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.     

Interaction of unfolded tRNA with the 3''-terminal region of E. coli 16S ribosomal RNA.

Fragments of tRNA possessing a free TpsiC-loop or a free D-loop form stable complexes with the colicin fragment (1494-1542) of 16S ribosomal RNA from E. coli. The colicin fragment does not bind to tRNA in which the T-loop and the D-loop are involved in tertiary interactions. Colicin cleavage of the 16S rRNA from E. coli is inhibited by aminoacyl-tRNA or tRNA fragments, indicating that a similar interaction may take place on the intact 70S ribosomes. The oligonucleotide d(G-T-T-C-G-A)homologous to the conserved sequence G-T-psi-C-Pu-(m1)A in the TpsiC-region of many elongator tRNAs binds to the conserved sequence U-C-G-mU-A-A-C (1495-1501) of the 16S rRNA. It is suggested that the 3'-end of the 16S rRNA may provide the part of the binding site for the elongator tRNAs on bacterial ribosomes.     

Investigation of the tertiary folding of Escherichia coli ribosomal RNA by intra-RNA cross-linking in vivo

"In vivo" cross-links were introduced into ribosomal RNA by direct ultraviolet irradiation of intact Escherichia coli cells, during growth in a 32P-labelled medium. Ribosomes were isolated from the irradiated cultures, dissociated into subunits and subjected to partial digestion with cobra venom nuclease. The intra-RNA cross-linked fragments were separated by two-dimensional gel electrophoresis and the sites of cross-linking determined, using our published methodology. A comparison with the data previously obtained by this procedure, after irradiation of isolated 30 S and 50 S subunits, showed that in the case of the 50 S subunit nine out of the ten previous cross-links in the 23 S RNA could be identified in the "in vivo" experiments, and correspondingly in the 30 S subunit five out of the six previous cross-links in the 16 S RNA were identified. Some new cross-links were found, as well as two cross-links in the 16 S RNA, which had hitherto only been observed after partial digestion of irradiated 30 S subunits with ribonuclease T1. The relevance of these data to the tertiary folding of the rRNA in situ is discussed, with particular reference to the work of other authors, in which "naked" RNA was used as the substrate for cross-linking and model-building studies.     

The tertiary folding of Escherichia coli 16S RNA, as studied by in situ intra-RNA cross-linking of 30S ribosomal subunits with bis-(2-chloroethyl)-methylamine.

Intra-RNA cross-links were introduced into E. coli 30S ribosomal subunits by treatment with bis-(2-chloroethyl)methylamine. The subunits were partially digested with cobra venom nuclease, and the cross-linked complexes were separated by two-dimensional electrophoresis and analysed according to our published procedures. Tertiary structural cross-links in the 16S RNA were identified between nucleotides 31 and 306, and between the tetranucleotide 693-696 and nucleotides 794 or 799. Secondary structural cross-links, lying at the ends of double-helical regions, were found between nucleotides 46 and the trinucleotide 362-364, and between the dinucleotide 148-149 and nucleotide 174. Cross-links within double-helical elements were identified between the tetranucleotide 128-131 and nucleotide 232, between nucleotide 250 and the dinucleotide 274-275, and between nucleotides 1413 and 1486. Adenine as well as guanine residues were involved in the cross-links.     

Altered topography of 16S RNA in the inactive form of Escherichia coli 30S ribosomal subunits.

We have studied the topography of 16S RNA in the inactive form of the 30S ribosomal subunit (Ginsburg, I., et al. (1973) J. Mol. Biol. 79, 481), using the guanine-specific reagent kethoxal. Oligonucleotides surrounding reactive guanine residues were isolated and quantitated by means of diagonal electrophoresis and sequenced. Comparison of these results with experiments on active or reactivated subunits reveals the following: (1) Most of the sites which are reactive in active 30S subunits are much more reactive (average 13-fold) in inactive subunits. Upon reactivation, these sites return to a less reactive state. Thus, a reversible increase in accessibility of specific 16S RNA sites parallels the reversible loss of protein synthesis activity of 30S subunits. (2) The number of kethoxal-reactive sites in inactive subunits is about twice that of active subunits. The nucleotide sequences and locations of the additional accessible sites in inactive subunits have been determined. (3) Sites that can be located in the 16S RNA sequence are distributed throughout the RNA chain in inactive subunits, in contrast to the clustering observed in active subunits. (4) The sites of kethoxal substitution are single stranded. Yet, of the 30 sites that can be located, 23 were predicted to be base paired in the proposed secondary structure model for 16S RNA (Ehresmann, C., et al. (1975), Nucleic Acids Res. 2, 265).     

The Escherichia coli 30S ribosomal subunit; an optimized three-dimensional fit between the ribosomal proteins and the 16S RNA.

We have generated a computerized fit between the 3-dimensional map of the E.coli 30S ribosomal proteins, as determined by neutron scattering, and the recently published 3-dimensional model for the 16S RNA. To achieve this, the framework of coordinates for RNA-protein cross-link sites on the phosphate backbone in the RNA model was related to the corresponding framework of coordinates for the mass centres of the proteins by a least squares fitting procedure. The resulting structure, displayed on a computer graphics system, gives the first complete picture of the E.coli 30S ribosomal subunit showing both the proteins and the double-helical regions of the RNA. The root mean square distance between cross-link sites and protein centres is 32 A. The position of the mass centre of the combined double-helical regions was calculated from the model and compared with the position of the mass centre of the complete set of proteins. The two centres are displaced relative to one another by 20 A in the model structure, in good agreement with the experimental value of 25 A found by neutron scattering.     

A conformational switch involving the 915 region of Escherichia coli 16 S ribosomal RNA

A novel alternative conformation, which involves an interaction between the 5' terminal and 915 regions (E. coli numbering), is proposed after a screening of compiled sequences of small subunit ribosomal RNAs. This conformation contains a pseudoknot helix between residues 12-16 and 911-915, and its formation requires the partial melting of the 5' terminal helix and the disruption of the 17-19/916-918 pseudoknot helix of the classical 16 S rRNA secondary structure. The alternate pseudoknot helix is proximal to the binding site of streptomycin and various mutations in rRNA which confer resistance to streptomycin have been located in each strand of the proposed helix. It is suggested that the presence of streptomycin favours the shift towards the alternate conformation, thereby stabilizing drug binding. Mutations which destabilize the novel pseudoknot helix would restrict the response to streptomycin.     

The 3''-terminal sequence of mitochondrial 13S ribosomal RNA.

We have examined the 3'-terminal sequence of the "small" structural ribosomal RNA ("13S") of hamster cell mitochondria, using a procedure involving [3H]isoniazide labeling of samples subjected to sequential periodate oxidation and beta-elimination. The terminus was found to be PyUAUUAOH, which is similar, but not identical, to the corresponding terminus of eukaryotic cytoplasmic 18S rRNA.     

Primary sequence of the 16S ribosomal RNA of Escherichia coli.

Recent progress in the nucleotide sequence analysis of the 16S ribosomal RNA from E. coli is described. The sequence which has been partially or completely determined so far encompasses 1520 nucleotides, i.e. about 95% of the molecule. Possible features of the secondary structure are suggested on the basis of the nucleotide sequence and data on sequence heterogeneities, repetitions and the location of modified nucleotides are presented. In the accompanying paper, the use of the nucleotide sequence data in studies of the ribosomal protein binding sites is described.     

The conformation of 16S RNA in the 30S ribosomal subunit from Escherichia coli.

The digestion of E. coli 16S RNA with a single-strand-specific nuclease produced two fractions separable by gel filtration. One fraction was small oligonucleotides, the other, comprising 67.5% of the total RNA, was highly structured double helical fragments of mol. wt. 7,600. There are thus about 44 helical loops of average size corresponding to 12 base pairs in each 16S RNA. 10% of the RNA could be digested from native 30S subunits. Nuclease attack was primarily in the intraloop single-stranded region but two major sites of attack were located in the interloop single-stranded regions. Nuclease digestion of unfolded subunits produced three classes of fragments, two of which, comprising 80% of the total RNA, were identical to fragments from 16S RNA. The third, consisting of 20% RNA, together with an equal weight of peotein, was a resistant core (sedimentation coefficient 7S).     

The Escherichia coli ribosomal protein S16 is an endonuclease

The histone-like protein HU isolated from Escherichia coli exhibited, after several purification steps, a Mg²⁺-dependent nuclease activity. We show here that this activity can be dissociated from HU by a denaturation-renaturation step, and is due to a small fraction of ribosomal protein S16 co-purifying with HU. S16 is an essential component of the 30S ribosomal particles. We have cloned, overproduced, and purified a histidine-tagged S16 and shown that this protein is a DNA-binding protein carrying a Mg²⁺-Mn²⁺-dependent endonuclease activity. This is an unexpected property for a ribosomal protein.     

Localisation of a series of intra-RNA cross-links in 16S RNA, induced by ultraviolet irradiation of Escherichia coli 30S ribosomal subunits

Mild ultraviolet irradiation of E. coli ribosomal subunits leads to the formation of a number of intra-RNA cross-links, in addition to the RNA-protein cross-links already reported (see refs. 9, 10). After partial ribonuclease digestion of the RNA from irradiated subunits, complexes containing these intra-RNA cross-links can be isolated on a two-dimensional gel electrophoresis system, and subjected to sequence analysis. A series of these cross-linked complexes is described, and the cross-linked RNA regions are compared with the secondary structures derived for 16S RNA (see refs. 6, 7).     

Chromosomal loci for 16S ribosomal RNA in Escherichia coli

Summary Genetic loci for 16S ribosomal RNA (rRNA) on the Escherichia coli chromosome were determined using the K-sequence, a characteristic oligonucleotide of strain K12, as a genetic marker. Oligonucleotide analyses of 16S rRNA from various recombinants between strain K12 and strain B(H) showed that the loci for 16S rRNA containing the K-sequence were near the metB locus which was at 77 min. on the chromosome map.     

Cross-linking of streptomycin to the 16S ribosomal RNA of Escherichia coli

[3H]Dihydrostreptomycin was cross-linked to the 30S ribosomal subunit from Escherichia coli with the bifunctional reagent nitrogen mustard. The cross-linking primarily involved the 16S RNA. To localize the site of cross-linking of streptomycin to the 16S RNA, we hybridized RNA labeled with streptomycin to restriction fragments of the 16S RNA gene. Labeled RNA hybridized to DNA fragments corresponding to bases 892-917 and bases 1394-1415. These two segments of the ribosomal RNA must be juxtaposed in the ribosome, since there is a single binding site for streptomycin. This region has been implicated both in the decoding site and in the binding of initiation factor IF-3, indicating its functional importance.     

The 3''-terminal region of bacterial 23S ribosomal RNA: structure and homology with the 3''-terminal region of eukaryotic 28S rRNA and with chloroplast 4.5s rRNA.

The sequence of the 110 nucleotide fragment located at the 3'-end of E.coli, P.vulgaris and A.punctata 23S rRNAs has been determined. The homology between the E.coli and P.vulgaris fragments is 90%, whereas that between the E.coli and A.punctate fragments is only 60%. The three rRNA fragments have sequences compatible with a secondary structure consisting of two hairpins. Using chemical and enzymatic methods recently developed for the study of the secondary structure of RNA, we demonstrated that one of these hairpins and part of the other are actually present in the three 3'-terminal fragments in solution. This supports the existence of these two hairpins in the intact molecule. Indeed, results obtained upon limited digestion of intact 23S RNA with T1 RNase were in good agreement with the existence of these two hairpins. We observed that the primary structures of the 3'-terminal regions of yeast 26S rRNA and X.laevis 28S rRNA are both compatible with a secondary structure similar to that found at the 3'-end of bacterial 23S rRNAs. Furthermore, both tobacco and wheat chloroplast 4.5S rRNAs can also be folded in a similar way as the 3'-terminal region of bacterial 23S rRNA, the 3'-end of chloroplast 4.5S rRNAs being complementary to the 5'-end of chloroplast 23S rRNA. This strongly reinforces the hypothesis that chloroplast 4.5S rRNA originates from the 3'-end of bacterial 23S rRNA and suggests that this rRNA may be base-paired with the 5'-end of chloroplast 23S rRNA. Invariant oligonucleotides are present at identical positions in the homologous secondary structures of E.coli 23S, yeast 26S, X.laevis 28S and wheat and tobacco 4.5S rRNAs. Surprisingly, the sequences of these oligonucleotides are not all conserved in the 3'-terminal regions of A.punctata or even P.vulgaris 23S rRNAs. Results obtained upon mild methylation of E.coli 50S subunits with dimethylsulfate strongly suggest that these invariant oligonucleotides are involved in RNA tertiary structure or in RNA-protein interactions.