Identification and assignment of base pairs in four helical segments of Bacillus megaterium ribosomal 5S RNA and its ribonuclease T1 cleavage fragments by means of 500-MHz proton homonuclear Overhauser enhancements.

Three different fragments of Bacillus megaterium ribosomal 5S RNA have been produced by enzymatic cleavage with ribonuclease T1. Fragment A consists of helices II and III, fragment B contains helix IV, and fragment C contains helix I of the universal 5S rRNA secondary structure. All (eight) imino proton resonances in the downfield region (9-15 ppm) of the 500-MHz proton FT NMR spectrum of fragment B have been identified and assigned as G80.C92-G81.C91-G82.C90-A83.++ +U89-C84.G88 and three unpaired U's (U85, U86, and U87) in helix IV by proton homonuclear Overhauser enhancement connectivities. The secondary structure in helix IV of the prokaryotic loop is completely demonstrated spectroscopically for the first time in any native or enzyme-cleaved 5S rRNA. In addition, G21.C58-A20.U59-G19.C60-A18.U61 in helix II, U32.A46-G31.C47-C30.G48-C29.G49 in helix III, and G4.C112-G5.C111-U6.G110 in the terminal stem (helix I) have been assigned by means of NOE experiments on intact 5S rRNA and its fragments A and C. Base pairs in helices I-IV of the universal secondary structure of B. megaterium 5S RNA are described.     

Analysis of a sequence region of 5S RNA from E. coli cross-linked in situ to the ribosomal protein L25.

70S ribosomes from E. coli were chemically cross-linked under conditions of in vitro protein biosynthesis. The ribosomal RNAs were extracted from reacted ribosomes and separated on sucrose gradients. The 5S RNA was shown to contain the ribosomal protein L25 covalently bound. After total RNase T1 hydrolysis of the covalent RNA-protein complex several high molecular weight RNA fragments were obtained and identified by sequencing. One fragment, sequence region U103 to U120, was shown to be directly linked to the protein first by protein specific staining of the particular fragment and second by phosphor cellulose chromatography of the covalent RNA-protein complex. The other two fragments, U89 to G106 and A34 to G51, could not be shown to be directly linked to L25 but were only formed under cross-linking conditions. While the fragment U89 to G106 may be protected from RNase T1 digestion because of a strong interaction with the covalent RNA-protein complex, the formation of the fragment A34 to G51 is very likely the result of a double monovalent modification of two neighbouring guanosines in the 5S RNA. The RNA sequences U103 to U120 established to be in direct contact to the protein L25 within the ribosome falls into the sequence region previously proposed as L25 binding site from studies with isolated 5S RNA-protein complexes.     

New model of tertiary structure of plant 5S rRNA is confirmed by digestions with alpha-sarcin

The cytotoxin alpha-sarcin was employed to test the model of secondary and tertiary structures of plant 5S rRNAs, which we recently proposed [(1990) Int. J. Biol. Macromol. (in press)]. alpha-Sarcin is a novel ribonuclease that hydrolyzes phosphodiester bonds adjacent to purines in nucleic acids. The digestion pattern obtained for lupin and wheat germ 5S rRNAs strongly suggests the existence of tertiary interactions between residues C34, C35, C36, A37 and G85, G86, G87, U88 as previously proposed. The results on the secondary structure of plant 5S rRNA are in line with a previously proposed model.     

The binding site for ribosomal protein complex L8 within 23 s ribosomal RNA of Escherichia coli

The ribosomal protein complex L8 of Escherichia coli consists of two dimers of protein L7/L12 and one monomer of protein L10. This pentameric complex and ribosomal protein L11 bind in mutually cooperative fashion to 23 S rRNA and protect specific fragments of the latter from digestion with ribonuclease T1. Oligonucleotides protected either by the L8 complex alone or by the complex plus protein L11 were isolated from such digests and shown to rebind specifically to these proteins. They were also subjected to nucleotide sequence analysis. The longest oligonucleotide, protected by the L8 complex alone, consisted of residues 1028-1124 of 23 S rRNA and included all the other RNA fragments produced in this study. Previously, protein L11 had been shown to protect residues 1052-1112 of 23 S rRNA. It is concluded that the binding sites for the L8 protein complex and for protein L11 are immediately adjacent within 23 S rRNA of E. coli.     

5S RNA structure and interaction with transcription factor A. 1. Ribonuclease probe of the structure of 5S RNA from Xenopus laevis oocytes

The structure of Xenopus laevis oocyte (Xlo) 5S ribosomal RNA has been probed with single-strand-specific ribonucleases T1, T2, and A with double-strand-specific ribonuclease V1 from cobra venom. The digestion of 5'- or 3'-labeled renatured 5S RNA samples followed by gel purification of the digested samples allowed the determination of primary cleavage sites. Results of these ribonuclease digestions provide support for the generalized 5S RNA secondary structural model derived from comparative sequence analysis. However, three putative single-stranded regions of the molecule exhibited unexpected V1 cuts, found at C36, U73, U76, and U102. These V1 cuts reflect additional secondary structural features of the RNA including A.G base pairs and support the extended base pairing in the stem containing helices IV and V which was proposed by Stahl et al. [Stahl, D. A., Luehrsen, K. R., Woese, C. R., & Pace, N. R. (1981) Nucleic Acids Res. 9, 6129-6137]. A conserved structure for helix V having a common unpaired uracil residue at Xlo position 84 is proposed for all eukaryotic 5S RNAs. Our results are compared with nuclease probes of other 5S RNAs.     

Mutual induced fit binding of Xenopus ribosomal protein L5 to 5S rRNA

A library of random mutations in Xenopus ribosomal protein L5 was generated by error-prone PCR and used to delineate the binding domain for 5S rRNA. All but one of the amino acid substitutions that affected binding affinity are clustered in the central region of the protein. Several of the mutations are conservative substitutions of non-polar amino acid residues that are unlikely to form energetically significant contacts to the RNA. Thermal denaturation, monitored by circular dichroism (CD), indicates that L5 is not fully structured and association with 5S rRNA increases the t(m) of the protein by 16 degrees C. L5 induces changes in the CD spectrum of 5S rRNA, establishing that the complex forms by a mutual induced fit mechanism. Deuterium exchange reveals that a considerable amount of L5 is unstructured in the absence of 5S rRNA. The fluorescence emission of W266 provides evidence for structural changes in the C-terminal region of L5 upon binding to 5S rRNA; whereas, protection experiments demonstrate that the N terminus remains highly sensitive to protease digestion in the complex. Analysis of the amino acid sequence of L5 by the program PONDR predicts that the N and C-terminal regions of L5 are intrinsically disordered, but that the central region, which contains three essential tyrosine residues and other residues important for binding to 5S rRNA, is likely to be structured. Initial interaction of the protein with 5S rRNA likely occurs through this region, followed by induced folding of the C-terminal region. The persistent disorder in the N-terminal domain is possibly exploited for interactions between the L5-5S rRNA complex and other proteins.     

The binding site for ribosomal protein L11 within 23 S ribosomal RNA of Escherichia coli

Ribosomal protein L11 of Escherichia coli was bound to 23 S rRNA and the resultant complex was digested with ribonuclease T1. A single RNA fragment, protected by protein L11, was isolated from such digests and was shown to rebind specifically to protein L11. The nucleotide sequence of this RNA fragment was examined by two-dimensional fingerprinting of ribonuclease digests. It proved to be 61 residues long and the constituent oligonucleotides could be fitted perfectly between residues 1052 and 1112 of the nucleotide sequence of E. coli 23 S rRNA.     

The 5S rRNA-protein complex of Escherichia coli studied by carbodiimide modification]

5S rRNA-protein complex has been reconstituted from 5S rRNA and total protein of large (L) ribosomal subunit of Escherichia coli. The complex consists of 5S rRNA and 3 proteins only: L5, L18, L25. A water-soluble carbodiimide [N-cyclohexyl-N'-(2-morpholinoethyl)-carbodiimide-methyl-p-toluolsulp honate] cross-links L18 to 5S rRNA at pH 7.2 and L25 to 5S rRNA at pH 7.7. This pH-dependence of cross-linked proteins is a consequence of the difference in stability of the initial complex: the complex has all three proteins at pH 7.7 but L18 mainly at pH 7.2. It has been shown that L18 stimulates the chemical modification of U87 and U89 residues of 5S rRNA by carbodiimide. A model of L18-5S rRNA complex has been proposed.     

A role for aromatic amino acids in the binding of Xenopus ribosomal protein L5 to 5S rRNA

The formation of the Xenopus L5-5S rRNA complex depends on nonelectrostatic interactions. Fluorescence assays with 1-anilino-8-naphthalenesulfonate demonstrate that a hydrophobic region on L5 becomes exposed upon removal of bound 5S rRNA by treatment with ribonucleases. Several conserved aromatic amino acids, mostly tyrosines, were identified by comparative sequence analysis and changed individually to alanine. Substitution with alanine at any of three positions, Y86, Y99, or Y226, essentially abolishes RNA-binding activity, whereas those made at Y95 and Y207 have more modest effects. Replacement with phenylalanine at Y86 and Y226 does not change binding affinity, indicating that the aromatic ring of the side chain, not the hydroxyl group, is the critical functionality for binding. Alternatively, the phenolic hydroxyls at Y99 and Y207 do contribute to binding. The structural integrity of the mutant proteins was assessed using thermal denaturation and limited digestion with proteases. The T(m) of Y99A is 10 degrees C lower than that of the wild-type protein, and there are some differences in the protease digestion patterns that together indicate the structure of this mutant has been significantly perturbed. The structures of the other variants are not detectably different from the wild-type protein. These results provide evidence that intermolecular stacking interactions involving at least two tyrosine residues, Y86 and Y226, are necessary for formation of the L5-5S rRNA complex and can account, at least in part, for the contribution nonelectrostatic interactions make to the free energy of binding.     

A ribonuclease-resistant region of 5S RNA and its relation to the RNA binding sites of proteins L18 and L25.

An RNA fragment, constituting three subfragments of nucleotide sequences 1-11, 69-87 and 89-120, is the most ribonuclease-resistant part of the native 5S RNA of Escherichia coli, at 0 degrees C. A smaller fragment of nucleotide sequence 69-87 and 90-110 is ribonuclease-resistant at 25 degrees. Degradation of the L25-5S RNA complex with ribonuclease A or T2 yielded RNA fragments similar to those of the free 5S RNA at 0 degrees C and 25 degrees C; moreover L25 remained strongly bound to both RNA fragments and also produced some opening of the RNA structure in at least two positions. Protein L18 initially protected most of the 5S RNA against ribonuclease digestion, at 0 degrees C, but was then gradually released prior to the formation of the larger RNA fragment. It cannot be concluded, therefore, as it was earlier (Gray et al., 1973), that this RNA fragment contains the primary binding site of L18.     

Detailed analysis of RNA-protein interactions within the bacterial ribosomal protein L5/5S rRNA complex

The crystal structure of ribosomal protein L5 from Thermus thermophilus complexed with a 34-nt fragment comprising helix III and loop C of Escherichia coli 5S rRNA has been determined at 2.5 A resolution. The protein specifically interacts with the bulged nucleotides at the top of loop C of 5S rRNA. The rRNA and protein contact surfaces are strongly stabilized by intramolecular interactions. Charged and polar atoms forming the network of conserved intermolecular hydrogen bonds are located in two narrow planar parallel layers belonging to the protein and rRNA, respectively. The regions, including these atoms conserved in Bacteria and Archaea, can be considered an RNA-protein recognition module. Comparison of the T. thermophilus L5 structure in the RNA-bound form with the isolated Bacillus stearothermophilus L5 structure shows that the RNA-recognition module on the protein surface does not undergo significant changes upon RNA binding. In the crystal of the complex, the protein interacts with another RNA molecule in the asymmetric unit through the beta-sheet concave surface. This protein/RNA interface simulates the interaction of L5 with 23S rRNA observed in the Haloarcula marismortui 50S ribosomal subunit.     

Nucleotide sequences of chloroplast 5S ribosomal ribonucleic acid in flowering plants.

Evidence for the sequence of duckweed (Lemna minor) chloroplast 5S rRNA was derived from the analysis of partial and complete enzymic digests of the 32P-labelled molecule. The possible sequence of the chloroplast 5S rRNA from three other flowering plants was deduced by complete digestion with T1 ribonuclease and comparison of the sequences of the oligonucleotide products with homologous sequences in the duckweed 5S rRNA. This analysis indicates that the chloroplast 5S rNA species differ appreciably from their cytosol counterparts but bear a strong resemblance to one another and to the 5S rRNA species of prokaryotes. Structural features apparently common to all 5S rRNA molecules are also discussed.     

The nature of the 5''-linked 5'' nucleotide sequence at the 5'' end of rabbit globin messenger ribonucleic acid.

Poly(A)-containing messenger RNA isolated from rabbit reticulocytes as estimated by periodate oxidation and condensation with [3H]isoniazid has two oxidizable end groups per molecule of mol. wt. 220000. When the mRNA is subjected to stepwise degradation by beta-elimination, only one oxidizable end-group is found. This indicates that one of the 2',3' hydroxyl end-groups is linked through the normal 3'--5' phosphodiester bond, but that the other is linked in such a way that after stepwise degradation no new 2',3 hydroxyl group is revealed. This structure could be a 5'-linked 5'-phospho di- or tri-ester. On digestion with ribonuclease the isoniazid-labelled RNA produced oligonucleotide hydrazones consistent with a poly(A) sequence at the 3' end plus fragments that are not found after stepwise degradation. These fragments have a charge of --6 and --8 from pancreatic ribonuclease or --7 from ribonuclease T1 digestion. These charges are changed to --3.4 and --4.1 after pancreatic ribonuclease, ribonuclease T2 and alkaline phosphatase digestion. methyl-3H-labelled-poly(A)-containing RNA isolated from late erythroid cells contain a methyl-labelled fragment resistant to endonuclease and phosphodiesterase II digestion. After digestion with phosphodiesterase I this fragment produces methyl-3 H-labelled nucleotides with the electrophoretic mobility of pm7G and pAm. It is concluded that globin mRNA has the 5' sequences m7G(5')ppp'AmpYpGp ... and m7G(5')pppAmpApGpYp.     

Characterization of a novel association between two trypanosome-specific proteins and 5S rRNA

P34 and P37 are two previously identified RNA binding proteins in the flagellate protozoan Trypanosoma brucei. RNA interference studies have determined that the proteins are essential and are involved in ribosome biogenesis. Here, we show that these proteins interact in vitro with the 5S rRNA with nearly identical binding characteristics in the absence of other cellular factors. The T. brucei 5S rRNA has a complex secondary structure and presents four accessible loops (A to D) for interactions with RNA-binding proteins. In other eukaryotes, loop C is bound by the L5 ribosomal protein and loop A mainly by TFIIIA. The binding of P34 and P37 to T. brucei 5S rRNA involves the LoopA region of the RNA, but these proteins also protect the L5 binding site located on LoopC.     

芹菜(Apium graveolens L.)叶细胞质5SrRNA的序列测定

应用Gupta等和Tanaka等建立的RNA序列双向直读技术,并辅以部分酶解法、化学法等,测定了芹菜叶细胞质的5SrRNA的全序列:与菠菜和蕃茄细胞质已知5SrRNA序列进行了比较,发现它们之间在序列上有高度的保守性。     

Altered features in the secondary structure of Vicia faba 5.8s rRNA.

We have re-examined the nucleotide sequence of Vicia faba (broad bean) 5.8S rRNA using partial chemical degradation and a new approach to high temperature (65-80 degrees C) sequencing gels. The results indicate that the secondary structure was not completely disrupted in previous studies (Tanaka, Y., Dyer, T.A. and Brownlee, G.G. (1980) Nucleic Acid Res. 8, 1259-1272) and explain ambiguities between the nucleotide sequence and T1 ribonuclease digests. Despite this revision, estimates in the secondary structure suggest that this 5.8S rRNA differs from previously examined examples in two respects, more open conformations in both the "GC-rich" and "AU-rich" stems. The secondary structure was probed under a variety of ionic conditions using limited pancreatic and T1 ribonuclease digestion and rapid gel sequencing techniques. These studies and theoretical considerations generally supported the "burp gun" model previously proposed for all 5.8S rRNAs and were inconsistent with the recently suggested "cloverleaf" configuration. More importantly, they were also consistent with more open stem structures in this higher plant.     

Effect of 2''-O-methylation on the structure of mammalian 5.8S rRNAs and the 5.8S-28S rRNA junction

The mammalian 5.8S rRNA contains a partially 2'-O-methylated uridylic acid residue at position 14 which is largely or entirely methylated in the cytoplasm (Nazar, R.N., Sitz, T.O. and Sommers, K.D. (1980) J. Mol. Biol. 142, 117-121). The effect of this methylation on the 5.8S RNA structure and 5.8-28S rRNA junction was investigated using both chemical and physical approaches. Electrophoretic studies indicated that the free 5.8S rRNA can take on at least two different conformations and that the 2'-O-methylation at U14 restricts the molecule to the more hydrodynamically open form. Structural studies using limited pancreatic or T1 ribonuclease digestion indicated that the methylated conformation was more susceptible to digestion, consistent with a more open tertiary structure. Modification-exclusion studies indicated that the first 29 nucleotides at the 5' end and residues 140 through 158 at the 3' end affect the 5.8S-28S rRNA interaction, supporting previous suggestions that the 5.8S RNA interacts with its cognate high molecular weight component through its termini. These results also suggested that the 2'-O-methylated uridylic acid residue plays a role in the 5.8S-28S rRNA interaction and thermal denaturation studies confirmed this by showing that methylation destabilizes the 5.8S-28S rRNA junction. The 5.8-28S rRNA interaction appears to be more complex than previously believed.