Covalent cross-linking of transfer ribonucleic acid to the ribosomal P site. Mechanism and site of reaction in transfer ribonucleic acid.

The covalent cross-linking of unmodified Escherichia coli N-acetylvalyl-tRNA to the 16S RNA of Escherichia coli ribosomes upon near-UV irradiation previously reported by us [Schwartz, I., & Ofengand, J. (1978) Biochemistry 17, 2524--2530] has been studied further. Up to 70% of the unmodified tRNA, nonenzymatically bound to tight-couple ribosomes at 7 mM Mg2+, could be cross-linked by 310--335-nm light. Covalent attachment was solely to the 16S RNA. It was dependent upon both irradiation and the presence of mRNA but was unaffected by the presence or absence of 4-thiouridine in the tRNA. The kinetics of cross-linking showed single-hit behavior. Twofold more cross-linking was obtained w-th tight-couple ribosomes than with salt-washed particles. Puromycin treatment after irradiation released the bound N-acetyl[3H]valine, demonstrating that the tRNA was covalently bound at the P site and that irradiation and covalent linking did not affect the peptidyl transferase reaction. Cross-linking was unaffected by the presence of O2, argon, ascorbate (1 mM), or mercaptoethanol (10 mM). Prephotolysis of a mixture of tRNA and ribosomes in the absence of puly(U2,G) did not block subsequent cross-linking in its presence nor did it generate any long-lived chemically reactive species. There was a strong tRNA specificity. E. coli tRNA1Val and tRNA1Ser and Bacillus subtilis tRNAVal and tRNAThr could be cross-linked, but E. coli tRNA2Val, 5-fluorouracil-substituted tRNA1Val, tRNAPhe, or tRNAFMet could not. By sequence comparison of the reactive and nonreactive tRNAs, the site of attachment in the tRNA was deduced to be the 5'-anticodon base, cmo5U, or ,o5U in all of the reactive tRNAs. The attachment site in 16S RNA is described in the accompanying paper [Zimmerman, R. A., Gates, S. M., Schwartz, I., & Ofengand, J. (1979) Biochemistry (following paper in this issue)]. The link between tRNA and 16S RNA is either direct or involves mRNA bases at most two nucleotides apart since use of the trinucleotide GpUpU in place of poly(U2,G) to direct the binding and cross-linking of N-acetylvalyl-tRNA to the P site did not affect either the rate or yield of cross-linking. Both B. subtilis tRNAVal (mo5U) and E. coli tRNA1Val (cmo5U) gave the same rate and yield of cross-linking when directed by the trinucleotide GpUpU. Therefore, the presence of the charged carboxyl group in the cmo5U-containing tRNA apparently does not markedly perturb the orientation of this base with respect to its reaction partner in the 16S RNA. The cross-linking of AcVal-tRNA only takes place from the P site. At 75 mM KCl and 75 mM NH4Cl, less than 0.4% cross-linking was found at the A site, while 55.5% was obtained at the P site. However, when the salt concentration was lowered to 50 mM NH4Cl, 5% cross-linking to the A site was detected, compared to 49% at the P site. Thus, a simple change in the ionic strength of the incubation mixture was able to alter the affinity labeling pattern of the ribosome.     

Cross-linking of streptomycin to the 30S subunit of Escherichia coli with phenyldiglyoxal

[3H]Dihydrostreptomycin was covalently linked to the 30S subunit of Escherichia coli K12A19 with the bifunctional cross-linking reagent phenyldiglyoxal. The cross-linking was abolished under conditions that prevent the binding of streptomycin, which indicates that the cross-linking occurs at the specific binding site of streptomycin. The cross-linking involved 16S RNA and the ribosomal proteins S1, S5, S11, and S13. This suggests that the streptomycin binding site is located in the upper part of the 30S subunit, facing the 50S subunit. Unexpectedly, the same extent and pattern of cross-linking were observed with the 30S subunits from a streptomycin-resistant mutant. We have shown previously that streptomycin induces conformational changes in the ribosomes from sensitive bacteria but not from streptomycin-resistant mutants. From this and from the results in the present study, it is suggested that the binding of streptomycin to streptomycin-sensitive ribosomes is a two-step reaction wherein an initial loose interaction at the antibiotic binding site is followed by a conformational rearrangement of the ribosomal particle. The second step would tighten the association with streptomycin and cause interference with protein synthesis. That step would be lacking in streptomycin-resistant mutants.     

The decoding region of 16S RNA; a cross-linking study of the ribosomal A, P and E sites using tRNA derivatized at position 32 in the anticodon loop.

A photo-reactive diazirine derivative was attached to the 2-thiocytidine residue at position 32 of tRNA(Arg)I from Escherichia coli. This modified tRNA was bound under suitable conditions to the A, P or E site of E.coli ribosomes. After photo-activation of the diazirine label, the sites of cross-linking to 16S rRNA were identified by our standard procedures. Each of the three tRNA binding sites showed a characteristic pattern of cross-linking. From tRNA at the A site, a major cross-link was observed to position 1378 of the 16S RNA, and a minor one to position 936. From the P site, there were major cross-links to positions 693 and to 957 and/or 966, as well as a minor cross-link to position 1338. The E site bound tRNA showed major cross-links to position 693 (identical to that from the P site) and to positions 1376/1378 (similar, but not identical, to the cross-link observed from the A site). Immunological analysis of the concomitantly cross-linked ribosomal proteins indicated that S7 was the major target of cross-linking from all three tRNA sites, with S11 as a minor product. The results are discussed in terms of the overall topography of the decoding region of the 30S ribosomal subunit.     

Localization of the release factor-2 binding site on 70 S ribosomes by immuno-electron microscopy

In protein synthesis Escherichia coli release factor-2 binds to 70 S ribosomes when the termination codon UAA or UGA appears at the decoding site. The weak interaction between factor and ribosome has been stabilized in vitro by chemical cross-linking. Factor so bound can still be recognized by a specific antibody to release factor-2. Examination of the resulting immuno-complexes by electron microscopy revealed 70 S ribosomes in different projection forms, and the occasional dissociated subunit labelled with antibody. The antibody-binding site was localized on previously characterized 70 S projection forms, and its three-dimensional localization on the 70 S model established. The release factor-2-binding site was found to be positioned at the ribosomal subunit interface, comprising the stalk-protuberance region of the large subunit and the head-neck region of the concave side of the small subunit.     

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)     

The ribosome modulation factor (RMF) binding site on the 100S ribosome of Escherichia coli

During the stationary growth phase, Escherichia coli 70S ribosomes are converted to 100S ribosomes, and translational activity is lost. This conversion is caused by the binding of the ribosome modulation factor (RMF) to 70S ribosomes. In order to elucidate the mechanisms by which 100S ribosomes form and translational inactivation occurs, the shape of the 100S ribosome and the RMF ribosomal binding site were investigated by electron microscopy and protein-protein cross-linking, respectively. We show that (i) the 100S ribosome is formed by the dimerization of two 70S ribosomes mediated by face-to-face contacts between their constituent 30S subunits, and (ii) RMF binds near the ribosomal proteins S13, L13, and L2. The positions of these proteins indicate that the RMF binding site is near the peptidyl transferase center or the P site (peptidyl-tRNA binding site). These observations are consistent with the translational inactivation of the ribosome by RMF binding. After the "Recycling" stage, ribosomes can readily proceed to the "Initiation" stage during exponential growth, but during stationary phase, the majority of 70S ribosomes are stored as 100S ribosomes and are translationally inactive. We suggest that this conversion of 70S to 100S ribosomes represents a newly identified stage of the ribosomal cycle in stationary phase cells, and we have termed it the "Hibernation" stage.     

In vitro assembly of 30S and 70S bacterial ribosomes from 16S RNA containing single base substitutions, insertions, and deletions around the decoding site (C1400)

An in vitro system developed for the site-specific mutagenesis of 16S RNA of Escherichia coli ribosomes [Krzyzosiak et al. (1987) Biochemistry 26, 2353-2364] was used to make 10 single base changes around C1400, a residue known to be at the decoding site. C1400 was replaced by U, A, or G, five single base deletions at and to either side of C1400 were made, and C or U was inserted next to C1400. Another mutant possessed seven additional nucleotides at the 3' end of the 16S RNA such that a stem and loop involving the anti-Shine-Dalgarno sequence could form. Each of the mutant RNAs was reconstituted with a complete mixture of 30S proteins to yield 30S ribosomes. Modified in vitro reconstitution conditions were required to obtain assembly of all of the synthetic ribosomes. Quantitative HPLC analysis of the protein content of each mutant showed that all of the proteins were present. The ability of synthetic 30S to form 70S particles under functional assay conditions was about 75% that of natural 30S and was unchanged by any of the mutations except for the deletion of G1401, which decreased the association activity under the standard conditions to 35-40% of synthetic 30S. That part of the ribosomal P site which interacts with the anticodon loop of tRNA was investigated by near-UV (greater than 300 nm) induced cross-linking of AcVal-tRNA. Cross-linking depended on both 30S subunits and the correct codon. The cross-linking yield of all mutants with a pyrimidine at position 1400 was equal to control isolated 30S, and the first-order rate constants for cross-linking of those mutants tested were like reconstituted natural 30S. The site of cross-linking for mutants with a C or U insertion between C1400 and G1401 was shifted to the inserted residue. Cross-linking to the base 5' to G1401 rather than to the residue 3' to C1399 indicates that G1401 is an important structural determinant of the P site.     

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

The nucleotide residues involved in the cross-link between P site bound acetylvalyl-tRNA (AcVal-tRNA) and 16-18S rRNA have been identified. This cross-link was formed by irradiation of Escherichia coli or Bacillus subtilis AcVal-tRNA bound to the P site of E. coli ribosomes or by irradiation of E. coli AcVal-tRNA bound to the P site of yeast ribosomes. The three cross-linked RNA heterodimers were obtained in 10-35% purity by disruption of the irradiated ribosome-tRNA complex with sodium dodecyl sulfate followed by sucrose gradient centrifugation. After total digestion with RNase T1, and labeling at either the 5'- or the 3'-end, the cross-linked oligomers could be identified and isolated before and after photolytic splitting of the cross-link. One of the oligomers was shown to be UACACACCG, a unique rRNA nonamer present in an evolutionarily conserved region. This oligomer was found in all three heterodimers. The other oligomer of the dimer had the sequence expected for the RNase T1 product encompassing the anticodon of the tRNA used. The precise site of cross-linking was determined by two novel methods. Bisulfite modification of the oligonucleotide dimer converted all C residues to U, except for any cross-linked C which would be resistant by being part of a cyclobutane dimer. Sequencing gel analysis of the UACACACCG oligomer showed that the C residue protected was the 3'-penultimate C residue, C1400 in E. coli rRNA or C1626 in yeast rRNA.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identification of cysteine-10 of protein S18 as part of the mRNA-binding site of Escherichia coli ribosomes by affinity-labeling studies with a chemically reactive A-U-G analog.

The reaction of a bromoacetamidophenyl derivative of the initiation codon A-U-G (A-U-G) with tight couples of Escherichia coli ribosomes leads to an exclusive crosslinking of label to protein S18. This crosslinking inhibits A-U-G-directed fMet-tRNAfMet binding into the puromycin-sensitive site of ribosomes and stimulates elongation-factor-dependent binding of Met-tRNAmMet. It is, therefore, concluded that protein S18 is located at or near the aminoacyl-tRNA binding site of E. coli ribosomes. Peptide as well as amino acid analysis shows that the reaction between A-U-G and ribosomes took place at cysteine-10 of protein S18. A-U-G could not be crosslinked to ribosomal proteins of the temperature-sensitive E. coli strain 258ts, where arginine-11 of protein S18 is replaced by a cysteine residue.     

Affinity labeling of the P site of Drosophila ribosomes: a comparison of results from (bromoacetyl)phenylalanyl-tRNA and mercurated fragment affinity reactions

The binding site of the peptidyl group of peptidyl-tRNA in the P site of Drosophila ribosomes was probed with (bromoacetyl)phenylalanyl-tRNA (BrAcPhe-tRNA). This affinity label binds specifically to the P site by virtue of its ability to participate in peptide bond formation with puromycin following its attachment to ribosomes. As many as nine ribosomal proteins may be labeled under these conditions; however, the majority of the labeling is associated with three large-subunit proteins and two small-subunit proteins. Two of the large-subunit proteins, L4 and L27, are electrophoretically very similar to the proteins labeled by the same reagent in Escherichia coli ribosomes L2 and L27. Reexamination by a different two-dimensional gel system of the ribosomal components labeled by a second P site reagent, the 3' pentanucleotide fragment of N-acetylleucyl-tRNA which is derivatized to contain mercury atoms at the C-5 position of all three cytosine residues, shows two major and three minor labeled proteins. These proteins, L10/L11, L26, S1/S4, S13, and S20, are likely present in the binding site of the 3' end of peptidyl-tRNA, a site that appears to span both subunits. These results have allowed us to construct a model for the protein positions in and near the peptidyl-tRNA binding site of Drosophila ribosomes.     

Basis for prokaryotic specificity of action of aminoglycoside antibiotics.

The aminoglycosides, a group of structurally related antibiotics, bind to rRNA in the small subunit of the prokaryotic ribosome. Most aminoglycosides are inactive or weakly active against eukaryotic ribosomes. A major difference in the binding site for these antibiotics between prokaryotic and eukaryotic ribosomes is the identity of the nucleotide at position 1408 (Escherichia coli numbering), which is an adenosine in prokaryotic ribosomes and a guanosine in eukaryotic ribosomes. Expression in E.coli of plasmid-encoded 16S rRNA containing an A1408 to G substitution confers resistance to a subclass of the aminoglycoside antibiotics that contain a 6' amino group on ring I. Chemical footprinting experiments indicate that resistance arises from the lower affinity of the drug for the eukaryotic rRNA sequence. The 1408G ribosomes are resistant to the same subclass of aminoglycosides as previously observed both for eukaryotic ribosomes and bacterial ribosomes containing a methylation at the N1 position of A1408. The results indicate that the identity of the nucleotide at position 1408 is a major determinant of specificity of aminoglycoside action, and agree with prior structural studies of aminoglycoside-rRNA complexes.     

2′-OH of mRNA are critical for the binding of its codons at the 40S ribosomal P site but not at the mRNA entry site

The roles of 2′-OH groups in the binding of mRNA to human ribosomes were studied using site-directed cross-linking. We found that both mRNA and mDNA analogues bearing a cross-linker can modify ribosomal proteins (rps) S3e and S2e at the mRNA entry site independently on tRNA presence, but only mRNA analogues were capable of a tRNA^Phe-dependent binding to human ribosomes and cross-linking to rpS26e in the mRNA binding centre. Thus, 2′-OH groups of mRNA are unimportant for binding at the entry site but they are crucial for codon-anticodon interactions at the P site, implying the existence of mRNA-ribosome contacts that do not occur in bacteria.     

Mechanism of ribosomal translocation. Translocation limits the rate of Escherichia coli elongation factor G-promoted GTP hydrolysis

The pre-steady-state kinetics of GTP hydrolysis catalysed by elongation factor G and ribosomes from Escherichia coli has been investigated by the method of quenched-flow. The GTPase activities either uncoupled from or coupled to the ribosomal translocation process were characterized under various experimental conditions. A burst of GTP hydrolysis, with a kapp value greater than 30 s-1 (20 degrees C) was observed with poly(U)-programmed vacant ribosomes, either in the presence or absence of fusidic acid. The burst was followed by a slow GTP turnover reaction, which disappears in the presence of fusidic acid. E. coli tRNAPhe, but not N-acetylphenylalanyl-tRNAPhe (N-AcPhe-tRNAPhe), stimulates the GTPase when bound in the P site. If the A site of poly(U)-programmed ribosomes, carrying tRNAPhe in the P site, is occupied by N-AcPhe-tRNAPhe, the burst of Pi discharge is replaced by a slow GTP hydrolysis. Since, under these conditions, N-AcPhe-tRNAPhe is translocated from the A to the P site, this GTP hydrolysis very probably represents a GTPase coupled to the translocation reaction.     

Covalent cross-linking of poly(A) to Escherichia coli ribosomes, and localization of the cross-link site within the 16S RNA.

Poly(A) can be cross-linked to E. coli 70S ribosomes in the presence of tRNALys by mild ultraviolet irradiation. The cross-linking reaction is exclusively with the 30S subunit, and involves primarily the RNA moiety. Following a partial nuclease digestion, cross-linked complexes containing poly(A) and fragments of the 16S RNA were isolated by affinity chromatography on oligo(dT)-cellulose. The complexes were purified by gel electrophoresis and subjected to oligonucleotide analysis, which revealed a single cross-link site within positions 1394-1399 of the 16S RNA. The same pattern of cross-linking, at about one-fifth of the intensity, was observed in the absence of tRNALys. The cross-link site to poly(A), together with other sites in the 16S RNA that have been implicated in ribosomal function, is discussed in the framework of our recent model for the three-dimensional structure of 16S RNA; all of the functional sites are clustered together in two distinct groups in the model.     

Uridine 5'-phosphate photohydrate formation in irradiated Escherichia coli 30S ribosomes: photochemistry and relation to ribonucleic acid-protein cross-linking

Irradiation of aqueous buffered solutions of Escherichia coli 30S ribosomes with doses of 254-nm radiation greater than 10(19) quanta causes formation of uridine 5'-phosphate (UMP) photohydrates in ribosomal 16S RNA (rRNA). The number of molecules of UMP photohydrate formed at doses less than 2 x 10(20) quanta is linearly dependent on dose of absorbed 254-nm radiation. Maximum UMP photohydrate formation is dependent on initial ribosome concentration. When solutions containing 1 A260 unit of 30S ribosomes/mL were irradiated with greater than 2 x 10(20) quanta of 254-nm radiation, maximum photohydrate formation was equal to 47 residues/ribosome. Irradiation of solutions containing 2 A260 units/mL with greater than 7 x 10(20) quanta caused formation of 102 UMP photohydrates/ribosome. These values correspond to conversion of either 15 or 33%, respectively, of the total UMP content of 30S ribosome 16S rRNA to photohydrates. Target theory analysis of UMP photohydration in 30S ribosomes showed that UMP photohydrates are formed by single-hit kinetics from two photochemically distinct precursors. Of the total 16S rRNA UMP residues, 10% was included in the most rapidly (low dose) reacting fraction. The respective photohydration cross sections are 0.014 (low dose) and 0.0095 cm2/muEinstein (high dose) for ribosome solutions containing 2 A260 units/mL. UMP photohydrate content of irradiated 30S ribosomes was compared with that of previous data for the extent of RNA-protein cross-linking at equivalent doses of absorbed 254-nm radiation. This comparison showed that at least two UMP photohydrates form per RNA-protein cross-linking event in 30S ribosomes irradiated with a dose of 254-nm radiation (1.5 x 10(19) quanta), which causes cross-linking of only three ribosomal proteins to 16S rRNA.     

Ribosomal RNA is the target for oxazolidinones, a novel class of translational inhibitors.

Oxazolidinones are antibacterial agents that act primarily against gram-positive bacteria by inhibiting protein synthesis. The binding of oxazolidinones to 70S ribosomes from Escherichia coli was studied by both UV-induced cross-linking using an azido derivative of oxazolidinone and chemical footprinting using dimethyl sulphate. Oxazolidinone binding sites were found on both 30S and 50S subunits, rRNA being the only target. On 16S rRNA, an oxazolidinone footprint was found at A864 in the central domain. 23S rRNA residues involved in oxazolidinone binding were U2113, A2114, U2118, A2119, and C2153, all in domain V. This region is close to the binding site of protein L1 and of the 3' end of tRNA in the E site. The mechanism of action of oxazolidinones in vitro was examined in a purified translation system from E. coli using natural mRNA. The rate of elongation reaction of translation was decreased, most probably because of an inhibition of tRNA translocation, and the length of nascent peptide chains was strongly reduced. Both binding sites and mode of action of oxazolidinones are unique among the antibiotics known to act on the ribosome.     

Covalent cross-linking of tRNAGly1 to the ribosomal P site via the dihydrouridine loop

The dihydrouracil residue at position 20 of Escherichia coli tRNAGly1 has been replaced by the photoaffinity reagent, N-(4-azido-2-nitrophenyl)glycyl hydrazide (AGH). The location of the substituent was confirmed by the susceptibility of the modified tRNA to cleavage with aniline. When N-acetylglycyl-tRNAGly1 derivatized with AGH was bound noncovalently to the P site of E. coli 70 S ribosomes, 5-6% on average was photochemically cross-linked to the ribosomal particles in a reaction requiring poly(G,U), irradiation and the presence of the AGH label in the tRNA. Approximately two-thirds of the covalently attached tRNA was associated with 16 S RNA in the 30 S subunit. This material was judged to be in the P site by the criterion of puromycin reactivity. As partial RNAase digestion of the tRNA-16 S RNA complex produced labeled fragments from both 5' and 3' segments of the rRNA, there appeared to be more than one site of cross-linking in the 30 S subunit. The small amount of N-acetylglycyl-tRNAGly1 associated with the 50 S subunit was also linked mainly to rRNA, but it was not puromycin-reactive.