Models for two tRNAs bound to successive codons on mRNA on the ribosome

We have investigated the structural changes necessary to build a model complex of two molecules of phenylalanine transfer RNA (tRNA(Phe) bound to successive codons in a short segment of a model messenger RNA (mRNA), consisting of U6. We keep the mRNA in an ideal helical conformation, deforming the tRNAs as necessary to eliminate steric overlaps while bringing the two 3' termini together. The resulting model has the two tRNAs oriented relative to one another in a manner that is very similar to a model developed by McDonald and Rein (1) in which the tRNAs maintain their ideal crystallographic conformations and all of the deformations are introduced into the mRNA. Consequently, regardless of how one divides the deformations between the tRNAs and the mRNA it is clear that, on the ribosome, the tRNA in the P site has its "front" side (that side with the variable loop) close to the "back" side of the tRNA in the A site (that side with the D loop). The space between the two molecules must be left free on the ribosome, in order to facilitate the transition from the A site to the P site. A detailed pathway is also proposed for changing the anticodon loop structure from that of the A site to that of the P site. The anticodon loop is always kept in a 3'-stacked conformation, since we find that the shift between the 3'-stacked and 5'-stacked structures proposed by Woese (2) is not feasible.     

EF-G-independent reactivity of a pre-translocation-state ribosome complex with the aminoacyl tRNA substrate puromycin supports an intermediate (hybrid) state of tRNA binding

Following peptide-bond formation, the mRNA:tRNA complex must be translocated within the ribosomal cavity before the next aminoacyl tRNA can be accommodated in the A site. Previous studies suggested that following peptide-bond formation and prior to EF-G recognition, the tRNAs occupy an intermediate (hybrid) state of binding where the acceptor ends of the tRNAs are shifted to their next sites of occupancy (the E and P sites) on the large ribosomal subunit, but where their anticodon ends (and associated mRNA) remain fixed in their prepeptidyl transferase binding states (the P and A sites) on the small subunit. Here we show that pre-translocation-state ribosomes carrying a dipeptidyl-tRNA substrate efficiently react with the minimal A-site substrate puromycin and that following this reaction, the pre-translocation-state bound deacylated tRNA:mRNA complex remains untranslocated. These data establish that pre-translocation-state ribosomes must sample or reside in an intermediate state of tRNA binding independent of the action of EF-G.     

A stereochemical model of the transpeptidation complex

Molecular models are proposed to describe the relative arrangement of aminoacyl and peptidyl tRNAs when bound to their respective A and P sites on the ribosome. The crystallographically determined structures of tRNAasp and tRNAphe have served as the models for these bound structures, while the imposed steric constraints for the model complexes were based on the results of published experimental data. The constructed models satisfy the stereochemical requirements needed for codon-anticodon interaction and for peptide bond formation. In this paper, the results of the complex containing tRNAphe as the A and P site bound transfer RNAs, is compared to a similarly constructed model which uses tRNAasp as the ribosome-bound transfer RNAs. The models have the following three major features: 1) the aminoacyl and peptidyl transfer RNAs assume an angle of approximately 45 degrees relative to each other; 2) in providing the proper stereochemistry for peptide bond condensation, a significant kink must be present in the messenger RNA between the A site and P site codons; and 3) a comparison of the two model complexes indicates that structural variations between the tRNAs or any allosteric transitions of the transfer RNAs associated with codon-anticodon recognition may be accommodated in the model by way of freedom of rotation about the phosphate backbone bonds in the mRNA between consecutive codons.     

Ribosome protection by tRNA derivatives against inactivation by virginiamycin M: evidence for two types of interaction of tRNA with the donor site of peptidyl transferase

Virginiamycin M (VM) was previously shown to interfere with the function of both the A and P sites of ribosomes and to inactivate tRNA-free ribosomes but not particles bearing peptidyl-tRNA. To explain these findings, the shielding ability afforded by tRNA derivatives positioned at the A and P sites against VM-produced inactivation was explored. Unacylated tRNA(Phe) was ineffective, irrespective of its position on the ribosome. Phe-tRNA and Ac-Phe-tRNA provided little protection when bound directly to the P site but were active when present at the A site. Protection by these tRNA derivatives was markedly enhanced by the formation of the first peptide bond and increased further upon elongation of peptide chains. Most of the shielding ability of Ac-Phe-tRNA and Phe-tRNA positioned at the A site was conserved when these tRNAs were translocated to the P site by the action of elongation factor G and GTP. Thus, a 5-10-fold difference in the protection afforded by these tRNAs was observed, depending on their mode of entry to the P site. This indicates the occurrence of two types of interaction of tRNA derivatives with the donor site of peptidyl transferase: one shared by acylated tRNAs directly bound to the ribosomal P site (no protection against VM) and the other characteristic of aminoacyl- or peptidyl-tRNA translocated from the A site (protection of peptidyl transferase against VM). To explain these data and previous observations with other protein synthesis inhibitors, a new model of peptidyl transferase is proposed.(ABSTRACT TRUNCATED AT 250 WORDS)     

Elongation factor G stabilizes the hybrid-state conformation of the 70S ribosome

Following peptide bond formation, transfer RNAs (tRNAs) and messenger RNA (mRNA) are translocated through the ribosome, a process catalyzed by elongation factor EF-G. Here, we have used a combination of chemical footprinting, peptidyl transferase activity assays, and mRNA toeprinting to monitor the effects of EF-G on the positions of tRNA and mRNA relative to the A, P, and E sites of the ribosome in the presence of GTP, GDP, GDPNP, and fusidic acid. Chemical footprinting experiments show that binding of EF-G in the presence of the non-hydrolyzable GTP analog GDPNP or GDP.fusidic acid induces movement of a deacylated tRNA from the classical P/P state to the hybrid P/E state. Furthermore, stabilization of the hybrid P/E state by EF-G compromises P-site codon-anticodon interaction, causing frame-shifting. A deacylated tRNA bound to the P site and a peptidyl-tRNA in the A site are completely translocated to the E and P sites, respectively, in the presence of EF-G with GTP or GDPNP but not with EF-G.GDP. Unexpectedly, translocation with EF-G.GTP leads to dissociation of deacylated tRNA from the E site, while tRNA remains bound in the presence of EF-G.GDPNP, suggesting that dissociation of tRNA from the E site is promoted by GTP hydrolysis and/or EF-G release. Our results show that binding of EF-G in the presence of GDPNP or GDP.fusidic acid stabilizes the ribosomal intermediate hybrid state, but that complete translocation is supported only by EF-G.GTP or EF-G.GDPNP.     

A Stereochemical Model of the Transpeptidation Complex

Abstract

Molecular models are proposed to describe the relative arrangement of aminoacyl and peptidyl tRNAs when bound to their respective A. and P sites on the ribosome. The crystallographically determined structures of tRNA^asp and tRNA^phe have served as the models for these bound structures, while the imposed steric constraints for the model complexes were based on the results of published experimental data. The constructed models satisfy the stereochemical requirements needed for codon-anticodon interaction and for peptide bond formation. In this paper, the results of the complex containing tRNA^phe as the A. and P site bound transfer RNAs, is compared to a similarly constructed model which uses tRNA^lsp as the ribosome-bound transfer RNAs. The models have the following three major features: 1) the aminoacyl and peptidyl transfer RNAs assume an angle of approximately 45° relative to each other; 2) in providing the proper stereochemistry for peptide bond condensation, a significant kink must be present in the messenger RNA between the A. site and P site codons; and 3) a comparison of the two model complexes indicates that structural variations between the tRNAs or any allosteric transitions of the transfer RNAs associated with codon-anticodon recognition may be accommodated in the model by way of freedom of rotation about the phosphate backbone bonds in the mRNA between consecutive codons.     

Ribosome-initiator tRNA complex as an intermediate in translation initiation in Escherichia coli revealed by use of mutant initiator tRNAs and specialized ribosomes.

For functional studies of mutant Escherichia coli initiator tRNAs in vivo, we previously described a strategy based on the use of tRNA genes carrying an anticodon sequence change from CAU to CUA along with a mutant chloramphenicol acetyltransferase (CAT) gene carrying an initiation codon change from AUG to UAG. Surprisingly, under conditions where the mutant initiator tRNA is optimally active, the CAT gene with the UAG initiation codon produced more CAT protein (3- to 9-fold more depending on the conditions) than the wild-type CAT gene. Here we show that two new mutant CAT genes having GUC and AUC initiation codons also produce more of the CAT protein in the presence of the corresponding mutant initiator tRNAs. These results are most easily understood if assembly of the 30S ribosome-initiator tRNA-mRNA initiation complex in vivo proceeds with the 30S ribosome binding first to the initiator tRNA and then to the mRNA. In cells overproducing the mutant initiator tRNAs, most ribosomes would carry the mutant initiator tRNA and these ribosomes would select the mutant CAT mRNA over the other mRNAs.     

Calculation of the relative geometry of tRNAs in the ribosome from directed hydroxyl-radical probing data

The many interactions of tRNA with the ribosome are fundamental to protein synthesis. During the peptidyl transferase reaction, the acceptor ends of the aminoacyl and peptidyl tRNAs must be in close proximity to allow peptide bond formation, and their respective anticodons must base pair simultaneously with adjacent trinucleotide codons on the mRNA. The two tRNAs in this state can be arranged in two nonequivalent general configurations called the R and S orientations, many versions of which have been proposed for the geometry of tRNAs in the ribosome. Here, we report the combined use of computational analysis and tethered hydroxyl-radical probing to constrain their arrangement. We used Fe(II) tethered to the 5' end of anticodon stem-loop analogs (ASLs) of tRNA and to the 5' end of deacylated tRNA(Phe) to generate hydroxyl radicals that probe proximal positions in the backbone of adjacent tRNAs in the 70S ribosome. We inferred probe-target distances from the resulting RNA strand cleavage intensities and used these to calculate the mutual arrangement of A-site and P-site tRNAs in the ribosome, using three different structure estimation algorithms. The two tRNAs are constrained to the S configuration with an angle of about 45 degrees between the respective planes of the molecules. The terminal phosphates of 3'CCA are separated by 23 A when using the tRNA crystal conformations, and the anticodon arms of the two tRNAs are sufficiently close to interact with adjacent codons in mRNA.     

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.     

Ribosome binding by tRNAs with fluorescent labeled 3'' termini.

Yeast and E. coli tRNAPhe samples were oxidized and labeled at the 3' end with dansyl hydrazine or fluorescein thiosemicarbazide. These tRNAs can bind to poly(U)-programmed E. coli 70S tight couple ribosomes in 25 mM magnesium at 8 degrees C. Two binding sites with binding constants of about 1 X 10(9) M-1 (P) and 3 X 10(7) M-1 (A) were determined for the yeast tRNAPhe derivatives. With E. coli tRNAPhe the A site affinity is similar to yeast tRNAPhe but the P site affinity is 5-fold weaker. Singlet-singlet energy transfer showd that the distance from the 3' end of tRNAPhe in the P site to a fluorescein derivative of erythromycin is 23 A. This supports in vitro studies suggesting that erythromycin binds near the peptide moiety of peptidyl tRNA. A distance of 34 A between the 3' ends of 2 tRNAs bound simulatneously on the ribosome was also measured. This long distance may mean that the deacylated fluorescent tRNA binds to the A site in an orientation like that in the stringent response rather than in protein synthesis.     

Locking and unlocking of ribosomal motions

During the ribosomal translocation, the binding of elongation factor G (EF-G) to the pretranslocational ribosome leads to a ratchet-like rotation of the 30S subunit relative to the 50S subunit in the direction of the mRNA movement. By means of cryo-electron microscopy we observe that this rotation is accompanied by a 20 A movement of the L1 stalk of the 50S subunit, implying that this region is involved in the translocation of deacylated tRNAs from the P to the E site. These ribosomal motions can occur only when the P-site tRNA is deacylated. Prior to peptidyl-transfer to the A-site tRNA or peptide removal, the presence of the charged P-site tRNA locks the ribosome and prohibits both of these motions.     

EF-G-catalyzed translocation of anticodon stem-loop analogs of transfer RNA in the ribosome.

Translocation, catalyzed by elongation factor EF-G, is the precise movement of the tRNA-mRNA complex within the ribosome following peptide bond formation. Here we examine the structural requirement for A- and P-site tRNAs in EF-G-catalyzed translocation by substituting anticodon stem-loop (ASL) analogs for the respective tRNAs. Translocation of mRNA and tRNA was monitored independently; mRNA movement was assayed by toeprinting, while tRNA and ASL movement was monitored by hydroxyl radical probing by Fe(II) tethered to the ASLs and by chemical footprinting. Translocation depends on occupancy of both A and P sites by tRNA bound in a mRNA-dependent fashion. The requirement for an A-site tRNA can be satisfied by a 15 nucleotide ASL analog comprising only a 4 base pair (bp) stem and a 7 nucleotide anticodon loop. Translocation of the ASL is both EF-G- and GTP-dependent, and is inhibited by the translocational inhibitor thiostrepton. These findings show that the D, T and acceptor stem regions of A-site tRNA are not essential for EF-G-dependent translocation. In contrast, no translocation occurs if the P-site tRNA is substituted with an ASL, indicating that other elements of P-site tRNA structure are required for translocation. We also tested the effect of increasing the A-site ASL stem length from 4 to 33 bp on translocation from A to P site. Translocation efficiency decreases as the ASL stem extends beyond 22 bp, corresponding approximately to the maximum dimension of tRNA along the anticodon-D arm axis. This result suggests that a structural feature of the ribosome between the A and P sites, interferes with movement of tRNA analogs that exceed the normal dimensions of the coaxial tRNA anticodon-D arm.     

A synthetic alanyl-initiator tRNA with initiator tRNA properties as determined by fluorescence measurements: comparison to a synthetic alanyl-elongator tRNA.

Two synthetic tRNAs have been generated that can be enzymatically aminoacylated with alanine and have AAA anticodons to recognize a poly(U) template. One of the tRNAs (tRNA(eAla/AAA)) is nearly identical to Escherichia coli elongator tRNA(Ala). The other has a sequence similar to Escherichia coli initiator tRNA(Met) (tRNA(iAla/AAA)). Although both tRNAs can be used in poly(U)-directed nonenzymatic initiation at 15 mM Mg2+, only the elongator tRNA can serve for peptide elongation and polyalanine synthesis. Only the initiator tRNA can be bound to 30S ribosomal subunits or 70S ribosomes in the presence of initiation factor 2 (IF-2) and low Mg2+ suggesting that it can function in enzymatic peptide initiation. A derivative of coumarin was covalently attached to the alpha amino group of alanine of these two Ala-tRNA species. The fluorescence spectra, quantum yield and anisotropy for the two Ala-tRNA derivatives are different when they are bound to 70S ribosomes (nonenzymatically in the presence of 15 mM Mg2+) indicating that the local environment of the probe is different. Also, the effect of erythromycin on their fluorescence is quite different, suggesting that the probes and presumably the alanine moiety to which they are covalently linked are in different positions on the ribosomes.     

Recognition and positioning of mRNA in the ribosome by tRNAs with expanded anticodons

Mutant tRNAs containing an extra nucleotide in the anticodon loop are known to suppress +1 frameshift mutations, but in no case has the molecular mechanism been clarified. It has been proposed that the expanded anticodon pairs with a complementary mRNA sequence (the frameshift sequence) in the A site, and this quadruplet "codon-anticodon" helix is translocated to the P site to restore the correct reading frame. Here, we analyze the ability of tRNA analogs containing expanded anticodons to recognize and position mRNA in ribosomal complexes in vitro. In all cases tested, 8 nt anticodon loops position the 3' three-quarters of the frameshift sequence in the P site, indicating that the 5' bases of the expanded anticodon (nucleotides 33.5, 34, and 35) pair with mRNA in the P site. We also provide evidence that four base-pairs can form between the P-site tRNA and mRNA, and the fourth base-pair involves nucleotide 36 of the tRNA and lies toward (or in) the 30 S E site. In the A site, tRNA analogs with the expanded anticodon ACCG are able to recognize either CGG or GGU. These data imply a flexibility of the expanded anticodon in the A site. Recognition of the 5' three-quarters of the frameshift sequence in the A site and subsequent translocation of the expanded anticodon to the P site results in movement of mRNA by four nucleotides, explaining how these tRNAs can change the mRNA register in the ribosome to restore the correct reading frame.     

tRNA binding sites of ribosomes from Escherichia coli

70S tight-couple ribosomes from Escherichia coli were studied with respect to activity and number of tRNA binding sites. The nitrocellulose filtration and puromycin assays were used both in a direct manner and in the form of a competition binding assay, the latter allowing an unambiguous determination of the fraction of ribosomes being active in tRNA binding. It was found that, in the presence of poly(U), the active ribosomes bound two molecules of N-AcPhe-tRNAPhe, one in the P and the other in the A site, at Mg2+ concentrations between 6 and 20 mM. A third binding site in addition to P and A sites was observed for deacylated tRNAPhe. At Mg2+ concentrations of 10 mM and below, the occupancy of the additional site was very low. Dissociation of tRNA from this site was found to be rather fast, as compared to both P and A sites. These results suggest that the additional site during translocation functions as an exit site, to which deacylated tRNA is transiently bound before leaving the ribosome. Since tRNA binding to this site did not require the presence of poly(U), a function of exit site bound tRNA in the fixation of the mRNA appears unlikely. Both the affinity and stability of binding to the additional site were found lower for the heterologous tRNAPhe from yeast as compared to the homologous one. This difference possibly indicates some specificity of the E. coli ribosome for tRNAs from the same organism.     

Codon-anticodon interaction at the P site is a prerequisite for tRNA interaction with the small ribosomal subunit

The arrival of high resolution crystal structures for the ribosomal subunits opens a new phase of molecular analysis and asks for corresponding analyses of ribosomal function. Here we apply the phosphorothioate technique to dissect tRNA interactions with the ribosome. We demonstrate that a tRNA bound to the P site of non-programmed 70 S ribosomes contacts predominantly the 50 S, as opposed to the 30 S subunit, indicating that codon-anticodon interaction at the P site is a prerequisite for 30 S binding. Protection patterns of tRNAs bound to isolated subunits and programmed 70 S ribosomes were compared. The results suggest the presence of a movable domain in the large ribosomal subunit that carries tRNA and reveal that only approximately 15% of a tRNA, namely residues 30 +/- 1 to 43 +/- 1, contact the 30 S subunit of programmed 70 S ribosomes, whereas the remaining 85% make contact with the 50 S subunit. Identical protection patterns of two distinct elongator tRNAs at the P site were identified as tRNA species-independent phosphate backbone contacts. The sites of protection correlate nicely with the predicted ribosomal-tRNA contacts deduced from a 5.5-A crystal structure of a programmed 70 S ribosome, thus refining which ribosomal components are critical for tRNA fixation at the P site.     

Adjacent codon-anticodon interactions of both tRNAs present at the ribosomal A and P or P and E sites

A labeled tRNA present at the A, P or E site can be partially chased from the ribosome, a cognate nonlabeled tRNA as chasing substrate being 3-12-times more efficient than non-cognate tRNA at a molar ratio tRNA: 70 S = 10:1. These findings indicate that a tRNA bound to a programmed ribosome undergoes codon-anticodon interaction at all three sites (A, P and E site). Furthermore, both labeled tRNA present on the ribosome can be chased more effectively with cognate than with non-cognate substrate at the same time. This finding provides strong evidence that both tRNAs present on the ribosome exhibit simultaneous codon-anticodon interaction. This is valid for both the pretranslocational state (Ac[3H]Lys-tRNALys in the A and [14C]tRNALys in the P site) as well as the posttranslocational state (Ac[3H]Lys-tRNALys in the P and [14C]tRNALys in the E site).     

Positioning of CCA-arms of the A- and the P-tRNAs towards the 28S rRNA in the human ribosome

Nucleotides of 28S rRNA involved in binding of the human 80S ribosome with acceptor ends of the A site and the P site tRNAs were determined using two complementary approaches, namely, cross-linking with application of tRNA^Asp analogues substituted with 4-thiouridine in position 75 or 76 and hydroxyl radical footprinting with the use of the full sized tRNA and the tRNA deprived of the 3′-terminal trinucleotide CCA. In general, these 28S rRNA nucleotides are located in ribosomal regions homologous to the A, P and E sites of the prokaryotic 50S subunit. However, none of the approaches used discovered interactions of the apex of the large rRNA helix 80 with the acceptor end of the P site tRNA typical with prokaryotic ribosomes. Application of the results obtained to available atomic models of 50S and 60S subunits led us to a conclusion that the A site tRNA is actually present in both A/A and A/P states and the P site tRNA in the P/P and P/E states. Thus, the present study gives a biochemical confirmation of the data on the structure and dynamics of the mammalian ribosomal pretranslocation complex obtained with application of cryo-electron microscopy and single-molecule FRET [Budkevich et al., 2011]. Moreover, in our study, particular sets of 28S rRNA nucleotides involved in oscillations of tRNAs CCA-termini between their alternative locations in the mammalian 80S ribosome are revealed.     

Neighbourhood of the central fold of the tRNA molecule bound to the E. coli ribosome--affinity labeling studies with modified tRNAs carrying photoreactive probes attached to the dihydrouridine loop.

The neighbourhood of the dihydrouridine loop of tRNA molecule bound to E. coli ribosome has been studied by affinity labeling, using modified tRNAs carrying photoreactive azidonitrophenyl probes attached to the 3-(3-amino-3-carboxypropyl)-uridine located at position 20:1 of Lupin methionine elongator tRNA. The maximum distance between the pyrimidine ring and the azido group estimated for the two probes employed in this study is 10-11 A and 18-19 A, respectively. Cross-linking of the uncharged, modified tRNAs has been studied with poly(A, U, G) as a message, under conditions directing uncharged tRNAs preferentially to the ribosomal P-site. Modified tRNAs bind covalently to both ribosomal subunits with high yields upon irradiation of the respective non-covalent complexes. Proteins S7, L33 and L1 have been consistently found cross-linked to tRNAs modified with both probes, and S5 and L5 to tRNA modified with the longer probe. Surprisingly, an S5-tRNA cross-linking product is reproducibly found in a protein fraction prepared from the purified 50S subunit. Cross-linking to rRNAs is significant only for the longer probe and is stimulated 2-4 fold in the presence of poly(A,U,G). The cross-linking sites are located between nucleotides 1302 and 1398 in 16S rRNA and between nucleotides 2281 and 2358 in 23S rRNA.