Conserved 5S rRNA complement to tRNA is not required for protein synthesis

5S rRNA and ribosome

5S rRNA is an integral component of the ribosome of all living organisms. It is known that the ribosome without 5S rRNA is functionally inactive. However, the question about the specific role of this RNA in functioning of the translation apparatus is still open. This review presents a brief history of the discovery of 5S rRNA and studies of its origin and localization in the ribosome. The previously expressed hypotheses about the role of this RNA in the functioning of the ribosome are discussed considering the unique location of 5S rRNA in the ribosome and its intermolecular contacts. Based on analysis of the current data on ribosome structure and its functional complexes, the role of 5S rRNA as an intermediary between ribosome functional domains is discussed.

Intragenomic heterogeneity of the 16S rRNA gene in strain UFO1 caused by a 100-bp insertion in helix 6

Two different versions of the 16S rRNA gene, one of which contained an unusual 100-bp insertion in helix 6, were detected in isolate UFO1 acquired from the Oak Ridge Integrated Field-Research Challenge (ORIFRC) site in Tennessee. rRNA was extracted from UFO1 and analyzed by reverse transcriptase-quantitative PCR with insert- and non-insert-specific primers; only the noninsert 16S rRNA gene sequence was detected. Similarly, PCR-based screening of a cDNA library (190 clones) constructed from reverse-transcribed rRNA from UFO1 did not detect any clones containing the 100-bp insert. Examination of cDNA with primers specific to the insert-bearing 16S rRNA gene, but downstream of the insert, suggests that the insert was excised from rRNA. Inspection of other 16S rRNA genes in the GenBank database revealed that a homologous insert sequence, also found in helix 6, has been reported in other environmental clones, including those acquired from ORIFRC enrichments. These findings demonstrate the existence of widely divergent copies of the 16S rRNA gene within the same organism, which may confound 16S rRNA gene-based methods of estimating microbial diversity in environmental samples.

Selective Recovery of 16S rRNA Sequences from Natural Microbial Communities in the Form of cDNA

Cloning of cDNA obtained from 16S rRNA (16S rcDNA) selectively retrieves species-specific sequence information useful for analyzing the composition and structure of natural microbial communities. With this technique we obtained recombinant 16S rcDNA libraries from Escherichia coli and from a model hot-spring cyanobacterial-mat community. The recombinant plasmids contained exclusively 16S rRNA-derived inserts. This selective approach is independent of biasing culture techniques and eliminates the laborious screening required to locate 16S rRNA gene-bearing recombinants in genomic DNA libraries obtained from natural communities.

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.

Potential New Antibiotic Sites in the Ribosome Revealed by Deleterious Mutations in RNA of the Large Ribosomal Subunit

The ribosome is the main target for antibiotics that inhibit protein biosynthesis. Despite the chemical diversity of the known antibiotics that affect functions of the large ribosomal subunit, these drugs act on only a few sites corresponding to some of the known functional centers. We have used a genetic approach for identifying structurally and functionally critical sites in the ribosome that can be used as new antibiotic targets. By using randomly mutagenized rRNA genes, we mapped rRNA sites where nucleotide alterations impair the ribosome function or assembly and lead to a deleterious phenotype. A total of 77 single-point deleterious mutations were mapped in 23 S rRNA and ranked according to the severity of their deleterious phenotypes. Many of the mutations mapped to familiar functional sites that are targeted by known antibiotics. However, a number of mutations were located in previously unexplored regions. The distribution of the mutations in the spatial structure of the ribosome showed a strong bias, with the strongly deleterious mutations being mainly localized at the interface of the large subunit and the mild ones on the solvent side. Five sites where deleterious mutations tend to cluster within discrete rRNA elements were identified as potential new antibiotic targets. One of the sites, the conserved segment of helix 38, was studied in more detail. Although the ability of the mutant 50 S subunits to associate with 30 S subunits was impaired, the lethal effect of mutations in this rRNA element was unrelated to its function as an intersubunit bridge. Instead, mutations in this region had a profound deleterious effect on the ribosome assembly.

Phylogeny of Bacteroides, Prevotella, and Porphyromonas spp. and related bacteria

The phylogenetic structure of the bacteroides subgroup of the cytophaga-flavobacter-bacteroides (CFB) phylum was examined by 16S rRNA sequence comparative analysis. Approximately 95% of the 16S rRNA sequence was determined for 36 representative strains of species of Prevotella, Bacteroides, and Porphyromonas and related species by a modified Sanger sequencing method. A phylogenetic tree was constructed from a corrected distance matrix by the neighbor-joining method, and the reliability of tree branching was established by bootstrap analysis. The bacteroides subgroup was divided primarily into three major phylogenetic clusters which contained most of the species examined. The first cluster, termed the prevotella cluster, was composed of 16 species of Prevotella, including P. melaninogenica, P. intermedia, P. nigrescens, and the ruminal species P. ruminicola. Two oral species, P. zoogleoformans and P. heparinolytica, which had been recently placed in the genus Prevotella, did not fall within the prevotella cluster. These two species and six species of Bacteroides, including the type species B. fragilis, formed the second cluster, termed the bacteroides cluster. The third cluster, termed the porphyromonas cluster, was divided into two subclusters. The first contained Porphyromonas gingivalis, P. endodontalis, P. asaccharolytica, P. circumdentaria, P. salivosa, [Bacteroides] levii (the brackets around genus are used to indicate that the species does not belong to the genus by the sensu stricto definition), and [Bacteroides] macacae, and the second subcluster contained [Bacteroides] forsythus and [Bacteroides] distasonis. [Bacteroides] splanchnicus fell just outside the three major clusters but still belonged within the bacteroides subgroup. With few exceptions, the 16 S rRNA data were in overall agreement with previously proposed reclassifications of species of Bacteroides, Prevotella, and Porphyromonas. Suggestions are made to accommodate those species which do not fit previous reclassification schemes.

Phylogeny of the Pasteurellaceae as determined by comparison of 16S ribosomal ribonucleic acid sequences

Previously, virtually complete 16S ribosomal ribonucleic acid sequences were determined for 54 strains of species in the family Pasteurellaceae. The sequences for 16 additional strains have been determined, bringing the total number of strains sequenced to 70. The additional strains include: Actinobacillus hominis, A. muris, A. salpingitis, Pasteurella bettyae, P. mairii, P. testudinis, and Bisgaard taxa 2, 3, 5, 6, 7, 8, 9, 13, and 14 (2 strains). A phylogenetic tree was constructed based upon sequence similarity using the Neighbor-Joining method. The additional sequence information and phylogenetic analysis generally supported our previously described phylogenetic structure for the family Pasteurellaceae. Cluster 1, containing Haemophilus sensu stricto, was unchanged. P. mairii was closely related to P. aerogenes and Bisgaard taxon 6 was related to H. somnus in Cluster 2. A. salpingitidis and Bisgaard taxa 2, 3, 7, and 13 fell in Cluster 3 which contains Pasteurella sensu stricto. A. hominis was closely related to Actinobacillus sensu stricto species in Cluster 4A. Bisgaard taxa 5, 8, 9 and P. bettyae fell in Cluster 4B. A. muris was related to P. pneumotropica in Cluster 5. Haemophilus parainfluenzae strains branched deeply as a 6th cluster. Bisgaard taxon 14 and P. testudinis formed a 7th cluster which branched deeper than any previously described clusters in the family Pasteurellaceae. The branching was extremely complex and taxonomic division of the family into phylogenetically and phenotypically coherent genera will be difficult.

The phylogeny of marine and freshwater caulobacters reflects their habitat

Caulobacter is a distinctive genus of prosthecate bacteria. Because caulobacters adhere to surfaces and are found in diverse locales, their role in oligotrophic environments and bacterial biofilm communities is of interest. The phylogenetic relationships of a group of marine and freshwater caulobacters were examined in part to address whether the taxonomic grouping of these bacteria (based primarily on morphological characters) was consistent with 16S rRNA sequence divergence. The caulobacters examined (9 marine and 11 freshwater species or strains) were affiliated with the alpha proteobacteria. They made up a diverse yet, with the possible exception of a strain of Caulobacter subvibrioides, coherent assemblage. The diversity was most apparent in a comparison of freshwater and marine isolates; an early divergence within the main caulobacter lineage generally corresponded to strains isolated from freshwater and marine habitats. The marine caulobacter assemblage was not exclusive; it also embraced strains of marine hyphomonads and Rhodobacter capsulatus. We hypothesize that these genera are derived from more ancestral caulobacters. Overall, the data are consistent with the interpretation that all of the caulobacters examined, with the possible exception of C. subvibrioides, are ancestrally related, albeit anciently, and that most often division by terrestrial and marine habitats corresponds to an early evolutionary divergence within the genus.

Phylogeny of 54 representative strains of species in the family Pasteurellaceae as determined by comparison of 16S rRNA sequences

Virtually complete 16S rRNA sequences were determined for 54 representative strains of species in the family Pasteurellaceae. Of these strains, 15 were Pasteurella, 16 were Actinobacillus, and 23 were Haemophilus. A phylogenetic tree was constructed based on sequence similarity, using the Neighbor-Joining method. Fifty-three of the strains fell within four large clusters. The first cluster included the type strains of Haemophilus influenzae, H. aegyptius, H. aphrophilus, H. haemolyticus, H. paraphrophilus, H. segnis, and Actinobacillus actinomycetemcomitans. This cluster also contained A. actinomycetemcomitans FDC Y4, ATCC 29522, ATCC 29523, and ATCC 29524 and H. aphrophilus NCTC 7901. The second cluster included the type strains of A. seminis and Pasteurella aerogenes and H. somnus OVCG 43826. The third cluster was composed of the type strains of Pasteurella multocida, P. anatis, P. avium, P. canis, P. dagmatis, P. gallinarum, P. langaa, P. stomatis, P. volantium, H. haemoglobinophilus, H. parasuis, H. paracuniculus, H. paragallinarum, and A. capsulatus. This cluster also contained Pasteurella species A CCUG 18782, Pasteurella species B CCUG 19974, Haemophilus taxon C CAPM 5111, H. parasuis type 5 Nagasaki, P. volantium (H. parainfluenzae) NCTC 4101, and P. trehalosi NCTC 10624. The fourth cluster included the type strains of Actinobacillus lignieresii, A. equuli, A. pleuropneumoniae, A. suis, A. ureae, H. parahaemolyticus, H. parainfluenzae, H. paraphrohaemolyticus, H. ducreyi, and P. haemolytica. This cluster also contained Actinobacillus species strain CCUG 19799 (Bisgaard taxon 11), A. suis ATCC 15557, H. ducreyi ATCC 27722 and HD 35000, Haemophilus minor group strain 202, and H. parainfluenzae ATCC 29242. The type strain of P. pneumotropica branched alone to form a fifth group. The branching of the Pasteurellaceae family tree was quite complex. The four major clusters contained multiple subclusters. The clusters contained both rapidly and slowly evolving strains (indicated by differing numbers of base changes incorporated into the 16S rRNA sequence relative to outgroup organisms). While the results presented a clear picture of the phylogenetic relationships, the complexity of the branching will make division of the family into genera a difficult and somewhat subjective task. We do not suggest any taxonomic changes at this time.

Helicobacter mustelae isolation from feces of ferrets: evidence to support fecal-oral transmission of a gastric Helicobacter

Helicobacter mustelae has been isolated from stomachs of ferrets with chronic gastritis and ulcers. When H. mustelae is inoculated orally into H. mustelae-negative ferrets, the animals become colonized and develop gastritis, a significant immune response, and a transient hypochlorhydria. All of these features mimic Helicobacter pylori-induced gastric disease in humans. Because the epidemiology of H. pylori infection is poorly understood and its route of transmission is unknown, the feces of weanling and adult ferrets were cultured for the presence of H. mustelae. H. mustelae was isolated from the feces of 11 of 36 ferrets by using standard helicobacter isolation techniques. H. mustelae was identified by biochemical tests, ultrastructural morphology, reactivity with specific DNA probes, and 16S rRNA sequencing. H. mustelae was not recovered from 20-week-old ferrets which had been H. mustelae positive as weanlings, nor was H. mustelae recovered from 1-year-old ferrets. Isolation of H. mustelae from feces may correspond to periods of transient hypochlorhydria, or H. mustelae may be shed in feces intermittently. The H. mustelae-colonized ferret provides an ideal model for studying the pathogenesis and transmission of H. pylori-induced gastric disease.

Phylogenetic analysis of the spirochetes

The 16S rRNA sequences were determined for species of Spirochaeta, Treponema, Borrelia, Leptospira, Leptonema, and Serpula, using a modified Sanger method of direct RNA sequencing. Analysis of aligned 16S rRNA sequences indicated that the spirochetes form a coherent taxon composed of six major clusters or groups. The first group, termed the treponemes, was divided into two subgroups. The first treponeme subgroup consisted of Treponema pallidum, Treponema phagedenis, Treponema denticola, a thermophilic spirochete strain, and two species of Spirochaeta, Spirochaeta zuelzerae and Spirochaeta stenostrepta, with an average interspecies similarity of 89.9%. The second treponeme subgroup contained Treponema bryantii, Treponema pectinovorum, Treponema saccharophilum, Treponema succinifaciens, and rumen strain CA, with an average interspecies similarity of 86.2%. The average interspecies similarity between the two treponeme subgroups was 84.2%. The division of the treponemes into two subgroups was verified by single-base signature analysis. The second spirochete group contained Spirochaeta aurantia, Spirochaeta halophila, Spirochaeta bajacaliforniensis, Spirochaeta litoralis, and Spirochaeta isovalerica, with an average similarity of 87.4%. The Spirochaeta group was related to the treponeme group, with an average similarity of 81.9%. The third spirochete group contained borrelias, including Borrelia burgdorferi, Borrelia anserina, Borrelia hermsii, and a rabbit tick strain. The borrelias formed a tight phylogenetic cluster, with average similarity of 97%. THe borrelia group shared a common branch with the Spirochaeta group and was closer to this group than to the treponemes. A single spirochete strain isolated fromt the shew constituted the fourth group. The fifth group was composed of strains of Serpula (Treponema) hyodysenteriae and Serpula (Treponema) innocens. The two species of this group were closely related, with a similarity of greater than 99%. Leptonema illini, Leptospira biflexa, and Leptospira interrogans formed the sixth and most deeply branching group. The average similarity within this group was 83.2%. This study represents the first demonstration that pathogenic and saprophytic Leptospira species are phylogenetically related. The division of the spirochetes into six major phylogenetic clusters was defined also by sequence signature elements. These signature analyses supported the conclusion that the spirochetes represent a monophylectic bacterial phylum.

Detection and identification of Treponema hyodysenteriae by using oligodeoxynucleotide probes complementary to 16S rRNA

Oligodeoxynucleotide probes (17 and 28 bases long) complementary to a unique region of Treponema hyodysenteriae 16S rRNA were developed. These probes bound specifically to partially purified rRNA and whole-cell rRNA of T. hyodysenteriae. No binding to partially purified rRNA or whole-cell rRNA of Treponema innocens, Treponema succinifaciens, Treponema bryantii, or Escherichia coli occurred under stringent conditions. The 28-base probe was 5 to 10 times more sensitive than the 17-base probe when hybridized with T. hyodysenteriae rRNA. The 28-base probe detected T. hyodysenteriae in the feces of experimentally inoculated pigs exhibiting clinical signs of swine dysentery.

Identification of Francisella species and discrimination of type A and type B strains of F. tularensis by 16S rRNA analysis

Tularemia is a zoonotic disease, occurring throughout the Northern Hemisphere. The causative agent, the bacterium Francisella tularensis, is represented by two main types. Type A is found in North America, whereas type B is mainly found in Asia and Europe and to a minor extent in North America. No routine technique for rapid diagnosis of tularemia has been generally applied. We have partially sequenced 16S rRNAs of two F. tularensis strains, as well as the closely related Francisella novicida. Of 550 nucleotides analyzed, only one difference in 16S rRNA primary sequence was found. This 16S rRNA analysis enabled the construction of oligonucleotides to be used as genus- and type-specific probes. Such probes were utilized for the establishment of a method for rapid and selective detection of the organism. This method allowed identification of Francisella spp. at the level of genus and also discrimination of type A and type B strains of F. tularensis. The analysis also permitted the detection of F. tularensis in spleen tissue from mice infected with the bacterium. The results presented will enable studies on the epizootiology and epidemiology of Francisella spp.

Fluorescent-oligonucleotide probing of whole cells for determinative, phylogenetic, and environmental studies in microbiology

Fluorescent-dye-conjugated oligonucleotides were used to classify 14 Fibrobacter strains by fluorescence microscopy. On the basis of partial 16S rRNA sequences of six Fibrobacter strains, four hybridization probes were designed to discriminate between the species Fibrobacter succinogenes and Fibrobacter intestinalis and to identify F. succinogenes subsp. succinogenes. After in situ hybridization to whole cells of the six sequenced strains, epifluorescence microscopy confirmed probe specificity. The four probes were then used to make presumptive species and subspecies assignments of eight additional Fibrobacter strains not previously characterized by comparative sequencing. These assignments were confirmed by comparative sequencing of the 16S rRNA target regions from the additional organisms. Single-mismatch discrimination between certain probe and nontarget sequences was demonstrated, and fluorescent intensity was shown to be enhanced by hybridization to multiple probes of the same specificity. The direct detection of F. intestinalis in mouse cecum samples demonstrated the application of this technique to the characterization of complex natural samples.

Identification of Vibrio anguillarum in fish by using partial 16S rRNA sequences and a specific 16S rRNA oligonucleotide probe

16S rRNA from seven different Vibrio anguillarum strains was partially sequenced and compared. From this sequence information we could design a 25-base-long oligonucleotide and use it as a specific probe for identification of V. anguillarum. This was determined by RNA-DNA colony hybridization and slot-blot hybridization. Strong, specific hybridization to the probe was observed for all V. anguillarum strains tested. Furthermore, no cross-hybridization could be seen against five other bacterial species. The detection limit was 5 x 10(3) bacteria per ml. It was even possible to detect V. anguillarum, by slot-blot hybridization, directly in a homogenized kidney from a fish that had died of vibriosis. The partial sequence information revealed small but significant differences between strains of the same species. These sequence differences are sufficiently significant to allow serotyping on the RNA level. Comparing strains of different serotypes revealed a 10-base and an 11-base difference in V. anguillarum serotypes O8 and O9, respectively, in a 122-base partial sequence.

The conserved 900 stem/loop region in Escherichia coli 16S ribosomal RNA is not required for protein synthesis

Plasmid pPM114 carries the Escherichia coli 16S ribosomal RNA gene under the control of a T7 promoter. It can generate in vitro transcribed 16S rRNA that can be assembled into functional 30S ribosomal subunits. Two deletion mutants were derived from pPM114, by partial or total deletion of the conserved 900 stem/loop region of the 16S rRNA. These mutants, pMG delta 10 and pMG delta 23, respectively lack bases 895 to 904 and 889 to 911 of the 16S rRNA. The amputated 16S rRNA transcripts synthesized from these mutated plasmids were assembled into 30S subunits which were as active under the direction of an artificial or a natural messenger as subunits reconstructed with the full-length 16S rRNA transcript. They also responded as well to the stimulation of misreading by streptomycin, although the deleted region is proximal to the streptomycin binding domain. However, when we attempted to delete the 895-904 or 889-911 region from the 16S rRNA gene in plasmid pKK3535 which carries the rrnB operon, no transformants harbouring plasmids with one of these deletions could be recovered. These observations suggest that the 900 stem/loop region of the 16S rRNA is not required for the ribosomal function but is probably essential for important cell regulatory functions.

Exploration of the L18 binding site on 5S RNA by deletion mutagenesis

Several deletion variants of E. coli 5S RNA have been constructed and produced either in vivo or in vitro using T7 RNA Polymerase. Their structures and ribosomal protein L18 binding properties have been examined. All of them are similar to wild-type 5S RNA in their helix II-III regions, where L18 binds [Huber, P.W. and Wool, I.G. (1984) Proc. Natl. Acad. Sci. (USA) 81, 322-326; Douthwaite, S., Christensen, A., and Garrett, R.A. (1982) Biochemistry 21, 2313-2320.], by NMR criteria. However, none of the molecules examined that lack the helix IV-helix V stem bind L18 efficiently, even though that portion of 5S RNA is outside the L18 footprint. The L18 binding site is clearly more than a simple hairpin loop.

In vitro incorporation of eubacterial, archaebacterial and eukaryotic 5S rRNAs into large ribosomal subunits of Bacillus stearothermophilus

Bacillus stearothermophilus large ribosomal subunits were reconstituted in the presence of 5S rRNAs from different origins and tested for their biological activities. The results obtained have shown that eubacterial and archaebacterial 5S rRNAs can easily substitute for B. stearothermophilus 5S rRNA in the reconstitution, while eukaryotic 5S rRNAs yield ribosomal subunits with reduced biological activities. From our results we propose an interaction between nucleotides 42-47 of 5S rRNA and nucleotides 2603-2608 of 23S rRNA during the assembly of the 50S ribosomal subunit. Other experiments with eukaryotic 5.8S rRNAs reveal, if at all, a very low incorporation of these RNA species into the reconstituted ribosomes.

Phylogenetic group-specific oligodeoxynucleotide probes for identification of single microbial cells

Examination of collections of 16S rRNA sequences revealed sequence domains that were unique to (and invariant within) the three primary lines of cellular descent: the archaebacteria, the eubacteria, and the eucaryotes. Oligodeoxynucleotides complementary to these conserved sequence domains were synthesized and used as hybridization probes. Each of the radiolabeled probes specifically hybridized to nylon membrane-bound 16S rRNA from the targeted kingdom. A probe complementary to a universally conserved sequence in 16S rRNAs was used as a positive control, while its complement provided a negative control for nonspecific binding. The abilities of the probes to bind specifically to whole, fixed cells representing a broad array of phylogenetic diversity were tested in whole-cell dot blot assays. Again, all of the probes specifically bound the targeted groups. By microautoradiography, the method was extended to permit phylogenetic identification of single cells microscopically.

Campylobacter pylori, the spiral bacterium associated with human gastritis, is not a true Campylobacter sp

Comparison of partial 16S rRNA sequences from representative Campylobacter species indicates that the Campylobacter species form a previously undescribed basic eubacterial group, which is related to the other major groups only by very deep branching. This analysis was extended to include the spiral bacterium associated with human gastritis, Campylobacter pylori (formerly Campylobacter pyloridis). The distance between C. pylori and the other Campylobacter species is sufficient to exclude the pyloric organism from the Campylobacter genus. The results indicate that C. pylori is more closely related to Wolinella succinogenes than it is to the other Campylobacter species inspected. Another close relative of the campylobacters was found to be Thiovulum, a sulfide-dependent marine bacterium.

500-MHz proton homonuclear Overhauser evidence for additional base pair in the common arm of eukaryotic ribosomal 5S RNA: wheat germ

A "common-arm" fragment from wheat germ (Triticum aestivum) 5S RNA has been produced by enzymatic cleavage with RNase T1 and sequenced via autoradiography of electrophoresis gels for the end-labeled fragments obtained by further RNase T1 partial digestion. The existence, base pair composition, and base pair sequence of the common arm are demonstrated for the first time by means of proton 500-MHz nuclear magnetic resonance. From Mg2+ titration, temperature variation, ring current calculations, sequence comparisons, and proton homonuclear Overhauser enhancement experiments, additional base pairs in the common arm of the eukaryotic 5S RNA secondary structure are detected. Two base pairs, G41 X C34 and A42 X U33 in the hairpin loop, could account for the lack of binding between the conserved GAAC segment of 5S RNA and the conserved Watson-Crick-complementary GT psi C segment of tRNAs.

In vitro construction of yeast tRNAAsp variants: nucleotide substitutions and additions in T-stem and T-loop

A procedure for the construction of 3'-end labelled yeast tRNAAsp harboring substitutions or additions of any desired nucleotide in T-stem and T-loop (position 57 to 61) has been developed. This was done by in vitro enzymatic manipulations of the yeast tRNAAsp involving specific hydrolysis with RNases, phosphorylation and dephosphorylation with T4 polynucleotide kinase and ligation with T4 RNA ligase. Using this procedure we have replaced conserved or semi-conserved nucleotides located in position 57 to 61 of yeast tRNAAsp. We have also constructed different yeast tRNAAsp with eight bases instead of seven in T-loop. Further use of these tRNAAsp variants will be discussed with the help of the crystallographic three-dimensional structure.

Structural analysis of 5S rRNA, 5S rRNA-protein complexes and ribosomes employing RNase H and d(GTTCGG)

The hybridization of d(GTTCGG) to eubacterial 5S rRNAs, 5S rRNA-protein complexes, 70S ribosomes and 50S and 30S ribosomal subunits was investigated. This oligonucleotide, which may be considered to be an analogue of the T psi CG loop of tRNAs, was chosen in order to investigate a possible interaction between tRNAs with ribosomal components during protein synthesis. The hybridization was analysed by RNase H hydrolysis studies and, in the case of the ribosomes and ribosomal subunits, in addition with the radioactively labelled oligodeoxyribonucleotide in binding studies. The results obtained lead to the conclusion that nucleotides in loop c, i.e. positions 42-47, are available for oligonucleotide interaction in free Escherichia coli and Bacillus stearothermophilus 5S rRNAs and not available in the corresponding 5S rRNA-protein complexes. The 70S ribosomes and ribosomal subunits did not interact with the oligonucleotide. Under the assumption that d(GTTCGG) is an analogue of the T psi CG loop of tRNAs and in view of the results obtained, we conclude that in the unprogrammed ribosomes the T psi CG loop of tRNAs does not interact via standard Watson-Crick base pairs with the ribosomal 5S, 16S or 23S RNAs.

Anticodon-anticodon interaction induces conformational changes in tRNA: yeast tRNAAsp, a model for tRNA-mRNA recognition

The crystal structure of yeast tRNAAsp enables visualization of an anticodon-anticodon interaction at the molecular level. Except for differences in the base stacking and twist, the overall conformation of the anticodon loop is quite similar to that of yeast tRNAPhe. The anticodon nucleotide triplets, GUC, of two symmetrically related molecules form a minihelix of the RNA type 11. The modified base m1G37 stacks on both sides of the triplets and enforces the continuity with the anticodon stems. Anticodon association induces long-range conformational changes in the region of the dihydrouracil and thymine loops. Experimental evidence includes the variation in the distribution of temperature factors between yeast tRNAPhe and tRNAAsp, the difference in the self-splitting patterns of tRNAAsp in crystal and solution, and the differential accessibility of cytidines to dimethyl sulfate in free and duplex tRNAAsp. These observations are linked to the fragility and disruption of the G.C Watson-Crick base pair at the corner of the molecule formed by the dihydrouracil and thymine loops.

Rapid determination of 16S ribosomal RNA sequences for phylogenetic analyses

Although the applicability of small subunit ribosomal RNA (16S rRNA) sequences for bacterial classification is now well accepted, the general use of these molecules has been hindered by the technical difficulty of obtaining their sequences. A protocol is described for rapidly generating large blocks of 16S rRNA sequence data without isolation of the 16S rRNA or cloning of its gene. The 16S rRNA in bulk cellular RNA preparations is selectively targeted for dideoxynucleotide-terminated sequencing by using reverse transcriptase and synthetic oligodeoxynucleotide primers complementary to universally conserved 16S rRNA sequences. Three particularly useful priming sites, which provide access to the three major 16S rRNA structural domains, routinely yield 800-1000 nucleotides of 16S rRNA sequence. The method is evaluated with respect to accuracy, sensitivity to modified nucleotides in the template RNA, and phylogenetic usefulness, by examination of several 16S rRNAs whose gene sequences are known. The relative simplicity of this approach should facilitate a rapid expansion of the 16S rRNA sequence collection available for phylogenetic analyses.

Interaction of unfolded tRNA with the 3'-terminal region of E. coli 16S ribosomal RNA

Fragments of tRNA possessing a free TpsiC-loop or a free D-loop form stable complexes with the colicin fragment (1494-1542) of 16S ribosomal RNA from E. coli. The colicin fragment does not bind to tRNA in which the T-loop and the D-loop are involved in tertiary interactions. Colicin cleavage of the 16S rRNA from E. coli is inhibited by aminoacyl-tRNA or tRNA fragments, indicating that a similar interaction may take place on the intact 70S ribosomes. The oligonucleotide d(G-T-T-C-G-A)homologous to the conserved sequence G-T-psi-C-Pu-(m1)A in the TpsiC-region of many elongator tRNAs binds to the conserved sequence U-C-G-mU-A-A-C (1495-1501) of the 16S rRNA. It is suggested that the 3'-end of the 16S rRNA may provide the part of the binding site for the elongator tRNAs on bacterial ribosomes.

Identification of the site of cross-linking in 16S rRNA of an aromatic azide photoaffinity probe attached to the 5'-anticodon base of A site bound tRNA

The site of Escherichia coli 16S ribosomal RNA cross-linked to the 5'-anticodon base of A site bound E. coli valyl-tRNA was identified. Cross-linking was via the affinity probe 6-[(2-nitro-4-azidophenyl)amino]caproate (NAK) or 3-[[2-[(2-nitro-4-azidophenyl)amino]ethyl]dithio]propionate (SNAP) attached to the carboxyl group of the 5'-anticodon base 5-(carboxyethoxy)uridine via an ethylenediamine spacer [Gornicki, P., Ciesiolka, J., & Ofengand, J. (1985) Biochemistry (preceding paper in this issue)]. With both probes, RNase T1 digestion of the isolated 16S RNA-tRNA covalent complex, 5'-32P postlabeling, and gel electrophoresis yielded two oligonucleotides larger than any fragments from non-cross-linked tRNA or rRNA. Appearance of the oligomers was dependent on the presence of the probe on the tRNA. Unmodified tRNA in the A and/or P sites did not yield any product. The presence of elongation factor Tu in the incubation mixture was also required. Dithiothreitol (DDT) treatment of the SNAP-induced covalent complex prior to electrophoresis also abolished the oligomers. Only the larger of the two oligomers (present in a 3:1 ratio) was sequenced. The SNAP dimer was cleaved with DTT, and the rRNA and tRNA oligomers were separated and sequenced as monomers. The NAK dimer was sequenced without cleavage by taking advantage of the differences in electrophoretic mobility among sequence and/or composition isomers of the same length. In both cases, the rRNA oligomer was identified as UACACACCG1401, and the nucleotide cross-linked was shown to be the C1400 residue. The expected tRNA modification site was also identified.(ABSTRACT TRUNCATED AT 250 WORDS)

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

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

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.

Cross-linking of the anticodon of Escherichia coli and Bacillus subtilis acetylvalyl-tRNA to the ribosomal P site. Characterization of a unique site in both E. coli 16S and yeast 18S ribosomal RNA

The nucleotide residues involved in the cross-link between P site bound acetylvalyl-tRNA (AcVal-tRNA) and 16-18S rRNA have been identified. This cross-link was formed by irradiation of Escherichia coli or Bacillus subtilis AcVal-tRNA bound to the P site of E. coli ribosomes or by irradiation of E. coli AcVal-tRNA bound to the P site of yeast ribosomes. The three cross-linked RNA heterodimers were obtained in 10-35% purity by disruption of the irradiated ribosome-tRNA complex with sodium dodecyl sulfate followed by sucrose gradient centrifugation. After total digestion with RNase T1, and labeling at either the 5'- or the 3'-end, the cross-linked oligomers could be identified and isolated before and after photolytic splitting of the cross-link. One of the oligomers was shown to be UACACACCG, a unique rRNA nonamer present in an evolutionarily conserved region. This oligomer was found in all three heterodimers. The other oligomer of the dimer had the sequence expected for the RNase T1 product encompassing the anticodon of the tRNA used. The precise site of cross-linking was determined by two novel methods. Bisulfite modification of the oligonucleotide dimer converted all C residues to U, except for any cross-linked C which would be resistant by being part of a cyclobutane dimer. Sequencing gel analysis of the UACACACCG oligomer showed that the C residue protected was the 3'-penultimate C residue, C1400 in E. coli rRNA or C1626 in yeast rRNA.(ABSTRACT TRUNCATED AT 250 WORDS)

Chemical reactivity of E. coli 5S RNA in situ in the 50S ribosomal subunit

E. coli 50S ribosomal subunits were reacted with monoperphthalic acid under conditions in which non-base paired adenines are modified to their 1-N-oxides. 5S RNA was isolated from such chemically reacted subunits and the two modified adenines were identified as A73 and A99. The modified 5S RNA, when used in reconstitution of 50S subunits, yielded particles with reduced biological activity (50%). The results are discussed with respect to a recently proposed three-dimensional structure for 5S RNA, the interaction of the RNA with proteins E-L5, E-L18 and E-L25 and previously proposed interactions of 5S RNA with tRNA, 16S and 23S ribosomal RNAs.

Carbodiimide modification analysis of aminoacylated yeast phenylalanine tRNA: evidence for change in the apex region

The G- and U-specific reagent, carbodiimide was used to probe the solution structure of aminoacylated yeast phenylalanine tRNA. Both quantitative and qualitative changes in modification were observed when the modification patterns of tRNA-CCA(3'OH), tRNA-CCA(3'NH2) and phe-tRNA-CCA(3'NH2) were compared. Five nucleotides were modified in all cases, D16 and G20 in the D-loop, U33 and Gm34 in the anticodon loop and U47, in the region of the extra arm. Small changes occurred in the D-loop with incorporation of the adenosine analogue manifest as new, low levels of modification of G22 (D-stem) and a loss of sensitivity to Mg+2 in modification of D16. Aminoacylation resulted in new modification of G19, modification of a residue in the T psi CG sequence, and a 2.5-fold increase in modification of G22. Taken together the results show that aminoacylation causes increased exposure of bases in the apex region of the L-shaped molecule where the D- and psi-loops are joined. The effects observed could occur as a consequence of stable or dynamic changes in conformation.