The primary structure of Bacillus subtilis and Bacillus stearothermophilus 5 S ribonucleic acids

On comparing two structured RNA multiple alignments

We present a method, called BlockMatch, for aligning two blocks, where a block is an RNA multiple sequence alignment with the consensus secondary structure of the alignment in Stockholm format. The method employs a quadratic-time dynamic programming algorithm for aligning columns and column pairs of the multiple alignments in the blocks. Unlike many other tools that can perform pairwise alignment of either single sequences or structures only, BlockMatch takes into account the characteristics of all the sequences in the blocks along with their consensus structures during the alignment process, thus being able to achieve a high-quality alignment result. We apply BlockMatch to phylogeny reconstruction on a set of 5S rRNA sequences taken from fifteen bacteria species. Experimental results showed that the phylogenetic tree generated by our method is more accurate than the tree constructed based on the widely used ClustalW tool. The BlockMatch algorithm is implemented into a web server, accessible at http://bioinformatics.njit.edu/blockmatch. A jar file of the program is also available for download from the web server.

Use of statistical measures for analyzing RNA secondary structures

With more and more RNA secondary structures accumulated, the need for comparing different RNA secondary structures often arises in function prediction and evolutionary analysis. Numerous efficient algorithms were developed for comparing different RNA secondary structures, but challenges remain. In this article, a new statistical measure extending the notion of relative entropy based on the proposed stochastic model is evaluated for RNA secondary structures. The results obtained from several experiments on real datasets have shown the effectiveness of the proposed approach. Moreover, the time complexity of our method is favorable by comparing with that of the existing methods which solve the similar problem.

Suprageneric classification of thermoactinomyces vulgaris by nucleotide sequencing of 5S ribosomal RNA

The 5S rRNA nucleotide sequence of Thermoactinomyces vulgaris was determined and compared with published sequences of representative Gram-positive bacteria. The primary and secondary structure of the sequence is of the type characteristic of Gram-positive bacteria that have DNA with a low proportion of guanine plus cytosine. It was evident from the phylogenetic trees that T. vulgaris has little in common with actinomycetes but is related to the genus Bacillus, showing a moderately high relationship with B. stearothermophilus. The taxonomic implications of these relationships are discussed and an emended description of the family Bacillaceae is given.

Sequence, proposed secondary structure, and phylogenetic analysis of the chloroplast 5S rRNA gene of the brown alga Pylaiella littoralis (L.) Kjellm

The chloroplast 5S rRNA gene of the brown alga Pylaiella littoralis (L.) Kjellm has been cloned and sequenced. The gene is located 23 bp downstream from the 3' end of the 23S rRNA gene. The sequence of the gene is as follows: GGTCTTG GTGTTTAAAGGATAGTGGAACCACATTGAT CCATATCGAACTCAATGGTGAAACATTATT ACAGTAACAATACTTAAGGAGGAGTCCTTTGGGAAGATAGCTTATGCCTAAGAC. A secondary structure model is proposed, and compared to those for the chloroplast 5S rRNAs of spinach and the red alga Porphyra umbilicalis. Cladograms based on chloroplast and bacterial 5S rRNA and rRNA gene sequences were constructed using the MacClade program with a user-defined character transformation in which transitions and transversions were assigned unequal step values. The topology of the resulting cladogram indicates a polyphyletic origin for photosynthetic organelles.

Evidence for movement of the alpha-amylase gene into two phylogenetically distant Bacillus stearothermophilus strains

The gene for an alpha-amylase cloned from strain DY-5 of Bacillus stearothermophilus was used to examine to what extent the corresponding genes are structurally similar in other B. stearothermophilus strains. The structure of the gene itself was almost identical in DY-5 and a group of strains represented by strain 799. The gene was not detected at all in strain DSM2334, which was phenotypically amylase deficient. Comparison of the structure of 5S rRNA and electrophoretic pattern of the ribosomal proteins indicates that strains DY-5 and DSM2334 are closely related to each other, whereas strain 799 is phylogenetically very distant from the two. We estimate that strain 799 separated from DY-5 and DSM2334 some 420 million years ago. Nucleotide sequencing of the region containing the amylase gene from strains DY-5 and 799 revealed the presence of a 3.4-kilobase stretch that was highly similar in the two strains. Furthermore, comparison of the restriction map surrounding the amylase gene of DY-5 with that of a corresponding region in DSM2334 indicated that the former strain contained an extra segment 5.5 kilobases in length, which included the 3.4-kilobase stretch mentioned above. This segment was missing in DSM2334. It thus appears that the alpha-amylase gene was brought into strains DY-5 and 799 from outside despite a large phylogenetic distance.

Identification of three G.U base pairs in Bacillus subtilis ribosomal 5S RNA via 500-MHz proton homonuclear Overhauser enhancements

Three distinct G.U base pairs in Bacillus subtilis 5S RNA have been identified via homonuclear Overhauser enhancements (NOE) of their low-field (9-15 ppm) proton Fourier transform nuclear magnetic resonances at 11.75 T. With these G.U resonances as starting points, short segments of NOE connectivity can be established. One G.U-G.C-G.C segment (most probably G4.C112-G5.C111-U6.G110) can definitely be assigned to the terminal helix. The existence of at least part of the terminal helical stem of the secondary structure of a Gram-positive bacterial 5S RNA has thus been established for the first time by direct experimental observation. Addition of Mg2+ produces almost no conformational changes in the terminal stem but results in major conformational changes elsewhere in the structure, as reflected by changes in the 1H 500-MHz low-field NMR spectrum. Assignment of the two remaining G.U base pairs will require further experiments (e.g., enzymatic-cleavage fragments). Finally, the implications of these results for analysis of RNA secondary structure are discussed.

Extended secondary structure in 5S rRNAs from a sulphur metabolizing archaebacterium, Thermococcus celer

While this sequence shares a significant homology with the 5S RNAs of other archaebacteria and is consistent with current models for the secondary structure of 5S RNAs, it contains three unusual features. The G + C content (72-74%) is significantly higher than other 5S RNAs; the secondary structure is distinguished by unusually stable and extended helical structures and, most important, there is evidence for sequence heterogeneity in the form of complementary base substitutions and precursor processing. This supports recent evidence (Newmann, H., Gierl, A., Tu, J., Leibrock, J., Staiger, D. and Zillig, W. (1983) Mol. Gen. Genet. 192, 66-72) that, like many of the higher eukaryotes, this group of sulphur-metabolizing bacteria may contain multiple 5S RNA genes.

Phylogeny of the 5S ribosomal RNA from Synechococcus lividus II: the cyanobacterial/chloroplast 5S RNAs form a common structural class

The complete nucleotide sequence of the 5S ribosomal RNA from the cyanobacterium Synechococcus lividus II has been determined. The sequence is (sequence in text) This 5S RNA has the cyanobacterial- and chloroplast-specific nucleotide insertion between positions 30 and 31 (using the numbering system of the generalized eubacterial 5S RNA) and the chloroplast-specific nucleotide-deletion signature between positions 34 and 39. The 5S RNA of S. lividus II has 27 base differences compared with the 5S RNA of the related strain S. lividus III. This large difference may reflect an ancient divergence between these two organisms. The electrophoretic mobilities on nondenaturing polyacrylamide gels of renatured 5S RNAs from S. lividus II, S. lividus III, and spinach chloroplasts are identical, but differ considerably from that of Escherichia coli 5S RNA. This most likely reflects differences in higher-order structure between the 5S RNA of E. coli and these cyanobacterial and chloroplast 5S RNAs.

Secondary structure and phylogeny of Staphylococcus and Micrococcus 5S rRNAs

Nucleotide sequences of 5S rRNAs from four bacteria, Staphylococcus aureus Smith (diffuse), Staphylococcus epidermidis ATCC 14990, Micrococcus luteus ATCC 9341 and Micrococcus luteus ATCC 4698, were determined. The secondary structural models of S. aureus and S. epidermidis sequences showed characteristics of the gram-positive bacterial 5S rRNA (116-N type [H. Hori and S. Osawa, Proc. Natl. Acad. Sci. U.S.A. 76:381-385, 1979]). Those of M. luteus ATCC 9341 and M. luteus ATCC 4698 together with that of Streptomyces griseus (A. Simoncsits, Nucleic Acids Res. 8:4111-4124, 1980) showed intermediary characteristics between the gram-positive and gram-negative (120-N type [H. Hori and S. Osawa, 1979]) 5S rRNAs. This and previous studies revealed that there exist at least three major groups of eubacteria having distinct 5S rRNA and belonging to different stems in the 5S rRNA phylogenic tree.

Preparative-scale isolation and purification of procaryotic and eucaryotic ribosomal 5 S RNA: Bacillus subtilis, Neurospora crassa, and wheat germ

Ribosomal 5 S RNA from three different organisms has been isolated in high yield and purity. Without prior isolation of ribosomes, a presoak in buffer followed by phenol extraction, DE-32 ion-exchange chromatography, and Sephadex G-75 gel-permeation chromatography yields at least 5-10 mg of electrophoretically homogeneous 5 S RNA from 100 g of cells. Ribonuclease activity is eliminated by various combinations of low temperature, sodium dodecyl sulfate, phenol, and bentonite. High-molecular-weight contaminants are suppressed by either 65 degrees C heat treatment or lowered sodium dodecyl sulfate concentration. For the eucaryotes, 5.8 S RNA contamination is reduced either by low temperature in the initial solubilization or by postponing 65 degrees C heat treatment until after the phenol extraction step.

Dynamics of ribosomal RNA structure

The structural dynamics of ribosomal 5S RNAs have been investigated by probing single strandedness through enzymatic cleavage and chemical modification. This comparative study includes 5S rRNAs from E. coli, B. stearothermophilus, T. thermophilus, H. cutirubrum, spinach chloroplast, spinach cytomplasm, and Artemia salina. The structural studies support a unique tertiary interaction in eubacterial 5S rRNAs, involving nucleotides around positions 43 and 75. In addition long range structural effects are demonstrated in E. coli 5S rRNA due to the conversion of C to U at position 92.

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.

Precursor-specific nucleotide sequences can govern RNA folding

An immediate precursor of 5S ribosomal RNA (rRNA) from Bacillus subtilis has 21 and 42 nucleotide precursor-specific segments associated with its 5' and 3' termini, respectively. On the basis of its nucleotide sequence, predicted secondary structure and location in the rRNA transcriptional unit, the 3' precursor element apparently functions during the termination of transcription. A portion of the 5' precursor element is shown to facilitate the native folding of the mature domain of the precursor. Precursor 5S rRNA molecules which lack the 5' terminal 8-9 nucleotides of the 5' precursor elements were fabricated. These abbreviated constructs assume a non-native conformation, as revealed by their behavior during polyacrylamide gel electrophoresis. The aberrant conformation is evidently forced upon the abbreviated constructs by the residual 5' precursor sequence, since its removal by the maturation endonuclease RNAase M5 precipitates the reordering of the mature domain into its native conformation. Inspection of the nucleotide sequence of the 5S precursor suggested the nature of the conformational aberration, and gel electrophoresis analyses of limited nuclease digests of end-labeled precursors in the native and aberrant conformations are consistent with the derived model. We conclude taht the 5' terminal six nucleotides in the intact 5S precursor assist in the folding of the mature domain by forming a base-paired duplex with neighboring nucleotides, thereby preventing that adjacent sequence from engendering the abnormal conformation. The involvement of precursor-specific sequences and conformational dynamics in RNA function are discussed.

Mode of degradation of precursor-specific ribonucleic acid fragments by Bacillus subtilis

A precursor of 5S ribosomal ribonucleic acid (rRNA) from Bacillus subtilis was cleaved by ribonuclease (RNase) M5 in cell-free extracts from B. subtilis to yield the mature 5S rRNA plus RNA fragments derived from both termini of the precursor. The released, mature 5S rRNA was stable in these extracts; however, as occurred in vivo, the precursor-specific fragments were rapidly and completely destroyed. Such destruction was not observed in the presence of partially purified RNase M5, so fragment scavenging was not effected by the maturation nuclease itself. The selective destruction of the precursor-specific fragments was shown to occur through a 3'-exonucleolytic process with the release of nucleoside 5'-monophosphates; the responsible activity therefore had the character of RNAse II. Consideration of the primary and probable secondary structures of the precursor-specific fragments and mature 5S rRNA suggested that involvement of 3' termini in tight secondary structure may confer protection against the scavenging activity.

RNA structure

This review is concerned primarily with the physical structure and changes in the structure of RNA molecules. It will be evident that we have not attempted comprehensive coverage of what amounts to a vast literature. We have tried to stay away from particular areas that have been recently reviewed elsewhere. Citations to and information from them are included, however, so that access to the literature is available. Much of what we treat in depth deals with the crystal structures and solution behaviour of model RNA compounds, including synthetic polymers and molecular fragments such as dinucleoside phosphates. Sequence data on natural RNA are cited, but not in detail. Similarly, apart from tRNA, natural RNAs the structural determinations of which are presently not so far advanced, are not dwelt upon. We have tried to present in detail the available structural data with scaled drawings that permit facile comparisons of molecular geometries.

Human globin messenger RNA: importance of cloning for structural analysis

The sequence of most of the human beta globin messenger RNA and large sections of the alpha globin messenger RNA has been determined. Partly because of genetic polymorphism, it was necessary to clone globin complementary DNA in order to extend the analysis. Purified human fetal globin messenger RNA was isolated and used as a template by reverse transcriptase to produce duplex complementary DNA molecules. These molecules were linked in vitro to plasmid DNA by use of T4 ligase in the presence of Escherichia coli Pol 1. Several colonies transformed by these molecules have been shown to hybridize with labeled human globin complementary RNA.