NMR evidence for the existence of two native conformations of 5S RNA

Specific features of 5S rRNA structure - its interactions with macromolecules and possible functions

Small non-coding RNAs are today a topic of great interest for molecular biologists because they can be regarded as relicts of a hypothetical "RNA world" which, apparently, preceded the modern stage of organic evolution on Earth. The small molecule of 5S rRNA (approximately 120 nucleotides) is a component of large ribosomal subunits of all living beings (5S rRNAs are not found only in mitoribosomes of fungi and metazoans). This molecule interacts with various protein factors and 23S (28S) rRNA. This review contains the accumulated data to date concerning 5S rRNA structure, interactions with other biological macromolecules, intracellular traffic, and functions in the cell.

Mapping tRNA and 5S RNA tertiary structures by charge dependent Fe(II)-catalyzed cleavage

Chemical and enzymatic footprinting experiments have made it possible to identify protein binding sites in DNA and RNA, and to localize structural differences within nucleic acids to a resolution of a single base pair. We show here that by combining three reagents, Fe(II).EDTA2-, Fe(II).EDDA and Fe2+, differential maps of sites in RNA that vary in their local conformation and/or charge can be constructed. Comparison of profiles with respect to controls in the absence of a counterion such as Mg2+ allows analysis of sites responsive to tertiary structure. A single site that is labile to metals such as Pb2+ exists in tRNA(Phe) and a number of other tRNA's; this site is hyper-reactive to Fe(II), but not to the other probes. Scission induced by the neutral complex, Fe(II).EDDA, offers the most general measure of surface accessibility, since its distribution about the target molecule is insensitive to charge. Enhanced cleavage by Fe(II) relative to the other agents is detected at several adjacent sites in 5S RNA, consistent with conformational mobility. Protection at a series of positions in the arm formed by loops E and D with helix IV suggests further that at low temperature this arm interacts with loop A and helix I.

Different conformational forms of Escherichia coli and rat liver 5S rRNA revealed by Pb(II)-induced hydrolysis

Different stable forms of Escherichia coli and rat liver 5S rRNA have been probed by Pb(II)-induced hydrolysis. In the native A forms of 5S rRNA, Pb2+ reveal single-stranded RNA stretches and regions of increased conformational flexibility or distorted by the presence of bulged nucleotides. Hydrolysis of urea/EDTA-treated E. coli 5S rRNA (B form) shows the presence of two strong helical domains; helix A retained from the A form and a helix composed of RNA regions G33-C42 and G79-C88. Other RNA regions resistant to hydrolysis may be involved in alternative base pairing, causing conformational heterogeneity of that form. Pb(II)-induced hydrolysis distinguishes two different forms of rat liver 5S rRNA; the native A form and the form obtained by renaturation of 5S rRNA in the presence of EDTA. Pb(II)-hydrolysis data suggest that both forms are highly structured. In the latter form, the orientation of the bulged C66 is changed with respect to helix B. At the same time, a new helical segment is possibly formed, composed of nucleotides from helix C and loop c on one side and from helix E and loop d' on the other.

Three-dimensional model of Escherichia coli ribosomal 5 S RNA as deduced from structure probing in solution and computer modeling

The conformation of Escherichia coli 5 S rRNA was investigated using chemical and enzymatic probes. The four bases were monitored at one of their Watson-Crick positions with dimethylsulfate (at C(N-3) and A(N-1], with a carbodiimide derivative (at G(N-1) and U(N-3] and with kethoxal (at G(N-1, N-2]. Position N-7 of purine was probed with diethylpyrocarbonate (at A(N-7] and dimethylsulfate (at G(N-7]. Double-stranded or stacked regions were tested with RNase V1 and unpaired guanine residues with RNase T1. We also used lead(II) that has a preferential affinity for interhelical and loop regions and a high sensitivity for flexible regions. Particular care was taken to use uniform conditions of salt, magnesium, pH and temperature for the different enzymatic chemical probes. Derived from these experimental data, a three dimensional model of the 5 S rRNA was built using computer modeling which integrates stereochemical constraints and phylogenetic data. The three domains of 5 S rRNA secondary structure fold into a Y-shaped structure that does not accommodate long-range tertiary interactions between domains. The three domains have distinct structural and dynamic features as revealed by the chemical reactivity and the lead(II)-induced hydrolysis: domain 2 (loop B/helix III/loop C) displays a rather weak structure and possesses dynamic properties while domain 3 (helix V/region E/helix IV/loop D) adopts a highly structured and overall helical conformation. Conserved nucleotides are not crucial for the tertiary folding but maintain an intrinsic structure in the loop regions, especially via non-canonical pairing (A.G, G.U, G.G, A.C, C.C), which can close the loops in a highly specific fashion. In particular, nucleotides in the large external loop C fold into an organized conformation leading to the formation of a five-membered loop motif. Finally, nucleotides at the hinge region of the Y-shape are involved in a precise array of hydrogen bonds based on a triple interaction between U14, G69 and G107 stabilizing the quasi-colinearity of helices II and V. The proposed tertiary model is consistent with the localization of the ribosomal protein binding sites and possesses strong analogy with the model proposed for Xenopus laevis 5 S rRNA, indicating that the Y-shape model can be generalized to all 5 S rRNAs.

Comparative calorimetric studies on the dynamic conformation of plant 5S rRNA: II. Structural interpretation of the thermal unfolding patterns for lupin seeds and wheat germ

Thermal unfolding of 5S rRNA from wheat germ (WG) and lupin seeds (LS) was studied in solution. Experimental curves of differential scanning calorimetry (DSC) were resolved into particular components according to the thermodynamic model of two-state transitions. The DSC temperature profiles for WG and LS differ significantly in spite of very high similarities in the sequence of both molecules. Those results are interpreted according to a model of the secondary and tertiary molecular structure of 5S rRNA. A comparison of the 'nearest neighbour' model of interaction with the experimental thermodynamic results enables a complete interpretation of the process of the melting of its structures. In light of our observations, the crucial differences between both DSC melting profiles are mainly an outcome of different thermodynamic properties of the first helical fragment 'A' made up of 9 complementary base pairs. It contains 6 differences in the nucleotide sequence of both types of molecules, which still retain 9-meric double helixes. The temperature stability of his helix in WG is much lower than of the LS one. Moreover, the results supply evidence for a strong specific tertiary interaction between the two hairpin loops 'c' and 'e' in both 5S rRNA molecules, modulated by small differences in the thermodynamic properties of both 5S rRNA.

Ribosomal 5S RNA from Xenopus laevis oocytes: conformation and interaction with transcription factor IIIA

This review describes extensive studies on 5S rRNA from X laevis oocytes combining conformational analyses in solution (using a variety of chemical and enzymatic probes), computer modeling, site-directed mutagenesis, crosslinking and TFIIIA binding. The proposed 3-dimensional model adopts a Y-shaped structure with no tertiary interactions between the different domains of the RNA. The conserved nucleotides are not crucial for the tertiary folding but they maintain an intrinsic structure in the loop regions. The model was tested by the analysis of several 5S rRNA mutants. A series of 5S RNA mutants with defined block sequence changes in regions corresponding to each of the loop regions was constructed by in vitro transcription of the mutated genes. Our results show that none of the mutations perturbs the Y-shaped structure of the RNA, although they induce conformational changes restricted to the mutated regions. The interaction of the resulting 5S rRNA mutants with TFIIIA was determined by a direct binding assay. Only the mutations in the hinge region between the 3 helical domains have a significant effect on the binding for the protein. Finally, TFIIIA was crosslinked by the use of trans-diamminedichloroplatinum (II) to a region covering the fork region. Our results show that (i) the tertiary structure does not involve long-range interactions; (ii) the intrinsic structures in loops are strictly sequence-dependent; (iii) the hinge nucleotides govern the relative orientation of the 3 helical domains; (iv) TFIIIA recognizes essentially specific features of the tertiary structure of 5S rRNA.

500-MHz proton NMR evidence for two solution structures of the common arm base-paired segment of wheat germ 5S ribosomal RNA

The base-pair protons of the common arm duplex fragment of wheat germ (Triticum aestivum) ribosomal 5S RNA have been identified and assigned by means of 500-MHz proton NMR spectroscopy. The two previously reported extra base pairs within the fragment [Li et al. (1987) Biochemistry 26, 1578-1585] are now explained by the presence of two distinct solution structures of the common arm fragment (and its corresponding base-paired segment in intact 5S rRNA). The present conclusions are supported by one- and two-dimensional proton homonuclear Overhauser enhancements in H2O and by temperature variation and Mg2+ titration of the downfield 1H NMR spectrum. The difference between the two conformers is most likely due to difference in helical tightness. Some additional amino proton resonances have also been assigned.

An NMR study of the helix V-loop E region of the 5S RNA from Escherichia coli

Experiments are described that complete the assignment of the imino proton NMR spectrum of the fragment 1 domain from the 5S RNA of Escherichia coli. Most of the new assignments fall in the helix V-loop E portion of the molecule (bases 70-78 and 98-106), the region most sensitive to the binding of ribosomal protein L25. The spectroscopic data are incompatible with the standard, phylogenetically derived model for 5S RNA, which makes all the base pairs possible in loop E with the sequences aligned in parallel (C70-G106, C71-G105, etc.) [see Delihas et al. (1984) Prog. Nucleic Acid Res. Mol. Biol. 31, 161-190]. Furthermore, the alternative loop E model proposed for spinach chloroplast 5S RNA by Romby et al. [(1988) Biochemistry 27, 4721-4730] does not apply to the closely homologous 5S RNA from E. coli. The 5S RNAs from E. coli and spinach chloroplasts do not have the same secondary structures in solution despite their strong sequence homologies, and neither appears to conform to the standard model for 5S RNA in the loop E region.

Computer modeling from solution data of spinach chloroplast and of Xenopus laevis somatic and oocyte 5 S rRNAs

Detailed atomic models of a eubacterial 5 S rRNA (spinach chloroplast 5 S rRNA) and of a eukaryotic 5 S rRNA (somatic and oocyte 5 S rRNA from Xenopus laevis) were built using computer graphic. Both models integrate stereochemical constraints and experimental data on the accessibility of bases and phosphates towards several structure-specific probes. The base sequence was first inserted on to three-dimensional structural fragments picked up in a specially devised databank. The fragments were modified and assembled interactively on an Evans & Sutherland PS330. Modeling was finalized by stereochemical and energy refinement. In spite of some uncertainty in the relative spatial orientation of the substructures, the broad features of the models can be generalized and several conclusions can be reached: (1) both models adopt a distorted Y-shape structure, with helices B and D not far from colinearity; (2) no tertiary interactions exist between loop c and region d or loop e; (3) the internal loops, in particular region d, contain several non-canonical base-pairs of A.A, U.U and A.G types; (4) invariant residues appear to be more important for protein or RNA binding than for maintaining the tertiary structure. The models are corroborated by footprinting experiments with ribosomal proteins and by the analysis of various mutants. Such models help to clarify the structure-function relationship of 5 S rRNA and are useful for designing site-directed mutagenesis experiments.

Higher order structure of chloroplastic 5S ribosomal RNA from spinach

The secondary and tertiary structure of chloroplastic 5S ribosomal RNA from spinach was investigated by the use of several chemical and enzymatic structure probes. The four bases were monitored at one of their Watson-Crick base-pairing positions with dimethyl sulfate [at A(N1) and C(N3)] and with 1-cyclohexyl-3-(2-morpholinoethyl)carbodiimide metho-p-toluenesulfonate [at G(N1) and U(N3)]. Position N7 of purines was probed with diethyl pyrocarbonate (adenines) and with dimethyl sulfate (guanines). Ethylnitrosourea was used to probe phosphate involved in tertiary interaction or in cation coordination. In order to estimate the degree of stability of helices, the various chemical reagents were employed under "native" conditions (300 mM KCl and 20 mM magnesium at 37 degrees C), under "semidenaturing" conditions [1 mM ethylenediaminetetraacetic acid (EDTA) at 37 degrees C], and under denaturing conditions (1 mM EDTA at 90 degrees C). Unstructured regions were also tested with single-strand-specific nucleases T1, U2, and S1 and double-stranded or stacked regions with RNase V1 from cobra Naja naja oxiana venom. The results confirm the existence of the five helices and the two external loops proposed in the consensus model of 5S rRNA. However, the regions depicted as unpaired internal loops appear to be folded into a more complex conformation. A three-dimensional model derived from the present data and graphic modeling for a region encompassing helix IV, helix V, loop D, and loop E (nucleotides 70-110) is proposed. Nucleotides in the so-called loop E (73-79/100-106) display unusual features: Noncanonical base pairs (A-A and A-G) are formed, and three nucleotides (C75, U78, and U105) are bulging out. This region adopts an unwound and extended conformation that can be well suited for tertiary interactions or for protein binding. Several bases and phosphates candidate for the tertiary folding of the RNA were also identified.

A comparison of the solution structures and conformational properties of the somatic and oocyte 5S rRNAs of Xenopus laevis

The secondary and tertiary structures of Xenopus oocyte and somatic 5S rRNAs were investigated using chemical and enzymatic probes. The accessibility of both RNAs towards single-strand specific nucleases (T1, T2, A and S1) and a helix-specific ribonuclease from cobra venom (RNase V1) was determined. The reactivity of nucleobase N7, N3 and N1 positions towards chemical probes was investigated under native (5 mM MgCl2, 100 mM KCl, 20 degrees C) and semi-denaturing (1 mM EDTA, 20 degrees C) conditions. Ethylnitrosourea was used to identify phosphates not reactive towards alkylation under native conditions. The results obtained confirm the presence of the five helical stems predicted by the consensus secondary structure model of 5S rRNA. The chemical reactivity data indicate that loops C and D are involved in a number of tertiary interactions, and loop E folds into an unusual secondary structure. A comparison of the data obtained for the two types of Xenopus 5S rRNA indicates that the conformations of the oocyte and somatic 5S rRNAs are very similar. However, the data obtained with nucleases under native conditions, and chemical probes under semi-denaturing conditions, reveal that helices III and IV in the somatic 5S rRNA are less stable than the same structures in oocyte 5S rRNA. Using chimeric 5S rRNAs, it was possible to demonstrate that the relative resistance of oocyte 5S rRNA to partial denaturation in 4 M urea is conferred by the five oocyte-specific nucleotide substitutions in loop B/helix III. In contrast, the superior stability of oocyte 5S rRNA in the presence of EDTA is related to a single C substitution at position 79.

Effects of mutation on the downfield proton nuclear magnetic resonance spectrum of the 5S RNA of Escherichia coli

The imino proton spectra of several mutants of the 5S RNA of Escherichia coli are compared with that of the wild type. Three of the variants discussed are point mutations, and the fourth is a deletion mutant lacking bases 11-69 of the parent sequence, all obtained by site-directed mutagenesis techniques. The spectroscopic effects of mutation are limited in all cases, and the differences between normal and mutant spectra can be used to make or confirm the assignments of resonances. Several new assignments in the 5S spectrum are reported. Spectroscopic differences due to sequence differences permit the products of single genes within the 5S gene family to be distinguished and their fates followed by NMR.

Secondary structure of 5S RNA: NMR experiments on RNA molecules partially labeled with nitrogen-15

A method has been found for reassembling fragment 1 of Escherichia coli 5S RNA from mixtures containing strand III (bases 69-87) and the complex consisting of strand II (bases 89-120) and strand IV (bases 1-11). The reassembled molecule is identical with unreconstituted fragment 1. With this technique, fragment 1 molecules have been constructed 15N-labeled either in strand III or in the strand II-strand IV complex. Spectroscopic data obtained with these partially labeled molecules show that the terminal helix of 5S RNA includes the GU and GC base pairs at positions 9 and 10 which the standard model for 5S secondary structure predicts [see Delihas, N., Anderson, J., & Singhal, R. P. (1984) Prog. Nucleic Acid Res. Mol. Biol. 31, 161-190] but that these base pairs are unstable both in the fragment and in native 5S RNA. The data also assign three resonances to the helix V region of the molecule (bases 70-77 and 99-106). None of these resonances has a "normal" chemical shift even though two of them correspond to AU or GU base pairs in the standard model. The implications of these findings for our understanding of the structure of 5S RNA and its complex with ribosomal protein L25 are discussed.

Defining the binding site of Xenopus transcription factor IIIA on 5S RNA using truncated and chimeric 5S RNA molecules

The interaction of TFIIIA with deletion fragments of Xenopus 5S RNA has been quantified using a nitrocellulose filter binding assay. TFIIIA binding was found to be more sensitive to the deletion of nucleotides from the 5' terminus of the 5S RNA as opposed to the 3' terminus. These effects have been correlated to the changes in RNA secondary structure resulting from the deletions. Nucleotides 11-108 of the intact 5S RNA provide the necessary sequence and conformational information required for the binding of TFIIIA. Synthetic 5S RNA genes have been constructed so that in vitro transcription with T7 RNA polymerase yields mature 5S RNA. The transcription factor has a higher affinity for somatic vs. oocyte 5S RNA, similar to the differential affinity of TFIIIA for the two genes. Binding studies with chimeric 5S RNA molecules indicated that the increased binding strength of somatic 5S RNA is conferred by nucleotide substitutions in the 5' half of the molecule.

Does 5S RNA from E. coli have a pseudoknotted structure?

Chemical modification and limited enzymatic hydrolysis on isolated E. coli 5S RNA have provided informations on the secondary- and tertiary structure compatible with pseudoknotted structures for the A- and B-conformers of the molecule. Changes in the accessibility and reactivity of nucleotides in loop C and at the stem of helix IV in two different 5S RNA conformers are highly suggestive for interactions between bases C35 to C37 with G105 to G107 for the A-form and C38 to U40 and A94 to G96 with additional interactions of C35, C37 with G98 and G100 for the B-form. In both cases the molecules are folded forming pseudoknots and two quasi--continuous double stranded helices with coaxial stacking. The two structures are in perfect agreement with the biochemical data concerning the stability of the molecule and the chemical reactivities of individual nucleotides of the 5S RNA A- and B-conformers.

NMR evidence for dynamic secondary structure in helices II and III of the RNA of Escherichia coli

A new ribonuclease A (RNase A) resistant fragment of the 5S ribonucleic acid (RNA) from Escherichia coli has been isolated and characterized. This fragment comprises helix III and most of helix II of the parent molecule, a part of the 5S RNA molecule for which several energetically equivalent secondary structures have been proposed [De Wachter, R., Chen, M.-W., & Vandenberghe, A. (1984) Eur. J. Biochem. 143, 175-182]. The imino proton spectrum of this fragment has been studied by nuclear magnetic resonance methods at 500 MHz. The data obtained are readily rationalized in terms of one of the structures proposed for this region of 5S RNA. They also suggest that upon heating, this structure is replaced by a second, different one, consistent with the view that the helix II-helix III region of 5S RNA is able to switch between alternative structures. Among the products of the nucleolytic digestion of 5S RNA is a species whose sequence indicates that RNase A can ligate RNA as well as hydrolyze it.

RNA structural dynamics: pre-melting and melting transitions in E. coli 5S rRNA

The temperature dependent transition from duplex to a single strand in E. coli 5S ribosomal RNA is a multistep process, and it involves intermediate states. We have analyzed these structural dynamics by chemical modification of cytidines and by single strand specific nuclease digestions. This combined approach led to the characterization of premelting and melting transitions within individual structural segments of the native macromolecule, which we feel may find general application to the structure of biological polyribonucleotides: 1) G-C base pairs at the termini of helices are relatively unstable and they readily undergo premelting transition. 2) Internal G-U/A-U rich stretches of helices exhibit dynamic premelting properties. 3) Hairpin loops have a relatively stronger destabilizing effect than internal loops. 4) Bulge loops destabilize the neighbouring base pairs. 5) Melting of helical segments occurs starting from the destabilizing structures listed above, preferentially from the helix termini. E. coli 5S rRNA has been shown to adopt different conformations. The presence of urea leads to induction of enhancement in the sensitivity for nuclease S1 at several nucleotide positions. The possibility of structural rearrangements will be discussed.

Characterization of the RNA binding properties of transcription factor IIIA of Xenopus laevis oocytes

A nitrocellulose filter binding assay has been developed to study the interaction of Xenopus transcription factor IIIA with 5S RNA. The protein binds Xenopus oocyte 5S RNA with an association constant of 1.4 X 10(9) M-1 at 0.1 M salt, pH 7.5 at 20 degrees C. TF IIIA binds wheat germ 5S RNA with a two-fold higher affinity, E. coli 5S RNA with a four-fold weaker affinity, and has a barely detectable interaction with yeast tRNAphe. The preference for binding eukaryotic 5S RNA is enhanced in competition assays. The homologous reconstituted complex contains one molecule each of protein and 5S RNA and is indistinguishable from native 7S RNP in mobility on non-denaturing polyacrylamide gels. The conformation of the RNA in reconstituted particles is identical to the conformation of RNA in native 7S RNP. Further analysis of the homologous interaction reveals that complex formation is a favoured both by enthalpy and entropy. The 5S RNA binding activity has a broad pH optimum spanning pH 6.0 to pH 8.0. Determination of the salt dependence of Ka reveals that as many as 5 lysine-phosphate type ionic bonds may be formed in the homologous complex. Approximately 68% of the free energy of complex formation is contributed by non-electrostatic interactions between TF IIIA and Xenopus 5S RNA.

Escherichia coli 5S RNA A and B conformers. Characterisation by enzymatic and chemical methods

The structures of the two stable conformers of Escherichia coli 5 S RNA, the and B form, were compared. Information about the structures were obtained using the methods of limited enzymatic hydrolysis and chemical modification of accessible nucleotides. Base-specific modifications were performed for adenosines and cytidines using diethylpyrocarbonate and dimethylsulfate in combination with a strand-scission reaction at the modified site. Base-specific (RNase T1) as well as conformation-specific (nuclease S1, cobra venom nuclease) enzymes were employed for the limited enzymatic hydrolysis. Clear differences in the accessibility of the two 5 S RNA conformers to the enzymes and the chemical reagents were established and the regions with altered reactivities were localized in the 5 S RNA structure. The results are consistent with the disruption of the secondary structural interactions in helix II and partly in helices III and IV during the transition from the A to the B form. (The numbering of the helices is according to the generally accepted Fox and Woese model.) In addition some regions presumably involved in the tertiary structure are distorted. There is evidence, however, for the new formation of structural regions between two distant sites in the 5 S RNA B form. The results enable us to refine the existing 5 S RNA A-form model and provide insight into the structural dynamics that lead to the formation of the 5 S RNA B form.

Assignment of resonances of exchangeable protons in the NMR spectrum of the complex formed by Escherichia coli ribosomal protein L25 and uniformly nitrogen-15 enriched 5 S RNA fragment

The downfield proton NMR spectrum of the aqueous nucleoprotein complex formed by Escherichia coli ribosomal protein L25 and uniformly nitrogen-15 enriched 5 S RNA fragment is presented. Many proton resonances show the effects of scalar coupling to nitrogen-15 and these resonances are assigned to nucleic acid imino protons. Selective nitrogen-15 decoupling difference proton spectroscopy revealed nitrogen-15 and proton chemical shift correlations from which the base types of nucleic acid imino proton resonances could be assigned because the nitrogen-15 chemical shifts of nucleic acid guanine and uracil imino nitrogens have separate small ranges for both nucleoproteins and isolated nucleic acids.

Oligonucleotide directed mutagenesis of Escherichia coli 5S ribosomal RNA: construction of mutant and structural analysis

The ribosomal 5S RNA gene from the rrnB operon of E. coli was mutagenised in vitro using a synthetic oligonucleotide hybridised to M13 ssDNA containing that gene. The oligonucleotide corresponded to the 5S RNA sequence positions 34 to 51 and changed the guanosine at position 41 to a cytidine. The DNA containing the desired mutation was identified by dot blot hybridisation and introduced back into the plasmid pKK 3535 which contains the total rrnB operon in pBR 322. Plasmid coded 5S rRNA was selectively labeled with 32p using a modified maxi-cell system, and the replacement of guanosine G41 by cytidine was confirmed by RNA sequencing. The growth of cells containing mutant 5S rRNA was not altered by the base change, and the 5S rRNA was processed and incorporated into 50S ribosomal subunits and 70S ribosomes. The structure of wildtype and mutant 5S rRNA was compared by chemical modification of accessible guanosines with kethoxal and limited enzymatic digestion using RNase T1 and nuclease S1. These results showed that the wildtype and mutant 5S rRNA do not differ significantly in their structure. Furthermore, the formation, interconversion and stability of the two 5S rRNA A- and B-conformers are unchanged.

The secondary structure of oocyte and somatic 5S ribosomal RNAs of the fish Misgurnus fossilis L. from nuclease hydrolyses and chemical modification data

We have studied the accessibility of 5'- 32P labeled oocyte and somatic 5S rRNAs from the fish Misgurnus fossilis L. to S1, T1 and cobra venom nucleases and have found that the cleavage sites of 5S rRNAs closely related in primary structures differ in these molecules. The data of nuclease hydrolyses revealed the existence of two conformers corresponding to renatured and partially denatured somatic 5S rRNA and capable of mutual interconversions. The exposed cytosine residues were located in oocyte and somatic 5S rRNAs converted into uridine ones by sodium bisulfite treatment. The data have been used to construct the secondary structure models of somatic and oocyte 5S rRNAs by means of specially devised computer program. These models differ in their 5'-halves which contain all the nucleotide substitutions in the primary structure, all differences in location of the exposed cytosine residues, and finally, in the cleavage pattern by the nucleases used.

Comparative structural analysis of eubacterial 5S rRNA by oxidation of adenines in the N-1 position

Adenines in free 5S rRNA from Escherichia coli, Bacillus stearothermophilus and Thermus thermophilus have been oxidized at their N-1 position using monoperphthalic acid. The determination of the number of adenine 1-N-oxides was on the basis of UV spectroscopic data of the intact molecule. Identification of the most readily accessible nucleotides by sequencing gel analysis reveals that they are located in conserved positions within loops, exposed hairpin loops and single-base bulge loops. Implications for the structure and function of 5S rRNA will be discussed on the basis of this comparative analysis.

Crystallization of a ribonuclease-resistant fragment of Escherichia coli 5 S ribosomal RNA and its complex with protein L25

A ribonuclease-resistant fragment of Escherichia coli 5 S ribosomal RNA has been crystallized. The space group is P6(1)22 or P6(5)22, with a = 59.5 A and C = 268 A. The crystals contain one molecule per asymmetric unit, and show diffraction to 4.0 A resolution. Also, a complex of this fragment with L25 ribosomal protein has been crystallized in the same space group, but with a = 119 A, c = 250 A and four molecules per asymmetric unit.

Open and closed 5 S ribosomal RNA, the only two universal structures encoded in the nucleotide sequences

The nucleotide sequences of small ribosomal RNA (5 S rRNA) molecules of different organisms are presumably designed to ensure folding of these molecules in some standard secondary structure(s). To extract this message contained in the sequences we have plotted the triangular matrix diagrams of all potential hairpins for 44 representative 5 S rRNA sequences. Subjecting these diagrams to simple image-processing procedures we have found that only five hairpins are universally present in all known 5 S rRNA molecules. Two of these hairpins share the same stretch of the nucleotide sequence, others being independent. Thus, only two major secondary structures of 5 S rRNA can be formed. These are of the well-known Y-like (open) form and a novel P-like form closed by the tertiary interaction which involves two complementary stretches four to seven bases long.