Action of Ribonuclease T1 on 30S Ribosomes of Escherichia coli and Its Role in Sequence Studies on 16S Ribonucleic Acid

Two large ribonucleic acid (RNA) fragments have been obtained from T1-RNase-treated 30S ribosomes of Escherichia coli. One fragment, about 475 nucleotides long, contains all the unique oligonucleotides found by Fellner and associates in sections of 16S RNA designated P, E, E', and K, and one-half the large oligonucleotides of section A. The other large fragment is about 300 nucleotides long and contains the oligonucleotides found in sections C, C', C'. The isolation of these large fragments seems to confirm the arrangement of sections within 16S RNA. There are also recovered from nuclease-treated ribosomes three small fragments, one (120 nucleotides long) from the 5' end, one (26 nucleotides long) from the 3' OH end of the chain, and another section (66 nucleotides long) from the middle of the 16S RNA chain. Small molecular weight material is also generated by nuclease treatment, and about half this material is derived from a region close to the 3' OH end of the 16S RNA chain. This indicates that the most accessible part of the rRNA of E. coli 30S ribosomes is a region 100 to 150 nucleotides long near the 3' end of the chain. A general scheme is proposed to explain the generation of the various-sized RNA products from the rRNA of the 30S ribosome.     

Comparative Surface Structure of 16S Ribosomal Ribonucleic Acid of 30S Ribosomes of Procaryotic Cells

Ribonuclease T(1) treatment of 30S ribosomes of Escherichia coli converts a large region at the 3' OH end of 16S ribosomal ribonucleic acid (rRNA) to low-molecular-weight RNA. The final 25 nucleotides at the 3' terminus of the molecule emerge relatively intact, whereas most of the region "upstream," for about 150 nucleotides, is converted to oligonucleotides. Identical enzyme treatment generates a fragment of about 60 nucleotides from the middle of 16S rRNA (section D'). To determine whether there are similar sequences in other bacteria, which occupy similar accessible surface locations, we treated 30S ribosomes from Azotobacter vinelandii and Bacillus stearothermophilus with RNase T(1). In each case, a fragment of RNA about 25 nucleotides in length containing the 3' OH end of 16S rRNA and a fragment of about 60 nucleotides in length similar, but not identical, in oligonucleotide composition to section D' of E. coli 16S rRNA were obtained from nuclease-treated 30S ribosomes. These data indicate that, although the primary structure at the 3' end and the middle (section D') of the various 16S rRNA's is not completely conserved, their respective conformations are conserved. A number of identical oligonucleotides were found in the low-molecular-weight fraction obtained from RNase T(1)-treated E. coli, A. vinelandii, and B. stearothermophilus 30S ribosomes. These results show that identical RNase T(1)-sensitive sequences are present in all three bacteria. Hydrolysis of these regions leads to the production of the fragments 25 and 60 nucleotides in length.     

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.     

Studies on the sequence of the 3'-terminal region of turnip-yellow-mosaic-virus RNA.

A fragment representing the 3'-terminal 'tRNA-like' region of turnip yellow mosaic (TYM) virus RNA has been purified following incubation of intact TYM virus RNA with Escherichia coli 'RNase P'. This fragment, which is 112+3-nucleotides long has been completely digested with T1 RNase and pancreatic RNase and all the oligonucleotides present in such digests have been sequenced using 32P-end labelling techniques in vitro. The TYM virus RNA fragment is free of modified nucleosides and does not contain a G-U-U-C-R sequence. Using nuclease P1 from Penicillium citrinum, the sequence of 26 nucleotides from the 5' end and 16 nucleotides from the 3' end of this fragment has been deduced. The nucleotide sequence at the 5' end of the TYM virus RNA fragment indicates that this fragment includes the end of the TYM virus coat protein gene.     

Application of a rapid gel method to the sequencing of fragments of 16S ribosomal RNA from Escherichia coli.

A gel sequencing method has been applied to two 5' end-labelled fragments of the 16S ribosomal RNA from E. coli. The procedure involves partial enzymatic hydrolysis by ribonucleases T1, U2 or A, in order to generate series of end-labelled subfragments terminating in guanine, adenine, or pyrimidine residues, respectively. The two fragments concerned were approximately 75 and 90 nucleotides in length, and both arose from the 3' region of the 16S RNA. The sequences deduced are compared with the published sequence of 16S RNA, and contribute information to the final ordering of the ribonuclease T1 oligonucleotides in the latter, as well as revealing some probable errors.     

A ribonucleoprotein fragment of the 30 S ribosome of E. coli: evidence for long range RNA-RNA interactions.

A stable homogeneous ribonucleoprotein fragment of the 30 S ribosomal subunit of E. coli has been prepared by mild nuclease digestion and heating in a constant ionic environment. The fragment contains about half of the 16 S ribosomal RNa and six proteins: S4, S7, S9, S13, S16 and S19. The RNA moiety contains the reported binding sites of all six proteins. After deproteinization, 80% of the RNA migrated as two major electrophoretic bands, which were isolated and sequenced. Each band contained sequences from the 5' and 3' thirds of the 16 S RNA but none from the central third. That these two noncontiguous RNA domains migrated together electrophoretically in Mg++-containing gels after deproteinization constitutes direct evidence that the 16 S RNA is folded in the intact ribosome so as to bring the two domains close together and that there are RNA-RNA interactions between them in the presence of Mg++.     

Preparation and sequencing of the cloacin fragment of Streptomyces aureofaciens 16S RNA

A fast method for isolation of a 3'-terminal fragment of Streptomyces aureofaciens 16S RNA was developed. The procedure involves reaction of 70S ribosomes with cloacin DF13 and subsequent fractionation of the reaction mixture by polyacrylamide gel electrophoresis. The cloacin fragment was eluted from the gel and used directly for 3'-end labeling with cytidine-3',5'-[5'-32P]bisphosphate. The labeled RNA fragment was sequenced by the enzymatic method. It consists of 50 nucleotides and has the sequence 5'-GUCGUAACAAGGUAACCGUACCGGA-AGGUGCGGUUGGAUCACCUCCUUUCOH. The differences from the E. coli and Bacillus sequences and their possible influence on the rate and specificity of polypeptide synthesis are discussed.     

Non-ribosomal nucleotide sequences in 7-S RNA, the immediate precursor of 5.8-S ribosomal RNA in yeast.

The topography and the length of the non-ribosomal sequences present in 7-S RNA, the immediate precursor of 5.8-S ribosomal RNA, from the yeast Saccharomyces carlsbergensis were determined by analyzing the nucleotide sequences of the products obtained after complete digestion of 7-S RNA with RNase T1. The results show that 7-S RNA contains approximately 150 non-ribosomal nucleotides. The majority (90%) of the 7-S RNA molecules was found to have the same 5'-terminal pentadecanucleotide sequence as mature 5.8-S rRNA. The remaining 10% exhibited 5'-terminal sequences identical to those of 5.9-S RNA, which has the same primary structure as 5.8-S rRNA except for a slight extension at the 5' end [Rubin, G.M. (1974) Eur. J. Biochem. 41, 197--202]. These data show that the non-ribosomal nucleotides present in 7-S RNA are all located 3'-distal to the mature 5.8-S rRNA sequence. Moreover, it can be concluded that 5.9-S RNA is a stable rRNA rather than a precursor of 5.8-S rRNA. The 3'-terminal sequence of 5.8-S rRNA (U-C-A-U-U-UOH) is recovered in a much longer oligonucleotide in the T1 RNase digest of 7-S RNA having the sequence U-C-A-U-U-U-(C-C-U-U-C-U-C)-A-A-A-C-A-(U-U-C-U)-Gp. The sequences enclosed in brackets are likely to be correct but could not be established with absolute certainty. The arrow indicates the bond cleaved during processing. The octanucleotide sequence -A-A-A-C-A-U-U-C- located near the cleavage site shows a remarkable similarity to the 5'-terminal octanucleotide sequence of 7-S RNA (-A-A-A-C-U-U-U-C-). We suggest that these sequences may be involved in determining the specificity of the cleavages resulting in the formation of the two termini of 5.8-S rRNA.     

Secondary structure of the 5'-terminal region of the 18S ribosomal RNA5.3S fragment from the rat liver

Two small RNA fragments, 5,3S and 4,7S, were observed in gel electrophoretic analysis of RNA of the 40S ribosomal subunit of rat liver. 5,3S RNA (134-136 nucleotides long) proved to be 5'-terminal fragment of 18S ribosomal RNA, whereas 4,7 RNA is the degradation product of 5,3S RNA with 27-28 5'-terminal nucleotides lost. The secondary structure of 5,3S RNA was probed with two structure-specific nucleases, S1 nuclease and the double-strand specific cobra venom endoribonuclease. The nuclease digestion data agree well with the computer generated secondary structure model for 5,3S RNA. This model predicts that the 5'-terminal part of rat liver ribosomal 18S RNA forms an independent structural domain. The affinity chromatography experiments with the immobilized 5,3S fragment show that 5,3S RNA does not bind rat liver ribosomal proteins.     

Probing the phosphates of the Escherichia coli ribosomal 16S RNA in its naked form, in the 30S subunit, and in the 70S ribosome

Ethylnitrosourea is an alkylating reagent which preferentially modifies phosphates in nucleic acids. It was used to map phosphates in naked Escherichia coli 16S rRNA engaged in tertiary interactions through hydrogen bonds or ion coordination. Of the phosphates, 7% are found involved in such interactions, and 57% of them are located in loops or interhelical regions, where they are involved in maintaining local intrinsic structures or long-distance tertiary interactions. The other phosphates (43%) are found in helical regions. These phosphates often occur at the proximity of bulged nucleotides or in irregular helices containing noncanonical base pairs (and bulges) and are assumed to bind cations in order to neutralize negative charges and to stabilize unusual phosphate backbone folding. In the 30S subunit, ENU allowed mapping of phosphates in contact with proteins. The RNA is not uniformly engaged in RNA/protein interactions. Regions 1-51, 250-310, 567-612, 650-670, and 1307-1382 are particularly buried whereas the 3'-terminal domain and the 5'-proximal region (nucleotides 53-218) are exposed. The conformation of 16S rRNA is not drastically affected by protein binding, but conformational adjustments are detected in several defined regions. They are found in the 5' domain (region 147-172), in the central domain (region 827-872), in the 3' major domain (nucleotides 955-956, 994, 1054, 1181, 1257, and 1262-1263), and in the 3'-terminal domain (around 1400). The 50S subunit shields clusters of phosphates located at the subunit interface. The most extensive protections are observed in the 3'-terminal domain (1490-1542), in the central region of the molecule (770-930), and in the upper 3' major domain.(ABSTRACT TRUNCATED AT 250 WORDS)     

Terminal nucleotide sequences of 17-S ribosomal RNA and its immediate precursor 18-S RNA in yeast.

The 5' and 3'-terminal nucleotide sequences of 17-S rRNA and its immediate precursor 18-S RNA from the yeast Saccharomyces carlsbergensis have been analysed. Identification of the terminal oligonucleotides, as present in Ti ribonuclease digests, was performed by diagonal procedures. The major (molar yield 0.9) 5'-terminal oligonucleotide (molar yield 0.15) with the overall composition pU (U2,C2)G was observed. 18-S precursor RNA was found to contain the same 5'-terminal sequences as 17-S rRNA. However, the 3'-terminal sequences of the two types of RNA appeared to be different. The 17-S rRNA yields the oligonucleotide A-U-C-A-U-U-AOH while at least half of the 18-S RNA molecules contain the sequence U-U-U-C-A-A-U-AOH. In addition 18-S RNA yields several minor 3'-terminal oligonucleotides which appear to be structurally related to the major 3'-terminal sequence. These results demonstrate that the extra nucleotides in 18-S RNA relative to 17-S RNA are located exclusively at the 3'-terminus of the 18-S RNA molecule. The possibility that the 3'-terminal nucleotide sequence of 18-S RNA plays a role in the maturation process is discussed.     

Specific ribonucleoprotein fragments from 40-S ribosomal subunits.

Well-defined ribonucleoprotein fragments, resulting from the action of endogenous nuclease on 40-S subunits, were able to be separated when using high concentrations of LiCl. The ribonucleoproteins obtained sedimented at 12, 17 S, 23 S and 30 S and contained 8 S, 12 S and 17 S RNA, respectively, associated with a few proteins. The proteins extracted from the fragments were [3H] labeled by reductive methylation and their molar proportion was determined. The smallest fragment (12, 17 S) contained only three proteins, S8, S9 and S24. The 23-S and 30-S materials contained some proteins in common, S15, S19, S22, S25; S16 was found mainly in 30 S. Two proteins, S26 and "protein y" were found mainly in 23 S material. Thus, these results can give information on the relative location of certain proteins in the 40-S subunits.     

Characterization of 20-S and 40-S non-polysomal cytoplasmic messenger ribonucleoprotein particles from rat liver

Two populations of free messenger ribonucleoprotein (mRNP) particles, sedimenting at 20 S and 40 S respectively, were isolated from a rat liver postpolysomal supernatant. After treatment with 0.5 M KCl and recentrifugation through a sucrose layer, the mRNP particles were characterized with respect to their low-molecular-weight RNA and protein components. 40-S and 20-S particles show very different RNA patterns. Four distinct low-molecular-weight RNA species of approximately 105, 139, 187 and 256 nucleotides were found as components of the 40-S mRNPs. The 20-S mRNP particles contain one major low-Mr RNA species of approximately 243 nucleotides and a characteristic pattern of low-Mr RNAs similar to the one found in nuclear ribonucleoprotein particles. In contrast to the low-Mr RNAs found in nuclear RNP particles most of the low-Mr RNA species present in 20-S and 40-S mRNP particles are rapidly labeled after [3H]orotate administration. Whereas the low-Mr RNA composition of 20-S and 40-S mRNP particles is very different, the protein patterns of both mRNP complexes are very similar. Six major polypeptides with the following molecular weights of 117000, 79800, 76700, 53800, 43900, 36300 and several minor ones were found in both 20-S and 40-S mRNPs. In a cell-free system from wheat germs neither 20-S nor 40-S mRNP particles stimulated the incorporation of [3H]leucine into proteins. However, phenol-extracted RNA from 20-S and 40-S mRNPs stimulated total protein synthesis 16-fold and 3-fold, respectively. Furthermore, the RNA from both mRNP pools directed the synthesis of albumin in vitro.     

Relationship Between Moloney Murine Leukemia and Sarcoma Virus RNAs: Purification and Hybridization Map of Complementary DNAs from Defined Regions of Moloney Murine Sarcoma Virus 124

Complementary DNAs (cDNA's) specific for various regions of the Moloney murine sarcoma virus (MSV) 124 RNA genome were prepared by cross-hybridization techniques. A cDNA specific for the first 1,000 nucleotides adjacent to the RNA 3' end (cDNA 3') was prepared and shown to also be complementary to the 3'-terminal 1,000 nucleotides of a related Moloney murine leukemia virus (MLV) genome. A cDNA complementary to the "MSV-specific" portion of the MSV 124 genome was prepared. This cDNA was shown not to anneal to Moloney MLV RNA and to anneal to a portion of the viral RNA of about 1,500 to 1,800 nucleotides in length, located 1,000 nucleotides from the 3' end of MSV RNA. A cDNA common to the genome of MSV and MLV was also obtained and shown to anneal to the 5'-terminal two-thirds, as well as to the 3'-terminal 1,000 nucleotides, of the MSV RNA genome. This cDNA also annealed to the RNA from MLV and mainly to the 5'-terminal half of the MLV genome. It is concluded that the 6-kilobase Moloney MSV 124 RNA genome has a sequence arrangement that includes (i) a 3' portion of about 1,000 nucleotides, which is also present at the 3' terminus of MLV; (ii) an MSV-specific region, not shared with MLV, which extends between 1,000 and 2,500 nucleotides from the 3' terminus; and (iii) a second "common" region, again shared with MLV, which extends from 2,500 nucleotides to the 5' terminus. This second common region appears to be located in the 5' half of the 10-kilobase MLV genome as well. Experiments in which a large excess of cold MLV cDNA was annealed to (3)H-labeled polyadenylic acid-containing fragments of MSV RNA gave results consistent with this arrangement of the MSV genome.     

Phylogenetic comparative chemical footprint analysis of the interaction between ribonuclease P RNA and tRNA.

Ribonuclease P RNA is the catalytic moiety of the ribonucleoprotein enzyme that endonucleolytically cleaves precursor sequences from the 5' ends of pre-tRNAs. The bacterial RNase P RNA-tRNA complex was examined with a footprinting approach, utilizing chemical modification to determine RNase P RNA nucleotides that potentially contact tRNA. RNase P RNA was modified with dimethylsulfate or kethoxal in the presence or absence of tRNA, and sites of modification were detected by primer extension. Comparison of the results reveals RNase P bases that are protected from modification upon binding tRNA. Analyses were carried out with RNase P RNAs from three different bacteria: Escherichia coli, Chromatium vinosum and Bacillus subtilis. Discrete bases of these RNAs that lie within conserved, homologous portions of the secondary structures are similarly protected. One protection among all three RNAs was attributed to the precursor segment of pre-tRNA. Experiments using pre-tRNAs containing precursor segments of variable length demonstrate that a precursor segment of only 2-4 nucleotides is sufficient to confer this protection. Deletion of the 3'-terminal CCA sequence of tRNA correlates with loss of protection of a particular loop in the RNase P RNA secondary structure. Analysis of mutant tRNAs containing sequential 3'-terminal deletions suggests a relative orientation of the bound tRNA CCA to that loop.