Maturation pathway for Novikoff ascites hepatoma 5.8 S ribosomal ribonucleic acid. Evidence for its presence in 32 S nuclear ribonucleic acid.

Evidence that 32 S nRNA contains 5.8 S rRNA was provided by studies on specific oligonucleotide sequences of these RNA species. Purified 32P-labeled 5.8 and 28 S rRNA and 32 S RNA were digested with T-1 ribonuclease, and the products were fractionated according to chain length by chromatography on DEAE-Sephadex A-25 at neutral pH. The oligonucleotides in Peak 8 were treated with alkaline phosphatase and the products were separated by two-dimensional electrophoresis on cellulose acetate at pH 3.5 and DEAE-paper in 7% formic acid. Seven unique oligonucleotide markers for 5.8 S rRNA including the methylated octanucleotide A-A-U-U-Gm-G-A-Gp were present in 32 S RNA but were not found in 28 S rRNA, indicating that 5.8 S rRNA is directly derived from the 32 S nucleolar precursor. These studies confirm a maturation pathway for rRNA species in which 32 S nucleolar RNA is a precursor of 5.8 S rRNA as well as 28 S rRNA.     

Stable low molecular weight RNA analyzed by staircase electrophoresis, a molecular signature for both prokaryotic and eukaryotic microorganisms

Low-molecular weight RNA (LMW RNA) analysis using staircase electrophoresis was performed for several species of eukaryotic and prokaryotic microorganisms. According to our results, the LMW RNA profiles of archaea and bacteria contain three zones: 5S RNA, class 1 tRNA and class 2 tRNA. In fungi an additional band is included in the LMW RNA profiles, which correspond to the 5.8S RNA. In archaea and bacteria we found that the 5S rRNA zone is characteristic for each genus and the tRNA profile is characteristic for each species. In eukaryotes the combined 5.8S and 5S rRNA zones are characteristic for each genus and, as in prokaryotes, tRNA profiles are characteristic for each species. Therefore, stable low molecular weight RNA, separated by staircase electrophoresis, can be considered a molecular signature for both prokaryotic and eukaryotic microorganisms. Analysis of the data obtained and construction of the corresponding dendrograms afforded relationships between genera and species; these were essentially the same as those obtained with 16S rRNA sequencing (in prokaryotes) and 18S rRNA sequencing (in eukaryotes).     

Probing the structure of mouse Ehrlich ascites cell 5.8S, 18S and 28S ribosomal RNA in situ.

The secondary structure of mouse Ehrlich ascites 18S, 5.8S and 28S ribosomal RNA in situ was investigated by chemical modification using dimethyl sulphate and 1-cyclohexyl-3-(morpholinoethyl) carbodiimide metho-p-toluene sulphonate. These reagents specifically modify unpaired bases in the RNA. The reactive bases were localized by primer extension followed by gel electrophoresis. The three rRNA species were equally accessible for modification i.e. approximately 10% of the nucleotides were reactive. The experimental data support the theoretical secondary structure models proposed for 18S and 5.8/28S rRNA as almost all modified bases were located in putative single-strand regions of the rRNAs or in helical regions that could be expected to undergo dynamic breathing. However, deviations from the suggested models were found in both 18S and 28S rRNA. In 18S rRNA some putative helices in the 5'-domain were extensively modified by the single-strand specific reagents as was one of the suggested helices in domain III of 28S rRNA. Of the four eukaryote specific expansion segments present in mouse Ehrlich ascites cell 28S rRNA, segments I and III were only partly available for modification while segments II and IV showed average to high modification.     

The hemolytic properties of the membrane modifying peptide antibiotics alamethicin, suzukacillin and trichotoxin (author's transl)

1. Using hybridisation techniques nuclei from both amoebae and plasmodia of Physarum polycephalum were found to contain 275 genes each coding for 5.8-S, 19-S and 26-S rRNA, 685 genes for 5-S rRNA and 1050 genes for tRNA. 2. Hybridisation of these RNA species to both amoebal and plasmodial DNA fractionated on CsCl gradients reveal that the 5.8-S, 19-S and 26-S rRNA genes are located at a satellite position (formula: see text) with respect to the main band of DNA, whereas 4-S RNA genes are located exclusively in the main band of DNA (formula: see text). 3. This result was confirmed by demonstrating that only the 5.8-S, 19-S and 26-S rRNA species hybridise to purified plasmodial ribosomal DNA. 4. The 19-S and 26-S rRNA genes of amoebae are located on extrachromosomal DNA molecules of a discrete size (Mr = 38 X 10(6)) with identical properties to plasmodial ribosomal DNA.     

Sixteen discrete RNA components in the cytoplasmic ribosome of Euglena gracilis

We have isolated cytoplasmic ribosomes from Euglena gracilis and characterized the RNA components of these particles. We show here that instead of the four rRNAs (17-19 S, 25-28 S, 5.8 S and 5 S) found in typical eukaryotic ribosomes, Euglena cytoplasmic ribosomes contain 16 RNA components. Three of these Euglena rRNAs are the structural equivalents of the 17-19 S, 5.8 S and 5 S rRNAs of other eukaryotes. However, the equivalent of 25-28 S rRNA is found in Euglena as 13 separate RNA species. We demonstrate that together with 5 S and 5.8 S rRNA, these 13 RNAs are all components of the large ribosomal subunit, while a 19 S RNA is the sole RNA component of the small ribosomal subunit. Two of the 13 pieces of 25-28 S rRNA are not tightly bound to the large ribosomal subunit and are released at low (0 to 0.1 mM) magnesium ion concentrations. We present here the complete primary sequences of each of the 14 RNA components (including 5.8 S rRNA) of Euglena large subunit rRNA. Sequence comparisons and secondary structure modeling indicate that these 14 RNAs exist as a non-covalent network that together must perform the functions attributed to the covalently continuous, high molecular weight, large subunit rRNA from other systems.     

Unusual ribosomal RNA of the intestinal parasite Giardia lamblia.

The anaerobic protozoan Giardia lamblia is a common intestinal parasite in humans, but is poorly defined at molecular and phylogenetic levels. We report here a structural characterization of the ribosomal RNA (rRNA) and rRNA genes of G. lamblia. Gel electrophoresis under native or non-denaturing conditions identified two high molecular weight rRNA species corresponding to the 16-18S and 23-28S rRNAs. Surprisingly, both species (1300 and 2300 nucleotides long, respectively) were considerably shorter than their counterparts from other protozoa (typically 1800 and 3400 nucleotides), and from bacteria as well (typically 1540 and 2900 nucleotides long). Denaturing polyacrylamide gel electrophoresis identified a major low molecular RNA of 127 nucleotides and several minor species, but no molecules with the typical lengths of 5.8S (160 nucleotides) and 5S (120 nucleotides) rRNA. The G. lamblia 1300, 2300, and 127 nucleotide RNAs are encoded within a 5.6 kilobase pair tandemly repeated DNA, as shown by Southern blot analysis and DNA cloning. Thus, the rRNA operon of this eukaryotic organism can be no longer than a typical bacterial operon. Sequence analysis identified the 127 nucleotide RNA as homologous to 5.8S RNA, but comparisons to archaebacterial rRNA suggest that Giardia derived from an early branch in eukaryotic evolution.     

A very large repeating unit of mouse DNA containing the 18S, 28S and 5.8S rRNA genes

The organization of the 18S, 28S and 5.8S rRNA genes in the mouse has been elucidated by mapping with restriction endonucleases Eco RI, Hind III and Bam HI. Ribosomal DNA fragments were detected in electrophoretically fractionated digests of total nuclear DNA by in situ hybridization with radioiodinated rRNAs or with complementary RNA synthesized directly on rRNA templates. A map of the rDNA which includes 13 restriction sites was constructed from the sizes of rDNA fragments and their labeling by different probes The map indicates that the rRNA genes lie within remarkably large units of reiterated DNA, at least 44,000 base pairs long. At least two, and possibly four, classes of repeating unit can be distinguished, the heterogeneity probably residing in the very large nontranscribed spacer region. The 5.8S rRNA gene lies in the transcribed region between the 18S and 28S genes.     

Unique arrangement of coding sequences for 5 S, 5.8 S, 18 S and 25 S ribosomal RNA in Saccharomyces cerevisiae as determined by R-loop and hybridization analysis.

The arrangement of the coding sequences for the 5 S, 5.8 S, 18 S and 25 S ribosomal RNA from Saccharomyces cerevisiae was analyzed in λ-yeast hybrids containing repeating units of the ribosomal DNA. After mapping of restriction sites, the positions of the coding sequences were determined by hybridization of purified rRNAs to restriction fragments, by R-loop analysis in the electron microscope, and by electrophoresis of S₁ nuclease-treated rRNA/rDNA hybrids in alkaline agarose gels. The R-loop method was improved with respect to the length calibration of RNA/DNA duplexes and to the spreading conditions resulting in fully extended 18 S and 25 S rRNA R-loops. The qualitative results are: (1) the 5 S rRNA genes, unlike those in higher eukaryotes, alternate with the genes of the precursor for the 5.8 S, 18 S and 25 S rRNA; (2) the coding sequence for 5.8 S rRNA maps, as in higher eukaryotes, between the 18 S and 25 S rRNA coding sequences. The quantitative results are: (1) the tandemly repeating rDNA units have a constant length of 9060 ± 100 nucleotide pairs with one SstI, two HindIII and, dependent on the strain, six or seven EcoRI sites; (2) the 18 S and 25 S rRNA coding regions consist of 1710 ± 80 and 3360 ± 80 nucleotide pairs, respectively; (3) an 18 S rRNA coding region is separated by a 780 ± 70 nucleotide pairs transcribed spacer from a 25 S rRNA coding region. This is then followed by a 3210 ± 100 nucleotide pairs mainly non-transcribed spacer which contains a 5 S rRNA gene.     

Quantitative analysis of rat liver nucleolar and nucleoplasmic ribosomal ribonucleic acids.

rRNA from detergent-purified nuclei was fractionated quantitatively, by two independent methods, into nucleolar and nucleoplasmic RNA fractions. The two RNA fractions were analysed by urea/agar-gel electrophoresis and the amount of pre-rRNA (precursor of rRNA) and rRNA components was determined. The rRNA constitutes 35% of total nuclear RNA, of which two-thirds are in nucleolar RNA and one-third in nucleoplasmic RNA. The identified pre-rRNA components (45 S, 41 S, 39 S, 36 S, 32 S and 21 S) are confined to the nucleolus and constitute about 70% of its rRNA. The remaining 30% are represented by 28 S and 18 S rRNA, in a molar ratio of 1.4. The bulk of rRNA in nucleoplasmic RNA is represented by 28 S and 18 S rRNA in a molar ratio close to 1.0. Part of the mature rRNA species in nucleoplasmic RNA originate from ribosomes attached to the outer nuclear membrane, which resist detergent treatment. The absolute amount of nuclear pre-rRNA and rRNA components was evaluated. The amount of 32 S and 21 S pre-rRNA (2.9 x 10(4) and 2.5 x 10(4) molecules per nucleus respectively) is 2-3-fold higher than that of 45 S, 41 S and 36 S pre-rRNA.     

The sequence of the 5.8 S ribosomal RNA of the crustacean Artemia salina. With a proposal for a general secondary structure model for 5.8 S ribosomal RNA.

We report the primary structure of 5.8 S rRNA from the crustacean Artemia salina. The preparation shows length heterogeneity at the 5'-terminus, but consists of uninterrupted RNA chains, in contrast to some insect 5.8 S rRNAs, which consist of two chains of unequal length separated in the gene by a short spacer. The sequence was aligned with those of 11 other 5.8 S rRNAs and a general secondary structure model derived. It has four helical regions in common with the model of Nazar et al. (J. Biol. Chem. 250, 8591-8597 (1975)), but for a fifth helix a different base pairing scheme was found preferable, and the terminal sequences are presumed to bind to 28 S rRNA instead of binding to each other. In the case of yeast, where both the 5.8 S and 26 S rRNA sequences are known, the existence of five helices in 5.8 S rRNA is shown to be compatible with a 5.8 S - 26 S rRNA interaction model.     

Selective alterations in hepatic enzyme response after reduction of nuclear triiodothyronine receptor sites by partial hepatectomy and starvation.

Barley embryo 5S rRNA hybridizes efficiently with barley embryo 18S rRNA but not with 26S rRNA. Mouse sarcoma 5S rRNA also selectively hybridizes, to a smaller extent, with mouse sarcoma 18S rRNA. The barley embryo 5S–18S rRNA complex has a sharp melting profile and a “Tm” of $\text{ca}$. 59° in 0.1 $\text{M}$ NaCl. The mouse sarcoma 5S–18S rRNA complex has a broader transition breadth and a “Tm” of $\text{ca}$ 52°. The conditions used for hybridization lead to very specific reconstitution of the “natural” complex between 5.8S and 26S–28S rRNA since both the $\text{in}\text{vivo}\text{and}\text{in}\text{vitro}$ complexes between 5.8S and 26S–28S rRNA from barley embryos and mouse sarcoma have equally sharp melting profiles and a “Tm” of $\text{ca}$. 52° in 0.1 $\text{M}$ NaCl.     

Sequence and secondary structure of Drosophila melanogaster 5.8S and 2S rRNAs and of the processing site between them.

Drosophila melanogaster 5.8S and 2S rRNAs were end-labeled with 32p at either the 5' or 3' end and were sequenced. 5.8S rRNA is 123 nucleotides long and homologous to the 5' part of sequenced 5.8S molecules from other species. 2S rRNA is 30 nucleotides long and homologous to the 3' part of other 5.8S molecules. The 3' end of the 5.8S molecule is able to base-pair with the 5' end of the 2S rRNA to generate a helical region equivalent in position to the "GC-rich hairpin" found in all previously sequenced 5.8S molecules. Probing the structure of the labeled Drosophila 5.8S molecule with S1 nuclease in solution verifies its similarity to other 5.8S rRNAs. The 2S rRNA is shown to form a stable complex with both 5.8S and 26S rRNAs separately and together. 5.8S rRNA can also form either binary or ternary complexes with 2S and 26S rRNA. It is concluded that the 5.8S rRNA in Drosophila melanogaster is very similar both in sequence and structure to other 5.8 rRNAs but is split into two pieces, the 2S rRNA being the 3' part. 2S anchors the 5.8S and 26S rRNA. The order of the rRNA coding regions in the ribosomal DNA repeating unit is shown to be 18S - 5.8S - 2S - 26S. Direct sequencing of ribosomal DNA shows that the 5.8S and 2S regions are separated by a 28 nucleotide spacer which is A-T rich and is presumably removed by a specific processing event. A secondary structure model is proposed for the 26S-5.8S ternary complex and for the presumptive precursor molecule.     

Adsorption chromatography of nucleic acids on silicone-coated porous glass

Bovine liver tRNA was adsorbed on silicone-coated porous glass in 5 M NaCl, 10 mM Tris-HCl (pH 7.6) and fractionated by elution with decreasing NaCl concentrations. tRNAPro, tRNAVal, tRNAIle, tRNAThr, tRNASer, and tRNAPhe were eluted in this order. tRNA which had been digested with ribonuclease A was not adsorbed. Q beta RNA (adsorbed onto the glass in 5 M NaCl) was eluted with 1.5 M NaCl. RNA species in a crude rRNA fraction from Escherichia coli were separated into tRNA, 5S rRNA, and high molecular weight rRNA on siliconized porous glass. A half of calf thymus DNA was adsorbed on the glass in 5 M NaCl and the residual part passed through the column. The CD spectra showed that DNA and tRNA took the C-form and the A-form in 5 M NaCl, respectively. Therefore, the discrepancies of behavior of the DNA and RNA on siliconized porous glass may be related to the occurrence of these forms. The recovery of these nucleic acids from the column was 83-100%. Adsorption chromatography on siliconized porous glass may be a useful method for the separation of tRNA, rRNA, and mRNA.     

Complementarity of sequences in low molecular weight RNAs to regions of messenger and ribosomal RNAs.

Total low molecular weight nuclear RNAs of mouse ascites cells have been labeled in vitro and used as probes to search for complementary sequences contained in nuclear or cytoplasmic RNA. From a subset of hybridizing lmw RNAs, two major species of 58,000 and 35,000 mol. wt. have been identified as mouse 5 and 5.8S ribosomal RNA. Mouse 5 and 5.8S rRNA hybridize not only to 18 and 28S rRNA, respectively, but also to nuclear and cytoplasmic poly(A+) RNA. Northern blot analysis and oligo-dT cellulose chromatography have confirmed the intermolecular base-pairing of these two small rRNA sequences to total poly(A+) RNA as well as to purified rabbit globin mRNA. 5 and 5.8S rRNA also hybridize with positive (coding) but not negative (noncoding) strands of viral RNA. Temperature melting experiments have demonstrated that their hybrid stability with mRNA sequences is comparable to that observed for the 5S:18S and 5.8S:28S hybrids. The functional significance of 5 and 5.8S rRNA base-pairing with mRNAs and larger rRNAs is unknown, but these interactions could play important coordinating roles in ribosome structure, subunit interaction, and mRNA binding during translation.     

The first complete monogenean ribosomal RNA gene operon: sequence and secondary structure of the Gyrodactylus salaris Malmberg, 1957, large subunit ribosomal RNA gene

The sequence of the Gyrodactylus salaris Malmberg, 1957, large subunit, or 28S, ribosomal RNA (rRNA) gene has been determined. This gene is the final portion of the Gyrodactylus rRNA gene operon to be sequenced and results in the first complete sequence of all rRNA genes and spacers from a monogenean. The nucleotide sequence was used to predict the secondary structure of the large subunit rRNA, and regions of conserved and variable sequence and structure were identified. The site where the 5' terminus of the 5.8S rRNA binds to a region within the large subunit rRNA was predicted and complements the anticipated interaction of the 3' terminus of the 5.8S with the 5' terminus of the large subunit rRNA. The large subunit gene may be useful in phylogenetic analysis of the Monogenea or Platyhelminthes and comparisons with other eukaryotes. The variable domains C and H may be most suitable for this purpose.     

p53 is covalently linked to 5.8S rRNA.

We report here the isolation and identification of the RNA specifically immunoprecipitated and covalently linked to the tumor suppressor gene product p53. After treatment with proteinase K, the sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) band of p53 yields a single, discrete 157-nucleotide RNA, which was cloned, sequenced, and identified as 5.8S rRNA. 5.8S rRNA was obtained only after proteolysis of the p53 SDS-PAGE band. Free 5.8S rRNA did not comigrate with p53 in SDS-PAGE. This RNA was only immunoprecipitated from cells containing p53. Protein-free RNA obtained by proteolysis of the p53 band hybridized to the single-stranded DNA vector containing the antisense sequence of 5.8S rRNA. The covalence of the p53-5.8S rRNA linkage was demonstrated by the following findings: (i) p53 and the linked 5.8S rRNA comigrated in SDS-PAGE; (ii) only after treatment of the p53-RNA complex with proteinase K did the 5.8S rRNA migrate differently from p53-linked 5.8S rRNA; and (iii) this isolated RNA was found linked to phosphoserine, presumably at the 5' end. Covalent linkage to the single, specific RNA suggests that p53 may be involved in regulating the expression or function of 5.8S rRNA.     

Unusual ribosomal RNA gene organization in copepods of the genus Calanus

Ribosomal RNA genes in the nuclear genomes of eukaryotes are generally found in tandemly repeated units encoding 18 S, 5.8 S and 28 S rRNA (in that order). 5 S rRNA genes typically lie outside these units, most often in tandem clusters coding exclusively for 5 S rRNA. Inclusion of 5 S genes within the 18 S-5.8 S-28 S repeat unit is known only for certain protozoa and fungi. Here we report that, in the copepod Calanus finmarchicus, single 5 S genes are included within many or all of the 18 S-5.8 S-28 S repeat units. Sequence analyses of regions cloned from two of these repeat units show that they indeed include 5 S genes (which are distal to 28 S genes) and that these are transcribed from opposite strands.