rRNA-protein neighbourhood in Escherichia coli 70 S ribosomes and 70 S initiation complex. Probing by bifunctional Pt(II)-containing reagent

The cleavable homobifunctional reagent dichloro[N,N,N',N'-tetrakis(2-aminoethyl)-1,6-hexamethylenediamminedi platinum (II)] dichloride was used for studying rRNA-protein cross-links in free 35S-labelled 70 S ribosomes and within initiation complex ribosome.AUGU6.fMet-tRNA(fMet). It was shown that the sets of proteins cross-linked to 16 S and 23 S rRNA in free 70 S ribosomes and in 70 S initiation complex do not differ significantly. The authors are the first to demonstrate most of the 23 S rRNA-protein cross-links and some 16 S rRNA-protein cross-links, in particular those with L7/L12 protein.     

Preparation of Escherichia coli 70S ribosomes labeled with 35S

[35S]--70S ribosomes (150 Ci/mmol) were isolated from E. coli MRE-600 cells grown on glucose-mineral media in the presence of [35S] ammonium sulfate. The labeled 30S and 50S subunits were obtained from [35S] ribosomes by centrifugation in a sucrose density gradient of 10--30% under dissociating conditions (0.5 mM Mg2+). The activity of [35S]--70S ribosomes obtained by reassociation of the labeled subunits during poly(U)-dependent diphenylalanine synthesis was not less than 70%. The activity of [35S]--70S ribosomes during poly(U)-directed polyphenylalanine synthesis was nearly the same as that of the standard preparation of unlabeled ribosomes. The 23S, 16S and 5S RNAs isolated from labeled ribosomes as total rRNA contained no detectable amounts of their fragments as revealed by polyacrylamide gel electrophoresis. The [35S] ribosomal proteins isolated from labeled ribosomes were analyzed by two-dimensional gel electrophoresis. The [35S] label was found in all proteins, with the exception of L20, L24 and L33 which did not contain methionine or cysteine residues.     

Protein--RNA interaction in the rat liver 5S rRNA-protein L5 complex studied by digestion with ribonucleases.

Protein-RNA interactions in the 5S rRNA-protein L5 complex from rat liver ribosomes were studied by limited digestion of free and protein bound 5S rRNA with ribonuclease A and T1. In the complex with protein L5 the digestion of 5S rRNA by ribonuclease T1 is decreased at G37 and G89, whereas U38 and C39, and to a lower extent also C10 and U12 become accessible for ribonuclease A.     

Laser Raman studies of the 5 S rRNA-protein L5 complex of rat liver ribosomes

The effects of ribosomal protein L5 on the conformation of 5 S rRNA in the 5 S rRNA-protein L5 complex extracted from rat liver ribosomes have been studied by laser Raman spectroscopy. A comparison of the spectra shows small protein-induced conformational changes in the 5 S rRNA, but most of the base-paired regions appear to be present in the complex with protein L5 as well as in the free 5 S rRNA. Furthermore specific interactions between 5 S rRNA and protein L5 are indicated. Cytosine (and/or uracil) residues in single-stranded regions and the N(7) of guanine are engaged in interactions with the protein as suggested by the Raman data.     

Structural analysis of 5S rRNA, 5S rRNA-protein complexes and ribosomes employing RNase H and d(GTTCGG)

The hybridization of d(GTTCGG) to eubacterial 5S rRNAs, 5S rRNA-protein complexes, 70S ribosomes and 50S and 30S ribosomal subunits was investigated. This oligonucleotide, which may be considered to be an analogue of the T psi CG loop of tRNAs, was chosen in order to investigate a possible interaction between tRNAs with ribosomal components during protein synthesis. The hybridization was analysed by RNase H hydrolysis studies and, in the case of the ribosomes and ribosomal subunits, in addition with the radioactively labelled oligodeoxyribonucleotide in binding studies. The results obtained lead to the conclusion that nucleotides in loop c, i.e. positions 42-47, are available for oligonucleotide interaction in free Escherichia coli and Bacillus stearothermophilus 5S rRNAs and not available in the corresponding 5S rRNA-protein complexes. The 70S ribosomes and ribosomal subunits did not interact with the oligonucleotide. Under the assumption that d(GTTCGG) is an analogue of the T psi CG loop of tRNAs and in view of the results obtained, we conclude that in the unprogrammed ribosomes the T psi CG loop of tRNAs does not interact via standard Watson-Crick base pairs with the ribosomal 5S, 16S or 23S RNAs.     

Structural diversity in bacterial ribosomes: mycobacterial 70S ribosome structure reveals novel features

Here we present analysis of a 3D cryo-EM map of the 70S ribosome from Mycobacterium smegmatis, a saprophytic cousin of the etiological agent of tuberculosis in humans, Mycobacterium tuberculosis. In comparison with the 3D structures of other prokaryotic ribosomes, the density map of the M. smegmatis 70S ribosome reveals unique structural features and their relative orientations in the ribosome. Dramatic changes in the periphery due to additional rRNA segments and extra domains of some of the peripheral ribosomal proteins like S3, S5, S16, L17, L25, are evident. One of the most notable features appears in the large subunit near L1 stalk as a long helical structure next to helix 54 of the 23S rRNA. The sharp upper end of this structure is located in the vicinity of the mRNA exit channel. Although the M. smegmatis 70S ribosome possesses conserved core structure of bacterial ribosome, the new structural features, unveiled in this study, demonstrates diversity in the 3D architecture of bacterial ribosomes. We postulate that the prominent helical structure related to the 23S rRNA actively participates in the mechanisms of translation in mycobacteria.     

Study of the mRNA-binding region of ribosomes at different steps of translation. II. Affinity modification of Escherichia coli ribosomes by benzylidene derivative of AUGU6 in the 70S initiation complex

2',3'-O-(4-[N-(2-chloroethyl)-N-methylamino]) benzylidene derivative of AUGU6 was used for identification of the proteins in the region of the mRNA-binding centre of E. coli ribosomes. This derivative alkylated ribosomes (preferentially 30S ribosomal) with high efficiency within the 70S initiation complex. In both 30S and 50S ribosomal subunits proteins and rRNA were modified. Specificity of the alkylation of ribosomal proteins and rRNA with the reagent was proved by the inhibitory action of AUGU6. Using the method of two-dimensional electrophoresis in polyacrylamide gel the proteins S4, S12, S13, S14, S15, S18, S19 and S20/L26 which are labelled by the analog of mRNA were identified.     

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.     

Blocking of the initiation of protein biosynthesis by a pentanucleotide complementary to the 3' end of Escherichia coli 16 S rRNA.

Hydrogen bonding between the 3' terminus of 16 S rRNA (... C-A-C-C-U-C-C-U-U-A-OH3) and complementary sequences within the initiator region of mRNA may be a crucial event in the specific initiation of protein biosynthesis (Shine, J., and Dalgarno, L. (1974) Proc. Natl. Acad. Sci. U. S. A. 71, 1342-1346; Steitz, J. A., and Jakes, K. (1975) Proc. Natl. Acad. Sci. U. S. A. 72, 4734-4738). Using equilibrium dialysis, we have studied the binding of G-A-dG-dG-U (which is complementary to the 3' end of 16 S rRNA and which has been synthesized enzymatically) to initiation factor-free Escherichia coli ribosomes. We have also investigated the effects of the pentanucleotide on initiation reactions in E. coli ribosomes. G-A-dG-dG-U has a specific binding site on the 30 S ribosome with an association constant of 2 x 10(6) M-1 at 0 degrees C. G-A-dG-dG-U inhibits the R17 mRNA-dependent binding of fMet-tRNA by about 70%, both with 70 S ribosomes and 30 S subunits. In contrast, the A-U-G-dependent initiation reaction and the poly(U)-dependent Phe-tRNA binding was not affected by the pentanucleotide with both ribosomal species.     

Ribosomal activity of the 16 S.23 S RNA complex

It has been demonstrated in this laboratory that 16 S and 23 S RNAs form a binary complex like 30 S and 50 S ribosomes under certain specific conditions, and 5 S RNA can be incorporated into the complex in stoichiometric amounts in presence of three ribosomal proteins, L5, L18, and L15/25. These studies raised the basic question of whether such complex will have biological activity. Therefore, the following steps in protein synthesis were examined with the complex in place of the ribosomes: (i) poly-U-dependent binding of phenylalanyl tRNA; (ii) EF-G-dependent GTPase activity; (iii) initiation complex formation; (iv) peptidyl transferase activity; and (v) poly-U-dependent polyphenylalanine synthesis. All the steps could be unequivocally demonstrated by the addition of a limited number of proteins although the complex had comparatively much less activity than 70 S ribosomes. It appears that rRNAs are directly involved in various steps of protein synthesis. Furthermore, the 16 S.23 S RNA complex might have acted as a primitive ribosome, as suggested by Crick and Orgel.     

rRNA topography in ribosome. IV. The accessibility of the 5'-end region of 16S rRNA

The accessibility of the 5'-end region of 16S rRNA (A₈GAGUUUG₁₅) inEscherichia coli ribosomes for complementary binding with the synthetic octanucleotide d(CAAACTCT) has been studied. Nonequilibrium gel-filtration was used to evaluate parameters of the binding of this oligonucleotide with free 16S rRNA, ribosomal subunits, and 70S ribosomes. A simple approach is presented to calculate the apparent association constants and the number of binding sites based upon the data obtained under those conditions. Free 16S rRNA, 30S subunits, and 70S ribosomes were found to form rather stable complexes with the octanucleotide, the association constants being similar in all three cases. These data strongly suggest the surface location of the 16S rRNA 5'-end inE. coli ribosomes.     

Affinity modification of Escherichia coli ribosomes with 2',3'-O-[4-(N-2-chloroethyl)-N-methylamino]-benzylidene derivative of AUGU3 in the 70S initiation complexes

Affinity labelling of the Escherichia coli ribosomes with the 2',3'-O-[4-(N-(2-chloroethyl)-N-methylamino]benzylidene derivative of AUGU3(AUGU3[14C]CHRCl) has been studied within 70S initiation complexes ribosome.AUGU3[14C]CHRCl.fMet-tRNA(Metf) and binary complex ribosome.AUGU3[14C]CHRCl. Various ways of the 70S initiation complex formation resulted in differently labelled products. Proteins S5, S7, S9, L1, L16 were thus identified as cross-linked with AUGU3[14C]CHRCl within an initiation complex obtained in the presence of initiation factors IF-1, IF-2, IF-3, whereas only proteins S5 and S7 were cross-linked within the complex obtained with the sole factor IF-2. Proteins S1, S3, L1 and L33 were labelled within the initiation complex obtained nonenzymatically but only protein S1 within the binary complex. In all complexes formed with use of initiation factors labelling of IF-2 factor was invariably observed.     

Effects of two photoreactive spermine analogues on peptide bond formation and their application for labeling proteins in Escherichia coli functional ribosomal complexes.

The effect of two photoreactive analogues of spermine, N(1)-azidobenzamidino- (ABA-) spermine and N(1)-azidonitrobenzoyl- (ANB-) spermine, on ribosomal functions was studied in a cell-free system derived from Escherichia coli. In the dark, both analogues stimulated the binding of AcPhe-tRNA to poly(U)-programmed ribosomes, enhanced the stability of the ternary complex AcPhe-tRNA.poly(U).ribosome (complex C), and caused stimulatory and inhibitory effects on peptidyltransferase activity. ABA-spermine exhibited more pronounced effects than ANB-spermine. Each photoprobe was covalently attached after irradiation to both ribosomal subunits and also to free rRNA isolated from 70S ribosomes. Photolabeled complex C showed a reactivity toward puromycin, similar to that exhibited by complex C reacting reversibly with photoprobes free in solution. The distribution of the incorporated radioactivity among the ribosomal components was determined under two experimental conditions, one stimulating and the other inhibiting peptidyltransferase activity. Under both conditions, ABA-spermine was the strongest cross-linker. Upon stimulatory conditions, 14% of ABA-[(14)C]spermine cross-linked to complex C was bound to the protein fraction. The proteins primarily labeled were identified as S3, S4, L2, L3, L6, L15, L17, and L18. Upon inhibitory conditions, a higher percent of the incorporated radioactivity was found in ribosomal proteins, while the pattern of protein labeling was characterized by a remarkable decrease of cross-linked proteins L2, L3, L6, L15, L17. and L18 and by an increase of cross-linked proteins S9, S18, L1, L16, L22, L23, and L27. On the basis of these results and literature data, the involvement of spermine in the conformation and important functions of ribosomes is discussed.     

Directed hydroxyl radical probing of 16S ribosomal RNA in ribosomes containing Fe(II) tethered to ribosomal protein S20.

The 16S ribosomal RNA neighborhood of ribosomal protein S20 has been mapped, in both 30S subunits and 70S ribosomes, using directed hydroxyl radical probing. Cysteine residues were introduced at amino acid positions 14, 23, 49, and 57 of S20, and used for tethering 1-(p-bromoacetamidobenzyl)-Fe(II)-EDTA. In vitro reconstitution using Fe(II)-derivatized S20, together with the remaining small subunit ribosomal proteins and 16S ribosomal RNA (rRNA), yielded functional 30S subunits. Both 30S subunits and 70S ribosomes containing Fe(II)-S20 were purified and hydroxyl radicals were generated from the tethered Fe(II). Hydroxyl radical cleavage of the 16S rRNA backbone was monitored by primer extension. Different cleavage patterns in 16S rRNA were observed from Fe(II) tethered to each of the four positions, and these patterns were not significantly different in 30S and 70S ribosomes. Cleavage sites were mapped to positions 160-200, 320, and 340-350 in the 5' domain, and to positions 1427-1430 and 1439-1458 in the distal end of the penultimate stem of 16S rRNA, placing these regions near each other in three dimensions. These results are consistent with previous footprinting data that localized S20 near these 16S rRNA elements, providing evidence that S20, like S17, is located near the bottom of the 30S subunit.     

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.     

Nuclease S1 mapping of 16S ribosomal RNA in ribosomes

Escherichia coli 16S rRNA and 16S-like rRNAs from other species have several universally conserved sequences which are believed to be single-stranded in ribosomes. The quantitative disposition of these sequences within ribosomes is not known. Here we describe experiments designed to explore the availability of universal 16S rRNA sequences for hybridization with DNA probes in 30S particles and 70S ribosomes. Unlike previous investigations, quantitative data on the accessibility of DNA probes to the conserved portions of 16S rRNA within ribosomes was acquired. Uniquely, the experimental design also permitted investigation of cooperative interactions involving portions of conserved 16S rRNA. The basic strategy employed ribosomes, 30S subunits, and 16S rRNAs, which were quantitatively analyzed for hybridization efficiency with synthetic DNA in combination with nuclease S1. In deproteinated E. coli 16S rRNA and 30S subunits, the regions 520-530, 1396-1404, 1493-1504, and 1533-1542 are all single-stranded and unrestricted for hybridization to short synthetic DNAs. However, the quantitative disposition of the sequences in 70S ribosomes varies with each position. In 30S subunits there appear to be no cooperative interactions between the 16S rRNA universal sequences investigated.     

Conformational studies of Escherichia coli ribosomes with the use of acridine orange as a probe

The interaction of E. coli vacant ribosomes with acridine orange (AO) was studied, to obtain conformational information about rRNAs in ribosomes. Acridine orange binds to an RNA in two different modes: cooperative outside binding with stacking of bound AO's and intercalation between nucleotide bases. Free 16S and 23S rRNAs have almost identical affinities to AO. At 1 mM Mg2+, AO can achieve stacking binding on about 40% of rRNA phosphate groups. The number of stacking binding sites falls to about 1/3 in the 30S subunit in comparison with free 16S rRNA. In the 50S subunit, the number of stacking binding sites is only 1/5 in comparison with free 23S rRNA. Mg2+ ions are more inhibitory for the binding of AO to ribosomes than to free rRNAs. The strength of stacking binding appears to be more markedly reduced by Mg2+ in active ribosomes than in rRNAs. "Tight couple" 70S particles are less accessible for stacking binding than free subunits. The 30S subunits that have irreversibly lost the capability for 70S formation under low Mg2+ conditions have an affinity to AO that is very different from that of active 30S but similar to that of free rRNA, though the number of stacking binding sites is little changed by the inactivation. 70S and 30S ribosomes with stacking bound AO's have normal sedimentation constants, but the 50S subunits reversibly form aggregates.     

The central pseudoknot in 16S ribosomal RNA is needed for ribosome stability but is not essential for 30S initiation complex formation.

To examine the function of the central pseudoknot in 16S rRNA, we have studied Escherichia coli 30S subunits with the A18 mutation in this structure element. Previously, this mutation, which changes the central base pair of helix 2, C18--G917, to an A18xG917 mismatch, was shown to inhibit translation in vivo and a defect in initiation was suggested. Here, we find that the mutant 30S particles are impaired in forming 70S tight couples and predominantly accumulate as free 30S subunits. Formation of a 30S initiation complex, as measured by toeprinting, was almost as efficient for mutant 30S subunits, derived from the tight couple fraction, as for the wild-type control. However, the A18 mutation has a profound effect on the overall stability of the subunit. The mutant ribosomes were inactivated by affinity chromatography and high salt treatment, due to easy loss of ribosomal proteins. Accordingly, the particles could be reactivated by partial in vitro reconstitution with 30S ribosomal proteins. Mutant 30S subunits from the free subunit fraction were already inactive upon isolation, but could also be reactivated by reconstitution. Apparently, the inactivity in initiation of these mutant 30S subunits is, at least in part, also due to the lack of essential ribosomal proteins. We conclude that disruption of helix 2 of the central pseudoknot by itself does not affect the formation of a 30S initiation complex. We suggest that the in vivo translational defect of the mutant ribosomes is caused by their inability to form 70S initiation complexes.     

Secondary structure features of ribosomal RNA species within intact ribosomal subunits and efficiency of RNA-protein interactions in thermoacidophilic (Caldariella acidophila, Bacillus acidocaldarius) and mesophilic (Escherichia coli) bacteria

Ribosomal subunits of Caldariella acidophila (max.growth temp., 90 degrees C) have been compared to subunits of Bacillus acidocaldarius (max. growth temp., 70 degrees C) and Escherichia coli (max. growth temp., 47 degrees C) with respect to (a) bihelical content of rRNA; (b) G . C content of bihelical domains and (c) tightness of rRNA-protein interactions. The principal results are as follows. Subunits of C. acidophilia ribosomes (Tm = 90-93 degrees C) exhibit considerable thermal tolerance over their B. acidocaldarius (Tm = 77 degrees C) and E. coli counterparts (Tm = 72 degrees C). Based on the "melting' hyperchromicities of the intact ribosomal subunits a 51-55% fraction of the nucleotides appears to participate in hydrogen-bonded base pairing regardless of ribosome source, whereas a larger fraction, 67-70%, appears to be involved in hydrogen bonding in the naked rRNA species. The G . C content of bihelical domains of both free and ribosome-bound rRNA increases with increasing thermophily; based on hyperchromicity dispersion spectra of intact subunits and free rRNA, the bihelical parts of C. acidophila rRNA are estimated to contain 63-64% G . C, compared to 58.5% G . C for B. acidocaldarius and 55% G . C for E. coli. The increment of ribosome Tm values with increasing thermophily is greater than the increase in Tm for the free rRNA, indicating that within ribosomes bihelical domains of the thermophile rRNA species are stabilized more efficiently than their mesophile counterparts by proteins or/ and other component(s). The efficiency of the rRNA-protein interactions in the mesophile and thermophile ribosomes has been probed by comparing the releases, with LiCl-urea, of the rRNA species from the corresponding ribosomal subunits stuck to a Celite column through their protein moiety; it has been established that the release of C. acidophila rRNA from the Celite-bound ribosomes occurs at salt-urea concentrations about 4-fold higher than those required to release rRNA from Celite-bound E. coli ribosomes. Compared to E. coli the C. acidophila 50 and 30 S ribosomal subunits are considerably less susceptible to treatment designed to promote ribosome unfolding through depletion of magnesium ions.