Multiple functions of the transcribed spacers in ribosomal RNA operons

Localization of rRNA transcribed spacer domains in the nucleolinus and maternal procentrosomes of surf clam (Spisula) oocytes

The nucleolinus is a nuclear subcompartment long ago posited to play a role in cell division. In a recent study using surf clam oocytes, cytoplasmic foci containing a nucleolinar protein were shown to later recruit γ-tubulin, identifying them as centrosomal precursors. (1) We now demonstrate the presence of structural RNAs from the nucleolinus in these procentrosomes. They include the well-known but poorly understood rRNA-transcribed spacer regions. In situ hybridization revealed a specific and dynamic association of these structural RNAs with the cell division apparatus that extends through the early stages of meiosis. In addition to their bearing on the debate over the nature of centrosome- and spindle-associated RNAs, the observations also suggest that rRNA spacer regions are not simply waste products to be discarded immediately, but may be functional byproducts that play a role in formation of the cell division apparatus.

Stem-loop structure of Cocksfoot mottle virus RNA is indispensable for programmed -1 ribosomal frameshifting

The -1 programmed ribosomal frameshifting (-1 PRF) mechanism utilized by many viruses is dependent on a heptanucleotide slippery sequence and a downstream secondary structure element. In the current study, the RNA structure downstream from the slippery site of cocksfoot mottle sobemovirus (CfMV) was proven to be a 12bp stem-loop with a single bulge and a tetranucleotide loop. Several deletion and insertion mutants with altered stem-loop structures were tested in wheat germ extract (WGE) for frameshifting efficiency. The impact of the same mutations on virus infectivity was tested in oat plants. Mutations shortening or destabilizing the stem region reduced significantly but did not abolish -1 PRF in WGE. The same mutations proved to be deleterious for virus infection. However, extending the loop region to seven nucleotides had no significant effect on frameshifting efficiency in WGE and did not hamper virus replication in infected leaves. This is the first report about the experimentally proven RNA secondary structure directing -1 PRF of sobemoviruses.

Erythromycin- and chloramphenicol-induced ribosomal assembly defects are secondary effects of protein synthesis inhibition

Several protein synthesis inhibitors are known to inhibit ribosome assembly. This may be a consequence of direct binding of the antibiotic to ribosome precursor particles, or it could result indirectly from loss of coordination in the production of ribosomal components due to the inhibition of protein synthesis. Here we demonstrate that erythromycin and chloramphenicol, inhibitors of the large ribosomal subunit, affect the assembly of both the large and small subunits. Expression of a small erythromycin resistance peptide acting in cis on mature ribosomes relieves the erythromycin-mediated assembly defect for both subunits. Erythromycin treatment of bacteria expressing a mixture of erythromycin-sensitive and -resistant ribosomes produced comparable effects on subunit assembly. These results argue in favor of the view that erythromycin and chloramphenicol affect the assembly of the large ribosomal subunit indirectly.

Granulibacter bethesdensis gen. nov., sp. nov., a distinctive pathogenic acetic acid bacterium in the family Acetobacteraceae

A Gram-negative, aerobic, coccobacillus to rod-shaped bacterium was isolated from three patients with chronic granulomatous disease. The organism was subjected to a polyphasic taxonomic study. A multilocus phylogenetic analysis based on the 16S rRNA gene, the internal transcribed spacer (ITS) region and the RecA protein demonstrated that the organism belongs to a new sublineage within the acetic acid bacteria in the family Acetobacteraceae. Phenotypic features are summarized as follows: the organism grew at an optimum temperature of 35-37 degrees C and optimum pH of 5.0-6.5. It produced a yellow pigment, oxidized lactate and acetate, the latter weakly, produced little acetic acid from ethanol and could use methanol as a sole carbon source. The two major fatty acids were a straight-chain unsaturated acid (C18:1omega7c) and C16:0. The DNA base composition was 59.1 mol% G+C. The very weak production of acetic acid from ethanol, the ability to use methanol, the yellow pigmentation and high optimum temperature for growth distinguished this organism from other acetic acid bacteria. The unique phylogenetic and phenotypic characteristics suggest that the bacterium should be classified within a separate genus, for which the name Granulibacter bethesdensis gen. nov., sp. nov. is proposed. The type strain is CGDNIH1T (=ATCC BAA-1260T=DSM 17861T).

Comparative sequence analysis of the internal transcribed spacer 1 of Ochrobactrum species

The internal 16S/23S rDNA (rrs/rrl) internal spacer region 1 (ITS1) of 54 Ochrobactrum strains and close relatives was analysed. Separation of ITS1 containing PCR products by gel-electrophoresis, DGGE, cloning and sequencing revealed ITS1 length and sequence heterogeneity. We found up to 5 different allelic ITS1 stretches within a single strain (Ochrobactrum intermedium LMG 3301T), and 2-3 different ITS1 alleles in O. tritici. Within ITS1, ITS1c, being part of the conserved double-stranded rrn processing stem dsPS1, produced the most reliable segment tree. The overall ITS1, ITS1c and rrs phylogenetic tree topologies were generally consistent, but there was evidence for horizontal rrn (segment) transfer in O. tritici LMG 2134 (formerly O. anthropi). Good correlations were found between ITS1, ITS1c and rrs sequence similarity and DNA-DNA hybridization values indicating that phylogenetic analysis of ITS1 and ITS1c both can be used to preliminarily deduce the phylogenetic affiliation if HGT was excluded. Strains sharing > 96.19% ITS1c (> 95.11% ITS1) similarity fell within a species, and < or = 68.42% ITS1c (< or = 70.33% ITS1) similarity outside a genus. Both ITS1 and ITS1c analysis resolved microdiversity more profoundly than rrs analysis and revealed clades (genomovars) within O. anthropi that were also produced in rep cluster analysis. There was no evidence for habitat-specific ITS1 genomovars within Ochrobactrum species. Diversity of Ochrobactrum was higher in soil than at the rhizoplane below and at the species level. Isolates from soil contained only 1 rrn type whereas isolates from human clinical, animal and rhizoplane specimens could contain more.

The seven E. coli ribosomal RNA operon upstream regulatory regions differ in structure and transcription factor binding efficiencies

Ribosomal RNAs in E. coli are transcribed from seven operons, which are highly conserved in their organization and sequence. However, the upstream regulatory DNA regions differ considerably, suggesting differences in regulation. We have therefore analyzed the conformation of all seven DNA elements located upstream of the major E. coli rRNA P1 promoters. As judged by temperature-dependent gel electrophoresis with isolated DNA fragments comprising the individual P1 promoters and the complete upstream regulatory regions, all seven rRNA upstream sequences are intrinsically curved. The degree of intrinsic curvature was highest for the rrnB and rrnD fragments and less pronounced for the rrnA and rrnE operons. Comparison of the experimentally determined differences in curvature with programs for the prediction of DNA conformation revealed a generally high degree of conformity. Moreover, the analysis showed that the center of curvature is located at about the same position in all fragments. The different upstream regions were analyzed for their capacity to bind the transcription factors FIS and H-NS, which are known as antagonists in the regulation of rRNA synthesis. Gel retardation experiments revealed that both proteins interact with the upstream promoter regions of all seven rDNA fragments, with the affinities of the different DNA fragments for FIS and H-NS and the structure of the resulting complexes deviating considerably. FIS binding was non-cooperative, and at comparable protein concentrations the occupancy of the different DNA fragments varied between two and four binding sites. In contrast, H-NS was shown to bind cooperatively and intermediate states of occupancy could not be resolved for each fragment. The different gel electrophoretic mobilities of the individual DNA/protein complexes indicate variable structures and topologies of the upstream activating sequence regulatory complexes. Our results are highly suggestive of differential regulation of the individual rRNA operons.

Importance of transient structures during post-transcriptional refolding of the pre-23S rRNA and ribosomal large subunit assembly

An important step of ribosome assembly is the folding of the rRNA into a functional structure. Despite knowledge of the folded state of rRNA in the ribosomal subunits, there is very little information on the rRNA folding pathway. We are interested in understanding how the functional structure of rRNA is formed and whether the rRNA folding intermediates have a role in ribosome assembly. To this end, transient secondary structures around both ends of pre-23S rRNA were analyzed by a chemical probing approach, using pre-23S rRNA transcripts. Metastable hairpin loop structures were found at both ends of 23S rRNA. The functional importance of the transient structures around the ends of 23S rRNA was tested by mutations that alter only the transient structure. The effect of mutations on 23S rRNA folding was tested in vitro and in vivo. It was found that both stabilization and destabilization of the transient structure around the 5' end of 23S rRNA inhibits post-transcriptional refolding in vitro and ribosome formation in vivo. The data suggest that the transient structure of rRNA has a function during 23S rRNA folding and thereby in ribosome assembly.

A putative transposase gene in the 16S–23S rRNA intergenic spacer region of Mycoplasma imitans

Examination of the nucleotide sequences of the 16S–23S intergenic transcribed spacer (ITS) region ofMycoplasma imitansandMycoplasma gallisepticumidentified a putative transposase gene located only in the ITS ofM. imitans, which can be used as a genetic marker to distinguish these two species. The relative size of the PCR products of the ITS region allowed a clear distinction to be made between strains ofM. imitansandM. gallisepticum, both of which could be readily discriminated from the type strains of all the other recognized avianMycoplasmaspecies. In addition, the putative transposase gene assigned in the ITS ofM. imitanswas shown to include a sequence homologous to that of the P75 gene ofM. gallisepticum. This is believed to be the first description of an insertion element in the rRNA operon region of a mycoplasma species.

Phylogenetic relationships between Bacillus species and related genera inferred from comparison of 3' end 16S rDNA and 5' end 16S-23S ITS nucleotide sequences

The nucleotide sequences of the 3' end of the 16S rDNA and the 16S-23S internal transcribed spacer (ITS) of 40 Bacillaceae species were determined. These included 21 Bacillus, 9 Paenibacillus, 6 Brevibacillus, 2 Geobacillus, 1 Marinibacillus and 1 Virgibacillus species. Comparative sequence analysis of a 220 bp region covering a highly conserved 150 bp sequence located at the 3' end of the 16S rRNA coding region and a conserved 70 bp sequence located at the 5' end of the 16S-23S ITS of the 40 species and six sequences available in GenBank were used to infer the phylogenetic relationships between all 46 taxa. When a maximal distance (D(max), where D refers to the number of nucleotide substitutions per site) of 0.31 was introduced as a threshold to determine groupings, 10 phylogenetically distinct clusters were revealed. Twenty-six Bacillus species were separated in seven groups (I, II, III, IV, V, VI and X), but Bacillus circulans remained ungrouped. All six Brevibacillus species under study were in Group VII. The nine Paenibacillus species fell into two distinct groups (VIII and IX). Species with D(max) values within 0.05 were considered to be very closely related. These were Bacillus psychrophilus and Bacillus psychrosaccharolyticus in Group II; 'Bacillus maroccanus' and Bacillus simplex in Group II; Bacillus amyloliquefaciens, Bacillus atrophaeus, Bacillus mojavensis and Bacillus subtilis in Group VI; Bacillus fusiformis and Bacillus sphaericus in Group VI; Brevibacillus brevis and Brevibacillus formosus in Group VII; Paenibacillus gordonae and Paenibacillus validus in Group VIII; and Bacillus anthracis, Bacillus cereus, Bacillus mycoides and Bacillus thuringiensis in Group X. The phylogenetic classification presented here is, in general, in agreement with current classifications based on phenotypic and molecular data. Our findings suggest, however, that in some cases, further divisions or, conversely, further groupings might be warranted. Should current classifications be re-examined in the light of our results, D(max) values of 0.31 and 0.05, as exemplified here, may prove useful threshold values for the grouping of Bacillaceae into taxa akin to genera and species, respectively. These D(max) thresholds may also reveal, in a different way, bacterial species for which further characterization might be warranted for proper classification and/or reassignment.

Effects of base change mutations within an Escherichia coli ribosomal RNA leader region on rRNA maturation and ribosome formation

The effects of base change mutations in a highly conserved sequence (boxC) within the leader of bacterial ribosomal RNAs (rRNAs) was studied. The boxC sequence preceding the 16S rRNA structural gene constitutes part of the RNase III processing site, one of the first cleavage sites on the pathway to mature 16S rRNA. Moreover, rRNA leader sequences facilitate correct 16S rRNA folding, thereby assisting ribosomal subunit formation. Mutations in boxC cause cold sensitivity and result in 16S rRNA and 30S subunit deficiency. Strains in which all rRNA operons are replaced by mutant transcription units are viable. Thermodynamic studies by temperature gradient gel electrophoresis reveal that mutant transcripts have a different, less ordered structure. In addition, RNA secondary structure differences between mutant and wild-type transcripts were determined by chemical and enzymatic probing. Differences are found in the leader RNA sequence itself but also in structurally important regions of the mature 16S rRNA. A minor fraction of the rRNA transcripts from mutant operons is not processed by RNase III, resulting in a significantly extended precursor half-life compared to the wild-type. The boxC mutations also give rise to a new aberrant degradation product of 16S rRNA. This intermediate cannot be detected in strains lacking RNase III. Together the results indicate that the boxC sequence, although important for RNase III processing, is likely to serve additional functions by facilitating correct formation of the mature 16S rRNA structure. They also suggest that quality control steps are acting during ribosome biogenesis.

Characterization of transient RNA-RNA interactions important for the facilitated structure formation of bacterial ribosomal 16S RNA

The co-transcribed leader sequences of bacterial rRNA are known to affect the structure and function of the small ribosomal subunits. Base changes in the leader nut -like sequence elements have been shown to cause misfolded but correctly processed 16S rRNA structures at low growth temperature. Transient interactions of leader sequences with the nascent 16S rRNA are considered to guide rRNA folding and to facilitate correct structure formation. In order to understand this chaperone-like activity of the leader RNA we have analyzed the thermodynamic stabilities of wild-type and mutant leader transcripts. We show here that base changes cause subtle differences in the melting profiles of the corresponding leader transcripts. Furthermore, we show that direct interaction between leader transcripts and the 16S rRNA is limited to the 5'-domain of the 16S rRNA for both wild-type and mutant leaders. Binding studies of mutant and wild-type leader transcripts to 16S rRNA revealed small changes in the affinities and the thermal stabilities as a consequence of the base changes. Different complex stabilities as a function of the Mg(2+) ion concentration indicated that mutant and wild-type leader transcripts interact differently with the 16S rRNA, consistent with a less stable and tightly folded structure of the mutant leader. Employing time-resolved oligonucleotide hybridization assays we could show different folding kinetics for 16S rRNA molecules when linked to wild-type leader, mutant leader or in the absence of leader RNA. The studies help to understand how bacterial rRNA leader transcripts may affect the folding of the small subunit rRNA.