Conformation of B. stearothermophilus 5S ribosomal RNA

The thermal melting of B. stearothermophilus 5S ribosomal RNA was studied, by means of derivative optical absorption and CD spectra, and high performance liquid chromatography, in Tris buffers with K+ and Mg2+ at pH 7.6. Biphasic changes in optical absorption and CD ellipticity were observed, which mean the melting of two helices. Change in molecular size was also examined in the melting process. The melting temperatures depended on ionic strength and concentration of Mg2+. Enhanced stability of the helix was indicated, as compared with the corresponding one in B. subtilis 5S ribosomal RNA. In the presence of a large amount of Mg2+, the third melting process was observed at low temperatures, which was suggested due to change in the tertiary structure.     

Oocyte and somatic 5S ribosomal RNA and 5S RNA encoding genes in Xenopus tropicalis.

We have investigated the structure of oocyte and somatic 5S ribosomal RNA and of 5S RNA encoding genes in Xenopus tropicalis. The sequences of the two 5S RNA families differ in four positions, but only one of these substitutions, a C to U transition in position 79 within the internal control region of the corresponding 5S RNA encoding genes, is a distinguishing characteristic of all Xenopus somatic and oocyte 5S RNAs characterized to date, including those from Xenopus laevis and Xenopus borealis. 5S RNA genes in Xenopus tropicalis are organized in clusters of multiple repeats of a 264 base pair unit; the structural and functional organization of the Xenopus tropicalis oocyte 5S gene is similar to the somatic but distinct from the oocyte 5S DNA in Xenopus laevis and Xenopus borealis. A comparative sequence analysis reveals the presence of a strictly conserved pentamer motif AAAGT in the 5'-flanking region of Xenopus 5S genes which we demonstrate in a separate communication to serve as a binding signal for an upstream stimulatory factor.     

5S ribosomal RNA is contained within a 25 S ribosomal RNA that accumulates in mutants of Escherichia coli defective in processing of ribosomal RNA.

A temperature-sensitive mutant strain of Escherichia coli defective in two RNA processing enzymes, RNase III and RNase E (rnc. rne), fails to produce normal levels of 23 S and 5 S rRNA at the non-permissive temperature. Instead, a molecule larger than 23 S is produced. This molecule, designated 25 S rRNA, can be processed in vitro to produce p5 rRNA. These findings further our understanding of the overall processing events of ribosomal RNA which take place in the bacterial cell.     

Nucleocytoplasmic transport of 5S ribosomal RNA

Nucleocytoplasmic transport of 5S ribosomal RNA in Xenopus oocytes occurs in the context of small, non-ribosomal RNPs. The complex with the zinc finger protein TFIIIA (7S RNP) is exported from the nucleus and stored in the cytoplasm, whereas the complex with the ribosomal protein L5 (5S RNP) shuttles between the nucleus and the cytoplasm. Nuclear import- and export-signals appear to reside within the protein moiety of these RNPs. Import of TFIIIA is inhibited by RNA binding, whereas nuclear transfer of L5 is not influenced by RNA binding. We propose that the export capacity of both, TFIIIA and L5, is regulated by the interaction with 5S ribosomal RNA.     

Higher order structure of the ribosomal 5 S RNA.

The structure of the ribosomal 5 S RNA was examined using Fe(II)-EDTA, a solvent-based reagent that cleaves the phosphodiester backbone of both double- and single-stranded RNA but is restricted by the three-dimensional structure. In the yeast 5 S RNA, cleavages were significantly restricted in six specific regions of the molecule; restrictions in only two of these regions were clearly dependent on a high salt/magnesium ion environment. A comparison of four RNAs of diverse origin revealed strong similarities in the cleavage profiles supporting a highly conserved higher order structure. Taken together with previous studies these data provide a more detailed modeling of the three-dimensional structure.     

Precursors of 5 S ribosomal RNA in Bacillus subtilis

Bacillus subtilis 168 accumulates subnormal quantities of mature 5 S ribo-somal RNA in the presence of inhibitors of protein synthesis, such as chloramphenicol, or during pulse-labeling experiments. However, two RNA species, evidently precursors of m5 rRNA and therefore designated as p5_A and p5_B, do accumulate under these conditions. These RNA species are substantially longer than B. subtilis m5 rRNA: p5_A is about 179 nucleotides in length and p5_B is composed of approximately 152 nucleotides. The sum of p5_A, p5_B and m5 rRNA accumulating in the absence of protein synthesis, less excess chain length associated with p5_A and p5_B, equals the expected quantities of m5 rRNA in growing cells. p5_A and p5P_B both contain all t₁ RNase-generated oligonucleotides characteristic of m5 rRNA plus additional sequences. At least the 5′ termini of p5_A and p5_B differ from that of m5. If chloramphenicol is removed from a culture in which p5_A and p5_B have accumulated and further RNA synthesis is inhibited, then a quantitative reciprocal loss of p5_A and p5_B occurs as m5 rRNA accumulates. No evidence suggests any p5_A to p5_B transition under these conditions.     

The genes for 5 S ribosomal RNA and transfer RNA in Tetrahymena pyriformis.

In the present communication a characterization of the 5 S rRNA genes and the tRNA genes of Tetrahymena pyriformis has been performed. The number of 5 S rRNA and tRNA genes in the macromolecular DNA has been established. Furthermore no sequence homology is observed for these genes. The number of both types of genes does not change significantly under starvation conditions. The genomic organization of the 5 S rRNA and tRNA genes has been investigated. From in vivo replication studies it is concluded, that replication of both 5 S rRNA and tRNA genes takes place throughout the whole S-period.     

5S ribosomal RNA genes of the newt Notophthalmus viridescens.

The genes which code for the 5S ribosomal RNA in the newt, Notophthalmus viridescens have been cloned and analyzed. Two types of repeating unit were detected: a major type consisting of a 120 bp coding region with a 111 bp spacer, and a minor type composed of a coding region, a pseudogene, and a 113 bp spacer. The pseudogene is a 36 bp segment which corresponds to the 3' terminal third of the 5S RNA gene, and is situated immediately 3' to the gene, being separated from it by 2 bp. Two recombinant plasmids were obtained in which the major and minor units were arranged in an interspersed pattern.     

Mutations at position A960 of E. coli 23 S ribosomal RNA influence the structure of 5 S ribosomal RNA and the peptidyltransferase region of 23 S ribosomal RNA

The proximity of loop D of 5 S rRNA to two regions of 23 S rRNA, domain II involved in translocation and domain V involved in peptide bond formation, is known from previous cross-linking experiments. Here, we have used site-directed mutagenesis and chemical probing to further define these contacts and possible sites of communication between 5 S and 23 S rRNA. Three different mutants were constructed at position A960, a highly conserved nucleotide in domain II previously crosslinked to 5 S rRNA, and the mutant rRNAs were expressed from plasmids as homogeneous populations of ribosomes in Escherichia coli deficient in all seven chromosomal copies of the rRNA operon. Mutations A960U, A960G and, particularly, A960C caused structural rearrangements in the loop D of 5 S rRNA and in the peptidyltransferase region of domain V, as well as in the 960 loop itself. These observations support the proposal that loop D of 5 S rRNA participates in signal transmission between the ribosome centers responsible for peptide bond formation and translocation.     

Two distinct conformations of rat liver ribosomal 5S RNA.

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

5S ribosomal RNA database Y2K

This paper presents the updated version (Y2K) of the database of ribosomal 5S ribonucleic acids (5S rRNA) and their genes (5S rDNA), http://rose.man/poznan.pl/5SData/index.html. This edition of the database contains 1985primary structures of 5S rRNA and 5S rDNA. They include 60 archaebacterial, 470 eubacterial, 63 plastid, nine mitochondrial and 1383 eukaryotic sequences. The nucleotide sequences of the 5S rRNAs or 5S rDNAs are divided according to the taxonomic position of the source organisms.     

Comparative studies on bacterial 5S ribosomal RNA

The 5S rRNAs of Escherichia coli, Bacillus stearothermophilus, and B. subtilis were isolated and their molecular conformation examined. All three 5S rRNAs were similar with regard to nucleotide chain length, base composition and general configuration. Several major differences were apparent between the secondary and tertiary conformations of the 5S rRNA of E. coli and the genus Bacillus. Only minor differences were noted between those from the two Bacillus species. Each 5S rRNA species had a different 5′-terminal nucleotide: E. coli-U; B. stearothermophilus-C; B. subtilis-G.     

A proposed role for 5S ribosomal RNA

Cytoplasmic ribosomes show protein-synthesizing activity with degraded large and small rRNA's, but only if 5S RNA is intact.     

Location of single-stranded and double-stranded regions in rat liver ribosomal 5S RNA and 5.8S RNA.

Rat liver 5S rRNA and 5.8S rRNA were end-labelled with 32P at 5'-end or 3'-end of the polynucleotide chain and partially digested with single-strand specific S1 nuclease and double-strand specific endonuclease from the cobra Naja naja oxiana venom. The parallel use of these two structure-specific enzymes in combination with rapid sequencing technique allowed the exact localization of single-stranded and double-stranded regions in 5S RNA and 5.8 S RNA. The most accessible regions to S1 nuclease in 5S RNA are regions 33-42, 74-78, 102-103 and in 5.8 S RNA 16-20, 26-29, 34-36, 74-80 and a region around 125-130. The cobra venom endonuclease cleaves the following areas in 5S RNA: 7-8, 17-20, 28-30, 49-51, 56-57, 60-64, 69-70, 81-82, 95-97, 106-112. In 5.8S RNA the venom endonuclease cleavage sites are 4-7, 10-13, 21-22, 33-35, 43-45, 51-55, 72-74, 85-87, 98-99, 105-106, 114-115, 132-135. According to these results the tRNA binding sequences proposed by Nishikawa and Takemura [(1974) FEBS Lett. 40, 106-109], in 5S RNA are located in partly single-stranded region, but in 5.8S RNA in double-stranded region.