The gene coding for small ribosomal subunit RNA in the basidiomycete Ustilago maydis contains a group I intron.

The nucleotide sequence of the gene coding for small ribosomal subunit RNA in the basidiomycete Ustilago maydis was determined. It revealed the presence of a group I intron with a length of 411 nucleotides. This is the third occurrence of such an intron discovered in a small subunit rRNA gene encoded by a eukaryotic nuclear genome. The other two occurrences are in Pneumocystis carinii, a fungus of uncertain taxonomic status, and Ankistrodesmus stipitatus, a green alga. The nucleotides of the conserved core structure of 101 group I intron sequences present in different genes and genome types were aligned and their evolutionary relatedness was examined. This revealed a cluster including all group I introns hitherto found in eukaryotic nuclear genes coding for small and large subunit rRNAs. A secondary structure model was designed for the area of the Ustilago maydis small ribosomal subunit RNA precursor where the intron is situated. It shows that the internal guide sequence pairing with the intron boundaries fits between two helices of the small subunit rRNA, and that minimal rearrangement of base pairs suffices to achieve the definitive secondary structure of the 18S rRNA upon splicing.     

Primary and secondary structure of the 18 S ribosomal RNA of the insect species Tenebrio molitor

The sequence of the 18 S rRNA of Tenebrio molitor is reported. A detailed secondary structure model for eukaryotic small subunit rRNAs is proposed. The model comprises 48 universal helices that eukaryotic and prokaryotic small subunit rRNAs have in common, plus a number of helices in areas of variable secondary structure. For the central area of the model, an alternative structure is possible, applicable only to eukaryotic small subunit rRNAs. Possibly, small subunit rRNA switched to this alternative conformation after the eukaryotic branch had been established in evolution. Another possibility is that the two conformers represent a dynamic structural switch functioning during the translational activity of the eukaryotic ribosome.     

Unusual pattern of ribonucleic acid components in the ribosome of Crithidia fasciculata, a trypanosomatid protozoan.

In a previous study from this laboratory, presumptive ribosomal ribonucleic acid (RNA) species were identified in the total cellular RNA directly extracted from intact cells of the trypanosomatid protozoan Crithidia fasciculata (M. W. Gray, Can. J. Biochem. 57:914-926, 1979). The results suggested that the C. fasciculata ribosome might be unusual in containing three novel, low-molecular-weight ribosomal RNA components, designated e, f, and g (apparent chain lengths 240, 195, and 135 nucleotides, respectively), in addition to analogs of eucaryotic 5S (species h) and 5.8S (species i) ribosomal RNAs. In the present study, all of the presumptive ribosomal RNAs were indeed found to be associated with purified C. fasciculata ribosomes, and their localization was investigated in subunits produced under different conditions of ribosome dissociation. When ribosomes were dissociated in a high-potassium (880 mM K+, 12.5 mM Mg2+) medium, species e to i were all found in the large ribosomal subunit, which also contained an additional, transfer RNA-sized component (species j). However, when subunits were prepared in a low-magnesium (60 mM K+, 0.1 mM Mg2+) medium, two of the novel species (e and g) did not remain with the large subunit, but were released, apparently as free RNAs. Control experiments have eliminated the possibility that the small RNAs are generated by quantitative and highly specific (albeit artifactual) ribonuclease cleavage of large ribosomal RNAs during isolation. In terms of RNA composition and dissociation properties, therefore, the ribosome of C. fasciculata is the most "atypical" eucaryotic ribosome yet described. These observations raise interesting questions about the function and evolutionary origin of C. fasciculata ribosomes and about the organization and expression of ribosomal RNA genes in this organism.     

Comparative analysis of more than 3000 sequences reveals the existence of two pseudoknots in area V4 of eukaryotic small subunit ribosomal RNA

The secondary structure of V4, the largest variable area of eukaryotic small subunit ribosomal RNA, was re-examined by comparative analysis of 3253 nucleotide sequences distributed over the animal, plant and fungal kingdoms and a diverse set of protist taxa. An extensive search for compensating base pair substitutions and for base covariation revealed that in most eukaryotes the secondary structure of the area consists of 11 helices and includes two pseudoknots. In one of the pseudoknots, exchange of base pairs between the two stems seems to occur, and covariation analysis points to the presence of a base triple. The area also contains three potential insertion points where additional hairpins or branched structures are present in a number of taxa scattered throughout the eukaryotic domain.     

An overview of the secondary structure of the V4 region of eukaryotic small-subunit ribosomal RNA.

The V4 region of the small subunit (18S) ribosomal RNA was examined in 72 different sequences representing a broad sample eukaryotic diversity. This domain is the most variable region of the 18S rRNA molecule and ranges in length from ca. 230 to over 500 bases. Based upon comparative analysis, secondary structural models were constructed for all sequences and the resulting generalized model shows that most organisms possess seven helices for this region. The protists and two insects show from one to as many as four helices in addition to the above seven. In this report, we summarize secondary structure information presented elsewhere for the V4 region, describe the general features for helical and apical regions, and identify signature sequences useful in helix identification. Our model generally agrees with other current concepts; however, we propose modifications or alternative structures for the start of the V4 region, the large protist inserts, and the sector that may possibly contain a pseudoknot.     

Alternative secondary structures in the 5' exon affect both forward and reverse self-splicing of the Tetrahymena intervening sequence RNA

The natural splice junction of the Tetrahymena large ribosomal RNA is flanked by hairpins that are phylogenetically conserved. The stem immediately preceding the splice junction involves nucleotides that also base pair with the internal guide sequence of the intervening sequence during splicing. Thus, precursors which contain wild-type exons can form two alternative helices. We have constructed a series of RNAs where the stem-loop in the 5' exon is more or less stable than in the wild-type precursor, and tested them in both forward and reverse self-splicing reactions. The presence of a stable hairpin in ligated exon substrates interferes with the ability of the intervening sequence to integrate at the splice junction. Similarly, the presence of the wild-type hairpin in the 5' exon reduces the rate of splicing 20-fold in short precursors. The data are consistent with a competition between unproductive formation of a hairpin in the 5' exon and productive pairing of the 5' exon with the internal guide sequence. The reduction of splicing by a hairpin that is a normal feature of rRNA structure is surprising; we propose that this attenuation is relieved in the natural splicing environment.     

The Conformation of a Conserved Stem-Loop Structure in Ribosomal RNA

Abstract

The RNA of small ribosomal subunits contains a conserved stem-loop structure near the 3′ end. Characteristics for the hairpins are: (a) a nine-basepairs stem; (b) a conserved ^A-U _U-Gjunction in the stem; (c) a conserved sequence Gm⁶ ₂Am⁶ ₂A sequence in the loop (except yeast mitochondria and mutants from bacteria). We are using UV-optics, micro-calorimetry and 500 MHz-NMR to investigate fragments of about 50 nucleotides cleaved from the 3′ ends of small ribosomal subunit RNA's by bacteriocins. Our preliminary conclusions are: (1) Dimethylation of the adenines in the loop destabilizes the hairpin because of an increased stacking; (2) melting of the hairpin starts at the ends as well as in the middle at the 5-H junction; (3) basepair substitutions have an unexpectedly large effect on thermal stability.     

Structure of a protein L23-RNA complex located at the A-site domain of the ribosomal peptidyl transferase centre

Protein L23 from the ribosome of Escherichia coli is the primary ribosomal product cross-linked to affinity-labelled puromycin; it lies, therefore, within the A-site domain of the peptidyl transferase centre on the 50 S subunit. We have characterized this functional domain by isolating and sequencing the RNA binding site of protein L23; it consists of two main fragments of 25 and 105 nucleotides that strongly interact and are separated by 172 nucleotides in the primary sequence. The higher-order structure of the RNA moiety was probed by chemical reagents, and by single-strand and double-strand-specific ribonucleases; a secondary structural model and a tertiary structural interaction are proposed on the basis of these data that are compatible with phylogenetic sequence comparisons.Several nucleotides exhibited altered chemical reactivity, both lower and higher, in the presence of protein L23, thereby implicating a large proportion of the RNA structure in the protein binding. The sites were located mainly at the extremities of the helices and at nucleotides that were putatively bulged out from the helices.The RNA moiety and an adjacent excised fragment contain several highly conserved sequences and a modified adenosine. Such sequences constitute important functional domains of the RNA and may contribute to the putative role of this RNA region in the peptidyl transferase centre.     

Secondary Structure and Molecular Evolution of the Mitochondrial Small Subunit Ribosomal RNA in Agaricales (Euagarics clade,Homobasidiomycota)

The complete sequences and secondary structures of the mitochondrial small subunit (SSU) ribosomal RNAs of both mostly cultivated mushrooms Agaricus bisporus (1930 nt) and Lentinula edodes (2164 nt) were achieved. These secondary structures and that of Schizophyllum commune (1872 nt) were compared to that previously established for Agrocybe aegerita. The four structures are near the model established for Archae, Bacteria, plastids, and mitochondria; particularly the helices 23 and 37, described as specific to bacteria, are present. Within the four Agaricales (Homobasidiomycota), the SSU-rRNA core is conserved in size (966 to 1009 nt) with the exception of an unusual extension of 40 nt in the H17 helix of S. commune. The four core sequences possess 76% of conserved positions and a cluster of C in their 3 end, which could constitute a signal involved in the RNA maturation process. Among the nine putative variable domains, three (V3, V5, V7) do not show significant length variations and possess similar percentages of conserved positions (69%) than the core. The other six variable domains show important length variations, due to independent large size inserted/deleted sequences, and higher rates of nucleotide substitutions than the core (only 31% of conserved positions between the four species). Interestingly, the inserted/deleted sequences are located in few preferential sites (hot spots for insertion/deletion) where they seem to arise or disappear haphazardly during evolution. These sites are located on the surface of the tertiary structure of the 30S ribosomal subunit, at the beginning of hairpin loops; the insertions lead to a lengthening of existing hairpins or to branching loops bearing up to five additional helices.     

Intermolecular base-paired interaction between complementary sequences present near the 3'' ends of 5S rRNA and 18S (16S) rRNA might be involved in the reversible association of ribosomal subunits.

Highly conserved sequences present at an identical position near the 3' ends of eukaryotic and prokaryotic 5S rRNAs are complementary to the 5' strand of the m2(6)A hairpin structure near the 3' ends of 18S rRNA and 16S rRNA, respectively. The extent of base-pairing and the calculated stabilities of the hybrids that can be constructed between 5S rRNAs and the small ribosomal subunit RNAs are greater than most, if not all, RNA-RNA interactions that have been implicated in protein synthesis. The existence of complementary sequences in 5S rRNA and small ribosomal subunit RNA, along with the previous observation that there is very efficient and selective hybridization in vitro between 5S and 18S rRNA, suggests that base-pairing between 5S rRNA in the large ribosomal subunit and 18S (16S) rRNA in the small ribosomal subunit might be involved in the reversible association of ribosomal subunits. Structural and functional evidence supporting this hypothesis is discussed.     

Probing the structure of RNAIII, the Staphylococcus aureus agr regulatory RNA, and identification of the RNA domain involved in repression of protein A expression

RNAIII, a 514-nt RNA molecule, regulates the expression of many Staphylococcus aureus genes encoding exoproteins and cell-wall-associated proteins. We have studied the structure of RNAIII in solution, using a combination of chemical and enzymatic probes. A model of the secondary structure was derived from experimental data with the help of computer simulation of RNA folding. The model contains 14 hairpin structures connected by unpaired nucleotides. The data also point to three helices formed by distant nucleotides that close off structural domains. This model was generally compatible with the results of in vivo probing experiments with dimethylsulfate in late exponential-phase cultures. Toe-printing experiments revealed that the ribosome binding site of hld, which is encoded by RNAIII, was accessible to the Escherichia coli 30S ribosomal subunit, suggesting that the in vitro structure represented a translatable form of RNAIII. We also found that, within the 3' end of RNAIII, the conserved hairpin 13 and the terminator form an intrinsic structural domain that exerts specific regulatory activity on protein A gene expression.     

Higher order structure in the 3'-minor domain of small subunit ribosomal RNAs from a gram negative bacterium, a gram positive bacterium and a eukaryote

An experimental approach was used to determine and compare the highest order structure within the 150 to 200 nucleotides at the 3'-ends of the RNAs from the small ribosomal subunits of Escherichia coli, Bacillus stearothermophilus and Saccharomyces cerevisiae. Chemical reagents were employed to establish the degree of stacking and/or accessibility of each adenosine, guanosine and cytidine. The double helices were probed with a cobra venom ribonuclease from Naja naja oxiana, and the relatively unstructured and accessible sequences were localized with the single strand-specific ribonucleases A, T1, T2 and S1. The data enabled the various minimal secondary structural models, proposed for the 3'-regions of the E. coli and S. cerevisiae RNAs, to be critically examined, and to demonstrate that the main common features of these models are correct. The results also reveal the presence and position of additional higher order structure in the renatured free RNA. It can be concluded that a high level of conservation of higher order structure has occurred during the evolution of the gram negative and gram positive eubacteria and the eukaryote in both the double helical regions and the "unstructured" regions. Several unusual structural features were detected. Multiple G X A pairings in two of the putative helices, which are compatible with phylogenetic sequence comparisons, are strongly supported by the occurrence of cobra venom ribonuclease cuts adjacent to, and in one case between, these pairings. Evidence is also provided for the stacking of an A X A pair within a double helix of the yeast RNA. Other special structural features include adenosines bulged out from double helices; such nucleotides, which are hyper-reactive, have been implicated in protein recognition in 5 S ribosomal RNA. The 3'-terminal regions of the RNAs are particularly important for the functioning of the ribosome. They are involved in mRNA, tRNA and ribosomal factor binding. The results reveal that while the functionally important RNA sequences tend to be conserved, they are not always accessible in the free RNA; the pyrimidine-rich "Shine and Dalgarno" sequence, for example, which is involved in mRNA recognition, occurs in a double helix in both eubacterial RNAs.     

A possible novel interaction between the 3′-end of 18 S ribosomal RNA and the 5'-leader sequence of many eukaryotic messenger RNAs

A novel interaction between the 5′-untranslated region of eukaryotic messenger RNAs and non-contiguous sequences in the 18 S ribosomal RNA is proposed. The small ribosomal RNA contains, at its 3′-terminus, a heavily conserved hairpin structure. It is suggested that mRNA 5′-leader sequence stabilises this structure by interacting with other conserved nucleotides which flank it. Sequences closely related to the required sequence (A—U—C—C—A—C—C) occur quite commonly in eukaryotic mRNAs and are often found immediately upstream from the AUG-codon. This interaction may have a role in the events which lead up to the initiation of protein synthesis.     

The nuclear 5S RNAs from chicken, rat and man. U5 RNAs are encoded by multiple genes

Preparations of chicken, rat and human nuclear 5S RNA contain two sets of molecules. The set with the lowest electrophoretic mobility (5Sa) contains RNAs identical or closely related to ribosomal 5S RNA from the corresponding animal species. In HeLa cells and rat brain, we only detected an RNA identical to the ribosomal 5S RNA. In hen brain and liver, we found other species differing by a limited number of substitutions. The results suggest that mutated 5S genes may be expressed differently according to the cell type. The set with the highest mobility corresponds to U5 RNA. In both rat brain and HeLa cells, U5 RNA was found to be composed of 4 and 5 different molecules respectively (U5A, U5B1-4) differing by a small number of substitutions or insertions. In hen brain, no U5B was detected but U5A' differing from U5A by the absence of the 3'-terminal adenosine. All the U5 RNAs contain the same set of modified nucleotides. They also have the same secondary structure which consists of two hairpins joined together by a 17 nucleotide long single-stranded region. The 3' half of the molecule has a compact conformation. Together, the results suggest that U5 RNAs are transcribed from a multigene family and that mutated genes may be expressed as far as secondary structure is conserved. The conformation of U5 RNA is likely to be related to its function and it is of interest to mention that several similarities of structure are found between U5 and U1A RNA.     

家蚕内网虫属微孢虫核糖体小亚单位RNA(SSUrRNA)核心序列的克隆和序列分析

Endoreticulatus bombycis is a new pathogenic microspordia isolated from the silkworm larvae.With polymerase chain reaction(PCR) method,we amplified a fragment of the core sequence of the small subunit ribosomal RNA( SSUr-RNA) of Endoreticulatus bombycis.The SSUrRNA fragment was inserted into pMD18-T Vector and then cloned.It had a length of 1230 nucleotides and a percentage GC content of 51.3%.The accession number in Genbank is gill 181769|AY009115.The secondary structure model of the SSUrRNA of Endoreticulatus bombycis was constructed both on the bases of the sequence alignment and RNAFOLD program of the PC-GENE package.The secondary structure model revealed that Endoreticulatus bombycis lacked many cukaryotic hclices.such as heli10,helix 11.helix 18,helix 43 and helix 46,but it has V4 region and has more of prokaryotic character.Analyzed by Blast,Endoreticulatus bombycis.Endoreticulatus schubergi and pleistophora sp.(Sd-Nu-IW8201) have a high similarity,over 98%,Phylogeny tree of Endoreticulatus and Pleistophora species showed that Endoreticulatus and Pleistophora sp.(Sd0Nu-IW8201) was in a group and the other Pleistophora species were in another group[Acta Zoologica Sinica 49(3):414-420,2001].     

Comparative sequence analysis and patterns of covariation in RNA secondary structures

A novel method of RNA secondary structure prediction based on a comparison of nucleotide sequences is described. This method correctly predicts nearly all evolutionarily conserved secondary structures of five different RNAs: tRNA, 5S rRNA, bacterial ribonuclease P (RNase P) RNA, eukaryotic small subunit rRNA, and the 3' untranslated region (UTR) of the Drosophila bicoid (bcd) mRNA. Furthermore, covariations occurring in the helices of these conserved RNA structures are analyzed. Two physical parameters are found to be important determinants of the evolution of compensatory mutations: the length of a helix and the distance between base-pairing nucleotides. For the helices of bcd 3' UTR mRNA and RNase P RNA, a positive correlation between the rate of compensatory evolution and helix length is found. The analysis of Drosophila bcd 3' UTR mRNA further revealed that the rate of compensatory evolution decreases with the physical distance between base-pairing residues. This result is in qualitative agreement with Kimura's model of compensatory fitness interactions, which assumes that mutations occurring in RNA helices are individually deleterious but become neutral in appropriate combinations.     

The small nuclear RNAs of the cellular slime mold Dictyostelium discoideum. Isolation and characterization

Three species of small nuclear RNA from the lower eucaryote Dictyostelium discoideum have been isolated and characterized with regard to size, cellular abundance, modified nucleotide content, and 5'-end structures. Previous studies had shown that the nuclei of mammalian cells contain a number of discrete low molecular weight, nonribosomal, nontransfer RNA molecules known as small nuclear RNAs. The mammalian small nuclear RNAs range in size from approximately 100 to 250 nucleotides and are quite abundant, in some cases approaching ribosomal RNA in number of copies/cell. Some of these molecules have an unusual cap structure at their 5'-ends similar to that found on eucaryotic messenger RNAs, and a number contain a characteristic set of internal modifications as well. Our results indicate that the small nuclear RNAs of Dictyostelium resemble their counterparts in higher eucaryotic cells structurally, but are present in significantly fewer copies/cell. The implications of these findings for small nuclear RNA function are discussed.     

Effects of single-base bulges on intercalator binding to small RNA and DNA hairpins and a ribosomal RNA fragment

The way in which a single-base bulge might affect the structure of an RNA helix has been examined by preparing a series of six RNA hairpins, all with seven base pairs and a four-nucleotide loop. Five of the hairpins have single-base bulges at different positions. The intercalating cleavage reagent (methidiumpropyl)-EDTA-Fe(II) [MPE-Fe(II)] binds preferentially at a CpG sequence in the helix lacking a bulge and in four of the five hairpins with bulges. Hairpins with a bulge one or two bases to the 3' side of the CpG sequence bind ethidium 4-5-fold more strongly than the others. V1 RNase, which is sensitive to RNA backbone conformation in helices, detects a conformational change in all of the helices when ethidium binds; the most dramatic changes, involving the entire hairpin stem, are in one of the two hairpins with enhanced ethidium affinity. Only a slight conformational change is detected in the hairpin lacking a bulge. A bulge adjacent to a CpG sequence in a 100-nucleotide ribosomal RNA fragment enhances MPE-Fe(II) binding by an order of magnitude. These results extend our previous observations of bulges at a single position in an RNA hairpin [White, S. A., & Draper, D.E. (1987) Nucleic Acids Res. 15, 4049] and show that (1) a structural change in an RNA helix may be propagated for several base pairs, (2) bulges tend to increase the number of conformations available to a helix, and (3) the effects observed in small RNA hairpins are relevant to larger RNAs with more extensive structure. A bulge in a DNA hairpin identical in sequence with the RNA hairpins does not enhance MPE-Fe(II) binding affinity, relative to a control DNA hairpin. The effects of bulges on ethidium intercalation are evidently modulated by helix structure.     

Modelling the secondary structures of slippage-prone hypervariable RNA regions: the example of the tiger beetle 18S rRNA variable region V4.

Variable regions within ribosomal RNAs frequently vary in length as a result of incorporating products of slippage. This makes constructing secondary structure models problematic because base homology is difficult or impossible to establish between species. Here, we model such a region by comparing the results of the MFOLD suboptimal folding algorithm for different species to identify conserved structures. Based on the reconstruction of base change on a phylogenetic tree of the species and comparison against null models of character change, we devise a statistical analysis to assess support of these structures from compensatory and semi-compensatory (i.e. G.C to G.U or A.U to G.U) mutations. As a model system we have used variable region V4 from cicindelid (tiger beetle) small subunit ribosomal RNAs (SSU rRNAs). This consists of a mixture of conserved and highly variable subregions and has been subject to extensive comparative analysis in the past. The model that results is similar to a previously described model of this variable region derived from a different set of species and contains a novel structure in the central, highly variable part. The method we describe may be useful in modelling other RNA regions that are subject to slippage.