Antibiotic effects on the photoinduced affinity labeling of Escherichia coli ribosomes by puromycin.

The effect of ribosomal antibiotics on the photoinduced affinity labeling of Escherichia coli ribosomes by puromycin [Cooperman, B.S., Jaynes, E.N., Brunswick, D.J., & Luddy, M.A. (1975) Proc. Natl. Acad. Sci. U.S.A. 72, 1974; Jaynes, E.N. Jr., Grant, P.G., Giangrande, G., Wieder, R., & Cooperman, B.S. (1978) Biochemistry 17, 561] has been studied. Although blasticidin S, sparsomycin, lincomycin, and erythromycin are essentially without effect, major changes are seen on addition of either chloramphenicol or tetracycline. The products of photoincorporation have been characterized by one- and two-dimensional gel electrophoresis and by specific immunoprecipitation with antibodies to ribosomal proteins. In the presence of chloramphenicol, protein S14 becomes the major labeled protein. In the presence of tetracycline, L23 remains the major labeled protein, but the yield of labeled ribosomes is enormously increased, and the labeling is more specific for L23. These results are discussed in terms of the known modes of action of these antibiotics and the photoreactivity of tetracycline.     

Inter-protein distances within the large subunit from Escherichia coli ribosomes.

Selected pairs of protonated ribosomal proteins were reconstituted into deuterated 50S subunits from Escherichia coli ribosomes. The rRNA of the deuterated ribosomal matrix was derived from cells grown in 76% D2O, the deuterated protein moiety from cells grown in 84% D2O. This procedure warrants that the coherent neutron scattering of deuterated proteins and rRNA is nearly the same and equals that of a D2O solution of approximately 90%. The neutron scattering is recorded in a reconstitution buffer containing approximately 90% D2O. The result is a significant improvement of the coherent signal:noise ratio over traditional methods; due to this dilute solutions can be used, thus preventing unfavorable inter-particle effects. From the diffraction pattern the distance between the mass centers of gravity of the two protonated proteins can be deduced. In this way, 50 distances between proteins within the large subunit have been determined which provide a basis for future models of the large ribosomal subunit describing the spatial distribution of the ribosomal proteins. A model containing seven ribosomal proteins is presented.     

Photoaffinity labeling of Escherichia coli ribosomes by an aryl azide analogue of puromycin. Evidence for the functional site specificity of labeling

The photoincorporation of p-azido[3H]puromycin [6-(dimethylamino)-9-[3'-deoxy-3'-[(p-azido-L-phenylalanyl)amino]-beta-D-ribofuranosyl]purine] into specific ribosomal proteins and ribosomal RNA [Nicholson, A. W., Hall, C. C., Strycharz, W. A., & Cooperman, B. S. (1982) Biochemistry (preceding paper in this issue)] is decreased in the presence of puromycin, thus demonstrating that labeling is site specific. The magnitudes of the decreases in incorporation into the major labeled 50S proteins found on addition of different potential ribosome ligands parallel the abilities of these same ligands to inhibit peptidyltransferase. This result provides evidence that p-azidopuromycin photoincorporation into these proteins occurs at the peptidyltransferase center of the 50S subunit, a conclusion supported by other studies of ribosome structure and function. A striking new finding of this work is that puromycin aminonucleoside is a competitive inhibitor of puromycin in peptidyltransferase. The photoincorporation of p-azidopuromycin is accompanied by loss of ribosomal function, but photoincorporated p-azidopuromycin is not a competent peptidyl acceptor. The significance of these results is discussed. Photolabeling of 30S proteins by p-azidopuromycin apparently takes place from sites of lower puromycin affinity than that of the 50S site. The possible relationship of the major proteins labeled, S18, S7, and S14, to tRNA binding is considered.     

The synthesis of a photoreactive puromycin analogue and its application for labeling proteins in the 50-S subunit of Escherichia coli ribosomes.

A photoreactive puromycin analogue, 6-dimethylamino-9-[3-(p-azido-L-beta-phenylalanylamino)-3-deoxy-beta-ribofuranosyl] purine, was synthesized. Biological activity was demonstrated by inhibition of the poly (U)-directed phenylalanine-incorporation system and by decomposition of isolated polysomes from Escherichia coli. The 3H-labeled puromycin analogue was covalently attached to the 50-S subunit of isolated 70-S ribosomes from Escherichia coli after irradiation. More than 90% of the radioactivity was bound to the protein fraction. The 70-S proteins were separated by two-dimensional gel electrophoresis. The proteins labeled primarily were those of the 50-S subunit, identified as L6, L13, L18, L22 and L25. On the basis of the affinity label used and supportive data from the literature, it is concluded that these proteins are at the active center of the 50-S particle and probably belong to the region of the ribosomal A site.     

On the structural specificity of puromycin binding to Escherichia coli ribosomes

We have examined the structural specificity of the puromycin binding sites on the Escherichia coli ribosome that we have previously identified [Nicholson, A. W., Hall, C. C., Strycharz, W. A., & Cooperman, B. S. (1982) Biochemistry 19, 3809-3817, and references cited therein] by examining the interactions of a series of adenine-containing compounds with these sites. We have used as measures of such interactions the inhibition of [3H]puromycin photoincorporation into ribosomal proteins from these sites, the site-specific photoincorporation of the 3H-labeled compounds themselves, and the inhibition of peptidyl transferase activity. For the first two of these measures we have made extensive use of a recently developed high-performance liquid chromatography (HPLC) method for ribosomal protein separation [Kerlavage, A. R., Weitzmann, C., Hasan, T., & Cooperman, B.S. (1983) J. Chromatogr. 266, 225-237]. We find that puromycin aminonucleoside (PANS) contains all of the structural elements necessary for specific binding to the three major puromycin binding sites, those of higher affinity leading to photoincorporation into L23 and S14 and that of lower affinity leading to photoincorporation into S7. Although tight binding to the L23 and S7 sites requires both the N6,N6-dimethyl and 3'-amino groups within PANS, only the N6,N6-dimethyl group and not the 3'-amino group is required for binding to the S14 site. Our current results reinforce our previous conclusion that photoincorporation into L23 takes place from the A' site within the peptidyl transferase center and lead us to speculate that the S14 site might be specific for the binding of modified nucleosides. They also force the conclusion that puromycin photoincorporation proceeds through its adenosyl moiety.     

Elongation factor-dependent affinity labeling of Escherichia coli ribosomes

Elongation factor-dependent affinity labeling of Escherichia coli ribosomes was obtained using a functional analogue of aminoacyl-tRNA. Since elongation factor Tu (EF-Tu) screens both the modified aminoacyl-tRNAs and the ribosomal complexes for active particles, only functional macromolecular complexes are examined. This approach also provides an unequivocal identification of the transfer RNA binding site from which affinity labeling occurs. N^ε-bromoacetyl-Lys-tRNA was prepared by covalently attaching an electrophilic group to the side-chain of the amino acid. This chemical modification did not interfere with function, since the ?BrAcLys-tRNA participated successfully in EF-Tu and poly(rA)-dependent binding to ribosomes, peptide bond formation, and elongation factor G (EF-G)-mediated translocation. Affinity labeling of ribosomal RNA was observed only in those incubations which contained both EF-Tu and EF-G. The crosslinking of ?BrAcLys-tRNA to 23 S rRNA was found even if fusidic acid was added to the incubation before EF-G. The dependence of the covalent reaction on EF-G demonstrates, unambiguously, that a reactive residue of 23 S rRNA is located adjacent to the 3′ end of the functionally defined P site. Similarly, the affinity labeling of proteins L13/14/15, L2, L32/33, and L24 required EF-G-dependent translocation of ?BrAcLys-tRNA into the P site. Protein L27 was alkylated following the EF-Tu-dependent binding of ?BrAcLys-tRNA to the ribosome, and the extent of affinity labeling was stimulated by the addition of EF-G to the incubation. Double-label dipeptide experiments confirmed that affinity labeling occurred from functional tRNA binding sites by demonstrating that the same ?BrAcLys-tRNA which reacted covalently with 23 S rRNA or a ribosomal protein could also participate in peptide bond formation. Finally, the ribosome affinity labeling obtained with ?BrAcLys-tRNA · EF-Tu · guanylylimidodiphosphate differed little from that obtained with ?BrAcLys-tRNA · EF-Tu · GTP. This work constitutes the first direct examination of the aminoacyl ends of the EF-Tu-dependent conformational states of the ribosomal complex, and demonstrates the potential value of functional Lys-tRNA analogues with different probes attached to the lysine side-chain.     

Photoinduced affinity labeling of the Escherichia coli ribosome puromycin site.

The photoincorporation of puromycin into Escherichia coli ribosomes has been studied in detail. Incorporation into protein L23 as a function of puromycin concentration follows a simple saturation curve and is specifically blocked by structural and functional analogues of puromycin, thus demonstrating that such incorporation proceeds via an affinity labeling process. Incorporation into L23 becomes more specific as the light fluence is reduced, indicating that such incorporation takes place from a native rather than light-denatured puromycin site. L23 remains the major labeled protein using ribosomes prepared by several procedures, suggesting the conservative nature of the site. In addition evidence is presented for affinity labeling of S14 and of a site in the RNA fraction of the 50S particle. Specific incorporation appears to proceed with an anomalously high quantum yield. The detailed photochemical mechanism is not understood, although 8-alkylation of purine moiety has been excluded. Incorporation is largely inhibited in the presence of thiol reagents.     

Primary structure of protein L19 from the large subunit of Escherichia coli ribosomes.

Protein L19, a component of the Escherichia coli 50S ribosomal subunit implicated in 30S-50S subunit interaction was sequenced by the dansyl-Edman method. L19 consists of a single polypeptide chain of 114 amino acids giving a calculated molecular weight of 13 002. Peptides obtained from various enzymatic cleavages were isolated on thin-layer peptide maps or gel filtration. Automated Edman degradation using a liquid phase sequenator was carried out on the whole protein as well as on a large 58-residue fragment arising from digestion with Staphylococcus aureus protease. Every position in protein L19 was confirmed at least twice. Results of secondary structure estimation and homologies with other E. coli ribosomal protein sequences are presented.     

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.     

Localization of spermine binding sites in 23S rRNA by photoaffinity labeling: parsing the spermine contribution to ribosomal 50S subunit functions

Polyamine binding to 23S rRNA was investigated, using a photoaffinity labeling approach. This was based on the covalent binding of a photoreactive analog of spermine, N¹-azidobenzamidino (ABA)-spermine, to Escherichia coli ribosomes or naked 23S rRNA under mild irradiation conditions. The cross-linking sites of ABA-spermine in 23S rRNA were determined by RNase H digestion and primer-extension analysis. Domains I, II, IV and V in naked 23S rRNA were identified as discrete regions of preferred cross-linking. When 50S ribosomal subunits were targeted, the interaction of the photoprobe with the above 23S rRNA domains was elevated, except for helix H38 in domain II whose susceptibility to cross-linking was greatly reduced. In addition, cross-linking sites were identified in domains III and VI. Association of 30S with 50S subunits, poly(U), tRNA^Phe and AcPhe-tRNA to form a post-translocation complex further altered the cross-linking, in particular to helices H11–H13, H21, H63, H80, H84, H90 and H97. Poly(U)-programmed 70S ribosomes, reconstituted from photolabeled 50S subunits and untreated 30S subunits, bound AcPhe-tRNA in a similar fashion to native ribosomes. However, they exhibited higher reactivity toward puromycin and enhanced tRNA-translocation efficiency. These results suggest an essential role for polyamines in the structural and functional integrity of the large ribosomal subunit.     

Study of the photoaffinity modification of Escherichia coli ribosomes near the donor tRNA-binding center

Affinity labelling of E. coli ribosomes near the donor tRNA-binding (P) site was studied with the use of photoreactive derivatives of tRNAPhe bearing arylazidogroups on N7 atoms of guanine residues (azido-tRNA). UV-irradiation of complexes 70S ribosome.poly(U).azido- tRNA(P-site) and 70S ribosome.poly(U).azido-tRNA(P-site).Phe- tRNAPhe(A-site) resulted in covalent attachment of azido-tRNA to ribosomes, both subunits being labelled. In both cases modification extent of 30S subunit was two-fold than that of the 50S one. It was shown that when the A-site was free the azido-tRNA located in P-site labelled proteins S9, S11, S12, S13, S21 and L14, L27, L31. Azido-tRNA located in P-site when the A-site was occupied with Phe-tRNAPhe labelled proteins S11, S12, S13, S14, S19, L32/L33 and possibly L23, L25. From the comparison of the sets of proteins labelled when A-site was free or occupied a conclusion was drawn that aminoacyl-tRNA located in ribosomal A-site affects the arrangement of deacylated tRNA in P-site. Data obtained allow to propose that proteins S5, S19, S20 and L24, L33 interact with guanine residues important for the tRNA tertiary structure formation.     

tRNA binding sites on the subunits of Escherichia coli ribosomes

Programmed 30 S subunits expose only one binding site, to which the different classes of tRNA (deacylated tRNAPhe, Phe-tRNAPhe, and N-acetylphenylalanyl (AcPhe)-tRNAPhe) bind with about the same affinity. Elongation factor Tu within the ternary complex does not contribute to the binding of Phe-tRNA. Binding of acylated or deacylated tRNA to 30 S depends on the cognate codon; nonprogrammed 30 S subunits do not bind tRNA to any significant extent. The existence of only one binding site/30 S subunit (and not, for example, two sites in 50% of the subunits) could be shown with Phe-tRNAPhe as well as deacylated tRNAPhe pursuing different strategies. Upon 50 S association the 30 S-bound tRNA appears in the P site (except the ternary complex which is found at the A site). Inhibition experiments with tetracycline demonstrated that the 30 S inhibition pattern is identical to that of the P site but differs from that of the A site of 70 S ribosomes. In contrast to 30 S subunits the 50 S subunit exclusively binds up to 0.2 and 0.4 molecules of deacylated tRNAPhe/50 S subunit in the absence and presence of poly(U), respectively, but neither Phe-tRNA nor AcPhe-tRNA. Noncognate poly(A) did not stimulate the binding indicating codon-anticodon interaction at the 50 S site. The exclusive binding of deacylated tRNA and its dependence on the presence of cognate mRNA is reminiscent of the characteristics of the E site on 70 S ribosomes. 30 and 50 S subunits in one test tube expose one binding site more than the sum of binding capacities of the individual subunits. The results suggest that the small subunit contains the prospective P site and the large subunit the prospective E site, thus implying that the A site is generated upon 30 S-50 S association.     

A photoaffinity labelling study of the messenger RNA-binding region of Escherichia coli ribosomes.

A photoaffinity labelling study of the messenger RNA-binding region of E. coli ribosomes has been made, using oligoadenylic acids as mRNA analogs. The oligonucleotides, of chain length 6 to 8 and thus several nucleotides longer than oligonucleotides previously employed for this purpose, carried a radioactive photolabile aromatic azide reagent bound covalently to the 3'-terminal ribose moiety. The synthesis of the reagent, p-azidobenzoyl-(3H)-glycylhydrazide, is described. The derivatized oligonucleotides were shown to be functional messengers. They stimulated the binding of the cognate aminoacyl-tRNA, lysyl-tRNA: their binding was reciprocally stimulated by lysyl-tRNA; and they competed with underivatized oligoadenylates for ribosomal binding sites. When the 70 S ribosomal binding complex was irradiated, the photolabile reagent reacted covalently with both RNA and proteins of the 30 S subunit and with tRNA, but not with the 50 S subunit. The 16 S RNA appeared to be labelled at more than one site. Of the proteins, S3 and S5 reacted with the reagent with high specificity; and the possibility was not eliminated that S4 may have been labelled to a minor degree. Functional studies in other laboratories have implicated S3 and S5 in the decoding process, but these proteins were not labelled by any of the previously reported mRNA affinity labelling analogs. The results reported here therefore indicate that S3 and S5 not only affect the decoding process, but are located in the mRNA-binding region of the ribosome, presumably to the 3' side of the decoding site.     

Mapping proteins of the 50S subunit from Escherichia coli ribosomes

Mapping of protein positions in the ribosomal subunits was first achieved for the 30S subunit by means of neutron scattering about 15 years ago. Since the 50S subunit is almost twice as large as the 30S subunit and consists of more proteins, it was difficult to apply classical contrast variation techniques for the localisation of the proteins. Polarisation dependent neutron scattering (spin-contrast variation) helped to overcome this restriction. Here a map of 14 proteins within the 50S subunit from Escherichia coli ribosomes is presented including the proteins L17 and L20 that are not present in archeal ribosomes. The results are compared with the recent crystallographic map of the 50S subunit from the archea Haloarcula marismortui.