Features of 80S mammalian ribosome and its subunits

It is generally believed that basic features of ribosomal functions are universally valid, but a systematic test still stands out for higher eukaryotic 80S ribosomes. Here we report: (i) differences in tRNA and mRNA binding capabilities of eukaryotic and bacterial ribosomes and their subunits. Eukaryotic 40S subunits bind mRNA exclusively in the presence of cognate tRNA, whereas bacterial 30S do bind mRNA already in the absence of tRNA. 80S ribosomes bind mRNA efficiently in the absence of tRNA. In contrast, bacterial 70S interact with mRNA more productively in the presence rather than in the absence of tRNA. (ii) States of initiation (P_i), pre-translocation (PRE) and post-translocation (POST) of the ribosome were checked and no significant functional differences to the prokaryotic counterpart were observed including the reciprocal linkage between A and E sites. (iii) Eukaryotic ribosomes bind tetracycline with an affinity 15 times lower than that of bacterial ribosomes (K_d 30 μM and 1–2 μM, respectively). The drug does not effect enzymatic A-site occupation of 80S ribosomes in contrast to non-enzymatic tRNA binding to the A-site. Both observations explain the relative resistance of eukaryotic ribosomes to this antibiotic.     

Ribosomal protein L1 from Escherichia coli. Its role in the binding of tRNA to the ribosome and in elongation factor g-dependent gtp hydrolysis

Two Escherichia coli mutants lacking ribosomal protein L1, previously shown to display 40 to 60% reduced capacity for in vitro protein synthesis (Subramanian, A. R., and Dabbs, E. R. (1980) Eur. J. Biochem. 112, 425-430), have been used to study partial reactions of protein biosynthesis. Both the binding of N-acetyl-Phe-tRNA to ribosomes and the 6 to 8-fold stimulation of the elongation factor G (EF-G)-dependent GTPase reaction by mRNA plus tRNA, assayed in the presence of wild type 30 S subunits, were low with L1-deficient 50 S subunits. Addition of pure protein L1 to the assay restored both reactions to 100% of the control. By contrast, the basic EF-G GTPase reaction in the absence of mRNA and tRNA was not at all affected (mRNA alone had no effect). None of the following partial reactions were more than moderately modified by the lack of protein L1: binding to ribosomes of EF-G.GDP plus fusidic acid; the translocation reaction catalyzed by EF-G plus GTP; poly(U)-dependent binding to ribosomes of Phe-tRNAPhe (whether dependent on elongation factor Tu plus GTP or not); and the EF-Tu-dependent GTPase activity. It is concluded that protein L1 is involved in the interaction between ribosomes and peptidyl-tRNA (or tRNA) in the peptidyl site and consequently in the ribosomal GTPase activity depending on the simultaneous action of tRNA and EF-G.     

Isolation and characterization of ribosomes and translation initiation factors from the gram-positive soil bacterium Streptomyces lividans

A primer extension inhibition (toeprint) assay was developed using ribosomes and ribosomal subunits from Streptomyces lividans. This assay allowed the study of ribosome binding to streptomycete leaderless and leadered mRNA. Purified 30S subunits were unable to form a ternary complex on aph leaderless mRNA, whereas 70S ribosomes could form ternary complexes on this mRNA. 30S subunits formed ternary complexes on leadered aph and malE mRNA. The translation initiation factors (IF1, IF2, and IF3) from S. lividans were isolated and included in toeprint and filter binding assays with leadered and leaderless mRNA. Generally, the IFs reduced the toeprint signal on leadered mRNA; however, incubation of IF1 and IF2 with 30S subunits that had been washed under high-salt conditions promoted the formation of a ternary complex on aph leaderless mRNA. Our data suggest that, as reported for Escherichia coli, initiation complexes with leaderless mRNAs might use a novel pathway involving 70S ribosomes or 30S subunits bound by IF1 and IF2 but not IF3. Some mRNA-ribosome-initiator tRNA reactions that yielded weak or no toeprint signals still formed complexes in filter binding assays, suggesting the occurrence of interactions that are not stable in the toeprint assay.     

Photoaffinity modification of Escherichia coli ribosomes by fMet-tRNAf Met derivatives in the 70S initiation complex

Photoaffinity labeling of E. coli ribosomes within the 70S initiation complex was studied by using photoreactive derivatives of fMet-tRNAfMet bearing arylazidogroups scattered statistically over guanosine residues. It is shown that fMet-azido-tRNAfMet-II bearing 2 moles of the reagent residues per mole of tRNA (modified in the conditions of stability of tRNA tertiary structure) is fully active in aminoacylation and in the factor-dependent binding with ribosomes to form the 70S initiation complex. Functional activity of fMet-azido-tRNAfMet-I bearing also 2 moles of the reagent residues per mole of tRNA (but modified in conditions of lability of tRNA tertiary structure) decreases up to approximately 45% in aminoacylation and up to 70% in IF-2 X GTP-dependent binding to the ribosomes. Irradiation of complexes 70S ribosome-MS2-RNA-fMet-azido-tRNAfMet results in covalent linking of the tRNA derivative to the ribosomes. Both subunits are labeled, the 30S to a larger extent than 50S. It is shown that fMet-azido-tRNAfMet-II labels proteins S1, S7, S9, L27 whereas fMet-azido-tRNAfMet-1--proteins S1, S3, S5, S9, S14, L1, L2, L7/L12.     

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.     

Affinity labelling of rat liver ribosomal protein S26 by heptauridylate containing a 5′-terminal alkylating group

Heptauridylate bearing a radioactive alkylating [¹⁴C]-4-(N-2-chloroethyl-N-methylamino)benzylamine attached to the 5-phosphate via amide bond, was bound to ribosomes and small ribosomal subunits from rat liver which thereby were coded to bind N-acylated Phe tRNA. After completion of the alkylating reaction and subsequent hydrolysis of the phosphamide bond ribosomal proteins were isolated. Radioactivity was found covalently associated preferentially with protein S26 and, to a very small extent, with proteins S3 and S3a. The affinity labelling reaction could be abolished by (pU)₁₄ and poly(U). From the results it is concluded that ribosomal protein S26 is located at the mRNA binding site of rat liver ribosomes.     

The human large subunit ribosomal protein L36A-like contacts the CCA end of P-site bound tRNA

Periodate-oxidized tRNA (tRNAox), the 2′,3′-dialdehyde derivative of tRNA, was used as a zero-length active site-directed affinity labeling reagent, to covalently label proteins at the binding site for the 3′-end of tRNA on human 80S ribosomes. When human 80S ribosomes were reacted with tRNA^Aspox positioned at the P-site, in the presence of an appropriate 12 mer mRNA, a set of two tRNAox-labeled ribosomal proteins (rPs) was observed. The majorily labeled protein was identified as the large subunit rP L36a-like (RPL36AL) by means of mass spectrometry. Intact tRNA^Asp competed with tRNA^Aspox for the binding to the P-site, by preventing tRNA-protein cross-linking with RPL36AL. Altogether, the data presented in this report are consistent with the presence of RPL36AL at or near the binding site for the CCA end of the tRNA substrate positioned at the P-site of human 80S ribosomes. It is the first time that a ribosomal protein is found in an intimate contact (i.e. at a zero-distance) with a nucleotide of the conserved CCA terminus of P-site tRNA which is the substrate of peptidyl transferase reaction. RPL36AL which is strongly conserved in eukaryotes belongs to the L44e family of rPs, a representative of which is Haloarcula marismortui RPL44e.     

Footprinting mRNA-ribosome complexes with chemical probes.

We footprinted the interaction of model mRNAs with 30S ribosomal subunits in the presence or absence of tRNA(fMet) or tRNA(Phe) using chemical probes directed at the sugar-phosphate backbone or bases of the mRNAs. When bound to the 30S subunits in the presence of tRNA(fMet), the sugar-phosphate backbones of gene 32 mRNA and 022 mRNA are protected from hydroxyl radical attack within a region of about 54 nucleotides bounded by positions -35 (+/- 2) and +19, extending to position +22 when tRNA(Phe) is used. In 70S ribosomes, protection is extended in the 5' direction to about position -39 (+/- 2). In the absence of tRNA, the 30S subunit protects only nucleotides -35 (+/- 2) to +5. Introduction of a stable tetraloop hairpin between positions +10 and +11 of gene 32 mRNA does not interfere with tRNA(fMet)-dependent binding of the mRNA to 30S subunits, but results in loss of protection of the sugar-phosphate backbone of the mRNA downstream of position +5. Using base-specific probes, we find that the Shine-Dalgarno sequence (A-12, A-11, G-10 and G-9) and the initiation codon (A+1, U+2 and G+3) of gene 32 mRNA are strongly protected by 30S subunits in the presence of initiator tRNA. In the presence of tRNA(Phe), the same Shine-Dalgarno bases are protected, as are U+4, U+5 and U+6 of the phenylalanine codon. Interestingly, A-1, immediately preceding the initiation codon, is protected in the complex with 30S subunits and initiator tRNA, while U+2 and G+3 are protected in the complex with tRNA(Phe) in the absence of initiator tRNA. Additionally, specific bases upstream from the Shine-Dalgarno region (U-33, G-32 and U-22) as well as 3' to the initiation codon (G+11) are protected by 30S subunits in the presence of either tRNA. These results imply that the mRNA binding site of the 30S subunit covers about 54-57 nucleotides and are consistent with the possibility that the ribosome interacts with mRNA along its sugar-phosphate backbone.     

Crosslinking of mRNA analog, pUUAGUAUUUAUU derivative with a photoactivated group at the guanosine residue, with human 80S ribosomes

Crosslinking of mRNA analog, dodecaribonucleotide pUUAGUAUUUAUU derivative carrying a perfluoroarylazido group at the guanine N7, was studied in model complexes with 80S ribosomes involving tRNA and in binary complex (i.e., in the absence of tRNA). It was shown that, irrespectively of complex formation conditions (13 mM Mg2+, or 4 mM Mg2+ in the presence of polyamines), the mRNA analog in binary complex with 80S ribosomes was crosslinked with sequence 1840-1849 of 18S rRNA, but in the complexes formed with participation of Phe-TPHKPhe (where the G residue carrying the arylazido group occupied position-3 to the first nucleotide of the UUU codon at the P site) the analog was crosslinked with nucleotide 1207. The presence and the nature of tRNA at the E site had no effect on the environment of position-3 of the mRNA analog. Efficient crosslinking of the mRNA analog with tRNA was observed in all studied types of complex. Modified codon GUA, when located at the E site, underwent crosslinking with both cognate valine tRNA and noncognate aspartate tRNA for which the extent of binding at the E site of 80S ribosomes was almost the same and depended little on Mg2+ concentration and the presence of polyamines.     

Crosslinking of mRNA Analog,pUUAGUAUUUAUU Derivative with Photoactivatable Group at the Guanosine Residue,with Human 80S Ribosomes

Crosslinking of mRNA analog, dodecaribonucleotide pUUAGUAUUUAUU derivative carrying a perfluoroarylazido group at the guanine N7, was studied in model complexes with 80S ribosomes involving tRNA and in binary complex (i.e., in the absence of tRNA). It was shown that, irrespectively of complex formation conditions (13 mM Mg²⁺, or 4 mM Mg²⁺ in the presence of polyamines), the mRNA analog in binary complex with 80S ribosomes was crosslinked with sequence 1840–1849 of 18S rRNA, but in the complexes formed with participation of Phe-tRNA^Phe (where the G residue carrying the arylazido group occupied position –3 to the first nucleotide of the UUU codon at the P site) the analog was crosslinked with nucleotide 1207. The presence and the nature of tRNA at the E site had no effect on the environment of position –3 of the mRNA analog. Efficient crosslinking of the mRNA analog with tRNA was observed in all studied types of complex. Modified codon GUA, when located at the E site, underwent crosslinking with both cognate valine tRNA and noncognate aspartate tRNA for which the extent of binding at the E site of 80S ribosomes was almost the same and depended little on Mg²⁺ concentration and the presence of polyamines.     

Ribosomes bind leaderless mRNA in Escherichia coli through recognition of their 5'-terminal AUG

Leaderless mRNAs are translated in the absence of upstream signals that normally contribute to ribosome binding and translation efficiency. In order to identify ribosomal components that interact with leaderless mRNA, a fragment of leaderless cI mRNA from bacteriophage λ, with a 4-thiouridine (4^S-U) substituted at the +2 position of the AUG start codon, was used to form cross-links to Escherichia coli ribosomes during binary (mRNA+ribosome) and ternary (mRNA+ribosome+initiator tRNA) complex formation. Ribosome binding assays (i.e., toeprints) demonstrated tRNA-dependent binding of leaderless mRNA to ribosomes; however, cross-links between the start codon and 30S subunit rRNA and r-proteins formed independent of initiator tRNA. Toeprints revealed that a leaderless mRNA's 5′-AUG is required for stable binding. Furthermore, the addition of a 5′-terminal AUG triplet to a random RNA fragment can make it both competent and competitive for ribosome binding, suggesting that a leaderless mRNA's start codon is a major feature for ribosome interaction. Cross-linking assays indicate that a subset of 30S subunit r-proteins, located at either end of the mRNA tunnel, contribute to tRNA-independent contacts and/or interactions with a leaderless mRNA's start codon. The interaction of leaderless mRNA with ribosomes may reveal features of mRNA binding and AUG recognition that are distinct from known signals but are important for translation initiation of all mRNAs.     

Identification of proteins functionally altered by chemical modification of the transfer RNA and polyuridylic acid binding sites of 30 S ribosomal subunits

Previous studies have shown that Rose Bengal-sensitized photo-oxidation of 30 S ribosomal subunits causes inactivation of tRNA binding and partial loss of poly(U) binding activities (Noller et al., 1971). The present studies, reconstitution of 30 S subunits from 16 S RNA, total protein from modified subunits, and purified proteins from untreated subunits, show that proteins S2 and S3 together completely restore these activities to the reconstituted subunits. The modified proteins are capable of in vitro assembly, and give rise to particles with normal sedimentation constants, showing that restoration of activity is not simply due to correction of an assembly defect.Protein S3 restores poly(U) binding and tRNA binding to the same extent, accounting for the lowered mRNA binding activity of the modified particles as well as a corresponding fraction of the tRNA binding activity. Protein S2 restores the remaining fraction of the tRNA binding activity, but has no effect on poly (U) binding. In 50 S-stimulated tRNA binding, proteins S1 and S5 are required in addition to S2 and S3 for full activity.     

Association of nascent polypeptide and transfer ribonucleic acid with 30S ribosomal subunits

1. Crude extracts of Escherichia coli programmed in protein synthesis by endogenous mRNA have incorporated amino acids into protein. Analysis of such extracts by sucrose-gradient centrifugation in low Mg(2+) concentration has revealed that 30S ribosomal subunits carry associated radioactive material of which a considerable proportion can be removed from ribosomes by treatment of pre-labelled extracts with puromycin. 2. Gradient analyses of incorporations carried out in the additional presence of added (32)P-labelled tRNA have indicated that tRNA sediments in the regions of the newly synthesized nascent protein and that both labels are associated with all ribosomal components detected on the gradients under the experimental conditions employed. 3. 30S ribosomal subunits carrying both (32)P and (14)C labels have been isolated, disrupted with sodium dodecyl sulphate, and analysed by chromatography on Sephadex G-200 columns. Both labels elute closely together and well away from a tRNA marker analysed under identical conditions. 4. It is proposed that 30S ribosomal subunits, isolated from extracts which have synthesized nascent peptides under the direction of endogenous mRNA, carry associated peptidyl-tRNA.     

The contribution of the zinc-finger motif to the function of Thermus thermophilus ribosomal protein S14

In the crystal structure of the 30S ribosomal subunit from Thermus thermophilus, cysteine 24 of ribosomal protein S14 (TthS14) occupies the first position in a CXXC-X12-CXXC motif that coordinates a zinc ion. The structural and functional importance of cysteine 24, which is widely conserved from bacteria to humans, was studied by its replacement with serine and by incorporating the resulting mutant into Escherichia coli ribosomes. The capability of such modified ribosomes in binding tRNA at the P and A-sites was equal to that obtained with ribosomes incorporating wild-type TthS14. In fact, both chimeric ribosomal species exhibited 20% lower tRNA affinity compared with native E. coli ribosomes. In addition, replacement of the native E. coli S14 by wild-type, and particularly by mutant TthS14, resulted in reduced capability of the 30S subunit for association with 50S subunits. Nevertheless, ribosomes from transformed cells sedimented normally and had a full complement of proteins. Unexpectedly, the peptidyl transferase activity in the chimeric ribosomes bearing mutant TthS14 was much lower than that measured in ribosomes incorporating wild-type TthS14. The catalytic center of the ribosome is located within the 50S subunit and, therefore, it is unlikely to be directly affected by changes in the structure of S14. More probably, the perturbing effects of S14 mutation on the catalytic center seem to be propagated by adjacent intersubunit bridges or the P-site tRNA molecule, resulting in weak donor-substrate reactivity. This hypothesis was verified by molecular dynamics simulation analysis.     

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.     

A fluorescent derivative of ribosomal protein S18 which permits direct observation of messenger RNA binding.

70 S Escherichia coli ribosomes were reacted with the fluorescent dye N-(iodoacetylaminoethyl)-5-naphthylamine-1-sulfonic acid for 10 min under mild conditions. The resulting ribosomes were fully active. 30 S subunits isolated from these particles were also fully active. They contain approximately 0.7 eq of fluorescent dye. Nearly all of it is attached to protein S18. Competitive reaction with N-ethylmaleimide implies that the fluorescent dye is located at cysteine 10 of the protein. The labeled 30 S particles will recombine with 50 S subunits to form stable 70 S particles. Thus the procedures we have developed allow the large scale preparation of an active fluorescent conjugate of the 70 S ribosome. The fluorescence of the 70 S particles is sensitive to the binding of mRNA, showing both quenching and a shift in emission spectra. Thus it affords a simple way to quantitate mRNA binding directly. In pilot studies without tRNA, the binding constant of the initiation triplet codon adenylyl-(3' leads to 5')-uridylyl-(3' leads to 5')-guanosine to 70 S ribosome was found to be an order of magnitude larger than that of polyuridylic acid.     

Ribosome-binding sites on chloroplastrbcL andpsbA mRNAs and light-induced initiation of D1 translation

Chloroplast ribosome-binding sites were identified on the plastidrbcL andpsbA mRNAs using toeprint analysis. TherbcL translation initiation domain is highly conserved and contains a prokaryotic Shine-Dalgarno (SD) sequence (GGAGG) located 4 to 12 nucleotides upstream of the initiator AUG. Toeprint analysis ofrbcL mRNA associated with plastid polysomes revealed strong toeprint signals 15 nucleotides downstream from the AUG indicating ribosome binding at the translation initiation site.Escherichia coli 30S ribosomes generated similar toeprint signals when mixed withrbcL mRNA in the presence of initiator tRNA. These results indicate that plastid SD sequences are functional in chloroplast translation initiation. ThepsbA initiator region lacks a SD sequence within 12 nucleotides of the initiator AUG. However, toeprint analysis of soluble and membrane polysome-associatedpsbA mRNA revealed ribosomes bound to the initiator region.E. coli 30S ribosomes did not associate with thepsbA translation initiation region.E. coli and chloroplast ribosomes bind to an upstream region which contains a conserved SD-like sequence. Therefore, translation initiation onpsbA mRNA may involve the transient binding of chloroplast ribosomes to this upstream SD-like sequence followed by scanning to localize the initiator AUG. Illumination 8-day-old dark-grown barley seedlings caused an increase in polysome-associatedpsbA mRNA and the abundance of initiation complexes bound topsbA mRNA. These results demonstrate that light modulates D1 translation initiation in plastids of older dark-grown barley seedlings.     

Unusual ribosome binding properties of mRNA encoding bacteriophage lambda repressor.

The mRNA encoding repressor cI of phage lambda is the only known E. coli message which starts directly with the initiation AUG codon. The ability of in vitro synthesized cI mRNA fragments (150 or 400 nts) to form ternary initiation complexes has been studied using the toeprint method. In the presence of tRNA(Met)f, these fragments are capable of forming the ternary complexes at the 5'-terminal AUG codon not only with 30S subunits but also with undissociated 70S ribosomes (70S tight couples). In the latter case, no binding at other positions of cI mRNA can be detected at all. The starting region of cI mRNA has a single stranded conformation and is highly enriched in A-residues. This feature of cI mRNA RBS is suggested to be the main factor which allows cI mRNA to form the initiation complex with the ribosome. Unlike 30S subunits, the binding to 70S tight couples is not affected by any of the initiation factors, although it is as efficient as that to 30S subunits supplemented with the factors. 30S subunits prefer to associate with the internal RBSs of the preformed mRNA molecules, provided that they are not sequestered by the secondary structure. In contrast, 70S tight couples tend to avoid extra sequences upstream of the codon directed to the P site and occupy a position as close as possible to the 5'-end of the message. This has been found to be the case both for tRNA(Met)f and for elongator tRNA(Glu)2. The structural features of mRNA RBSs which influence their different binding for 30S subunits and 70S ribosomes are discussed.     

Conformational change in the 16S rRNA in the Escherichia coli 70S ribosome induced by P/P- and P/E-site tRNAPhe binding

The effects of P/P- and P/E-site tRNA(Phe) binding on the 16S rRNA structure in the Escherichia coli 70S ribosome were investigated using UV cross-linking. The identity and frequency of 16S rRNA intramolecular cross-links were determined in the presence of deacyl-tRNA(Phe) or N-acetyl-Phe-tRNA(Phe) using poly(U) or an mRNA analogue containing a single Phe codon. For N-acetyl-Phe-tRNA(Phe) with either poly(U) or the mRNA analogue, the frequency of an intramolecular cross-link C967 x C1400 in the 16S rRNA was decreased in proportion to the binding stoichiometry of the tRNA. A proportional effect was true also for deacyl-tRNA(Phe) with poly(U), but the decrease in the C967 x C1400 frequency was less than the tRNA binding stoichiometry with the mRNA analogue. The inhibition of the C967 x C1400 cross-link was similar in buffers with, or without, polyamines. The exclusive participation of C967 with C1400 in the cross-link was confirmed by RNA sequencing. One intermolecular cross-link, 16S rRNA (C1400) to tRNA(Phe)(U33), was made with either poly(U) or the mRNA analogue. These results indicate a limited structural change in the small subunit around C967 and C1400 during tRNA P-site binding sensitive to the type of mRNA that is used. The absence of the C967 x C1400 cross-link in 70S ribosome complexes with tRNA is consistent with the 30S and 70S crystal structures, which contain tRNA or tRNA analogues; the occurrence of the cross-link indicates an alternative arrangement in this region in empty ribosomes.     

Further evidence for the participation of proteins S 3, S 14 and S 19 in tRNA binding to E. coli 30 S subunits

Previous studies have shown that iodination of 30 S subunits causes inactivation for both enzymatic fMet-tRNA and non-enzymatic phe-tRNA binding activities. This inactivation was shown to be due to the modification of three to five ribosomal proteins [1]. In this report the role of these proteins in tRNA binding activity has been further studied. Purified ribosomal proteins, isolated from modified subunits, are re-assembled into otherwise unmodified 30 S ribosomes and assayed for tRNA binding capacity. The presence of modified S 3, S 14 and S 19 (S 15) in the reconstituted particle results in substantial reduction of both fMet-tRNA and phe-tRNA binding activities. This reduction in tRNA binding activity does not appear to be due to an assembly defect.