermus thermophilus X-ray crystal structures shows extensive agreement but also distinct differences. As a prelude to time-resolved OH footprinting studies, the reactivity profiles obtained using Fe(II)EDTA and X-ray generated OH were comprehensively compared. The reactivity patterns are similar except for a small number of nucleotides that have decreased reactivity to OH generated from Fe(II)EDTA compared to X-rays. These nucleotides are generally close to ribosomal proteins, which can quench diffusing radicals by virtue of side-chain oxidation. Synchrotron X-ray OH footprinting was used to monitor the kinetics of association of the 30 S and 50 S subunits. The rates individually measured for the inter-subunit contacts are comparable within experimental error. The application of this approach to the study of ribosome dynamics during the translation cycle is discussed.     

Structural analysis of three prokaryotic 5S rRNA species and selected 5S rRNA--ribosomal-protein complexes by means of Pb(II)-induced hydrolysis.

Lead ions have been applied to the structural analysis of 5S rRNA from Thermus thermophilus, Bacillus stearothermophilus and Escherichia coli. Based on the distribution of Pb(II)-induced cleavages, some minor modifications of the consensus secondary structure model of 5S rRNA are proposed. They include the possible base pairing between nucleotides at positions 11 and 109, as well as changes in secondary interactions within the helix B region. The 'prokaryotic arm' region is completely resistant to hydrolysis in the three RNA species, suggesting that it is a relatively stable, highly ordered structure. Hydrolysis of E. coli 5S rRNA complexed with ribosomal protein L18 shows, besides the shielding effect of the bound protein, a highly enhanced cleavage between A108 and A109. It supports the concept that the major L18-induced conformational change involves the junction of helices A, B and D.     

30S ribosomal subunits with fragmented 16S RNA: a new approach for structure and function study of ribosomes.

A new approach for function and structure study of ribosomes based on oligodeoxyribonucleotide-directed cleavage of rRNA with RNase H and subsequent reconstitution of ribosomal subunits from fragmented RNA has been developed. The E coli 16S rRNA was cleaved at 9 regions belonging to different RNA domains. The deletion of 2 large regions was also produced by cleaving 16S rRNA in the presence of 2 or 3 oligonucleotides complementary to different RNA sites. Fragmented and deleted RNA were shown to be efficiently assembled with total ribosomal protein into 30S-like particles. The capacity to form 70S ribosomes and translate both synthetic and natural mRNA of 30S subunits reconstituted from intact and fragmented 16S mRNA was compared. All 30S subunits assembled with fragmented 16S rRNA revealed very different activity: the fragmentation of RNA at the 781-800 and 1392-1408 regions led to the complete inactivation of ribosomes, whereas the RNA fragmentation at the regions 296-305, 913-925, 990-998, 1043-1049, 1207-1215, 1499-1506, 1530-1539 did not significantly influence the ribosome protein synthesis activity, although it was also reduced. These findings are mainly in accordance with the data on the functional activity of some 16S rRNA sites obtained by other methods. The relations between different 16S RNA functional sites are discussed.     

The PIN domain endonuclease Utp24 cleaves pre-ribosomal RNA at two coupled sites in yeast and humans

During ribosomal RNA (rRNA) maturation, cleavages at defined sites separate the mature rRNAs from spacer regions, but the identities of several enzymes required for 18S rRNA release remain unknown. PilT N-terminus (PIN) domain proteins are frequently endonucleases and the PIN domain protein Utp24 is essential for early cleavages at three pre-rRNA sites in yeast (A0, A1 and A2) and humans (A0, 1 and 2a). In yeast, A1 is cleaved prior to A2 and both cleavages require base-pairing by the U3 snoRNA to the central pseudoknot elements of the 18S rRNA. We found that yeast Utp24 UV-crosslinked in vivo to U3 and the pseudoknot, placing Utp24 close to cleavage at site A1. Yeast and human Utp24 proteins exhibited in vitro endonuclease activity on an RNA substrate containing yeast site A2. Moreover, an intact PIN domain in human UTP24 was required for accurate cleavages at sites 1 and 2a in vivo, whereas mutation of another potential site 2a endonuclease, RCL1, did not affect 18S production. We propose that Utp24 cleaves sites A1/1 and A2/2a in yeast and human cells.