Immunoelectron microscopic localization of the S19 site on the 30 S ribosomal subunit which is crosslinked to A site bound transfer RNA

Phe-tRNA of Escherichia coli, specifically derivatized at the S4U8 position with the 9 A long p-azidophenacyl photoaffinity probe, was crosslinked exclusively to protein S19 of the 30 S ribosomal subunit when the transfer RNA occupied the ribosomal A site (Lin et al., 1983). Two antigenic sites for S19 are known, on opposite sides of the head of the subunit. In this work, discrimination between these two sites was accomplished by affinity immunoelectron microscopy. A dinitrophenyl group was placed on the acp3U47 residue of the same tRNA molecules bearing the photoprobe on S4U8. Addition of this group affected neither aminoacylation, A site binding, nor crosslinking. It also made possible specific affinity purification of crosslinked tRNA-30 S complexes from unreactive 30 S. Reaction of the 2,4-dinitrophenyl-labeled tRNA-30 S complex with antibody was followed by immunoelectron microscopy to reveal the sites of attachment. All of the bound antibody was associated with the ribosome region corresponding to only one of the two known antigenic sites for S19, namely the one closer to the large side projection of the 30 S subunit. A site within this region must be within 10 A of the S4U8 residue of tRNA when it is bound in the ribosomal A site.     

Covalent crosslinking of Escherichia coli phenylalanyl-tRNA and valyl-tRNA to the ribosomal A site via photoaffinity probes attached to the 4-thiouridine residue

tRNAPhe and tRNAVal of Escherichia coli were derivatized at the S4U8 position with p-azidophenacyl and p-azidophenacylacetate photoaffinity probes. The modified tRNAs could still function efficiently in all of the partial reactions of protein synthesis except for an approximately sevenfold decrease in the rate of translocation. Irradiation (310 to 340 nm) of probe-modified Phe-tRNA or Val-tRNA placed in the ribosomal A site led to crosslinking that was totally dependent on irradiation, the presence of the azido group on the probe, mRNA, and elongation factor Tu (EFTu). Prephotolysis of the modified tRNA abolished crosslinking, but prephotolysis of the ribosomes and factors had little effect. Crosslinking was efficiently quenched by mercaptoethanol or dithiothreitol, demonstrating accessibility of the probe to solvent. Use of GDPCP in place of GTP also blocked crosslinking, probably because of the retention of EFTu on the ribosome. Crosslinking with the p-azidophenacyl acetate (12 A) probe was only half as efficient as with the p-azidophenacyl (9 A) probe, and this ratio was not changed by varying Mg2+ from 5 to 15 mM. The crosslink was from a functional A site, since AcPhePhe-tRNA at the A site could be crosslinked, and it was A site-specific, because neither translocation nor direct non-enzymatic P site binding yielded any significant covalent product. The crosslink was to ribosomal protein(s) of the 30 S subunit. No other ribosomal component was crosslinked. Identification of the protein crosslinked is described in the accompanying paper.     

Elongation factor Tu ternary complex binds to small ribosomal subunits in a functionally active state

A complex between elongation factor Tu (EF-Tu), GTP, phenylalanyl-tRNA (Phe-tRNA), oligo(uridylic acid) [oligo(U)], and the 30S ribosomal subunit of Escherichia coli has been formed and isolated. Binding of the EF-Tu complex appears to be at the functionally active 30S site, by all biochemical criteria that were examined. The complex can be isolated with 0.25-0.5 copy of EF-Tu bound per ribosome. The binding is dependent upon the presence of both the aminoacyl-tRNA and the cognate messenger RNA. Addition of 50S subunits to the preformed 30S-EF-Tu-GTP-Phe-tRNA-oligo(U) complex ("30S-EF-Tu complex") causes a rapid hydrolysis of GTP. This hydrolysis is coordinated with the formation of 70S ribosomes and the release of EF-Tu. Both the release of EF-Tu and the hydrolysis of GTP are stoichiometric with the amount of added 50S subunits. 70S ribosomes, in contrast to 50S subunits, neither release EF-Tu nor rapidly hydrolyze GTP when added to the 30S-EF-Tu complexes. The inability of 70S ribosomes to react with the 30S-EF-Tu complex argues that the 30S-EF-Tu complex does not dissociate prior to reaction with the 50S subunit. The requirements of the 30S reaction for Phe-tRNA and oligo(U) and the consequences of the addition of 50S subunits resemble the reaction of EF-Tu with 70S ribosomes, although EF-Tu binding to isolated 30S subunits does not occur during the elongation microcycle. This suggests that the EF-Tu ternary complex binds to isolated 30S subunits at the same 30S site that is occupied during ternary complex interaction with the 70S ribosome.(ABSTRACT TRUNCATED AT 250 WORDS)     

Binding of aminoacyl-tRNA to rat liver ribosomal proteins

Rat liver ribosome treatment with ethanol and 1 M NH₄Cl releases some 31–33 ribosomal proteins. This split protein fraction binds Phe-tRNA, Ac-Phe-tRNA, Met-tRNA_M and f-Met-tRNA_F in the absence of K⁺ and Mg⁺⁺ ions. When the split protein fraction is passed through Sephadex G-100 only six proteins are retained in the column: S10, S14, S15, S19, L35, and L36. The aminoacyl-tRNA binding activity of this protein fraction retained in the Sephadex G-100 column is similar to that of the total split protein fraction, suggesting that the above six proteins, or only some of them, are involved in the binding reaction.     

Protein-protein proximity in the association of ribosomal subunits of Escherichia coli: crosslinking of 30 S protein S16 to 50 S proteins by glutaraldehyde or formaldehyde

The interaction of ribosomal subunits from Escherichia coli has been studied using crosslinking reagents. Radioactive ³⁵S-labeled 50 S subunits and non-radioactive 30 S subunits were allowed to reassociate to form 70 S ribosomes. The 70 S particles, containing radioactivity only in the 50 S protein moiety, were incubated with glutaraldehyde or formaldehyde. As a result of this treatment a substantial fraction of the 70 S particles did not dissociate at 1 mm-Mg²⁺. This fraction was isolated and the ribosomal proteins were extracted. The protein mixture was analyzed by the Ouchterlony double diffusion technique by using eighteen antisera prepared against single 30 S ribosomal proteins (all except those against S3, S15 and S17). As a result of the crosslinking procedure it was found that only anti-S16 co-precipitated ³⁵S-labeled 50 S protein. It is concluded that the 30 S protein S16 is at or near the site of interaction between subunits and can become crosslinked to one or more 50 S ribosomal proteins.     

Crosslinking of eukaryotic initiation factor eIF3 to the 40S ribosomal subunit from rabbit reticulocytes

Complexes of purified 40S ribosomal subunits and initiation factor 3 from rabbit reticulocytes were crosslinked using the reversible protein crosslinking reagent, 2-iminothiolane, under conditions shown previously to lead to the formation of dimers between 40S proteins but not higher multimers. The activity of both the 40S subunits and initiation factor 3 was maintained. Protein crosslinked to the factor was purified by sucrose density gradient centrifugation following nuclease digestion of the ribosomal subunit: alternatively, the total protein was extracted from 40S: factor complexes. The protein obtained by either method was analyzed by two-dimensional diagonal polyacrylamide/sodium dodecyl sulfate gel electrophoresis. Ribosomal proteins were found in multimeric complexes of high molecular weight due to their crosslinking to components of eIF3. Identification of the ribosomal proteins appearing below the diagonal was accomplished by elution, radioiodination, two-dimensional polyacrylamide/urea gel electrophoresis, and radioautography. Proteins S2, S3, S3a, S4, S5, S6, S8, S9, S11, S12, S14, S15, S16, S19, S24, S25, and S26 were identified. Because many of the proteins in this group form crosslinked dimers with each other, it was impossible to distinguish proteins directly crosslinked to eIF3 from those crosslinked indirectly through one bridging protein. The results nonetheless imply that the 40S ribosomal proteins identified are at or near the binding site for initiation factor 3.     

Action of virginiamycin M on the stability of different ribosomal complexes to ultracentrifugation

It was previously shown that virginiamycin M produces in vivo an accumulation of pressure-sensitive (60 S) ribosomes, and in vitro an inactivation of the donor and acceptor sites of peptidyl transferase. The latter action, however, is expected to cause the accumulation in vivo of ribosome complexes carrying acylated tRNA species: such complexes are usually endowed with pressure resistance. However, present data indicate that poly(U).ribosome complexes carrying Phe-tRNA, Ac-Phe-tRNA or Ac-Phe-Phe-tRNA at either the A or the P site become pressure-sensitive after exposure to virginiamycin M in vitro. It is known also that uncoupled EF-G GTPase is stimulated by P-site-bound unacylated tRNA, not by the acylated species. Our data show, however, a stimulation of EF-G GTPase, when ribosomal complexes carrying Ac-Phe-tRNA or Ac-Phe-Phe-tRNA at the P site are incubated with virginiamycin M. The interpretation proposed to account for all these findings is that complexes carrying A- and P-site-bound aminoacyl-tRNA derivatives, which undergo a stable interaction with the peptidyl transferase, are endowed with ultracentrifugal stability, whereas complexes with unacylated tRNA (which does not interact with the enzyme) are pressure-sensitive. By inactivating the donor and acceptor sites of peptidyltransferase, virginiamycin M causes aminoacyl-tRNA.ribosome complexes to mimic tRNA.ribosome complexes in their pressure-lability and competence in EF-G GTPase stimulation. This interpretation is supported by the finding that the ribosome-promoted protection of aminoacyl-tRNA against spontaneous hydrolysis is suppressed by virginiamycin M.     

The complex between ribosomal proteins and aminoacyl-tRNA: the interactions and hydrolytic activities are not confined to the proteins L2 and L16 of Escherichia coli ribosomes

The capacity of some Escherichia coli (E. coli) ribosomal proteins to bind to tRNA and to hydrolyse their aminoacylated derivatives has been analysed. The following results were obtained: (1) The basic proteins L2, L16 and L33 and S20 bound f[3H]Met-tRNA to a similar extent as the total proteins from 30 S (TP30) or 50 S (TP50) when tested by nitrocellulose filtration, in contrast to the more acidic proteins L7/L12 and S8. (2) The proteins of the peptidyltransferase centre, L2 and L16, showed no distinct specificity, binding various charged tRNAs from E. coli and Saccharomyces cerevisiae (S. cerevisiae). (3) A number of isolated ribosomal proteins hydrolysed aminoacyl-tRNA as assessed by trichloroacetic acid precipitation, in contrast to the TP30 and TP50. (4) The loss of radiolabel from Ac[14C]Phe-tRNA and from [14C]tRNA in the presence of these proteins could not be prevented by RNasin, a ribonuclease inhibitor, whereas that mediated by a sample of non-RNase-free bovine serum albumin was inhibited. (5) When double-labelled, Ac[3H]Phe-[14C]tRNA was incubated with L2 both radiolabels were lost, indicating that this potential candidate for a peptidyltransferase enzyme does not specifically cleave the ester bond between the aminoacyl residue and the tRNA.     

The action of virginiamycin M on the acceptor, donor, and catalytic sites of peptidyltransferase

Virginiamycin M inhibits both peptide bond formation and binding of aminoacyl-tRNA to bacterial ribosomes, and induces a lasting inactivation of the 50 S subunit (50 S). In the present work, the effects of this antibiotic on the acceptor and donor sites of peptidyltransferase have been explored, in the presence of virginiamycin M as well as after its removal. Virginiamycin M inhibited the binding of puromycin to ribosomes and reduced both the enzymatic and nonenzymatic binding of Phe-tRNA to the A site by inducing its release from the ribosomes (similar effects were observed with 50 S), whereas the antibiotic had no effect on the binding of unacylated tRNAPhe to the same site. Moreover, virginiamycin M caused Ac-Phe-tRNA or Phe-tRNA to be released from the ribosomal P site, when complexes were incubated with unacylated tRNA, elongation factor G, and GTP (similar finding with 50 S). Instead, peptide bond formation between Ac-Phe-tRNA positioned at the P site and Phe-tRNA at the A site was found to take place, albeit at a very low rate, in the presence of the antibiotic. The overall conclusion is that both the acceptor and donor substrate binding sites of the peptidyltransferase, which interact with the aminoacyl moiety of tRNA, are permanently altered upon transient contact of ribosomes with virginiamycin M.     

The 30S ribosomal P site: a function of 16S rRNA

The 30S ribosomal P site serves several functions in translation. It must specifically bind initiator tRNA during formation of the 30S initiation complex; bind the anticodon stem-loop of peptidyl-tRNA during the elongation phase; and help to maintain the translational reading frame when the A site is unoccupied. Early experiments provided evidence that 16S rRNA was an important component of the 30S P site. Footprinting and crosslinking studies later implicated specific nucleotides in interactions with tRNA. The crystal structures of the 30S subunit and 70S ribosome-tRNA complexes confirmed the interactions between 16S rRNA and tRNA, but also revealed contacts between tRNA and the C-terminal tails of proteins S9 and S13. Deletion of these tails now shows that the 16S rRNA contacts alone are sufficient to support protein synthesis in living cells.     

Affinity labelling of yeast ribosomal peptidyl transferase

Summary Using p-nitrophenylcarbamyl-phenylananyl-tRNA (PNPC-Phe-tRNA) and N-Iodoacetyl-phenylalanyl-tRNA as affinity labels we have attempted to identify the components of the aminoacyl-tRNA binding sites located in the vicinity of the peptidyl transferase centre of the yeast ribosome. Both Phe-tRNA derivatives bind to the ribosomal A-site in the presence of 20 mM Mg⁺⁺ ion concentration and can be translocated to the ribosomal P-site in the presence of elongation factor. After the labels have been allowed to react covalently with ribosomes they were found associated with the large ribosomal subunit. Proteins L36, L43, L42, L29, L2, L17/18, L19/20 and proteins L26, L38, L22/23, L7/9, L4/6, L36, L11, L43, L39 were labelled in samples treated with PNPC-Phe-tRNA and N-Iodoacetyl-Phe-tRNA respectively. In contrast, when only the components of the ribosomal P-site were analysed by reacting the treated particles with puromycin fewer spots were labelled, corresponding to proteins L36 and L19/20 using PNPC-Phe-tRNA and proteins L4/6, L36, and L43 using N-Iodoacetyl-Phe-tRNA.     

On the Phe-tRNA induced binding of fluorescent oligonucleotides to the ribosomal decoding site.

Fluorescent oligonucleotides were prepared by dansylation of 5'-amino uridylates of varying chainlength. Except for the trinucleoside diphosphate, they stimulated the binding of PhetRNA TO 70S E. coli ribosomes as efficiently as underivatised oligouridylic acids of comparable chainlength. The ternary ribosomal complex [70S X Phe-tRNA X dansyl-n5'U(pU)4] was separated from excess oligonucleotide and its fluorescence spectra were measured. The quantum yield of the dansylated pentauridylate was enhanced 2.5 fold when bound to the ribosomal decoding site, but no shift of the emission spectrum was observed. The ribosomal complex is considered useful for topographic investigations by singlet energy transfer, using the functionally defined decoding site as reference point.     

Functional heterogeneity of the 30S ribosomal subunit of E. coli

Summary When 30S ribosomal subunits from E. coli are incubated with poly U, two separable components are recovered by zonal centrifugation of the incubation mixture. The faster sedimenting component is an aggregate of 30S subunits and poly U, while the slower one corresponds to the 30S ribosomal subunit. One ribosomal protein, protein 30S-1 is predominantly present in the faster sedimenting aggregate. The amount of poly U-30S subunit complex formed in the incubation mixture is limited by the amount of protein 30S-1 present. Consequently the number of ribosomal binding sites available for Phe-tRNA is limited in a similar fashion by the presence of protein 30S-1. When 30S ribosomal subunits are reconstituted in the absence of protein 30S-1, very little poly U or Phe-tRNA binding capacity is manifest under our assay conditions. We conclude that protein 30S-1 is required for maximum capacity of ribosomes to bind mRNA. Since this protein is present only on a fraction of the ribosome at any one time, it must exchange from one ribosome to another during protein synthesis.Abbreviations Poly U (polyuridylic acid) - t-RNA (transfer ribonucleic acid) - mRNA (messenger ribonucleic acid) - Phe (phenylanine) - A₂₆₀ unit (unit of material which gives an optical density of 1.0 at 260 nm in a one centimeter optical path)     

From stand-by to decoding site. Adjustment of the mRNA on the 30S ribosomal subunit under the influence of the initiation factors.

The hypothesis of an adjustment of the mRNA in its ribosomal channel under the influence of the initiation factors has been tested by site-directed crosslinking experiments. Complexes containing 30S subunits with bound mRNA having 4-thio-uracil at specific positions were prepared in the presence or absence of initiation factors and/or fMet-tRNA and subjected to UV irradiation to obtain specific crosslinks of the radioactively labeled mRNA with bases of the 16S rRNA and with ribosomal proteins. The subsequent identification of the specific sites of both mRNA and rRNA and individual ribosomal proteins involved in the crosslinking, obtained under different conditions of complex formation, provide direct evidence for the occurrence of a partial relocation of the mRNA on the 30S ribosomal subunits under the influence of the factors. The nature of this mRNA relocation is compatible with our previous proposal of a shift of the template from an initial ribosomal "stand-by site" to a second site closer to that occupied when the initiation triplet of the mRNA is decoded in the P-site.     

A signal relay between ribosomal protein S12 and elongation factor EF-Tu during decoding of mRNA

Codon recognition by aminoacyl-tRNA on the ribosome triggers a process leading to GTP hydrolysis by elongation factor Tu (EF-Tu) and release of aminoacyl-tRNA into the A site of the ribosome. The nature of this signal is largely unknown. Here, we present genetic evidence that a specific set of direct interactions between ribosomal protein S12 and aminoacyl-tRNA, together with contacts between S12 and 16S rRNA, provide a pathway for the signaling of codon recognition to EF-Tu. Three novel amino acid substitutions, H76R, R37C, and K53E in Thermus thermophilus ribosomal protein S12, confer resistance to streptomycin. The streptomycin-resistance phenotypes of H76R, R37C, and K53E are all abolished by the mutation A375T in EF-Tu. A375T confers resistance to kirromycin, an antibiotic freezing EF-Tu in a GTPase activated state. H76 contacts aminoacyl-tRNA in ternary complex with EF-Tu and GTP, while R37 and K53 are involved in the conformational transition of the 30S subunit occurring upon codon recognition. We propose that codon recognition and domain closure of the 30S subunit are signaled through aminoacyl-tRNA to EF-Tu via these S12 residues.     

tRNA binding capacities of ribosomal subunits from the archaebacterium Halobacterium halobium

tRNA saturation experiments were performed with ribosomal subunits from the extreme halophilic archaebacterium Halobacterium halobium. In the presence of poly(U) the 30S subunit could bind equally well one AcPhe-tRNAPhe, Phe-tRNAPhe, or deacylated tRNAPhe molecule, respectively. Binding experiments with a mixture of two differently labeled tRNA species revealed that all three kinds of tRNA bound to one and the same binding site on the 30S subunit. Poly(U) dependent binding to the 50S subunit was insignificant for AcPhe-tRNA and Phe-tRNA. In the absence of poly(U) both AcPhe-tRNAPhe and Phe-tRNAPhe showed no significant binding to either subunit, whereas the binding of deacylated tRNAPhe could not be clearly determined. These results are in good agreement with those obtained from ribosomal subunits of the eubacterium Escherichia coli.     

The functional role of the C-terminal tail of the human ribosomal protein uS19

The eukaryotic ribosomal protein uS19 has a C-terminal tail that is absent in its bacterial homologue. This tail has been shown to be involved in the formation of the decoding site of human ribosomes. We studied here the previously unexplored functional significance of the 15 C-terminal amino acid residues of human uS19 for the assembly of ribosomes and translation using HEK293-based cell cultures capable of producing FLAG-labeled uS19 (uS19^FLAG) or its mutant form deprived of the mentioned amino acid ones. The examination of polysome profiles of cytoplasmic extracts from the respective cells revealed that the deletion of the above uS19 amino acid residues barely affected the assembly and maturation of 40S subunits and the initiation of translation, but completely prevented the formation of polysomes. This implied the crucial importance of the uS19 tail in the elongation process. Analysis of tRNAs associated with 40S subunits and 80S ribosomes containing wild type uS19^FLAG or its truncated form showed that the deletion of the C-terminal pentadecapeptide fragment of uS19 did not interfere with the binding of aminoacyl-tRNA (aa-tRNA) at the ribosomal A site. The results led to the conclusion that the transpeptidation, which occurs on the large ribosomal subunit after decoding the A site codon by the incoming aa-tRNA, is the most likely elongation stage, where this uS19 fragment can play a critical role. Our findings suggest that the uS19 tail is a keystone player in the accommodation of aa-tRNA at the A site, which is a pre-requisite for the peptide transfer.     

Chemical modification in situ of Escherichia coli 30 S ribosomal proteins by the site-specific reagent pyridoxal phosphate. Inactivation of the aminoacyl-tRNA and mRNA binding sites

epsilon-Amino groups of lysines of 30 S ribosomal subunits with affinity for phosphate groups were selectively modified in situ by reaction with pyridoxal phosphate and reduction of the Schiff base with nonradioactive or radioactive sodium borohydride. This reaction modified only a limited number of ribosomal proteins and resulted in the loss of only some 30 S activities. The modified proteins were identified and the extent of their modification determined. The main targets of the reaction were S3 greater than S1 greater than S6. The activity most severely affected by the pyridoxal phosphate reaction was mRNA-dependent aminoacyl-tRNA binding. Some inhibition of poly(U) binding was also observed, while neither binding of initiation factors nor association with 50 S subunits was inhibited. The inhibition of aminoacyl-tRNA binding showed distinct selectivity: the inhibition was far greater with NAcPhe-tRNA than with fMet-tRNA and with "A" site than with "P" site binding. In addition, initiation complex formation with some mRNAs (e.g. MS2 RNA) was affected more than with others (e.g. T7 early mRNA). Ribosome reconstitution experiments showed that the modification of protein S3 was the primary cause of the inhibition; a role was also played by ribosomal proteins S1, S2, and S21. Substrate protection experiments showed that the 30 S activity can be protected from pyridoxal phosphate inactivation upon formation of a ternary complex with poly(U) and tRNAPhe or NAcPhe-tRNAPhe. Accordingly, the extent of modification of ribosomal protein S3 was reduced in the ternary complex while modification of S1 was reduced in the presence of poly(U) alone.     

A codon sugar structure strongly influences tRNA binding to programmed ribosomes.

To study the role of a codon sugar-phosphate backbone in aminoacyl-tRNA selection on the ribosome a comparison of tRNA(Phe) affinity for pdTpdTpdT and prUprUprU in solution, and for correspondingly programmed 30S ribosomal subunits has been performed. In solution the tRNA(Phe) affinity for pdTpdTpdT appeared to be even slightly higher than for prUprUprU, whereas deoxyribocodon was significantly less efficient in the stimulation of Phe-tRNA(Phe) binding to the 30S ribosomal subunit. Some difference in neomycin action in both systems was revealed.     

Affinity modification of Escherichia coli ribosomes near the acceptor tRNA-binding site

It was shown that Phe-tRNA Phe derivatives bearing arylazidogroups scattered statistically on N7 guanosine residues retain the ability to EF-Tu-dependent binding to E. coli ribosomes. UV-irradiation of the corresponding complex with the derivative of Phe-tRNA Phe located at A-site results in a specific modification of both ribosomal subunits to an approximately equal extent. It was found that proteins S9, S15, S16, S17, S18, S19 and L8/L9, L13, L15, L27 are labelled at A-site.