RNA-protein cross-linking in Escherichia coli 50S ribosomal subunits; determination of sites on 23S RNA that are cross-linked to proteins L2, L4, L24 and L27 by treatment with 2-iminothiolane.

RNA-protein cross-links were introduced into E. coli 50S ribosomal subunits by treatment with 2-iminothiolane followed by mild ultraviolet irradiation. After partial digestion of the RNA, the cross-linked RNA-protein complexes were separated by our recently published three-step procedure. In cases where this separation was inadequate, a further purification step was introduced, involving affinity chromatography with antibodies to the ribosomal 50S proteins. Analysis of the isolated complexes enabled four new cross-link sites on the 23S RNA to be identified, as well as re-confirming several previously established sites. The new sites are as follows: Protein L2 is cross-linked within an oligonucleotide at positions 1818-1823 in the 23S RNA, protein L4 within positions 320-325, protein L24 within positions 99-107, and protein L27 within positions 2320-2323.     

Identification of sites of 4'-(hydroxymethyl)-4,5',8-trimethylpsoralen cross-linking in Escherichia coli 23S ribosomal ribonucleic acid

The reagent 4'-(hydroxymethyl)-4,5',8-trimethylpsoralen (HMT) was used to cross-link 23S rRNA from Escherichia coli under 50S ribosomal subunit reconstitution conditions. Following partial digestion of the RNA with ribonuclease T1, two-dimensional diagonal electrophoresis in denaturing polyacrylamide gels was used to isolate fragments derived from the cross-linked sites. These fragments were analyzed by digestion with ribonucleases T1 and A and their positions in the 23S RNA sequence identified. Fragment a1 (positions 1325-1426) is cross-linked to a2 (positions 1574-1623); fragment b1 (positions 1700-1731) is cross-linked to b2 (positions 1732-1753); and a cross-link is formed within fragment c (or c') (positions 863-916). In the latter case, the cross-link was located precisely, linking residues C867 and U913. All three HMT-mediated cross-links are consistent with a proposed secondary structure model for 23S RNA [Noller, H. F., Kop, J., Wheaton, V., Brosius, J., Gutell, R. R., Kopylov, A. M., Dohme, F., Herr, W., Stahl, D. A., Gupta, R., & Woese, C. R. (1981) Nucleic Acids Res. 9, 6167-6189].     

Binding of Escherichia coli ribosomal proteins to 23S RNA under reconstitution conditions for the 50S subunit.

The RNA binding capacity of 50S proteins from E. coli ribosomes has been tested under improved conditions; purified proteins active in reconstitution assays were used, and the binding was studied under the conditions of the total reconstitution procedure for the 50S subunit. The results are: 1) Interaction of 23S RNA was found with 17 proteins, namely L1, L2, L3, L4, L7/L12, L9, L10, L11, L15, L16, L17, L18, L20, L22, L23, L24 and L29. 2) The proteins L1, L2, L3, L4, L9, L23 and L24 bound to 23S RNA at a level of about one copy per RNA molecule, whereas L20 could bind more than one copy (no saturation was observed at 1.8 copies per 23S RNA), and the other proteins bound 0.2--0.6 copies per RNA. 3) L1, L3, L7/L12 showed a slight binding to 16S RNA, L26 (identical with S20) strong binding to 16S RNA. 4) The binding of L2, L7/L12, L10, L11, L15, L16 and L18 was preparation sensitive, i.e. the binding ability changed notably from preparation to preparation. 5) All proteins bound equally well to 23S RNA in presence of 4 and 20 mM Mg2+, respectively, except L2, L3, L4, L7/L12, L9, L10, L15, L16 and L18, which bound less strongly at 20 mM than at 4 mM Mg2+.     

RNA-protein cross-linking in Escherichia coli 30S ribosomal subunits; determination of sites on 16S RNA that are cross-linked to proteins S3, S4, S7, S9, S10, S11, S17, S18 and S21 by treatment with bis-(2-chloroethyl)-methylamine.

RNA-protein cross-links were introduced into E. coli 30S ribosomal subunits by treatment with bis-(2-chloroethyl)-methylamine. After partial nuclease digestion of the RNA moiety, a number of cross-linked RNA-protein complexes were isolated by a new three-step procedure. Protein and RNA analysis of the individual complexes gave the following results: proteins S4 and S9 are cross-linked to the 16S RNA at positions 413 and 954, respectively. Proteins S11 and S21 are both cross-linked to the RNA within an oligonucleotide encompassing positions 693-697, and proteins S17, S10, S3 and S7 are cross-linked within oligonucleotides encompassing positions 278-280, 1139-1144, 1155-1158, and 1531-1542, respectively. A cross-link to protein S18 was found by a process of elimination to lie between positions 845 and 851.     

The ribosomal neighbourhood of the central fold of tRNA: cross-links from position 47 of tRNA located at the A, P or E site.

The naturally occurring nucleotide 3-(3-amino-3-carboxy-propyl)uridine (acp3U) at position 47 of tRNA(Phe) from Escherichia coli was modified with a diazirine derivative and bound to ribosomes in the presence of suitable mRNA analogues under conditions specific for the ribosomal A, P or E sites. After photo-activation at 350 nm the cross-links to ribosomal proteins and RNA were identified by our standard procedures. In the 30S subunit protein S19 (and weakly S9 and S13) was the target of cross-linking from tRNA at the A site, S7, S9 and S13 from the P site and S7 from the E site. Similarly, in the 50S subunit L16 and L27 were cross-linked from the A site, L1, L5, L16, L27 and L33 from the P site and L1 and L33 from the E site. Corresponding cross-links to rRNA were localized by RNase H digestion to the following areas: in 16S rRNA between positions 687 and 727 from the P and E sites, positions 1318 and 1350 (P site) and 1350 and 1387 (E site); in the 23S rRNA between positions 865 and 910 from the A site, 1845 and 1892 (P site), 1892 and 1945 (A site), 2282 and 2358 (P site), 2242 and 2461 (P and E sites), 2461 and 2488 (A site), 2488 and 2539 (all three sites) and 2572 and 2603 (A and P sites). In most (but not all) cases, more precise localizations of the cross-link sites could be made by primer extension analysis.     

Investigation of the tertiary folding of Escherichia coli 16S RNA by in situ intra-RNA cross-linking within 30S ribosomal subunits.

Intra-RNA cross-links were introduced into E. coli 30S ribosomal subunits by mild ultraviolet irradiation. The subunits were partially digested with cobra venom nuclease, followed in some cases by a second partial digestion with ribonuclease H in the presence of the hexanucleotide d-(CTTCCC). The cross-linked RNA complexes were separated by two-dimensional gel electrophoresis and the sites of cross-linking analysed by our published procedures. Tertiary structural cross-links in the 16S RNA were identified between positions 31 and 48, between oligonucleotides 1090-1094 and 1161-1164, and between oligonucleotides 1125-1127 and 1280-1281. The first of these imposes a rigid constraint on the relative orientations of helices 3 and 4 of the 16S secondary structure. A further tertiary cross-link (which could not be precisely localised) was found between regions 1-72 and 1020-1095, and secondary structural cross-links were identified between positions 497 and 545-548, and positions 1238-1240 and 1298.     

The use of 2-iminothiolane as an RNA-protein cross-linking agent in Escherichia coli ribosomes, and the localisation on 23S RNA of sites cross-linked to proteins L4, L6, L21, L23, L27 and L29.

When E. coli ribosomal subunits are reacted with 2-iminothiolane and then subjected to a mild ultraviolet irradiation, an RNA-protein cross-linking reaction occurs. About 5% of the total protein in each subunit becomes cross-linked to the RNA, and a specific sub-set of proteins is involved in the reaction. In the case of the 50S subunit, the sites of cross-linking to the 23S RNA have been determined for six of these proteins: protein L4 is cross-linked within an oligonucleotide comprising positions 613-617 in the 23S sequence, L6 within positions 2473-2481, L21 within positions 540-548, L23 within positions 137-141, L27 within positions 2332-2337 and L29 within positions 99-107.     

Construction and functional analysis of ribosomal 5S RNA from Escherichia coli with single base changes in the ribosomal protein binding sites

The ribosomal 5S RNA gene from E. coli was altered by oligonucleotide-directed mutagenesis at positions A66 and U103. The mutant genes were cloned into an expression vector and selectively transcribed in an UV-sensitive E. coli strain using a modified maxicell system. The mutant 5S RNA genes were found to be transcribed and processed normally. The 5S RNA molecules were assembled into 50S ribosomal subunits. Under in vitro conditions the stability of the mutant 70S ribosomes seemed, however, to be reduced, since they dissociated into their subunits more easily than those of the wild type. The isolated mutated 5S RNAs with base changes in the ribosomal protein binding sites for L18 and L25, together with a point mutant at G41 (G to C), constructed earlier, were tested for their capacity to bind the 5S RNA binding proteins L5, L18 and L25. The following effects were observed: The base change A66 to C within the L18 binding site did not affect the binding of the ribosomal protein L18 but enhanced the stability of the L25-5S RNA complex considerably. The base changes U103 to G and G41 to C slightly reduced the binding of L5 and L25 whereas the binding of L18 to the mutant 5S RNAs was not altered. In addition 70S ribosomes with the single point mutations in their 5S RNAs were tested in their tRNA binding capacity. Mutants containing a C41 in their 5S RNA showed a reduction in the poly(U)-dependent Phe-tRNA binding, whereas the mutations to C66 and G 103 lead to completely inactive ribosomes in the same assay. Based on previous results a spatial model of the 5S RNA molecule is presented which is consistent with the findings reported in this paper.     

RNA-protein interactions in the ribosome: VIII. Co-operative interactions in the 50 S subunit of Escherichia coli

Six 50 S ribosomal subunit proteins, each unable to interact independently with the 23 S RNA, were shown to associate specifically with ribonucleoprotein complexes consisting of intact 23 S RNA, or fragments derived from it, and one or more RNA-binding proteins. In particular, L21 and L22 depend for attachment upon L20 and L24, respectively; L5, L10 and L11 interact individually with complexes containing L2 and L16; and one or both proteins of the $\text{L}\text{17}\text{L}\text{27}$ mixture are stimulated to bind in the presence of L1, L3, L6, L13 and L23. Moreover, L14 alone was found to interact with a fragment from the 3′ end of the 23 S RNA, even though it cannot bind to 23 S RNA. By correlating the data reported here with the findings of others, it has been possible to formulate a partial in vitro assembly map of the Escherichia coli 50 S subunit encompassing both the 5 S and 23 S RNAs as well as 21 of the 34 subunit proteins.     

Protection of specific sites in 23 S and 5 S RNA from chemical modification by association of 30 S and 50 S ribosomes.

The effect of 30S subunit attachment on the accessibility of specific sites in 5 S and 23 S RNA in 50 S ribosomal subunits was studied by means of the guanine-specific reagent kethoxal. Oligonucleotides surrounding the sites of kethoxal substitution were resolved and quantitated by diagonal electrophoresis. In contrast to the extensive protection of sites in 16 S RNA in 70 S ribosomes (Chapman &; Noller, 1977), only two strongly (approx. 90%) protected sites were detected in 23 S RNA. The nucleotide sequences at these sites are

in which the indicated kethoxal-reactive guanines (with K above them) are strongly protected by association of 30 S and 50 S subunits. The latter sequence has the potential to base-pair with nucleotides 816 to 821 of the 16 S RNA, a site which has been shown to be protected from kethoxal by 50 S subunits and essential for subunit association. Six additional sites in 23 S RNA are partially (30 to 50%) protected by 30 S subunits. One of these sequences,

is complementary to nucleotides 787 to 792 of 16 S RNA. a site which is also 50 S-protected and essential for association. Of the two kethoxal-reactive 5 S RNA sites in 50 S subunits, G₁₃ is partially protected in 70 S ribosomes. while G₄₁ remains unaffected by subunit association.The relatively small number of kethoxal-reactive sites in 23 S RNA that is strongly protected in 70 S ribosomes suggests that subunit association may involve contacts between single-stranded sites in 16 S RNA and 50 S subunit proteins or non-Watson-Crick interactions with 23 S RNA. in addition to the two suggested base-paired contacts.     

Studies on the primary structure of the ribosomal 23S RNA of Escherichia coli: II. A characterisation and an alignment of 24 sections spanning the entire molecule and its application to the localisation of specific fragments.

We have employed new methodology to obtain 23S RNA fragments which includes a) the digestion of the RNA within 50S subunits and b) the limited hydrolysis of the 13S and 18S fragments. By comparing all 23S RNA fragments, obtained heretofore, we have characterised and aligned 24 sections of this RNA spanning nearly the entire molecule. These results allow the localisation of any new 23S RNA fragment by comparison of the fingerprint of its T1 ribonuclease digest to the characteristic ones of the different sections. In this way we obtained a more definite localisation of the binding sites of the 50S proteins L1, L5, L9, L18, L20, L23 and L25. We also specified a ribonuclease sensitive region of 23S RNA in native 50S subunits, extending from the 1100th nucleotide from the 5' end to the 1000th nucleotide from the 3' end; this region contains a cluster of 5 modified nucleotides and may be at the subunit interface.     

Comparative cross-linking study on the 50S ribosomal subunit from Escherichia coli

We have carried out an extensive protein-protein cross-linking study on the 50S ribosomal subunit of Escherichia coli using four different cross-linking reagents of varying length and specificity. For the unambiguous identification of the members of the cross-linked protein complexes, immunoblotting techniques using antisera specific for each individual ribosomal protein have been used, and for each cross-link, the cross-linking yield has been determined. With the smallest cross-linking reagent diepoxybutane (4 A), four cross-links have been identified, namely, L3-L19, L10-L11, L13-L21, and L14-L19. With the sulfhydryl-specific cross-linking reagent o-phenylenedimaleimide (5.2 A) and p-phenylenedimaleimide (12 A), the cross-links L2-L9, L3-L13, L3-L19, L9-L28, L13-L20, L14-L19, L16-L27, L17-L32, and L20-L21 were formed; in addition, the cross-link L23-L29 was exclusively found with the shorter o-phenylenedimaleimide. The cross-links obtained with dithiobis(succinimidyl propionate) (12 A) were L1-L33, L2-L9, L2-L9-L28, L3-L19, L9-L28, L13-L21, L14-L19, L16-L27, L17-L32, L19-L25, L20-L21, and L23-L34. The good agreement of the cross-links obtained with the different cross-linking reagents used in this study demonstrates the reliability of our cross-linking approach. Incorporation of our cross-linking results into the three-dimensional model of the 50S ribosomal subunit derived from immunoelectron microscopy yields the locations for 29 of the 33 proteins within the larger ribosomal subunit.     

Nucleotide sequences of accessible regions of 23S RNA in 50S ribosomal subunits.

Nucleotide sequences around kethoxal-reactive guanine residues of 23S RNA in 50S ribosomal subunits have been determined. By use of the diagonal paper electrophoresis method )Noller, H.F. (1974), Biochemistry 13, 4694-4703), 41 ribonuclease T1 oligonucleotides, originating from about 25 sites, were identified and sequenced. These sites are single stranded and accessible in free 50S subunits, and are thus potential sites for interaction with functional ligands during protein synthesis. Examination of these sequences for potential intermolecular base-pairing reveals the following: (1) There are 19 possible complementary combinations between exposed sequences in 16S and 23S RNA containing more than 4 base pairs: 15 containing 5 base pairs and 4 containing 6 base pairs. Nine of these complementary combinations contain 16S RNA sequences which we have previously shown to be protected from kethoxall by 50S subunits (Chapman, N.M., and Noller, H.F. (1977), J. Mol. Biol. 109, 131-149). (2) One of the exposed sites in 23S RNA has a sequence which is complementary to the invariant GT psi CR sequence in tRNA.     

RNA-protein cross-linking in Escherichia coli 30S ribosomal subunits; determination of sites on 16S RNA that are cross-linked to proteins S3, S4, S5, S7, S8, S9, S11, S13, S19 and S21 by treatment with methyl p-azidophenyl acetimidate.

RNA-protein cross-links were introduced into E. coli 30S ribosomal subunits by treatment with methyl p-azidophenyl acetimidate. After partial nuclease digestion of the RNA moiety, a number of cross-linked RNA-protein complexes were isolated by a new three-step procedure. Protein and RNA analysis of the individual complexes gave the following results: Proteins S3, S4, S5 and S8 are cross-linked to the 5'-terminal tetranucleotide of 16S RNA. S5 is also cross-linked to the 16S RNA within an oligonucleotide encompassing positions 559-561. Proteins S11, S9, S19 and S7 are cross-linked to 16S RNA within oligonucleotides encompassing positions 702-705, 1130-1131, 1223-1231 and 1238-1240, respectively. Protein S13 is cross-linked to an oligonucleotide encompassing positions 1337-1338, and is also involved in an anomalous cross-link within positions 189-191. Protein S21 is cross-linked to the 3'-terminal dodecanucleotide of the 16S RNA.     

Structures of complexes of 5S RNA with ribosomal proteins L5, L18 and L25 from Escherichia coli: identification of kethoxal-reactive sites on the 5S RNA.

The topography of Escherichia coli 5S RNA has been examined in the presence of ribosomal proteins L5, L18 and L25 and their different combinations, by comparing the kethoxal modification characteristics of the various RNA-protein complexes with those of the free A-conformer of 5S RNA (Noller &; Garrett, 1979, accompanying paper).Two of the four most reactive guanines, G₁₃ and G₄₁, are unaffected by the protein, in accord with the finding that these are the only two guanines that are accessible in the 50S subunit (Noller &; Herr, 1974). The other two very reactive guanines, G₂₄ and G₆₉, are strongly protected by protein L18, either in the presence or absence of proteins L5 and L25. Protein binding studies with kethoxal-modified 5S RNA provide evidence that one or both of these two guanines are directly involved in the protein-RNA interactions, and this conclusion is supported by the occurrence of guanines in these two positions in all the other sequenced prokaryotic 5S RNAs.The group of less reactive guanines, G₁₆, G₂₃, G₄₄, G₈₆ and G₁₀₇, are protected to some extent by each of the proteins L5, L18 and L25; the strongest effect is with L18. We suggest that this is attributable to a small increase in the conformational homogeneity of the 5S RNA and that L18, in particular, induces some tightening of the RNA structure.Only one guanine, G₆₉, is rendered more accessible by the proteins. This effect is produced by protein L25, which is known to cause some destructuring of the 5S RNA (Bear et al., 1977). There was no other evidence for any destructuring of the 5S RNA. In particular, the sequence 72 to 83, which is complementary to a sequence in 23S RNA (Herr &; Noller, 1975), is not modified. However, in contrast to an earlier report (Erdmann et al., 1973), the conserved sequence G₄₄-A-A-C, which has been implicated in tRNA binding, was not rendered more accessible by the proteins.     

Letter: Binding of 50 S ribosomal subunit proteins to 23 S RNA of Escherichia coli

Each of the 50 S ribosomal subunit proteins of Escherichia coli was tested independently in two laboratories for its ability to bind specifically to 23 S RNA. Four new RNA-binding proteins, L1, L3, L4 and L13 were identified in this way. Consistent with earlier work, proteins L2, L6, L16, L20, L23 and L24 were found to interact directly and independently with 23 S RNA as well. No binding of L17 was detected, however, contrary to previous reports, and the results for L19 were variable. The molar ratio of protein and RNA in each complex was measured at saturation. Significant differences in binding stoichiometry were noted among the various proteins. In addition, saturation levels were found to be influenced by the state of both the RNA and the proteins.     

Selective isolation and detailed analysis of intra-RNA cross-links induced in the large ribosomal subunit of E. coli: a model for the tertiary structure of the tRNA binding domain in 23S RNA.

Intramolecular RNA cross-links were induced within the large ribosomal subunit of E. coli by mild ultraviolet irradiation. Regions of the 23S RNA previously implicated in interactions with ribosomal-bound tRNA were then specifically excised by addressed cleavage using ribonuclease H, in conjunction with synthetic complementary decadeoxyribonucleotides. Individual cross-linked fragments within these regions released by such 'directed digests' were isolated by two-dimensional gel electrophoresis and the sites involved in the cross-links determined using classical oligonucleotide analysis techniques. Using this approach, seven 'new' cross-links could be precisely localised, between positions 1782 and 2608-2609, 1940 and 2554, 1941-1942 and 1964-1965, 1955 and 2552-2553, 2145-2146 and 2202, 2518-2519 and 2544-2545, and between positions 2790-2791 and 2892-2895 in the 23S RNA sequence. These data, in conjunction with data from RNA-protein cross-linking studies carried out in our laboratory, were used to define a model for the tertiary organisation of the tRNA binding domain of 23S RNA 'in situ', in which the specific nucleotides associated with tRNA binding in the 'A' and 'P' sites are clustered at the base of the 'central protuberance' of the 50S subunit.     

Protein-protein cross-linking of the 50 S ribosomal subunit of Escherichia coli using 2-iminothiolane. Identification of cross-links by immunoblotting techniques

We have investigated the protein-protein cross-links formed within the 50 S subunit of the Escherichia coli ribosome using 2-iminothiolane as the cross-linking reagent. The members of the cross-links have been identified by immunoblotting from one-dimensional and two-dimensional diagonal sodium dodecyl sulfate-polyacrylamide gels using antisera specific for the individual ribosomal proteins. This method also allowed a quantitation of the yield of cross-linking for each cross-link. A total of 14 cross-links have been identified: L1-L33, L2-L9, L2-L9-L28, L3-L19, L9-L28, L13-L21, L14-L19, L16-L27, L17-L30, L17-L32, L19-L25, L20-L21, L22-L32, and L23-L34. Our results are compared with those of Traut and coworkers (Traut, R. R., Tewari, D. S., Sommer, A., Gavino, G. R., Olson, H. M., and Glitz, D. G. (1986) in Structure, Function and Genetics of Ribosomes (Hardesty, B. and Kramer, G., eds) pp. 286-308, Springer-Verlag, New York). Our cross-linking data allow us to propose the approximate locations of eight proteins of the 50 S ribosomal subunit that so far have not been localized by immunoelectron microscopy and they thus contribute considerably to our knowledge of ribosome structure.     

Localisation of a series of intra-RNA cross-links in the secondary and tertiary structure of 23S RNA, induced by ultraviolet irradiation of Escherichia coli 50S ribosomal subunits.

Intra-RNA cross-links were introduced into E. coli 50S ribosomal subunits by mild ultraviolet irradiation. The subunits were partially digested with cobra venom nuclease, and the cross-linked RNA complexes were isolated by two-dimensional electrophoresis. Many of the complexes were submitted to a second partial digestion procedure. Oligonucleotide analysis of the RNA fragments obtained in this manner enabled cross-links between the following ribonuclease T1 oligonucleotides in the 23S RNA to be established: positions 292-296 and 339-350; 601-604 and 652-656; 1018-1022 and 1140-1149; 1433-1435 and 1556-1560; 1836-1839 and 1898-1903; 2832-2834 (tentative) and 2878-2885; 2849-2852 and 2865-2867 (tentative); 739-748 and 2609-2618; 571-577 and 2030-2032; 1777-1792 (tentative) and 2584-2588. The first seven of these cross-links lie within the secondary structure of the 23S RNA, whereas the last three are tertiary structural cross-links. The degree of precision of the individual determinations was variable, depending on the nucleotide sequence in the vicinity of the cross-link site concerned.