Subunits of oncornavirus high-molecular-weight RNA. II. Detection of double-stranded-regions in 60S AMV (avian myeloblastosis virus) RNA

Nuclease S₁, specifically splitting only single-stranded polynucleotides has been used to detect the double-stranded regions of high-molecular-weight AMV-RNA. Nuclease S₁-resistant material comprising approx. 8% of 60S AMV-RNA molecule was isolated, purified and found to be completely nuclease S₁-resistant when native and completely nuclease S₁-sensitive upon heat denaturation. The symmetric nucleotide composition with equal G-C and equal A-U contents is also consistent with double-stranded nature of this material. Poly A does not participate significantly, if at all, in nuclease S₁-resistant structures. It is suggested that those base paired regions might participate in linking the RNA subunits together to form an aggregate 60S RNA molecule of oncornaviruses.     

Structure and function of 5S ribosomal ribonucleic acid from Torulopsis utilis. III. Detection of single-stranded regions by digestion with nuclease S1

Identification of single-stranded regions in Torulopsis utilis 5S RNA was attempted by the use of Nuclease S1, a single-strand specific endonuclease. When T. utilis 5S RNA was subjected to prolonged incubation with Nuclease S1, about 50% of the substrate 5S RNA remained as large oligonucleotide "cores." Such Nuclease S1-resistant fragments were purified and sequenced by column chromatographic procedures. These analyses revealed that regions around positions 12, 40, 57, and 110 are in exposed single-stranded loops at 37 degrees C and that regions around positions 12 and 40 are most exposed at 20 degrees C. These results are compatible with our secondary structure model for T. utilis 5S RNA (Nishikawa & Takemura (1974) J. Biochem. 76, 935-947) except that the 5' part of the molecule (from the region around position 22 to that around position 57) might have a somewhat looser conformation than our secondary structure model suggests. The implications of such results are also discussed in relation to the presumed function of the sequence C-G-A-U-C (around position 40) as one of the recognition sites for initiator tRNA binding on ribosomes.     

Probing the structure of 16 S ribosomal RNA from Bacillus brevis

A majority (approximately 89%) of the nucleotide sequence of Bacillus brevis 16 S rRNA has been determined by a combination of RNA sequencing methods. Several experimental approaches have been used to probe its structure, including (a) partial RNase digestion of 30 S ribosomal subunits, followed by two-dimensional native/denatured gel electrophoresis, in which base-paired fragments were directly identified; (b) identification of positions susceptible to cleavage by RNase A and RNase T1 in 30 S subunits; (c) sites of attack by cobra venom RNase on naked 16 S rRNA; and (d) nucleotides susceptible to attack by bisulfite in 16 S rRNA. These data are discussed with respect to a secondary structure model for B. brevis 16 S rRNA derived by comparative sequence analysis.     

Protein binding sites on Escherichia coli 16S RNA; RNA regions that are protected by proteins S7, S14 and S19 in the presence or absence of protein S9.

14C-labelled proteins from E. coli 30S ribosomal subunits were isolated by HPLC, and selected groups of these proteins were reconstituted with 32P-labelled 16S RNA. The isolated reconstituted particles were partially digested with ribonuclease A, and the RNA fragments protected by the proteins were separated by gel electrophoresis and subjected to sequence analysis. Protein S7 alone gave no protected fragments, but S7 together with S14 and S19 protected an RNA region comprising the sequences 936-965, 972-1030, 1208-1262 and 1285-1379 of the 16S RNA. Addition of increasing amounts of protein S9 to the S7/S14/S19 particle resulted in a parallel increase in the protection of the hairpin loop between bases 1262 and 1285. The results are discussed in terms of the three-dimensional folding of 16S RNA in the 30S subunit.     

Evidence for the formation of nucleosome-like histone complexes on single-stranded DNA.

Using histones reconstituted with RNA and DNA celluloses, we have shown elsewhere that histones elute identically with salt from single- and double-stranded DNA, but differently from RNA (Palter and Alberts, 1979). In this paper we characterize further the suspected specific binding interactions between histones and single-stranded DNA. Nuclease digestion of complexes of histone reconstituted with single-stranded DNA generates only a small yield of discrete (approximately 9S) particles. We can, however, efficiently obtain such 9S "nucleosome-like" complexes when nuclease treatment is avoided and histones are reconstituted directly with short single-stranded DNA pieces. Strikingly, these 9S subunits contain an equimolar composition of the four nucleosomal histones. When these subunits are visualized in the electron microscope, they appear as globular particles which are morphologically indistinguishable from normal mononucleosomes. Based on their sedimentation properties, histone-to-DNA ratio, histone composition and particle diameter, we conclude that they represent an octamer of the four histones (containing two molecules of each histone) associated with single-stranded DNA. These data, viewed in the context of other information concerning chromatin, suggest that nucleosome cores may become transiently bound to single strands of DNA as DNA and RNA polymerases pass.     

Mechanism of ribosomal subunit association: discrimination of specific sites in 16 S RNA essential for association activity.

Modification of 30 S ribosomal subunits with kethoxal causes loss of their ability to associate with 50 S subunits under tight couple conditions. To identify those 16 S RNA sequences important for the association. ³²P-labeled 30 S subunits were partially inactivated by reaction with kethoxal. The remaining association-competent 30 S subunits were selected from the modified population by their ability to form 70 S ribosomes. Comparison of kethoxal diagonal maps of the association-competent subunits with those of the total population of modified subunits reveals nine sites in 16 S RNA whose modification leads to loss of association activity. Eight of these sites were previously found to be protected from kethoxal attack and one was shown to have enhanced reactivity in 70 S ribosomes (Chapman &; Noller, 1977). As before, these sites are not distributed thoughout the molecule, but are found to be clustered in two regions, at the middle and at the 3′ terminus of the 16 S RNA chain.We interpret these findings in terms of a simple preliminary model for the functional organization of 16 S RNA, supported by the observations of other investigators, in which we divide the molecule into four domains. (1) Residues 1 to 600 are involved mainly in structural organization and assembly. (2) Residues 600 to 850 include sites which make contact with the 50 S subunit and are essential for subunit association. (3) Sites from the domain comprising residues 850 to 1350 line a pocket at the interface between the two ribosomal subunits. and contribute to the binding site(s) for transfer RNA. (4) Residues 1350 to 1541 also contain sequences which bind the 50 S subunit, but some sites in this domain alternatively participate in the initiation of protein synthesis.     

An experimentally-derived model for the secondary structure of the 16S ribosomal RNA from Escherichia coli

Ribonucleoprotein fragments are isolated by mild ribonuclease digestion of E. coli 30S ribosomal subunits, and are deproteinized and subjected to a second partial digestion. Base-pairing between the resulting small RNA fragments is investigated using the two-dimensional gel electrophoresis procedure already reported (see Ref. 1). The interactions thus found are incorporated into a secondary structure model covering approximately 80% of the 16S RNA.     

Nuclease S1-sensitive sites in multigene families: human U2 small nuclear RNA genes.

We show here that human U2 small nuclear RNA genes contain a 'strong nuclease S1 cleavage site' (SNS1 site), a sequence that is very sensitive to digestion by nuclease S1. This site is located 0.50-0.65 kb downstream of the U2 RNA coding region. It comprises a 0.15-kb region in which (dC-dT)n:(dA-dG)n co-polymeric stretches represent greater than 90% of the sequence. Nuclease S1 is able to excise unit length repeats of the human U2 RNA genes both from cloned fragments and total human genomic DNA. The precise locations of the cleavage sites are dependent on the superhelicity of the substrate DNA. In negatively supercoiled substrates, cleavages are distributed over the entire 0.15-kb region, but in linearized substrates, they occur within a more limited region, mainly at the boundary of the SNS1 site closest to the human U2 RNA coding region. Nuclease S1 cleavage of negatively supercoiled substrates occurs at pHs as high as 7.0; in contrast, cleavage of linearized substrates requires a pH less than 5.0, indicating that supercoiling contributes to the sensitivity of this site. Mung bean nuclease gives results similar to that observed with nuclease S1.     

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.     

Secondary structure of a 345-base RNA fragment covering the S8/S15 protein binding domain of Escherichia coli 16S ribosomal RNA

A technique for isolating defined fragments of a large RNA has been developed and applied to a ribosomal RNA. A section of the Escherichia coli rrnB cistron corresponding to the S8/S15 protein binding domain of 16S ribosomal RNA was cloned into a single-stranded DNA phage; after hybridization of the phage DNA with 16S RNA and digestion with T1 ribonuclease, the protected RNA was separated from the DNA under denaturing conditions to yield a 345-base RNA fragment with unique ends (bases 525-869 in the 16S sequence). The secondary structure of this fragment was determined by mapping the cleavage sites of enzymes specific for single-stranded or double-helical RNA. The fragment structure is almost identical with that proposed for the corresponding region of intact 16S RNA on the basis of phylogenetic comparisons [Woese, C. R., Gutell, R., Gupta, R., & Noller, H. (1983) Microbiol. Rev. 47, 621-669]. We conclude that this section of RNA constitutes an independently folding domain that may be studied in isolation from the rest of the 16S RNA. The structure mapping experiments have indicated several interesting features in the RNA structure. (i) The largest bulge loop in the molecule (20 bases) contains specific tertiary structure. (ii) A region of long-range secondary structure, pairing bases about 200 residues apart in the sequence, can hydrogen bond in two different mutually exclusive schemes. Both appear to exist simultaneously in the RNA fragment under our conditions. (iii) The long-range secondary structure and one adjacent helix melt between 37 and 60 degrees C in the absence of Mg2+, while the rest of the structure is quite stable.     

Protein binding sites on Escherichia coli 16S ribosomal RNA; RNA regions that are protected by proteins S7, S9 and S19, and by proteins S8, S15 and S17.

Selected groups of isolated 14C-labelled proteins from E. coli 30S ribosomal subunits were reconstituted with 32P-labelled 16S RNA, and the reconstituted complexes were partially digested with ribonuclease A. RNA fragments protected by the proteins were separated by gel electrophoresis and subjected to sequence analysis. Complexes containing proteins S7 and S19 protected an RNA region comprising helices 29 to 32, part of helix 41, and helices 42 and 43 of the 16S RNA secondary structure. Addition of protein S9 had no effect. When compared with previous data for proteins S7, S9, S14 and S19, these results suggest that S14 interacts with helix 33, and that S9 and S14 together interact with the loop-end of helix 41. Complexes containing proteins S8, S15 and S17 protected helices 7 to 10 as well as the "S8-S15 binding site" (helices 20, 22 and parts of helices 21 and 23). When protein S15 was omitted, S8 and S18 showed protection of part of helix 44 in addition to the latter regions. The results are discussed in terms of our model for the detailed arrangement of proteins and RNA in the 30S subunit.     

Characterisation of RNA fragments obtained by mild nuclease digestion of 30-S ribosomal subunits from Escherichia coli.

When Escherichia coli 30-S ribosomal subunits are hydrolysed under mild conditions, two ribonucleoprotein fragments of unequal size are produced. Knowledge of the RNA sequences contained in these hydrolysis products was required for the experiments described in the preceding paper, and the RNA sub-fragments have therefore been examined by oligonucleotide analysis. Two well-defined small fragments of free RNA, produced concomitantly with the ribonucleoprotein fragments, were also analysed. The larger ribonucleoprotein fragment, containing predominantly proteins S4, S5, S8, S15, S16 (17) and S20, contains a complex mixture of RNA sub-fragments varying from about 100 to 800 nucleotides in length. All these fragments arose from the 5'-terminal 900 nucleotides of 16-S RNA, corresponding to the well-known 12-S fragment. No long-range interactions could be detected within this RNA region in these experiments. The RNA from the smaller ribonucleoprotein fragment (containing proteins S7, S9 S10, S14 and S19) has been described in detail previously, and consists of about 450 nucleotides near the 3' end of the 16-S RNA, but lacking the 3'-terminal 150 nucleotides. The two small free RNA fragments (above) partly account for these missing 150 nucleotides; both fragments arose from section A of the 16-S RNA, but section J (the 3'-terminal 50 nucleotides) was not found. This result suggests that the 3' region of 16-S RNA is not involved in stable interactions with protein.     

Cloning and characterization of 4.5S and 5S RNA genes in tobacco chloroplasts

Tobacco chloroplast 4.5S and 5S RNAs were shown to hybridize with a 0.9 . 10(6) dalton EcoRI fragment of tobacco chloroplast DNA. Recombinant plasmids were constructed from fragments produced by partial digestion of the chloroplast DNA with EcoRI and the pMB9 plasmid as a vector. Five recombinants containing the 4.5S and 5S genes were selected by the colony hybridization technique. One of these plasmids contained also the 16S and 23S RNA genes and was mapped using several restriction endonucleases as well as DNA-RNA hybridization. The order of rRNA genes is 16S-23S-4.5S-5S and the four rRNA genes are coded for by the same DNA strand.     

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.     

30S ribosomal subunits with fragmented 16S RNA: a new approach for structure and function study of ribosomes.

A new approach for function and structure study of ribosomes based on oligodeoxyribonucleotide-directed cleavage of rRNA with RNase H and subsequent reconstitution of ribosomal subunits from fragmented RNA has been developed. The E coli 16S rRNA was cleaved at 9 regions belonging to different RNA domains. The deletion of 2 large regions was also produced by cleaving 16S rRNA in the presence of 2 or 3 oligonucleotides complementary to different RNA sites. Fragmented and deleted RNA were shown to be efficiently assembled with total ribosomal protein into 30S-like particles. The capacity to form 70S ribosomes and translate both synthetic and natural mRNA of 30S subunits reconstituted from intact and fragmented 16S mRNA was compared. All 30S subunits assembled with fragmented 16S rRNA revealed very different activity: the fragmentation of RNA at the 781-800 and 1392-1408 regions led to the complete inactivation of ribosomes, whereas the RNA fragmentation at the regions 296-305, 913-925, 990-998, 1043-1049, 1207-1215, 1499-1506, 1530-1539 did not significantly influence the ribosome protein synthesis activity, although it was also reduced. These findings are mainly in accordance with the data on the functional activity of some 16S rRNA sites obtained by other methods. The relations between different 16S RNA functional sites are discussed.     

RNA--protein interactions in the ribosome. IV. Structure and properties of binding sites for proteins S4, S16/S17 and S20 in the 16S RNA

Proteins S4, S16/S17 and S20 of the 30 S ribosomal subunit of Escherichia coli+ associate with specific binding sites in the 16 S ribosomal RNA. A systematic investigation of the co-operative interactions that occur when two or more of these proteins simultaneously attach to the 16 S RNA indicate that their binding sites lie near to one another. The binding site for S4 has previously been located within a 550-nucleotide RNA fragment of approximately 9 S that arises from the 5′-terminal portion of the 16 S RNA upon limited hydrolysis with pancreatic ribonuclease. The 9 S RNA was unable to associate with S20 and S16/S17, however, either alone or in combination. A fragment of similar size and nucleotide sequence, termed the 9 S¹ RNA, has been isolated following ribonuclease digestion of the complex of 16 S RNA with S20 and S16/S17. The 9 S¹ RNA bound not only S4, but S20 and S16/S17 as well, although the fragment complex was stable only when both of the latter protein fractions were present together. Nonetheless, measurements of binding stoichiometry demonstrated the interactions to be specific under these conditions. A comparison of the 9 S and 9 S¹ RNAs by electrophoresis in polyacrylamide gels containing urea revealed that the two fragments differ substantially in the number and distribution of hidden breaks. Contrary to expectation, the RNA in the ribonucleoprotein complex appeared to be more accessible to ribonuclease than the free 16 S RNA as judged by the smaller average length of the sub-fragments recovered from the 9 S¹ RNA. These results suggest that the binding of S4, S16/S17 and S20 brings about a conformational alteration within the 5′ third of the 16 S RNA.To delineate further the portions of the RNA chain that interact with S4, S16/S17 and S20, specific fragments encompassing subsequences from the 5′ third of the 16 S RNA were sought. Two such fragments, designated 12 S-I and 12 S-II, were purified by polyacrylamide gel electrophoresis from partial T₁ ribonuclease digests of the 16 S RNA. The two RNAs, which contain 290 and 210 nucleotides, respectively, are contiguous and together span the entire 5′-terminal 500 residues of the 16 S RNA molecule. When tested individually, neither 12 S-I nor 12 S-II bound S4, S16/S17 or S20. If heated together at 40 °C in the presence of Mg²⁺ ions, however, the two fragments together formed an 8 S complex which associated with S4 alone, with S16/S17 + S20 in combination, and with S4 + S16/S17 + S20 when incubated with an un fractionated mixture of 30 S subunit proteins. These results imply that each fragment contains part of the corresponding binding sites.     

Fragment of protein L18 from the Escherichia coli ribosome that contains the 5S RNA binding site.

A fragment of ribosomal protein L18 was prepared by limited trypsin digestion of a specific complex of L18 and 5S RNA. It was characterised for sequence and the very basic N-terminal region of the protein was found to be absent. No smaller resistant fragments were produced. 5S RNA binding experiments indicated that the basic N-terminal region, from amino acid residues 1 to 17, was not important for the L18-5S RNA association. Under milder trypsin digestion conditions three resistant fragments were produced from the free protein. The largest corresponded to that isolated from the complex. The smaller ones were trimmed slightly further at both N- and C-terminal ends. These smaller fragments did not reassociate with 5S RNA. It was concluded on the basis of the trypsin protection observations and the 5S RNA binding results that the region extending from residues 18 to 117 approximates to the minimum amount of protein required for a specific and stable protein-RNA interaction. The accessibility of the very basic N-terminal region of L18, in the L18-5S RNA complex, suggests that it may be involved, in some way, in the interaction of 5S RNA with 23S RNA.     

Localization of the binding site for protein S4 on 16 S ribosomal RNA by chemical and enzymatic probing and primer extension

We have examined the effect of binding ribosomal protein S4 to 16 S rRNA on the susceptibility of the RNA to a variety of chemical and enzymatic probes. We have used dimethyl sulfate to probe unpaired adenines (at N-1) and cytosines (at N-3), kethoxal to probe unpaired guanines (at N-1 and N-2) and cobra venom (V1) ribonuclease as a probe of base-paired regions of 16 S rRNA. Sites of attack by the probes were identified by primer extension using synthetic oligodeoxynucleotides. Comparison of probing results for naked and S4-bound rRNA shows: Protein S4 protects a relatively compact region of the 5' domain of 16 S rRNA from chemical and enzymatic attack. This region is bounded by nucleotides 27 to 47 and 394 to 556, and has a secondary structure characterized by the junction of five helical elements. Phylogenetically conserved irregular features (bulged nucleotides, internal loops and flanking unpaired nucleotides) and helical phosphodiester bonds of four of the helices are specifically protected in the S4-RNA complex. We conclude that this is the major, and possibly sole region of contact between 16 S rRNA and S4. Many of the S4-dependent changes mimic those observed on assembly of 16 S rRNA into 30 S ribosomal subunits. Binding of S4 causes enhanced chemical reactivity coupled with protection from V1 nuclease outside the S4 junction region in the 530, 720 and 1140 loops. We interpret these results as indicative of loss of structure, and suggest that S4 binding causes disruption of adventitious pairing in these regions, possibly by stabilizing the geometry of the RNA such that these interactions are prevented from forming.     

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.     

Oligonucleotide sequences of pancreatic and T1 ribonuclease digests of 5S ribosomal RNA from mouse cells.

Oligonucleotides produced by complete pancreatic and T1 RNase digestion of 5S ribosomal RNA from a mouse hepatoma, MH 134, have been separated with two-dimensional electrophoresis and their nucleotide sequences determined. Except for the presence of a 5'-terminal diphosphate, these nucleotide sequences were identical with those of KB cells, confirming the identity of the primary structure of 5S RNA between these animals. Both oligonucleotide patterns produced with these enzymes from 5S RNA of the liver were also identical with those of the hepatoma. All these agree with the strong conservation of 5S RNA genes in animal species. However, when 5S ribosomal RNA was extracted from ribosomes which were prepared from microsomal pellet, pancreatic RNase digest contained two trinucleotides (A-G-Cp and G-A-Cp) that were not found in 5S RNA prepared with a one-step procedure. It was concluded that different isolation procedure might indeed cause artifactual fragments on enzymatic digestion due to internal nicks produced during isolation. The significance of 5'-terminal diphosphate in relation to the biosynthesis of 5S ribosomal RNA is also discussed.