Cross-linking of the anticodon of Escherichia coli and Bacillus subtilis acetylvalyl-tRNA to the ribosomal P site. Characterization of a unique site in both E. coli 16S and yeast 18S ribosomal RNA

Possible interaction sites of mRNA, tRNA, translation factors and the nascent peptide in 5S, 5.8S and 28S rRNA in in vivo assembled eukaryotic ribosomal complexes

We have investigated possible interaction sites for mRNA, tRNA, translation factors and the nascent peptide on 5S, 5.8S and 28S rRNA in in vivo assembled translational active mouse ribosomes by comparing the chemical footprinting patterns derived from native polysomes, salt-washed polysomes (mainly lacking translational factors) and salt-washed runoff ribosomes (lacking mRNA, tRNA and translational factors). Several ligand-induced footprints were observed in 28S rRNA while no reactivity changes were seen in 5S and 5.8S rRNA. Footprints derived from mRNA, tRNA and/or the nascent peptide chain were observed in domain I of 28S rRNA (hairpin 23), in domain II (helix 37/38 and helices 42 and 43 and in the eukaryotic expansion segment 15), in domain IV (helices 67 and 74) and in domain V (helices 94 and 96 and in the peptidyl transferase ring). Some of the protected sites were homologous to sites previously suggested to be involved in mRNA, tRNA and/or peptide binding in in vitro assembled prokaryotic complexes. Additional footprints were located in regions that have not previously been found involved in ligand binding. Part of these sites could derive from the nascent peptide in the exit channel of the ribosome.

An antibiotic-binding motif of an RNA fragment derived from the A-site-related region of Escherichia coli 16S rRNA

A small RNA derived from the decoding region of Escherichia coli 16S rRNA can bind to antibiotics of aminoglycosides (neomycin and paromomycin) that act on the small ribosomal subunit [Purohit,P. and Stern,S. (1994) Nature, 370, 659-662]. In the present study, the P-site subdomain was removed from this decoding region RNA to construct a 27mer RNA (designated as ASR-27), which includes the A-site-related region (positions 1402-1412 and 1488-1497) of 16S rRNA. Footprint experiments with dimethyl sulfate as a chemical probe indicated that the ASR-27 RNA can interact with the neomycin family in the same manner as the decoding region RNA. A mutagenesis analysis of the ASR-27 RNA revealed that paromomycin binding of ASR-27 involves the C1407.G1494 and C1409-G1491 base pairs, and the internal loop comprising A1408 and the nucleotides in positions 1492-1493, located between the two C.G base pairs. In addition, a G or U in position 1495, and base pairing between positions 1405 and 1496 are also involved. These structural features were found in a viral RNA element, the Rev-binding site of human immunodeficiency virus type-1, which may explain why neomycin can bind to this viral RNA.

Pseudouridine and O2'-methylated nucleosides. Significance of their selective occurrence in rRNA domains that function in ribosome-catalyzed synthesis of the peptide bonds in proteins

Pseudouridine (5-ribosyluracil, psi) was the first of a host of modified nucleoside constituents detected in cellular RNA and it remains the most abundant, being broadly distributed in the RNA of archaebacteria, eubacteria and eukaryotes. Like some other modifications, psi is particularly abundant in more complex organisms, reaching 2-3% of the total nucleoside constituents in tRNA, snRNA and rRNA of multicellular plants and animals. Like all other modified nucleosides, psi arises by site-specific, enzymically catalyzed modification of a nucleoside residue in an RNA molecule. Unlike all other modified nucleosides, psi arises by isomerisation (not substitution) of a classical nucleoside, uridine (1-ribosyluracil). There have been suggestions that key processes such as ribosome assembly and peptidyl transfer may rely, more than is generally appreciated, on RNA modifications such as O2'-methylation and pseudouridylation, respectively. However, a persuasive case for the view that secondary modifications are of primary importance in ribosome function has not been convincingly made. Accordingly, we think it is timely to broaden what is generally meant by the 'catalytic properties of rRNA', and to ask, to what extent do modifications contribute to in vivo rates of ribosome assembly and ribosomal peptide-bond synthesis? The first part of this article sets forth the evidence that there is a conspicuous association between modified nucleosides and cellular RNAs that participate in group-transfer reactions. The second part reviews evidence in support of the view that the functions of psi and other modified nucleosides are likely of central importance for understanding the dynamics and stereostructural modeling at functionally significant sites in the ribosome.

G1401: a keystone nucleotide at the decoding site of Escherichia coli 30S ribosomes

16S ribosomal RNA contains three highly conserved single-stranded regions. Centrally located in one of these regions is the C1400 residue. Zero-length cross-linking of this residue to the anticodon of ribosome-bound tRNA showed that it was at or near the ribosomal decoding site [Ehresmann, C., Ehresmann, B., Millon, R., Ebel, J-P., Nurse, K., & Ofengand, J. (1984) Biochemistry 23, 429-437]. To assess the functional significance of sequence conservation of rRNA in the vicinity of this functionally important site, a series of site-directed mutations in this region were constructed and the effects of these mutations on the partial reactions of protein synthesis determined. Mutation of C1400 or C1402 to any other base only moderately affected a set of in vitro protein synthesis partial reactions. However, any base change from the normal G1401 residue blocked all of the tested ribosomal functions. This was also true for the deletion of G1401. Deletion of C1400 or C1402 had more complex effects. Whereas subunit association was hardly affected, 30S initiation complex formation was blocked by deletion of C1400 but much less so by deletion of C1402. Alternatively, tRNA binding to the ribosomal A site was more strongly affected by deletion of C1402 than by deletion of C1400. P site binding was inhibited by either deletion. HPLC analysis of the in vitro reconstituted mutant ribosomes showed that none of the functional effects were due to the absence or gross reduction in amount of any ribosomal protein.(ABSTRACT TRUNCATED AT 250 WORDS)

Photochemical cross-linking of the anticodon loop of yeast tRNA(Phe) to 30S-subunit protein S7 at the ribosomal A and P sites

Yeast tRNA(Phe), containing the photoreactive nucleoside 2-azidoadenosine at position 37 within the anticodon loop, has been cross-linked to the aminoacyl-tRNA (A) and peptidyl-tRNA (P) binding sites of the Escherichia coli ribosome. The 30S subunit was exclusively labeled in each case, and cross-linking occurred to both protein and 16S rRNA. Electrophoretic and immunological analyses demonstrated that S7 was the only 30S-subunit protein covalently attached to the tRNA. However, digestion of the A and P site-labeled S7 with trypsin revealed a unique pattern of cross-linked peptide(s) at each site. Thus, while the anticodon loop of tRNA is in close proximity to protein S7 at both the A and P sites, it neighbors a different portion of the protein molecule in each. The placement of the aminoacyl- and peptidyl-tRNA binding sites is discussed in relationship to recent models of the 30S ribosomal subunit.

Assembly of the Escherichia coli 30S ribosomal subunit reveals protein-dependent folding of the 16S rRNA domains

Protein-nucleic acid interactions involved in the assembly process of the Escherichia coli 30S ribosomal subunit were quantitatively analyzed by high-resolution scanning transmission electron microscopy. The in vitro reconstituted ribonucleoprotein (core) particles were characterized by their morphology, mass, and radii of gyration. During the assembly of the 30S subunit, the 16S rRNA underwent significant conformational changes that were governed by the cooperative interactions of the ribosomal proteins. The sequential association of the first 12 proteins with the 16S rRNA resulted in the formation of core particles containing up to three mass centers at distinct stages of the assembly process. These globular mass centers may correspond to the three major domains (5', central, and 3') of the 16S rRNA. Through the subsequent interactions of the late assembly proteins with the 16S rRNA, two of the three domains merge, yielding the basic structural traits of the native 30S subunit. The fine morphological features of the native 30S subunit became distinctly resolved only after the addition of the full complement of proteins. The fully reconstituted 30S subunits are active in polyphenylalanine synthesis assays. Visualization of the assembly mechanism of the E. coli 30S ribosomal subunit revealed domain-specific folding of the 16S rRNA through the formation of distinct intermediate core particles hitherto not observed.

The side-by-side model of two tRNA molecules allowing the alpha-helical conformation of the nascent polypeptide during the ribosomal transpeptidation

Lim and Spirin [25] proposed a preferable conformation of the nascent peptide during the ribosomal transpeptidation. Spirin and Lim [26] excluded the possibilities of the side-by-side model proposed by Johnson et al [13] and the three-tRNA binding model (A, P and E sites) of Rheinberger and Nierhaus [3]. However, a slight conformational change at the 3' end regions of both A and P site tRNA molecules can enable the three different tRNA binding models to converge. With a modification of the angles of the ribose rings of both anticodon and mRNA this model can also be related to the model of Sundaralingam et al [19]. In this model of E coli rRNA the 3' end sequence ACCA76 or GCCA76 of P site tRNA is base-paired to UGGU810 of 23S rRNA, while the ACC75 or GCC75 of A site tRNA are base-paired to GGU1621 23S rRNA. The conformation of the A76 of A site tRNA is necessarily different from that of P site tRNA, at least during the course of the transpeptidation. The A76 of A site tRNA overlaps the binding region of puromycin. The C1400 of 16S rRNA in this model is located at a distance of 4 A from the 5' end of the anticodon of P site tRNA [14] and 17 A from the 5' end of the anticodon of A site tRNA [15]. It is also shown that a considerable but reasonable modification in the conformation of the anticodon loops could lead to accommodation of three deacylated tRNA(Phe) molecules at a time on 70S ribosome in the presence of poly(U) as observed experimentally [6]. A sterochemical explanation for the negatively-linked allosteric interactions between the A and E sites is also shown in the present model.

The conformation of the initiator tRNA and of the 16S rRNA from Escherichia coli during the formation of the 30S initiation complex

The conformation of the E. coli initiator tRNA and of the 16S rRNA at different steps leading to the 30S.IF2.fMet-ARN(fMet).AUG.GTP complex has been investigated using several structure-specific probes. As compared to elongator tRNA, the initiator tRNA exhibits specific structural features in the anticodon arm, the T and D loops and the acceptor arm. Initiation factor 2 (IF2) interacts with the T-loop and the minor groove of the T stem of the RNA, and induces an increased flexibility in the anticodon arm. In the 30S initiation complex, additional protection is observed in the acceptor stem and in the anticodon arm of the tRNA. Within the 30S subunit, IF2 does not significantly shield defined portions of 16S rRNA, but induces both reduction and enhancement of reactivity scattered in the entire molecule. Most are constrained in a region corresponding to the cleft, the lateral protrusion and the part of the head facing the protrusion. All the reactivity changes induced by the binding of IF2 are still observed in the presence of the initiator tRNA and AUG message. The additional changes induced by the tRNA are mostly centered around the cleft-head-lateral protrusion region, near positions affected by IF2 binding.

Photochemical cross-linking of yeast tRNA(Phe) containing 8-azidoadenosine at positions 73 and 76 to the Escherichia coli ribosome

The 3'-terminal -A-C-C-A sequence of yeast tRNA(Phe) has been modified by replacing either adenosine-73 or adenosine-76 with the photoreactive analogue 8-azidoadenosine (8N3A). The incorporation of 8N3A into tRNA(Phe) was accomplished by ligation of 8-azidoadenosine 3',5'-bisphosphate to the 3' end of tRNA molecules which were shortened by either one or four nucleotides. Replacement of the 3'-terminal A76 with 8N3A completely blocked aminoacylation of the tRNA. In contrast, the replacement of A73 with 8N3A has virtually no effect on the aminoacylation of tRNA(Phe). Neither substitution hindered binding of the modified tRNAs to Escherichia coli ribosomes in the presence of poly(U). Photoreactive tRNA derivatives bound noncovalently to the ribosomal P site were cross-linked to the 50S subunit upon irradiation at 300 nm. Nonaminoacylated tRNA(Phe) containing 8N3A at either position 73 or position 76 cross-linked exclusively to protein L27. When N-acetylphenylalanyl-tRNA(Phe) containing 8N3A at position 73 was bound to the P site and irradiated, 23S rRNA was the main ribosomal component labeled, while smaller amounts of the tRNA were cross-linked to proteins L27 and L2. Differences in the labeling pattern of nonaminoacylated and aminoacylated tRNA(Phe) containing 8N3A in position 73 suggest that the aminoacyl moiety may play an important role in the proper positioning of the 3' end of tRNA in the ribosomal P site. More generally, the results demonstrate the utility of 8N3A-substituted tRNA probes for the specific labeling of ribosomal components at the peptidyltransferase center.

Direct localization of the tRNA--anticodon interaction site on the Escherichia coli 30 S ribosomal subunit by electron microscopy and computerized image averaging

Previous immunoelectron microscopy studies have shown that the anticodon of valyl-tRNA, photocrosslinked to the ribosomal P site at the C1400 residue of the 16 S RNA, is located in the vicinity of the cleft of the small ribosomal subunit of Escherichia coli. In this study we used single-particle image-averaging techniques to demonstrate that the 30 S-bound tRNA molecule can be localized directly, without the need for specific antibody markers. In agreement with the immunoelectron microscopy results, we find that the tRNA molecule appears to be located deep in the cleft of the 30 S subunit. We believe that the use of computer image averaging to localize ligands bound to ribosomes and other macromolecular complexes will become widespread because of the superior sensitivity, precision and objectivity of this technique compared with conventional immunoelectron microscopy.

Prediction of three-dimensional structure of Escherichia coli ribosomal RNA

A model for the tertiary structure of 23S, 16S and 5S ribosomal RNA molecules interacting with three tRNA molecules is presented using the secondary structure models common to E. coli, Z. mays chloroplast, and mammalian mitochondria. This ribosomal RNA model is represented by phosphorus atoms which are separated by 5.9 A in the standard A-form double helix conformation. The accumulated proximity data summarized in Table 1 were used to deduce the most reasonable assembly of helices separated from each other by at least 6.2 A. Straight-line approximation for single strands was adopted to describe the maximum allowed distance between helices. The model of a ribosome binding three tRNA molecules by Nierhaus (1984), the stereochemical model of codon-anticodon interaction by Sundaralingam et al. (1975) and the ribosomal transpeptidation model, forming an alpha-helical nascent polypeptide, by Lim & Spirin (1986), were incorporated in this model. The distribution of chemically modified nucleotides, cross-linked sites, invariant and missing regions in mammalian mitochondrial rRNAs are indicated on the model.

Crosslinking of the anticodon of P site bound tRNA to C-1400 of E.coli 16S RNA does not require the participation of the 50S subunit

Crosslinking of the 5'-anticodon base of ribosomal P site bound AcVal-tRNA to residue C-1400 of 16S RNA or to its equivalent in 18S RNA has been shown to occur on 70S or 80S ribosomes of both prokaryotes and eukaryotes [Ciesiolka, J., Nurse, K., Klein, J. and Ofengand, J. (1985) Biochemistry 24, 3233-3239]. In the present work, we show that the crosslinking rate, crosslinking yield, and site of crosslinking are all unchanged when the 50S subunit is omitted. Therefore, all of the positional features of tRNA-ribosome complexes which allow crosslinking to occur are entirely contained in the 30S subunit. Blockage of reverse transcription by crosslink formation was used to determine the site of crosslinking. This analysis revealed that RNA modifications which do not directly block base-pairing ligands sometimes allow the modified base to be transcribed, leading to doublet band formation even when there is only a single crosslink site.

Covalent cross-linking of AcVal-tRNA to Tetrahymena thermophila cytoplasmic ribosomes and two of its 17S rRNA mutants

Tetrahymena thermophila 80S ribosomes have been cross-linked to non-enzymatically bound AcVal-tRNA, presumably at the ribosomal P-site. Like the ribosomes from Escherichia coli, yeast, and Artemia salina, cross-linking is exclusively to C-1609, the equivalent of the E. coli C-1400 residue. Mutation of the RNA from G-1707 to A or from U-1711 to C which results in resistance to paromomycin or hygromycin, respectively, failed to affect the rate, yield, or site of cross-linking. The presence of the antibiotics during cross-linking also was without effect. It is concluded that at these two positions the base changes made do not interfere with the tertiary structure of the decoding site.

Higher-order structure of domain III in Escherichia coli 16S ribosomal RNA, 30S subunit and 70S ribosome

We have investigated in detail the conformation of domain III of 16S rRNA (nucleotides 913-1408), using a variety of chemical and enzymatic structure probes. The sites of reaction were identified by primer extension with reverse transcriptase using appropriate oligodeoxyribonucleotide primers. This study has been done on 16S rRNA in its naked form, in the 30S subunit and in the 70S ribosome. Data obtained with naked RNA broadly confirm the secondary structure model proposed essentially by comparative sequence analysis, and allow identification of nucleotides involved in tertiary interactions. Our results are in reasonably good agreement with structure probing experiments of Moazed et al. [1]. However, several discrepancies have been observed. Within the 30S subunit, a high number of nucleotides become unreactive whereas other nucleotides show an enhanced reactivity. This probably reflects local conformational changes. Interestingly, they are located in strategic regions of the RNA, e.g. around C1400 (involved in tRNA binding) and C1192 (involved in spectinomycin recognition). Results are also discussed together with the topographical localization of the ribosomal proteins in this area. The study on the 70S particle allows identification of regions at the interface of subunits or exposed at the surface of the ribosome.

Cross-linking of initiation factor IF3 to Escherichia coli 30S ribosomal subunit by trans-diamminedichloroplatinum(II): characterization of two cross-linking sites in 16S rRNA; a possible way of functioning for IF3

The initiation factor IF3 is platinated with trans-diamminedichloroplatinum(II) and cross-linked to Escherichia coli 30S ribosomal subunit. Two cross-linking sites are unambiguously identified on the 16S rRNA: a major one, in the region 819-859 in the central domain, and a minor one, in the region 1506-1529 in the 3'-terminal domain. Specific features of these sequences together with their particular location within the 30S subunit lead us to postulate a role for IF3, that conciliates topographical and functional observations made so far.

Point mutations define a sequence flanking the AUG initiator codon that modulates translation by eukaryotic ribosomes

By analyzing the effects of single base substitutions around the ATG initiator codon in a cloned preproinsulin gene, I have identified ACCATGG as the optimal sequence for initiation by eukaryotic ribosomes. Mutations within that sequence modulate the yield of proinsulin over a 20-fold range. A purine in position -3 (i.e., 3 nucleotides upstream from the ATG codon) has a dominant effect; when a pyrimidine replaces the purine in position -3, translation becomes more sensitive to changes in positions -1, -2, and +4. Single base substitutions around an upstream, out-of-frame ATG codon affect the efficiency with which it acts as a barrier to initiating at the downstream start site for preproinsulin. The optimal sequence for initiation defined by mutagenesis is identical to the consensus sequence that emerged previously from surveys of translational start sites in eukaryotic mRNAs. The mechanism by which nucleotides flanking the ATG codon might exert their effect is discussed.

Identification of the site of cross-linking in 16S rRNA of an aromatic azide photoaffinity probe attached to the 5'-anticodon base of A site bound tRNA

The site of Escherichia coli 16S ribosomal RNA cross-linked to the 5'-anticodon base of A site bound E. coli valyl-tRNA was identified. Cross-linking was via the affinity probe 6-[(2-nitro-4-azidophenyl)amino]caproate (NAK) or 3-[[2-[(2-nitro-4-azidophenyl)amino]ethyl]dithio]propionate (SNAP) attached to the carboxyl group of the 5'-anticodon base 5-(carboxyethoxy)uridine via an ethylenediamine spacer [Gornicki, P., Ciesiolka, J., & Ofengand, J. (1985) Biochemistry (preceding paper in this issue)]. With both probes, RNase T1 digestion of the isolated 16S RNA-tRNA covalent complex, 5'-32P postlabeling, and gel electrophoresis yielded two oligonucleotides larger than any fragments from non-cross-linked tRNA or rRNA. Appearance of the oligomers was dependent on the presence of the probe on the tRNA. Unmodified tRNA in the A and/or P sites did not yield any product. The presence of elongation factor Tu in the incubation mixture was also required. Dithiothreitol (DDT) treatment of the SNAP-induced covalent complex prior to electrophoresis also abolished the oligomers. Only the larger of the two oligomers (present in a 3:1 ratio) was sequenced. The SNAP dimer was cleaved with DTT, and the rRNA and tRNA oligomers were separated and sequenced as monomers. The NAK dimer was sequenced without cleavage by taking advantage of the differences in electrophoretic mobility among sequence and/or composition isomers of the same length. In both cases, the rRNA oligomer was identified as UACACACCG1401, and the nucleotide cross-linked was shown to be the C1400 residue. The expected tRNA modification site was also identified.(ABSTRACT TRUNCATED AT 250 WORDS)

Cross-linking of the anticodon of P and A site bound tRNAs to the ribosome via aromatic azides of variable length: involvement of 16S rRNA at the A site

The topography of the ribosomal decoding site was explored by affinity labeling from the 5'-anticodon base, 5-(carboxymethoxy)uridine-34, of P or A site bound tRNA1Val. A nitrophenyl azide was attached to the carboxyl group of this nucleotide via side chains varying in length from 18 to 24 A. Binding of acetylvalyl-tRNA to the P site was codon dependent and that of valyl-tRNA to the A site was both codon and elongation factor Tu (EFTu) dependent. Cross-linking to both A and P sites was irradiation, probe, codon, and, in the case of the A site, EFTu dependent. Putative P-site cross-linked aminoacyl-tRNA was reactive with puromycin. The yield of cross-linking was little affected by placement of the tRNA at the A or P site but varied considerably with the length and structure of the probe side chain. When the distance from the pyrimidine C-5 atom to the azide group was 23 A, 42-45% cross-linking was obtained at each site, but when the distance was decreased to 18 A, only 7-12% was found. Placing an S-S bond in the center of the 23-A leash decreased the A-site yield to about half, while insertion of a CONH group decreased A-site cross-linking about 8-fold. P-site cross-linking was more sensitive to mercaptan quenching (50% at 0.5 mM) than was that at the A site (50% at greater than 2.0 mM) but both were partially shielded from solvent.(ABSTRACT TRUNCATED AT 250 WORDS)

Conservation of RNA sequence and cross-linking ability in ribosomes from a higher eukaryote: photochemical cross-linking of the anticodon of P site bound tRNA to the penultimate cytidine of the UACACACG sequence in Artemia salina 18S rRNA

The complex of Artemia salina ribosomes and Escherichia coli acetylvalyl-tRNA could be cross-linked by irradiation with near-UV light. Cross-linking required the presence of the codon GUU, GUA being ineffective. The acetylvalyl group could be released from the cross-linked tRNA by treatment with puromycin, demonstrating that cross-linking had occurred at the P site. This was true both for pGUU- and also for poly(U2,G)-dependent cross-linking. All of the cross-linking was to the 18S rRNA of the small ribosomal subunit. Photolysis of the cross-link at 254 nm occurred with the same kinetics as that for the known cyclobutane dimer between this tRNA and Escherichia coli 16S rRNA. T1 RNase digestion of the cross-linked tRNA yielded an oligonucleotide larger in molecular weight than any from un-cross-linked rRNA or tRNA or from a prephotolyzed complex. Extended electrophoresis showed this material to consist of two oligomers of similar mobility, a faster one-third component and a slower two-thirds component. Each oligomer yielded two components on 254-nm photolysis. The slower band from each was the tRNA T1 oligomer CACCUCCCUVACAAGp, which includes the anticodon. The faster band was the rRNA 9-mer UACACACCGp and its derivative UACACACUG. Unexpectedly, the dephosphorylated and slower moving 9-mer was derived from the faster moving dimer. Deamination of the penultimate C to U is probably due to cyclobutane dimer formation and was evidence for that nucleotide being the site of cross-linking. Direct confirmation of the cross-linking site was obtained by "Z"-gel analysis [Ehresmann, C., & Ofengand, J. (1984) Biochemistry 23, 438-445].(ABSTRACT TRUNCATED AT 250 WORDS)

Escherichia coli translational initiation factor IF3: a unique case of translational regulation

The Escherichia coli translational initiation factor IF3 is encoded by an mRNA that has an unusual ribosome binding site. We have explored a mechanism that may account for the translation of IF3 and that provides regulation of the quantity of IF3 relative to ribosomes.