Does 5S RNA function by a switch between two secondary structures?

Structural dynamics of a mitochondrial tRNA possessing weak thermodynamic stability

Folding dynamics are ubiquitously involved in controlling the multivariate functions of RNAs. While the high thermodynamic stabilities of some RNAs favor purely native states at equilibrium, it is unclear whether weakly stable RNAs exist in random, partially folded states or sample well-defined, globally folded conformations. Using a folding assay that precisely tracks the formation of native aminoacylable tRNA, we show that the folding of a weakly stable human mitochondrial (hmt) leucine tRNA is hierarchical with a distinct kinetic folding intermediate. The stabilities of the native and intermediate conformers are separated by only about 1.2 kcal/mol, and the species are readily interconvertible. Comparison of folding dynamics between unmodified and fully modified tRNAs reveals that post-transcriptional modifications produce a more constrained native structure that does not sample intermediate conformations. These structural dynamics may thus be crucial for recognition by some modifying enzymes in vivo, especially those targeting the globular core region, by allowing access to pretransition state conformers. Reduced conformational sampling of the native, modified tRNAs could then permit improved performance in downstream processes of translation. More generally, weak stabilities of small RNAs that fold in the absence of chaperone proteins may facilitate conformational switching that is central to biological function.

Roles of DEAD-box proteins in RNA and RNP Folding

RNAs and RNA-protein complexes (RNPs) traverse rugged energy landscapes as they fold to their native structures, and many continue to undergo conformational rearrangements as they function. Due to the inherent stability of local RNA structure, proteins are required to assist with RNA conformational transitions during initial folding and in exchange between functional structures. DEAD-box proteins are superfamily 2 RNA helicases that are ubiquitously involved in RNA-mediated processes. Some of these proteins use an ATP-dependent cycle of conformational changes to disrupt RNA structure nonprocessively, accelerating structural transitions of RNAs and RNPs in a manner that bears a strong resemblance to the activities of certain groups of protein chaperones. This review summarizes recent work using model substrates and tractable self-splicing intron RNAs, which has given new insights into how DEAD-box proteins promote RNA folding steps and conformational transitions, and it summarizes recent progress in identifying sites and mechanisms of DEAD-box protein activity within more complex cellular targets.

RNA misfolding and the action of chaperones

RNA folds to a myriad of three-dimensional structures and performs an equally diverse set of functions. The ability of RNA to fold and function in vivo is all the more remarkable because, in vitro, RNA has been shown to have a strong propensity to adopt misfolded, non-functional conformations. A principal factor underlying the dominance of RNA misfolding is that local RNA structure can be quite stable even in the absence of enforcing global tertiary structure. This property allows non-native structure to persist, and it also allows native structure to form and stabilize non-native contacts or non-native topology. In recent years it has become clear that one of the central reasons for the apparent disconnect between the capabilities of RNA in vivo and its in vitro folding properties is the presence of RNA chaperones, which facilitate conformational transitions of RNA and therefore mitigate the deleterious effects of RNA misfolding. Over the past two decades, it has been demonstrated that several classes of non-specific RNA binding proteins possess profound RNA chaperone activity in vitro and when overexpressed in vivo, and at least some of these proteins appear to function as chaperones in vivo. More recently, it has been shown that certain DExD/H-box proteins function as general chaperones to facilitate folding of group I and group II introns. These proteins are RNA-dependent ATPases and have RNA helicase activity, and are proposed to function by using energy from ATP binding and hydrolysis to disrupt RNA structure and/or to displace proteins from RNA-protein complexes. This review outlines experimental studies that have led to our current understanding of the range of misfolded RNA structures, the physical origins of RNA misfolding, and the functions and mechanisms of putative RNA chaperone proteins.

Facilitating RNA structure prediction with microarrays

Determining RNA secondary structure is important for understanding structure-function relationships and identifying potential drug targets. This paper reports the use of microarrays with heptamer 2'-O-methyl oligoribonucleotides to probe the secondary structure of an RNA and thereby improve the prediction of that secondary structure. When experimental constraints from hybridization results are added to a free-energy minimization algorithm, the prediction of the secondary structure of Escherichia coli 5S rRNA improves from 27 to 92% of the known canonical base pairs. Optimization of buffer conditions for hybridization and application of 2'-O-methyl-2-thiouridine to enhance binding and improve discrimination between AU and GU pairs are also described. The results suggest that probing RNA with oligonucleotide microarrays can facilitate determination of secondary structure.

A statistical sampling algorithm for RNA secondary structure prediction

An RNA molecule, particularly a long-chain mRNA, may exist as a population of structures. Further more, multiple structures have been demonstrated to play important functional roles. Thus, a representation of the ensemble of probable structures is of interest. We present a statistical algorithm to sample rigorously and exactly from the Boltzmann ensemble of secondary structures. The forward step of the algorithm computes the equilibrium partition functions of RNA secondary structures with recent thermodynamic parameters. Using conditional probabilities computed with the partition functions in a recursive sampling process, the backward step of the algorithm quickly generates a statistically representative sample of structures. With cubic run time for the forward step, quadratic run time in the worst case for the sampling step, and quadratic storage, the algorithm is efficient for broad applicability. We demonstrate that, by classifying sampled structures, the algorithm enables a statistical delineation and representation of the Boltzmann ensemble. Applications of the algorithm show that alternative biological structures are revealed through sampling. Statistical sampling provides a means to estimate the probability of any structural motif, with or without constraints. For example, the algorithm enables probability profiling of single-stranded regions in RNA secondary structure. Probability profiling for specific loop types is also illustrated. By overlaying probability profiles, a mutual accessibility plot can be displayed for predicting RNA:RNA interactions. Boltzmann probability-weighted density of states and free energy distributions of sampled structures can be readily computed. We show that a sample of moderate size from the ensemble of an enormous number of possible structures is sufficient to guarantee statistical reproducibility in the estimates of typical sampling statistics. Our applications suggest that the sampling algorithm may be well suited to prediction of mRNA structure and target accessibility. The algorithm is applicable to the rational design of small interfering RNAs (siRNAs), antisense oligonucleotides, and trans-cleaving ribozymes in gene knock-down studies.

Inhibition of ribosomal subunit association and protein synthesis by oligonucleotides corresponding to defined regions of 18S rRNA and 5S rRNA

Strong complementarity between a conserved sequence near the 3' end of 18S (16S) rRNA of the small ribosomal subunit and a conserved sequence in the 5S rRNA of the large ribosomal subunit supported the suggestion that base-paired interaction between the two RNA molecules could be responsible for the reversible association of ribosomal subunits during protein synthesis. If this were true then oligonucleotides corresponding to defined regions of the 18S and 5S rRNAs should have profound effects on the association of ribosomal subunits and protein synthesis. In this report we show that oligonucleotides, corresponding to a defined region of eukaryotic 18S rRNA, when bound to wheat embryo 60S ribosomal subunits, inhibited association with 40S ribosomal subunits and also inhibited in vitro protein synthesis. Similarly oligonucleotides corresponding to a defined region of 5S rRNA when bound to 40S ribosomal subunits also inhibited the formation of 80S ribosomes and in vitro protein synthesis. The minimum sequences responsible for the inhibition of ribosomal subunit association and in vitro protein synthesis corresponded to the 5' strand of the m2(6)A m2(6)A hairpin structure near the 3' end of 18S rRNA and nucleotides 91-100 of 5S rRNA which are complementary to each other. Sequences at identical positions of Escherichia coli 16S and 5S rRNAs are also complementary to each other.

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.

Effect of sequence mutations on the higher order structure of the yeast 5 S rRNA

Mutant yeast ribosomal 5 S RNAs were probed by enzymatic cleavage and chemical reactivity to define further the higher order structure. Mutations that destabilized helix IV resulted in an altered tertiary structure in which a reduced reactivity to ethylnitrosourea at U90 and G91 could be correlated with greater enzymatic and Fe(II)-EDTA cleavages in helices II and V. The results provide direct evidence for, and a further definition of, a structural juxtaposition between helix II and the end of helix IV and indicate that, in contrast to earlier suggestions, the remaining tertiary structure is sufficiently stable to prevent "pseudoknot-like" interactions between helices III and IV. The data are fully consistent with the "lollipop" model of the tertiary structure.

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.

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.

S4-alpha mRNA translation regulation complex. II. Secondary structures of the RNA regulatory site in the presence and absence of S4

The secondary structure of the Escherichia coli alpha mRNA leader sequence has been determined using nucleases specific for single- or double-stranded RNA. Three different length alpha RNA fragments were studied at 0 degrees C and 37 degrees C. A very stable eight base-pair helix forms upstream from the ribosome initiation site, defining a 29 base loop. There is evidence for base-pairing between nucleotides within this loop and for a "pseudo-knot" interaction of some loop bases with nucleotides just 3' to the initiation codon, forming a region of complex structure. A weak helix also pairs sequences near the 5' terminus of the alpha mRNA with bases near the Shine-Dalgarno sequence. Affinity constants for the translational repressor S4 binding different length alpha mRNA fragments indicate that most of the S4 recognition features must be contained within the main helix and hairpin regions. Binding of S4 to the alpha mRNA alters the structure of the 29 base hairpin region, and probably melts the weak pairing between the 5' and 3' termini of the leader. The pseudo-knot structure and the conformational changes associated with it provide a link between the structures of the S4 binding site and the ribosome binding site. The alpha mRNA may therefore play an active role in mediating translational repression.

Evolutionary changes in the higher order structure of the ribosomal 5S RNA

Comparative studies have been undertaken on the higher order structure of ribosomal 5S RNAs from diverse origins. Competitive reassociation studies show that 5S RNA from either a eukaryote or archaebacterium will form a stable ribonucleoprotein complex with the yeast ribosomal 5S RNA binding protein (YL3); in contrast, eubacterial RNAs will not compete in a similar fashion. Partial S1 ribonuclease digestion and ethylnitrosourea reactivity were used to probe the structural differences suggested by the reconstitution experiments. The results indicate a more compact higher order structure in eukaryotic 5S RNAs as compared to eubacteria and suggest that the archaebacterial 5S RNA contains features which are common to either group. The potential significance of these results with respect to a generalized model for the tertiary structure of the ribosomal 5S RNA and to the heterogeneity in the protein components of 5S RNA-protein complexes are discussed.

Accessibility of phosphodiester bonds in the yeast ribosomal 5 S RNA protein complex

The tertiary structure of the protein-associated yeast ribosomal 5 S RNA was examined using ethylnitrosourea reactivity as a probe for phosphodiester bonds. A reduced reactivity was consistently observed in at least nine residues within four distinct regions of the RNA sequence. Seven of these were also observed in three regions of the free RNA molecule while two, A27 and G30, were only present in the ribonucleoprotein complex. The results strongly suggest that the tertiary structure of the free eukaryotic 5 S RNA is largely conserved in the 5 S RNA-protein complex although it appears to be further stabilized in interaction with the ribosomal protein.

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.

Attachment of the 5'-terminal portion of globin mRNAs to 5S-RNA X L5-protein in the 80S initiation complex

An 80S initiation complex was formed by incubating a heterologous cell-free system with 125I-labeled globin mRNAs in the presence of sparsomycin. The 80S initiation complex was then digested with micrococcal nuclease. The ribosomal 5S-RNA X L5-protein (5S RNP) fraction, released by EDTA treatment, contained 125I-labeled mRNA fragments. The attachment of labeled mRNA fragments to 5S RNP was shown by (a) CsCl isopycnic centrifugation, (b) recentrifugation through a sucrose density gradient and (c) acrylamide gel electrophoresis of 5S RNP purified by (b). Labeled fragments were released from 5S RNP by treatment with sodium dodecyl sulfate or pronase, indicating the participation of protein L5 in the attachment. The attached mRNA fragments were 23-25 nucleotides in length. Hybridization experiments, using restriction fragments of cDNA for rabbit beta globin mRNA, showed that the attached mRNA fragments were derived from the 5' portion of globin mRNAs. The attachment of 125I-labeled mRNA fragments to 5S RNP was also observed in the 80S initiation complex formed by incubation of reticulocyte lysate with 125I-labeled globin mRNA, but not in labeled polysomal fractions. These findings may indicate that 5S RNP interacted with the 5' portion of globin mRNA, containing the translation initiation codon of globin mRNA in the 80S initiation complex. The biochemical significance of these results is discussed.

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.

Structural and functional analysis of Escherichia coli ribosomes containing small deletions around position 1760 in the 23S ribosomal RNA

Three different small deletions were produced at a single Pvu 2 restriction site in E. coli 23S rDNA of plasmid pKK 3535 using exonuclease Bal 31. The deletions were located around position 1760 in 23S rRNA and were characterized by DNA sequencing as well as by direct fingerprinting and S1-mapping of the rRNA. Two of the mutant plasmids, Pvu 2-32 and Pvu 2-33, greatly reduced the growth rate of transformed cells while the third mutant, Pvu 2-14 grew as fast as cells containing the wild-type plasmid pKK 3535. All three mutant 23S rRNAs were incorporated into 50S-like particles and were even found in 70S ribosomes and polysomes in vivo. The conformation of mutant 23S rRNA in 50S subunits was probed with a double-strand specific RNase from cobra venom. These analyses revealed changes in the accessibility of cleavage sites near the deletions around position 1760 and in the area around position 800 in all three mutant rRNAs. We suggest, that an altered conformation of the rRNAs at the site of the deletion is responsible for the slow growth of cells containing mutant plasmids Pvu 2-32 and Pvu 2-33.

Equilibria in 5-S ribosomal RNA secondary structure. Bulges and interior loops in 5-S RNA secondary structure may serve as articulations for a flexible molecule

The basic assumption in this paper is that the secondary structure of a 5-S ribosomal RNA cannot be represented by a single model. We propose that the molecule can adopt, at least within the ribosome, a series of slightly different structures of nearly equal stability. The different structures arise from the existence of ambiguous base-pairing opportunities in bulged helices and the adjacent interior loops. In eubacterial 5-S RNAs there is one such an area, in eukaryotic 5-S RNAs two such areas that can give rise to structural switches. We explain how a change in secondary structure in these areas may influence the relative orientation of the surrounding helices, in other words how bulges and interior loops may serve as articulations and give rise to a flexible tertiary structure.

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.

Three-dimensional structural model of eubacterial 5S RNA that has functional implications

Escherichia coli 5S RNA and its specific protein complexes were hydrolyzed with the single-strand-specific nuclease S1. Based on the results, a tertiary structural model for E. coli 5S RNA is proposed in which ribosomal proteins E-L5, E-L18, and E-L25 influence the conformation of the RNA. This may be of significance for ribosomal function. Comparison of the proposed E. coli 5S RNA structure with those of 18 other prokaryotic 5S RNAs led to a generalized eubacterial 5S RNA tertiary structure in which the majority of the conserved nucleotides are in non-base-paired regions and several conserved "looped-out" adenines (in E. coli, adenines -52, -53, -57, -58, and -66) are implied to be important for protein recognition or interaction or both.

Two distinct conformations of rat liver ribosomal 5S RNA

Three different conformers of rat liver 5S ribosomal RNA were investigated by partial nuclease cleavage technique using S1 nuclease and cobra venom endoribonuclease (CVE) as conformational probes. Urea-treated and renatured 5S RNA co-migrate on non-denaturing gels, but exhibit distinct differences in their nuclease cleavage patterns. The most prominent differences in S1 nuclease and CVE accessibility of these conformers are located in region 30-50 and around nucleotides 70 and 90. The third form of 5S RNA with higher electrophoretic mobility was generated by EDTA treatment. The cleavage patterns of this 5S RNA conformer are similar to that characteristic for the renatured 5S RNA. The results demonstrate the difference in secondary structure and possibly different tertiary base-pairing interactions of 5S RNA conformers.

Conservation of secondary structure in 5 S ribosomal RNA: a uniform model for eukaryotic, eubacterial, archaebacterial and organelle sequences is energetically favourable

The most commonly accepted secondary structure models for 5S RNA differ for molecules of eubacterial origin, where the four-helix model of Fox and Woese is generally cited, and those of eukaryotic origin, where a fifth helix is assumed to exist. We have carefully aligned all available sequences from eukaryotes, eubacteria, chloroplasts, archaebacteria and plant mitochondria. We could thus derive a unified secondary structure model applicable to all 5S RNA sequences known to-date. It contains the five helices already present in the eukaryotic model, extended by additional segments that were not previously assumed to be universally present. One of the helices can be written in two equilibrium forms, which could reflect the existence of a flexible, dynamic structure. For the derivation of the model and the estimation of the free energies we followed a set of rules optimized to predict the tRNA cloverleaf. The stability of the unified model is higher than that of nearly all previously proposed sequence-specific and general models.

A structural model of 5S RNA from E. coli based on intramolecular crosslinking evidence

We describe new results obtained using the bifunctional chemical reagent phenyldiglyoxal (PDG) to study the intramolecular crosslinking of ribosomal 5S RNA from E. coli. In a previous publication (Wagner & Garrett [1]) we reported the identification of a crosslink in the stem region of 5S RNA (G2-G112) using the same reagent but were unable to obtain further information because of the presence of monofunctional adducts which confused the analyses. To overcome this problem, we have removed the monoaddition products by coupling them via their free reagent ends to a solid support bearing reactive groups. Using this system we have been able to identify a new crosslink G41-G72 in native 5S RNA which has considerable structural implications. We propose a structural model in which the proximity of both nucleotides is maintained by secondary interactions.

A hydrogen exchange study of Escherichia coli 5S RNA

Using the tritium Sephadex method, the number of exchangeable protons in E. coli 5S RNA and the kinetics of their exchange reactions have been measured at two different Mg++ concentrations (10(-2) M and 10(-3) M). A quantitative analysis of these results indicates the presence of two classes of protons exchanging with very different rates. The protons of the slow class, not seen in linear molecules of double helical RNA, exchange with a half-time of 0.6 hour and their exchange kinetics are independent of Mg++ concentration. Reduction of the Mg++ concentration from 10(-2) ot 10(-3) M, however, results in a decrease in the number of these exchangeable protons form 26 to 19. Neither the total number, nor the exchange kinetics of the fast protons are affected by this change in Mg++ concentration. Comparison of these results with those previously obtained with tRNA, suggests the presence of a Mg++ dependent tertiary structure in 5S RNA. The number of exchangeable protons obtained from extrapolation of the exchange curves (120 and 126 respectively for 10(-3) and 10(-2) M Mg++ concentration) are compared to the calculated number of exchangeable protons predicted by previous proposed structural models for E.Coli 5S RNA.

Primary sequence of wheat mitochondrial 5S ribosomal ribonucleic acid: functional and evolutionary implications

Using the procedures of Donis-Keller et al. [Donis-Keller, H., Maxam, A. M., & Gilbert, W. (1977) Nucleic Acids Res. 4, 2527--2538 (1977)] and Peattie [Peattie, D. A. (1979) Proc. Natl. Acad. Sci. U.S.A. 76, 1760--1764], we have determined the nucleotide sequence of wheat mitochondrial 5S ribosomal ribonucleic acid (rRNA). This sequence [Formula: see text] is the first to be reported for a plant mitochondrial RNA. A highly conserved region (underlined) readily identifies the molecule as a structural homologue of other 5S rRNAs, as do potential base-paired regions which are characteristic of all known (prokaryotic, chloroplast, eukaryotic cytosol) 5S rRNA sequences. However, when assessed in terms of those structural features which distinguish prokaryotic from eukaryotic 5S rRNAs, wheat mitochondrial 5S rRNA cannot be classified readily as one or the other but instead displays characteristics of both types. In addition, the mitochondrial 5S rRNA has several unusual features, including (i) a variable number (two to three) of A residues at both the 5' and 3' ends, (ii) a unique sequence (CGACC, italic) in place of the prokaryotic sequence (CGAAC) which has been postulated to interact with aminoacyl-tRNA during translation, and (iii) a novel sequence, AUAUAUAU, immediately following the highly conserved sequence. In terms of overall primary sequence, wheat mitochondrial and cytosol 5S rRNAs seem to be slightly more divergent from each other than either is from Escherichia coli 5S rRNA, with which they are about equally homologous. From these observations, we propose that wheat mitochondrial 5S rRNA represents a distinct class of 5S rRNA. Our observations raise a number of questions about the evolutionary origin and functional role(s) of plant mitochondrial 5S rRNA.

Nucleotide sequence of Lactobacillus viridescens 5S RNA

The nucleotide sequence of Lactobacillus viridescens ATCC 12706 5S RNA was determined to be pU-G-U-U-G-U-G-A-U-G-A-U-G-G-C-A-U-U-G-A-G-G-U-C-A-C-A-C C-U-G-U-U-C-C-C-A-U-A-C-C-G-A-A-C-A-C-A-G-A-A-G-U-U-A-A-G-C-U-C-A-A-U-A-G-C-G C-C-G-A-A-A-G-U-A-G-U-U-G-G-A-G-G-A-U-C-U-C-U-U-C-C-U-G-C-G-A-G-G-A-U-A-G-G-A C-G-U-C-G-C-A-A-U-G-COH. When compared with other published sequences of prokaryotic 5S RNA species, this sequence shows as much homology with that from B. substilis (80% homology when all variations included) and B. megaterium (77% homology) as with the 5S RNA from another member of Lactobacillaceae family (L. brevis, 79% homology). The sequence contains the proposed tRNA binding site (CGAAC, positions 41-45) and can accomodate most, but not all, of the more recently proposed helical regions of secondary structure.

Prediction of pairing schemes in RNA molecules-loop contributions and energy of wobble and non-wobble pairs

Previously published models for predicting pairing schemes in RNA molecules, when applied to tRNA, give the clover leaf structure in only half the cases. We made a systematic investigation of the predictability of the clover leaf structure under various assumptions concerning the energetic contributions of single and double-stranded regions. We tested 21 different models and variants on a set of 100 tRNA sequences and many other variants on a smaller set of sequences. In our models we allowed not only G.C, A.U and G.U pairing, but also every other pair. Under conditions which are much less restrictive than those of previous attempts, we can nevertheless reach 90 per cent predictability for the clover leaf structure of tRNA. A most surprising and far-reaching result is that we can assign to C.G and C.C pairs binding energies quite close to the energies of G.U pairs, and still predict the clover leaf. The following ranking for non-complementary pairs was obtained : G.U, G.G and C.C, U.U, C.A, A.A and G.A, U.C. The main practical innovation which made possible the improvements in predictability are: i) not counting the stacking of base pairs separated by a bulge loop; ii) making the terminal C.C's in stems more stable than the terminal A.U's by merely -- 0.7 kcal; iii) replacing the distinction between G.C and A.U-closed loops by a distinction based on the presence of loop-favoring residues; iv) carefully adjusting the energetic balance between the various kinds of loops; v) narrowing the gap between the GC/GC and the GC/AU contributions; vi) using observations on nearest-neighbours in tRNA sequences to refine the contributions of G.U pairs.

The 5-S RNA . protein complex from an extreme halophile, Halobacterium cutirubrum. Purification and characterization

A 5-S RNA . protein complex has been isolated from the 50-S ribosomal subunit of an extreme halophile, Halobacterium cutirubrum. The 50-S ribosomal subunit from the extreme halophile requires 3.4 M K+ and 100 mM Mg2+ for stability. However, if the high K+ concentration is maintained but the Mg2+ concentration lowered to 0.3 mM, the 5-S RNA . protein complex is selectively extracted from the subunit. After being purified on an Agarose 0.5-m column the complex had a molecular weight of about 80000 and contained 5-S RNA and two proteins, HL13 and HL19, with molecular weights (by sedimentation equilibrium) of 18700 and 18000, respectively. No ATPase or GTPase activity could be detected in the 5-S RNA . protein complex. The amino acid composition and electrophoretic mobility on polyacrylamide gels indicated both proteins were much more acidic than the equivalent from Escherichia coli or Bacillus stearothermophilus. Partial amino acid sequence data suggest HL13 is homologous to EL18 and HL19 to EL5.