Structure of a U.U pair within a conserved ribosomal RNA hairpin.

A conserved hairpin corresponding to nt 1057-1081 of large subunit rRNA (Escherichia coli numbering) is part of a domain targeted by antibiotics and ribosomal protein L11. The stem of the hairpin contains a U.U juxtaposition, found as either U.U or U.C in virtually all rRNA sequences. This hairpin has been synthesized and most of the aromatic and sugar protons were assigned by two-dimensional proton NMR. Distances and sugar puckers deduced from the NMR data were combined with restrained molecular dynamics calculations to deduce structural features of the hairpin. The two U residues are stacked in the helix, form one NH3-O4 hydrogen bond and require an extended backbone conformation (trans alpha and gamma) at one of the U nucleotides. The hairpin loop, UAGAAGC closed by a U-A pair, is the same size as tRNA anticodon loops, but not as well ordered.     

Thermodynamics of protein-RNA recognition in a highly conserved region of the large-subunit ribosomal RNA

Ribosomal protein L11 from Escherichia coli specifically binds to a highly conserved region of 23S ribosomal RNA. The thermodynamics of forming a complex between this protein and several different rRNA fragments have been investigated, by use of a nitrocellulose filter binding assay. A 57-nucleotide region of the RNA (C1052-U1108) contains all the protein recognition features, and an RNA fragment containing this region binds L11 10(3)-10(4)-fold more tightly than tRNA. Binding constants are on the order of 10 microM-1 and are only weakly dependent on K+ concentration (delta log K/delta log [K+] = -1.4) or temperature. Binding requires multivalent cations; Mg2+ is taken up into the complex with an affinity of approximately 3 mM-1. Other multivalent cations tested, Ca2+ and Co(NH3)63+, promote binding nearly as well. The pH dependence of binding is a bell-shaped curve with a maximum near neutral pH, but the entire curve is shifted to higher pH for the smaller of two RNA fragments tested. This result suggests that the smaller fragment favors a conformation stabilizing protonated forms of the RNA recognition site and is potentially relevant to a hypothesis that this rRNA region undergoes an ordered series of conformational changes during the ribosome cycle.     

Fine structure of ribosomal RNA. III. Location of evolutionarily conserved regions within ribosomal DNA

In order to define functional regions within ribosomal RNA, we have identified areas of the molecule which have been conserved during evolution. Our previous studies showed that there is evolutionary conservation between the rRNAs of different eukaryotes and that the sequences conserved between distantly related species are a subset of those conserved between closely related species. In the present work, we have employed DNA-DNA and DNA-RNA hybridization techniques to localize these conserved regions to mapped restriction fragments 50 to 300 base-pairs in length within cloned Xenopus laevis ribosomal DNA. Our experiments have detected evolutionary conservation only within the coding regions, suggesting that if there is any conservation within the spacers, these sequences must be very short. Regions of conservation can be classified either by evolutionary distance or by the extent of conservation between two species. Three regions, including one near the 3' end of 18 S and two near the 3' end of 28 S rRNA are conserved over great evolutionary distance, that is between Escherichia coli and X. laevis. In addition, several fragments in the central portions of the 188 and 28 S rRNAs are exceptional in the extent of their conservation between yeast and Xenopus. We have been able to correlate the regions we have defined as conserved with certain structural or functional roles, such as initiation of translation, possible interaction with transfer RNA, rRNA methylation, and the site where intervening sequences interrupt some eukaryotic rRNAs. As a result, these studies serve to define relatively short (less than 300 base-pairs) segments within the almost 11,000 base X. laevis rDNA repeat unit which are worthy of further investigation.     

RNA apatamers for yeast ribosomal protein L32 have a conserved purine-rich internal loop.

Two in vitro selection experiments were conducted to determine the RNA sequence requirements for binding ribosomal protein L32 (RPL32) from Saccharomyces cerevisiae. To preserve the wild-type stem-internal loop-stem fold, only a limited portion of the RNA comprising the internal loop region was randomized. Most of the selected RNAs have secondary structures similar to that of the wild-type, and four purines on both sides of the internal loop are highly conserved. Indeed, a pair of 5'-GA-3' dinucleotides is found in all but one of the stem-loop-stem L32 aptamers and these conserved purines may contact the protein directly or form a necessary RNA secondary or tertiary structure. These aptamers have a potential G:U pair bordering the loop adjacent to the conserved GAs, but a cytidine replaces a phylogenetically conserved adenosine at one loop position in many of the selected RNAs. In model RNAs, the cytidine-bearing variant binds protein slightly more strongly than does the wild-type RNA. That the seven-member, 2 + 5 internal loop is important for protein binding is reinforced by the finding that the position, but not the size, of the loop is variable. A minority of the RNA aptamers has three consecutive uridines and may fold into a similar structure, but with the internal loop inverted.     

The RNA binding domain of the hantaan virus N protein maps to a central, conserved region

The nucleocapsid (N) protein of hantaviruses encapsidates both viral genomic and antigenomic RNAs, although only the genomic viral RNA (vRNA) is packaged into virions. To define the domain within the Hantaan virus (HTNV) N protein that mediates these interactions, 14 N- and C-terminal deletion constructs were cloned into a bacterial expression vector, expressed, and purified to homogeneity. Each protein was examined for its ability to bind the HTNV S segment vRNA with filter binding and gel electrophoretic mobility shift assays. These studies mapped a minimal region within the HTNV N protein (amino acids 175 to 217) that bound vRNA. Sequence alignments made from several hantavirus N protein sequences showed that the region identified has a 58% identity and an 86% similarity among these amino acid sequences. Two peptides corresponding to amino acids 175 to 196 (N1) and 197 to 218 (N2) were synthesized. The RNA binding of each peptide was measured by filter binding and competition analysis. Three oligoribonucleotides were used to measure binding affinity and assess specificity. The N2 peptide contained the major RNA binding determinants, while the N1 peptide, when mixed with N2, contributed to the specificity of vRNA recognition.     

Fibrillarin genes encode both a conserved nucleolar protein and a novel small nucleolar RNA involved in ribosomal RNA methylation in Arabidopsis thaliana

Fibrillarin is a key nucleolar protein in eukaryotes which associates with box C/D small nucleolar RNAs (snoRNAs) directing 2'-O-ribose methylation of the rRNA. In this study we describe two genes in Arabidopsis thaliana, AtFib1 and AtFib2, encoding nearly identical proteins conserved with eukaryotic fibrillarins. We demonstrate that AtFib1 and AtFib2 proteins are functional homologs of the yeast Nop1p (fibrillarin) and can rescue a yeast NOP1-null mutant strain. Surprisingly, for the first time in plants, we identified two isoforms of a novel box C/D snoRNA, U60.1f and U60.2f, nested in the fifth intron of AtFib1 and AtFib2. Interestingly after gene duplication the host intronic sequences completely diverged, but the snoRNA was conserved, even in other crucifer fibrillarin genes. We show that the U60f snoRNAs accumulate in seedlings and that their targeted residue on the 25 S rRNA is methylated. Our data reveal that the three modes of expression of snoRNAs, single, polycistronic, and intronic, exist in plants and suggest that the mechanisms directing rRNA methylation, dependent on fibrillarin and box C/D snoRNAs, are evolutionarily conserved in plants.     

Mutations in the intersubunit bridge regions of 23 S rRNA

The large and small subunits of the ribosome are joined by a series of bridges that are conserved among mitochondrial, bacterial, and eukaryal ribosomes. In addition to joining the subunits together at the initiation of protein synthesis, a variety of other roles have been proposed for these bridges. These roles include transmission of signals between the functional centers of the two subunits, modulation of tRNA-ribosome and factor-ribosome interactions, and mediation of the relative movement of large and small ribosomal subunits during translocation. The majority of the bridges involve RNA-RNA interactions, and to gain insight into their function, we constructed mutations in the 23 S rRNA regions involved in forming 7 of the 12 intersubunit bridges in the Escherichia coli ribosome. The majority of the mutants were viable in strains expressing mutant rRNA exclusively but had distinct growth phenotypes, particularly at 30 degrees C, and the mutant ribosomes promoted a variety of miscoding errors. Analysis of subunit association activities both in vitro and in vivo indicated that, with the exception of the bridge B5 mutants, at least one mutation at each bridge site affected 70 S ribosome formation. These results confirm the structural data linking bridges with subunit-subunit interactions and, together with the effects on decoding fidelity, indicate that intersubunit bridges function at multiple stages of protein synthesis.     

The intersubunit disulfide bridge of ricin is essential for cytotoxicity

Alkylation of the cysteine residues which link the A and B chains of ricin through a disulfide bridge produces a molecule which still binds to HeLa cells and is toxic toward in vitro ribosome-directed translation, but which has little or no cytotoxicity toward cells in culture. This and similar observations on diphtheria toxin implicate the intersubunit disulfide bridge in the transport of the toxic subunits of these toxins into the cytoplasm.     

Evolutionarily conserved binding of ribosomes to the translocation channel via the large ribosomal RNA

During early stages of cotranslational protein translocation across the endoplasmic reticulum (ER) membrane the ribosome is targeted to the heterotrimeric Sec61p complex, the major component of the protein-conducting channel. We demonstrate that this interaction is mediated by the 28S rRNA of the eukaryotic large ribosomal subunit. Bacterial ribosomes also bind via their 23S rRNA to the bacterial homolog of the Sec61p complex, the SecYEG complex. Eukaryotic ribosomes bind to the SecYEG complex, and prokaryotic ribosomes to the Sec61p complex. These data indicate that rRNA-mediated interaction of ribosomes with the translocation channel occurred early in evolution and has been conserved.     

Contribution of intersubunit bridges to the energy barrier of ribosomal translocation

In every round of translation elongation, EF-G catalyzes translocation, the movement of tRNAs (and paired codons) to their adjacent binding sites in the ribosome. Previous kinetic studies have shown that the rate of tRNA–mRNA movement is limited by a conformational change in the ribosome termed ‘unlocking’. Although structural studies offer some clues as to what unlocking might entail, the molecular basis of this conformational change remains an open question. In this study, the contribution of intersubunit bridges to the energy barrier of translocation was systematically investigated. Unlike those targeting B2a and B3, mutations that disrupt bridges B1a, B4, B7a and B8 increased the maximal rate of both forward (EF-G dependent) and reverse (spontaneous) translocation. As bridge B1a is predicted to constrain 30S head movement and B4, B7a and B8 are predicted to constrain intersubunit rotation, these data provide evidence that formation of the unlocked (transition) state involves both 30S head movement and intersubunit rotation.     

Interaction of ribosomal proteins, S6, S8, S15 and S18 with the central domain of 16 S ribosomal RNA

We have constructed complexes of ribosomal proteins S8, S15, S8 + S15 and S8 + S15 + S6 + S18 with 16 S ribosomal RNA, and probed the RNA moiety with a set of structure-specific chemical and enzymatic probes. Our results show the following effects of assembly of proteins on the reactivity of specific nucleotides in 16 S rRNA. (1) In agreement with earlier work, S8 protects nucleotides in and around the 588-606/632-651 stem from attack by chemical probes; this is supported by protection in and around these same regions from nucleases. In addition, we observe protection of positions 573-575, 583, 812, 858-861 and 865. Several S8-dependent enhancements of reactivity are found, indicating that assembly of this protein is accompanied by conformational changes in 16 S rRNA. These results imply that protein S8 influences a much larger region of the central domain than was previously suspected. (2) Protein S15 protects nucleotides in the 655-672/734-751 stem, in agreement with previous findings. We also find S15-dependent protection of nucleotides in the 724-730 region. Assembly of S15 causes several enhancements of reactivity, the most striking of which are found at G664, A665, G674, and A718. (3) The effects of proteins S6 and S18 are dependent on the simultaneous presence of both proteins, and on the presence of protein S15. S6 + S18-dependent protections are located in the 673-730 and 777-803 regions. We observed some variability in our results with these proteins, depending on the ratio of protein to RNA used, and in different trials using enzymatic probes, possibly due to the limited solubility of protein S18. Consistently reproducible was protection of nucleotides in the 664-676 and 715-729 regions. Among the latter are three of the nucleotides (G664, G674 and A718) that are strongly enhanced by assembly of protein S15. This result suggests that an S15-induced conformational change involving these nucleotides may play a role in the co-operative assembly of proteins S6 and S18.     

Recognition of the highly conserved GTPase center of 23 S ribosomal RNA by ribosomal protein L11 and the antibiotic thiostrepton

The antibiotic thiostrepton, a thiazole-containing peptide, inhibits translation and ribosomal GTPase activity by binding directly to a limited and highly conserved region of the large subunit ribosomal RNA termed the GTPase center. We have previously used a filter binding assay to examine the binding of ribosomal protein L11 to a set of ribosomal RNA fragments encompassing the Escherichia coli GTPase center sequence. We show here that thiostrepton binding to the same RNA fragments can also be detected in a filter binding assay. Binding is relatively independent of monovalent salt concentration and temperature but requires a minimum Mg2+ concentration of about 0.5 mM. To help determine the RNA features recognized by L11 and thiostrepton, a set of over 40 RNA sequence variants was prepared which, taken together, change every nucleotide within the 1051 to 1108 recognition domain while preserving the known secondary structure of the RNA. Binding constants for L11 and thiostrepton interaction with these RNAs were measured. Only a small number of sequence variants had more than fivefold effects on L11 binding affinities, and most of these were clustered around a junction of helical segments. These same mutants had similar effects on thiostrepton binding, but more than half of the other sequence changes substantially reduced thiostrepton binding. On the basis of these data and chemical modification studies of this RNA domain in the literature, we propose that L11 makes few, if any, contacts with RNA bases, but recognizes the three-dimensional conformation of the RNA backbone. We also argue from the data that thiostrepton is probably sensitive to small changes in RNA conformation. The results are discussed in terms of a model in which conformational flexibility of the GTPase center RNA is functionally important during the ribosome elongation cycle.     

Mechanism of translation based on intersubunit complementarities of ribosomal RNAs and tRNAs

A universal rule is found about nucleotide sequence complementarities between the regions 2653-2666 in the GTPase-binding site of 23S rRNA and 1064-1077 of 16S rRNA as well as between the region 1103-1107 of 16S rRNA and GUUCG (or GUUCA) of tRNAs. This rule holds for all species in the living kingdoms except for two protista mitochondrial rRNAs of Trypanosoma brucei and Plasmodium falciparum. We found that quite similar relationships for the two species hold under the assumption presented in the present paper. The complementarity between T-loop of tRNA and the region 1103-1107 of 16S rRNA suggests that the first interaction of a ribosome with aminoacyl-tRNAEF-TuGTP ternary complex or EF-GGDP complex could occur at the region 1103-1107 of 16S rRNA with the T-loop-D-loop contact region of the ternary complex or the domain IV-V bridge region of the EF-GGDP complex. The second interaction should occur between the A-site codon and the anticodon loop or between the anticodon stem/loop of A-site tRNA and the tip of domain IV of EF-G. The above stepwise interactions would facilitate the collision of the region 1064-1077 of 16S rRNA with the region around A2660 at the alpha-sarcin/ricin loop of 23S rRNA. In this way, the universal rule is capable of explaining how spectinomycin-binding region of 16S rRNA takes part in translocation, how GTPases such as EF-Tu and EF-G can be introduced into their binding site on the large subunit ribosome in proper orientation efficiently and also how driving forces for tRNA movement are produced in translocation and codon recognition. The analysis of T-loops of all tRNAs also presents an evolutionary trend from a random and seemingly primitive sequence, as defined to be Y type, to the most developed structure, such as either 5G7 or 5A7 types in the present definition.     

Deletion of a ribosomal ribonucleic acid operon in Escherichia coli.

One (rrnE) of the seven operons which codes for ribosomal ribonucleic acid in Escherichia coli was deleted. No significant change in phenotype was observed even under maximum laboratory growth conditions.     

Complementarity of conserved sequence elements present in 28S ribosomal RNA and in ribosomal protein genes of Xenopus laevis and Xenopus tropicalis

The sequence analysis of the L1 ribosomal protein (r-protein) gene of Xenopus laevis has revealed a strong homology in four out of the nine introns of the gene; this homology region spans 60 nucleotides (nt) with 80% homology [Loreni et al., EMBO J. 4 (1985) 3483-3488]. We have extended our analysis to X. tropicalis, a species which is closely related to X. laevis. Partial sequencing of the isolated L1 gene has revealed that these 60-nt homology regions are also present in at least two introns of the X. tropicalis L1 gene. Computer analysis has revealed that perfect nt sequence complementarity exists between 13 nt of this intron region and the 28S ribosomal RNA in a region which is conserved in all eukaryotes, suggesting a possible base-pairing interaction between these two sequences.