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.     

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.     

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.     

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.     

Multiple crosslinks of proteins S7 and S9 to domains 3 and 4 of 16S ribosomal RNA in the Escherichia coli 30S particle

RNA-protein cross-links were introduced into Escherichia coli 30S subunits by treatment with 1-ethyl-3(3-dimethylaminopropyl)carbodiimide. 16S rRNA, cross-linked to 30S ribosomal proteins, was isolated and hybridized with seven single-stranded bacteriophage M13-DNA probes. These probes, each carrying an inserted rDNA fragment, were used to select contiguous RNA sections covering domains 3 and 4 (starting at nucleotide 868 and ending at the 3'OH terminus) of the 16S rRNA. The proteins covalently linked to each selected RNA section were identified by two-dimensional polyacrylamide gel electrophoresis. Proteins S7 and S9 were shown to be efficiently cross-linked to multiple sites belonging to both domains.     

Effects of the ribosomal subunit association on the chemical modification of the 16S and 23S RNAs from Escherichia coli

70S ribosomes and 30S and 50S ribosomal subunits from Escherichia coli were modified under non-denaturing conditions with the chemical reagent dimethylsulfate. The ribosomal 23S and 16S RNAs were isolated after the reaction and the last 200 nucleotides from the 3' ends were analyzed for differences in the chemical modification. A number of accessibility changes could be detected for 23S and 16S RNA when 70S ribosomes as opposed to the isolated subunits were modified. In addition to a number of sites which were protected from modification several guanosines showed enhanced reactivities, indicating conformational changes in the ribosomal RNA structures when 30S and 50S subunits associate to a 70S particle. Most of the accessibility changes can be localized in double-helical regions within the secondary structures of the two RNAs. The results confirm the importance of the ribosomal RNAs for ribosomal functions and help to define the RNA domains which constitute the subunit interface of E. coli ribosomes.     

Intra-RNA cross-linking in Escherichia coli 30S ribosomal subunits: selective isolation of cross-linked products by hybridization to specific cDNA fragments.

M13 clones were constructed with cDNA inserts corresponding to specific regions of E. coli ribosomal RNA. The DNA from the clones was immobilized by coupling to diazobenzyloxymethyl cellulose, and was used for the selective isolation by hybridization of cross-linked RNA complexes containing the complementary sequences. Immobilized DNA samples with inserts complementary to four different regions covering bases 735-1384 of the 16S RNA were hybridized with a mixture of 16S RNA fragments generated by partial digestion of 30S subunits that had been cross-linked by ultraviolet irradiation in vivo. After dehybridization, the individual RNA fragments and cross-linked complexes were separated by gel electrophoresis and analysed by our usual procedures. Nine cross-links are described; four of these are hitherto unobserved "secondary structural" cross-links, and one is a new "tertiary structural" cross-link between positions 243-247 and 891-894 of the 16S RNA.     

The topography of the 3''-terminal region of Escherichia coli 16S ribosomal RNA; an intra-RNA cross-linking study.

30S ribosomal subunits, 70S ribosomes or polysomes from E. coli were subjected to mild ultraviolet irradiation, and the 3'-terminal region of the 16S RNA was excised by 'addressed cleavage' using ribonuclease H in the presence of suitable complementary oligodeoxynucleotides. RNA fragments from this region containing intra-RNA cross-links were separated by two-dimensional gel electrophoresis and the cross-link sites identified by our standard procedures. Five new cross-links were found in the 30S subunit, which were localized at positions 1393-1401 linked to 1531-1532, 1393-1401 linked to 1506, 1393-1401 to 1502-1504, 1402-1403 to 1498-1501, and 1432 to 1465-69, respectively. In 70S ribosomes or polysomes the first four of these were absent, but instead two cross-links between the 1400-region and tRNA were observed. These results are discussed in the context of the tertiary folding of the 3'-terminal region of the 16S RNA and its known functional significance as part of the ribosomal decoding centre.     

Composition of the Escherichia coli 70S ribosomal interface: a cross-linking study

70S tight-couple ribosomes from Escherichia coli were cross-linked by using the bifunctional reagent phenyl-diglyoxal (PDG). The reaction was stopped after 4-h incubation while still in the linear range. In comparison with untreated ribosomes, 30% of those treated with PDG were shown, by sucrose gradient experiments, not to be separable into their subunits, but remained as 70S particles. There was no detectable change in the structure of the reacted particles when their sedimentation behavior was compared with that of native 70S controls. When the cross-linking reaction was performed in the presence of tRNAPhe and poly(U), the reacted ribosomes retained 40-50% of their tRNA binding activity. The reaction leads predominantly to the formation of RNA-protein cross-links but protein--protein as well as RNA-RNA cross-links could also be detected. Cross-linked material was extracted, and the individual RNAs were separated into 23S, 16S, and 5S RNAs. Proteins were identified electrophoretically after reversal of the RNA-protein cross-links. Proteins were found to be cross-linked to RNAs within and across the ribosomal subunits; the latter are considered to be close to or at the 70S subunit interface. The arrangement of RNA and protein at the subunit interface is discussed.     

2'-O-methylated oligonucleotides in ribosomal 18S and 28S RNA of a mouse hepatoma, MH 134.

Simple two-dimensional thin-layer chromatography was found to be useful for the separation of sugar methylated dinucleotides in RNA. Of the 16 possible sequences of the type Nm-Np, 15 were separated and all the sequences were determined. In a mouse hepatoma, MH 134, the levels of the sugar methylation in the 18S and 28S RNA molecules were 17-18 and 11-12 per 1000 nucleotides, respectively. Thus, 18s RNA contained approximately 35 2'-O-methylated dinucleotides and 28S RNA approximately 60 2'-O-methylated dinucleotides. The pattern of distribution was also distinct between these two molecules. Two 2'-O-methylated trinucleotides were identified in the 28S RNA with the sequences Um-Gm-Up and Um-Gm-psip. A unique 2'-O-methylated tetranucleotide was present also in the 28S RNA, the sequence of which was Am-Gm-Cm-Ap. The 5'-terminal nucleotides of both 18S and 28S RNA were obtained as nucleoside 3',5'-diphosphates (pNp) in the trinucleotide fraction of the RNase T2 digest. The 5'-termimi of 18S and 28S RNA were pUp and pCp, respectively, and found to be almost homogeneous.     

Multiple crosslinks of proteins S7, S9, S13 to domains 3 and 4 of 16S RNA in the 30S particle.

Functionally active 70S ribosomes containing 4-thiouracil in place of uracil (substitution level 2%) were prepared by an in vivo substitution method. RNA-protein crosslinks were introduced by 366 nm photoactivation of 4-thiouracil in the purified 30S subunits. Seven single stranded M13 probes containing rDNA inserts complementary to domains 3 and 4 of 16S RNA were constructed. These inserts approximately 100 nucleotides long starting at nucleotide 868 and ending at the 3' OH terminus were used to select contiguous RNA sections. The proteins covalently linked to each selected RNA section were identified by 2D gel electrophoresis. Proteins S7, S9, S13 were shown to be efficiently crosslinked to multiple sites belonging to both domains.     

Site-directed cross-linking of mRNA analogues to 16S ribosomal RNA; a complete scan of cross-links from all positions between '+1' and '+16' on the mRNA, downstream from the decoding site.

mRNA analogues containing 4-thiouridine residues at selected sites were used to extend our analysis of photo-induced cross-links between mRNA and 16S RNA to cover the entire downstream range between positions +1 and +16 on the mRNA (position +1 is the 5'-base of the P-site codon). No tRNA-dependent cross-links were observed from positions +1, +2, +3 or +5. Position +4 on the mRNA was cross-linked in a tRNA-dependent manner to 16S RNA at a site between nucleotides ca 1402-1415 (most probably to the modified residue 1402), and this was absolutely specific for the +4 position. Similarly, the previously observed cross-link to nucleotide 1052 was absolutely specific for the +6 position. The previously observed cross-links from +7 to nucleotide 1395 and from +11 to 532 were however seen to a lesser extent with certain types of mRNA sequence from neighbouring positions (+6 to +10, and +10 to +13, respectively); no tRNA-dependent cross-links to other sites on 16S RNA were found from these positions, and no cross-linking was seen from positions +14 to +16. In each case the effect of a second cognate tRNA (at the ribosomal A-site) on the level of cross-linking was studied, and the specificity of each cross-link was confirmed by translocation experiments with elongation factor G, using appropriate mRNA analogues.     

Ribosomal protein L7/L12 cross-links to proteins in separate regions of the 50 S ribosomal subunit of Escherichia coli

The 50 S ribosomal subunits from Escherichia coli were modified by reaction with 2-iminothiolane under conditions in which 65 sulfhydryl groups, about 2/protein, were added per subunit. Earlier work showed that protein L7/L12 was modified more extensively than the average but that nearly all 50 S proteins contained sulfhydryl groups. Mild oxidation led to the formation of disulfide protein-protein cross-links. These were fractionated by urea gel electrophoresis and then analyzed by diagonal gel electrophoresis. Cross-linked complexes containing two, three, and possibly four copies of L7/L12 were evident. Cross-links between L7/L12 and other ribosomal proteins were also formed. These proteins were identified as L5, L6, L10, L11, and, in lower yield, L9, L14, and L17. The yields of cross-links to L5, L6, L10, and L11 were comparable to the most abundant cross-links formed. Similar experiments were performed with 70 S ribosomes. Protein L7/L12 in 70 S ribosomes was cross-linked to proteins L6, L10, and L11. The strong L7/L12-L5 cross-link found in 50 S subunits was absent in 70 S ribosomes. No cross-links between 30 S proteins and L7/L12 were observed.     

RNA-protein cross-linking in Escherichia coli ribosomal subunits: localization of sites on 16S RNA which are cross-linked to proteins S17 and S21 by treatment with 2-iminothiolane.

Treatment of E. coli ribosomal subunits with 2-iminothiolane coupled with mild ultraviolet irradiation leads to the formation of a large number of RNA-protein cross-links. In the case of the 30S subunit, a number of sites on 16S RNA that are cross-linked to proteins S7 and S8 by this procedure have already been identified (see ref. 6). Here, by using new or modified techniques for the partial digestion of the RNA and the subsequent isolation of the cross-linked RNA-protein complexes, three new iminothiolane cross-links have been localized: Protein S17 is cross-linked to the 16S RNA within an oligonucleotide encompassing positions 629-633, and protein S21 is cross-linked to two sites within oligonucleotides encompassing positions 723-724 and positions 1531-1542 (the 3'-end of the 16S RNA).     

Sequence analysis and in vitro maturation of five precursor 5S RNAs from Bacillus Q.

Bacillus Q, which is closely related to B. subtilis, contains at least six different precursors of 5S rRNA. The complete nucleotide sequences of four of these precursors, as well as the major part of the sequence of a fifth one, have been determined. They all contain the same 5'-terminal non-conserved segment which is to a large degree homologous with the corresponding segment of the B. subtilis p5S RNAs (Sogin, M.L., Pace, N.R., Rosenberg, M., Weissman, S.M. (1976) J. Biol. Chem. 251, 3480-3488). On the other hand the 3'-terminal non-conserved sequences of the various Bacillus Q precursors show considerable differences both in length and in nucleotide sequence, while there is also little or no homology with the 3'-terminal non-conserved sequence of the B. subtilis precursors. Bacillus Q p5S RNAs do not possess tetranucleotide repeats around the sites which are cleaved during maturation, as does B. subtilis p5S RNA. Like in B. subtilis, however, the cleavage sites are contained within a double-helical region of the precursor molecules. Crude RNAse M5 isolated from various Bacillus strains can maturate the Bacillus Q p5S RNAs with high efficiency. Despite considerable differences in primary structure between the precursors from the various strains, each RNAs M5 preparation can maturate all these precursors with about the same efficiency.     

An RNA secondary structure switch between the inactive and active conformations of the Escherichia coli 30 S ribosomal subunit

Psoralen cross-linking was used to produce intramolecular cross-links in the Escherichia coli 16 S ribosomal RNA in the inactive and active forms of the 30 S subunit. A number of psoralen cross-links were made in the inactive form that were not made in the active form. The most frequent of these cross-links was sequenced by a series of techniques and identified as C-924 to U-1532. In this region, a three-base complementary, (921-923).(1532-1534), forms a site where psoralen can stack and produce a cross-link between C-924 and U-1532. When psoralen monoadducts were placed on inactive subunits and the conformation was switched to the active form before cross-linking, a new cross-link involving U-1393 was detected. U-1393 is part of the complementarity, (923-925).(1391-1393), that has previously been proposed as being an element of the functional secondary structure on the basis of sequence comparison. The complementarity between (921-923).(1532-1534) occurs in most nonmitochondrial small subunit RNAs; however, there are several counter examples in which it does not occur. This suggests that this alternate secondary structure interaction is not necessary for the function of the 30 S subunit.     

Characterization of the Low-Molecular-Weight RNAs Associated with the 70S RNA of Rous Sarcoma Virus

Two low-molecular-weight RNAs are associated with the 70S RNA complex of Rous sarcoma virus: a previously described 4S RNA and a newly identified 5S RNA. The 4S RNA constitutes 3 to 4% of the 70S RNA complex or the equivalent of 12 to 20 molecules per 70S RNA. It exhibits a number of structural properties characteristic of transfer RNA as revealed by two-dimensional electrophoresis of oligonucleotides obtained from a T1 ribonuclease digest of the 4S RNA species. The 5S RNA is approximately 120 nucleotides in length, constitutes 1% of the 70S RNA complex or the equivalent of 3 to 4 molecules per molecules of 70S RNA, and is identical in nucleotide composition and structure to 5S RNA from uninfected chicken embryo fibroblasts. Melting studies indicate that the 5S RNA is released from the 70S RNA complex at the same temperature required to dissociate 70S RNA into its constituent 35S subunits. In contrast, greater than 80% of the 4S RNA is released from 70S RNA prior to its conversion into subunits. The possible biological significance of these 70S-associated RNAs is discussed.     

Precise localisation of three intra-RNA cross-links in 23S RNA and one in 5S RNA, induced by treatment of Escherichia coli 50S ribosomal subunits with bis-(2-chloroethyl)-methylamine.

Treatment of E. coli 50S ribosomal subunits with low doses of bis-(2-chloroethyl)-methylamine ("nitrogen mustard") leads to formation of a number of intra-RNA and RNA-protein cross-links. After partial digestion of the cross-linked subunits with cobra venom nuclease, followed by destruction of the protein moiety with proteinase K, complexes containing the intra-RNA cross-links were isolated by two-dimensional gel electrophoresis. The individual complexes were subjected to oligonucleotide analysis, either directly or after a second partial digestion procedure using ribonuclease T1, and the cross-link sites determined. In 23S RNA, the cross-links found were between bases 763 and 1567, 1210 and 1236, 1482 and 1501; in 5S RNA, base 69 was cross-linked to base 107. The significance of these cross-links in relation to the three-dimensional organization of the ribosomal RNA is discussed.     

Cross-links between ribosomal proteins of 30S subunits in 70S tight couples and in 30S subunits

Ribosome 70S tight couples and 30S subunits derived from them were modified with 2-iminothiolane under conditions where about two sulfhydryl groups per protein were added to the ribosomal particles. The 70S and 30S particles were not treated with elevated concentrations of NH4Cl, in contrast to those used in earlier studies. The modified particles were oxidized to promote disulfide bond formation. Proteins were extracted from the cross-linked particles by using conditions to preclude disulfide interchange. Disulfide-linked protein complexes were fractionated on the basis of charge by electrophoresis in polyacrylamide/urea gels at pH 5.5. The proteins from sequential slices of the urea gels were analyzed by two-dimensional diagonal polyacrylamide/sodium dodecyl sulfate gel electrophoresis. Final identification of proteins in cross-linked complexes was made by radioiodination of the proteins, followed by two-dimensional polyacrylamide/urea gel electrophoresis. Attention was focused on cross-links between 30S proteins. We report the identification of 27 cross-linked dimers and 2 trimers of 30S proteins, all but one of which were found in both 70S ribosomes and free 30S subunits in similar yield. Seven of the cross-links, S3-S13, S13-S21, S14-S19, S7-S12, S9-S13, S11-S21, and S6-S18-S21, have not been reported previously when 2-iminothiolane was used. Cross-links S3-S13, S13-S21, S7-S12, S11-S21, and S6-S18-S21 are reported for the first time. The identification of the seven new cross-links is illustrated and discussed in detail. Ten of the dimers reported in the earlier studies of Sommer & Traut (1976) [Sommer, A., & Traut, R. R. (1976) J. Mol. Biol. 106, 995-1015], using 30S subunits treated with high salt concentrations, were not found in the experiments reported here.