The Synthesis of 5s RNA and Its Relationship to 18s and 28s Ribosomal RNA in the Bobbed Mutants of DROSOPHILA MELANOGASTER

Ribosomes contain one molecule each of 5S, 18S and 28S RNA. In Drosophila melanogaster although the genes for 18S+28S are physically separated from the 5S RNA genes, the multiplicity of various ribosomal RNA genes is roughly the same. Thus a coordinate synthesis of these three molecules might seem feasible. This problem has been approached by determining the molar ratios of various RNA's in ovaries and in adult flies. In ovaries there is a slight excess of 5S RNA molecules over other rRNA's, but in adult flies no such differences exist. Bobbed mutants also have the same molar ratios as wild-type flies. Results on 5S RNA synthesis in both in vitro and in vivo studies show that it is reduced in coordination with 18S+28S rRNA in the bobbed mutants of Drosophila melanogaster. Various possibilities are discussed in considering the implications of these results.     

Ribosomal RNA synthesis in mitochondria of Neurospora crassa

Ribosomal RNA synthesis in Neurospora crassa mitochondria has been investigated by continuous labeling with [5-³H]uracil and pulse-chase experiments. A short-lived 32 S mitochondrial RNA was detected, along with two other short-lived components; one slightly larger than large subunit ribosomal RNA, and the other slightly larger than small subunit ribosomal RNA. The experiments give support to the possibility that 32 S RNA is the precursor of large and small subunit ribosomal RNA's. Both mature ribosomal RNA's compete with 32 S RNA in hybridization to mitochondrial DNA. Quantitative results from such hybridization-competition experiments along with measurements of electrophoretic mobility have been used to construct a molecular size model for synthesis of mitochondrial ribosomal RNA's. The large molecular weight precursor (32 S) of both ribosomal RNA's appears to be 2.4 × 10⁶ daltons in size. Maturation to large subunit RNA (1.28 × 10⁶ daltons) is assumed to involve an intermediate ~1.6 × 10⁶ daltons in size, while cleavage to form small subunit RNA (0.72 × 10⁶ daltons) presumably involves a 0.9 × 10⁶ dalton intermediate. In the maturation process ~22% of the precursor molecule is lost. As is the case for ribosomal RNA's, the mitochondrial precursor RNA has a strikingly low G + C content.     

Secondary structure maps of ribosomal RNA. II. Processing of mouse L-cell ribosomal RNA and variations in the processing pathway

Secondary structure mapping in the electron microscope was applied to ribosomal RNA and precusor ribosomal RNA molecules isolated from nucleoli and the cytoplasm of mouse L-cells. Highly reproducible loop patterns were observed in these molecules. The polarity of L-cell rRNA was determined by partial digestion with 3′-exonuclease. The 28 S region is located at the 5′-end of the 45 S rRNA precursor. Together with earlier experiments on labeling kinetics, these observations established a processing pathway for L-cell rRNA. The 45 S rRNA precursor is cleaved at the 3′-end of the 18 S RNA sequence to produce a 41 S molecule and a spacer-containing fragment (24 S RNA). The 41 S rRNA is cleaved forming mature 18 S rRNA and a 36 S molecule. The 36 S molecule is processed through a 32 S intermediate to the mature 28 S rRNA. This pathway is similar to that found in HeLa cells, except that in L-cells a 36 S molecule occurs in the major pathway and no 20 S precusor to 18 S RNA is found. The processing pathway and its intermediates in L-cells are analogous to those in Xenopus laevis, except for a considerable size difference in all rRNAs except 18 S rRNA.The arrangement of gene and transcribed spacer regions and of secondary structure loops, as well as the shape of the major loops were compared in L-cells, HeLa cell and Xenopus rRNA. The over-all arrangement of regions and loop patterns is very similar in the RNA from these three organisms. The shapes of loops in mature 28 S RNA are also highly conserved in evolution, but the shapes of loops in the transcribed spacer regions vary greatly. These observations suggest that the sequence complementarity that gives rise to this highly conserved secondary structure pattern may have some functional importance.     

Characterization and mutational analysis of yeast Dbp8p, a putative RNA helicase involved in ribosome biogenesis

RNA helicases of the DEAD box family are involved in almost all cellular processes involving RNA molecules. Here we describe functional characterization of the yeast RNA helicase Dbp8p (YHR169w). Our results show that Dbp8p is an essential nucleolar protein required for biogenesis of the small ribosomal subunit. In vivo depletion of Dbp8p resulted in a ribosomal subunit imbalance due to a deficit in 40S ribosomal subunits. Subsequent analyses of pre-rRNA processing by pulse–chase labeling, northern hybridization and primer extension revealed that the early steps of cleavage of the 35S precursor at sites A₁ and A₂ are inhibited and delayed at site A₀. Synthesis of 18S rRNA, the RNA moiety of the 40S subunit, is thereby blocked in the absence of Dbp8p. The involvement of Dbp8p as a bona fide RNA helicase in ribosome biogenesis is strongly supported by the loss of Dbp8p in vivo function obtained by site-directed mutagenesis of some conserved motifs carrying the enzymatic properties of the protein family.     

Topography of 16 S RNA in 30 S subunits and 70 S ribosomes accessibility to cobra venom ribonuclease

A ribonuclease extracted from the venom of the cobra Naja oxiana, which shows an unusual specificity for double-stranded RNA regions, was used to obtain new insight on the topography of Escherichia coli ribosomal 16 S RNA in the 30 S subunit and in the 70 S couple. ³²P-labeled 30 S subunits or reconstituted 70 S tight couples containing ³²P-labeled 16 S RNA have been digested under progressively stronger conditions. The cleavage sites have been precisely localized and the chronology of the hydrolysis process studied.The enzyme cleaves the 16 S RNA within 30 S subunits at 21 different sites, which are not uniformly distributed along the molecule. These results provide valuable information on the 16 S RNA topography and evidence for secondary structure features.The binding of the 50 S subunit markedly reduces the rate of the 16 S RNA hydrolysis and provides protection for several cleavage sites. Four of them are clustered in the 3′-terminal 200 nucleotides of the molecule, one in the middle (at position 772) and one in the 5′ domain (at position 336). Our results provide further evidence that the 3′-terminal and central regions of the RNA chain are close to each other in the ribosome structure and lie at the interface of the two subunits. They also suggest that the 5′ domain is probably not involved exclusively in structure and assembly.     

Free ribosomal DNA molecules from Tetrahymena pyriformis GL are giant palindromes

Restriction ondonuclease EcoRI was used to study the structure of the free ribosomal DNA molecules from Tetrahymena pyriformis, strain GL. From the following observations we conclude that the free rDNA molecules from Tetrahymena are giant palindromes³, each containing two genes for preribosomal RNA arranged in rotational symmetry as inverted repeating sequences. Analyses of the sizes of products of partial or complete digestion and quantitative analyses of the products of complete digestion of uniformly ³²P-labeled rDNA yielded an RI endonucleolytic cleavage map which showed that the EcoRI recognition sites are arranged symmetrically about the center of the rDNA molecule.When heat-denatured rDNA was rapidly cooled under conditions in which no renaturation would occur between separated complementary strands of DNA, molecules of half the size of the original rDNA molecule were produced. These were double-stranded DNA molecules as evidenced by their resistance to digestion with S1 nuclease. Moreover, they could be digested with EcoRI to produce fragments of sizes which would be predicted from the assumption that each single strand of the original rDNA molecule had folded back on itself to form a “hair-pin” double-stranded DNA structure. Hybridization experiments between ribosomal RNA and purified rDNA showed that each rDNA molecule contains two genes for rDNA. Hybridization of the isolated EcoRI fragments of rDNA with 25 S or 17 S rRNA suggested that the two structural genes for 17 S rRNA are located near the center of the rDNA molecule and the two genes for 25 S rRNA are found in distal positions.     

A new method for detecting sites of 2'-O-methylation in RNA molecules.

2'-O-methylation of eukaryotic ribosomal RNAs occurs in the cell nucleoli. At least 100 modification sites that are highly conserved among vertebrate rRNAs have been mapped. However, in part because of the insensitivity of current approaches, there are 2'-O-methylated sites that remain unidentified. We have developed an extremely sensitive method for detecting 2'-O-methylated residues that are predicted within a long RNA molecule. Utilizing RNase H cleavage directed by a 2'-O-methyl RNA-DNA chimeric oligonucleotide, this method has allowed identification of two methylated nucleotides, G1448 in Xenopus 18S rRNA and A394 in Xenopus 28S rRNA. The latter (A394 in 28S) had not been detected before. We have confirmed that the methylation at G1448 in 18S is dependent upon Xenopus U25 snoRNA and have demonstrated that the methylation at A394 in 28S requires U26 snoRNA. One advantage of this technique is that it can examine specific rRNA and precursor molecules. We show that about 30% of the 40S pre-rRNA has been methylated at these two sites and their methylation is complete at the stage of 20S (immediate precursor to 18S) and 32S (immediate precursor to 28S). We also show that methylation at these two sites is not essential for rRNA transport from the nucleus to the cytoplasm.     

The Kinetics of the Synthesis of Ribosomal RNA in E. coli

The kinetics of the synthesis of ribosomal RNA in E. coli has been studied using C¹⁴-uracil as tracer. Two fractions of RNA having sedimentation constants between 4 and 8S have kinetic behavior consistent with roles of precursors. The first consists of a very small proportion of the RNA found in the 100,000 g supernatant after ribosomes have been removed. It has been separated from the soluble RNA present in much larger quantities by chromatography on DEAE-cellulose columns. The size and magnitude of flow through this fraction are consistent with it being precursor to a large part of the ribosomal RNA.

A fraction of ribosomal RNA of similar size is also found in the ribosomes. This fraction is 5 to 10 per cent of the total ribosomal RNA and a much higher proportion of the RNA of the 20S and 30S ribosomes present in the cell extract. The rate of incorporation of label into this fraction and into the main fractions of ribosomal RNA of 18S and 28S suggests that the small molecules are the precursors of the large molecules. Measurements of the rate of labeling of the 20, 30, and 50S ribosomes made at corresponding times indicate that ribosome synthesis occurs by concurrent conversion of small to large molecules of RNA and small to large ribosomes.

     

Some characteristics of processing sites in ribosomal precursor RNA of yeast.

The DNA sequences of the intergenic region between the 17S and 5.8S rRNA genes of the ribosomal RNA operon in yeast has been determined. In this region the 37S ribosomal precursor RNA is specifically cleaved at a number of sites in the course of the maturation process. The exact position of these processing sites has been established by sequence analysis of the terminal fragments of the respective RNA species. There appears to be no significant complementarity between the sequences surrounding the two termini of the 18S secondary precursor RNA nor between those surrounding the two termini of 17S mature rRNA. This finding implies that the processing of yeast 37S ribosomal precursor RNA is not directed by a double-strand specific ribonuclease previously shown to be involved in the processing of E. coli ribosomal precursor RNA [see Refs 1,2]. The processing sites of yeast ribosomal precursor RNA described in the present paper are all flanked at one side by a very [A+T]-rich sequence. In addition, sequence repeats are found around the processing sites in this precursor RNA. Finally, sequence homologies are present at the 3'-termini [6 nucleotides] and the 5'-termini [13 nucleotides] of a number of mature rRNA products and intermediate ribosomal RNA precursors. These structural features are discussed in terms of possible recognition sites for the processing enzymes.     

Detection of specific sequences among DNA fragments separated by gel electrophoresis.

Ribosomal RNA and precursor ribosomal RNA from at least one representative of each vertebrate class have been analyzed by electron microscopic secondary structure mapping. Reproducible patterns of hairpin loops were found in both 28 S ribosomal and precursor ribosomal RNA, whereas almost all the 18 S ribosomal RNA molecules lack secondary structure under the spreading conditions used. The precursor ribosomal RNA of all species analyzed have a common design. The 28 S ribosomal RNA is located at or near the presumed 5′-end and is separated from the 18 S ribosomal RNA region by the internal spacer region. In addition there is an external spacer region at the 3′-end of all precursor ribosomal RNA molecules. Changes in the length of these spacer regions are mainly responsible for the increase in size of the precursor ribosomal RNA during vertebrate evolution. In cold blooded vertebrates the precursor contains two short spacer regions; in birds the precursor bears a long internal and a short external spacer region, and in mammals it has two long spacer regions. The molecular weights, as determined from the electron micrographs, are 2·6 to 2·8 × 10⁶ for the precursor ribosomal RNA of cold blooded vertebrates, 3·7 to 3·9 × 10⁶ for the precursor of birds, and 4·2 to 4·7 × 10⁶ for the mammalian precursor. Ribosomal RNA and precursor ribosomal RNA of mammals have a higher proportion of secondary structure loops when compared to lower vertebrates. This observation was confirmed by digesting ribosomal RNAs and precursor ribosomal RNAs with single-strandspecific S₁ nuclease in aqueous solution. Analysis of the double-stranded, S₁-resistant fragments indicates that there is a direct relationship between the hairpin loops seen in the electron microscope and secondary structure in aqueous solution.     

Mapping of mitochondrial 4 S RNA genes in Xenopus laevis by electron microscopy

The distribution of sites hybridizing with mitochondrial 4 S RNA molecules on mitochondrial DNA of Xenopus laevis has been mapped in relation to the ribosomal RNA genes and EcoRI restriction endonuclease sites. RNA molecules linked to ferritin were employed for this purpose. We have obtained evidence for 15 4 S RNA sites on the H-strand and six sites on the L-strand of X. laevis mtDNA^∥. An indication of the possible existence of one additional site on the H-strand and four additional sites on the L-strand has been obtained. One 4 S RNA site is located in the gap between the two rRNA genes, and one site flanks each outside end of the rRNA genes. The other 4 S RNA sites are distributed almost evenly throughout both strands of the mtDNA. A comparison with the map of 4 S RNA sites on the mtDNA of HeLa cells (Angerer et al., 1976) suggests considerable evolutionary conservation of site organization.     

Processing enzyme ribonuclease E specifically cleaves RNA I. An inhibitor of primer formation in plasmid DNA synthesis

When the RNA processing enzyme RNAase E is inactivated in an Escherichia coli strain carrying derivatives of the colicin E1 plasmid, a small RNA, about 100 nucleotides long, accumulates. Structural analysis of this RNA showed that it is RNA I, the RNA that inhibits plasmid DNA synthesis. RNA I is a specific substrate for RNAase E and the cleavage takes place between the fifth and sixth nucleotides from the 5' end of the molecule. This is only the second natural RNA substrate that has been found, so far, for the RNA processing enzyme ribonuclease E, the other being a precursor for 5 S ribosomal RNA. It is remarkable that nine nucleotides around the cleavage sites are identical in both substrates: (Formula: see text). Therefore, we suggest that at least part of the interaction between RNAase E and its substrate is controlled by these nine nucleotides.     

Nucleolar function of the dense crescent in the yeast nucleus : A biochemical and ultrastructural study

A fraction rich in dense crescent material, as judged by electron microscopy, has been isolated from yeast nuclei. Double-labelling experiments with ¹⁴C-uracil and ³H-Me-methionine show that nearly all of the 37S and 28S ribosomal precursor RNA is confined to this dense crescent fraction. The presence of both 37S and 28S ribosomal precursors in the dense crescent fraction strongly suggests that both biosynthesis and processing of the ribosomal precursors take place in the dense crescent. The biochemical and electron microscopic data represent strong evidence that the dense crescent in yeast has to be regarded as a nucleolus in both morphological and biochemical sense. Apparently the yeast cell resembles the higher eukaryotes with regard to the organization within a nucleolus of the synthesis of ribosomal RNA via large precursor molecules.     

RRP20, a component of the 90S preribosome,is required for pre-18S rRNA processing in Saccharomyces cerevisiae

A strain of Saccharomyces cerevisiae, defective in small subunit ribosomal RNA processing, has a mutation in YOR145c ORF that converts Gly235 to Asp. Yor145c is a nucleolar protein required for cell viability and has been reported recently to be present in 90S pre-ribosomal particles. The Gly235Asp mutation in YOR145c is found in a KH-type RNA-binding domain and causes a marked deficiency in 18S rRNA production. Detailed studies by northern blotting and primer extension analyses show that the mutant strain impairs the early pre-rRNA processing cleavage essentially at sites A₁ and A₂, leading to accumulation of a 22S dead-end processing product that is found in only a few rRNA processing mutants. Furthermore, U3, U14, snR10 and snR30 snoRNAs, involved in early pre-rRNA cleavages, are not destabilized by the YOR145c mutation. As the protein encoded by YOR145c is found in pre-ribosomal particles and the mutant strain is defective in ribosomal RNA processing, we have renamed it as RRP20.     

Nature of the ribosomal RNA transcribed from the X and Y chromosomes of Drosophila melanogaster

In Drosophila melanogaster there is one nucleolar organizer (NO) on each X and Y chromosome. Experiments were carried out to compare the ribosomal RNAs derived from the two nucleolar organizers. ³²PO₄-labelled ribosomal RNA was isolated from two strains of D. melanogaster, one containing only the X chromosome NO, the other containing only the Y chromosome NO. 28 S and 18 S RNA from the two strains were subjected to a variety of “fingerprinting” and sequencing procedures. Fingerprints of 28 S RNA were very different from those of 18 S RNA. Fingerprints of “X” and “Y” 28 S RNA were indistinguishable from each other, as also were fingerprints of “X” and “Y” 18 S RNA. In combined “T₁ plus pancreatic” RNAase fingerprints several distinctive products were characterized and quantitated. Identical products were obtained from X and Y RNA, and the molar yields of the products were indistinguishable. Together these findings imply that the rRNA sequences encoded by the X and Y NOs are closely similar and probably identical to each other.Two further findings were of interest in “T₁ plus pancreatic” RNAase fingerprints: (1) in 28 S (as well as in 18 S) fingerprints several distinctive products were recovered in approximately unimolar yields. This indicates that 28 S RNA does not consist of two identical half molecules, though it does consist of two non-identical half molecules together with a “5.8 S” fragment. (2) Several methylated components in Drosophila rRNA also occur in rRNA from HeLa cells and yeast. This suggests that certain features of rRNA structure involving methylated nucleotides may be highly conserved in eukaryotic evolution.     

Functional significance of intermediate cleavages in the 3'ETS of the pre-rRNA from Schizosaccharomyces pombe

Pathways for the maturation of ribosomal RNAs are complex with numerous intermediate cleavage sites that are not always conserved closely in the course of evolution. Both in eukaryotes and bacteria genetic analyses and in vitro studies have strongly implicated RNase III-like enzymes in the processing of rRNA precursors. In Schizosacharomyces pombe, for example, the RNase III-like Pac1 nuclease has been shown to cleave the free 3′ETS at two known intermediate sites but, in the presence of RAC protein, the same RNA also is cleaved at the 3′-end of the 25 S rRNA sequence. In this study normal and mutant 3′ETS sequences were digested with the Pac1 enzyme to further evaluate its role in rRNA processing. Accurate cleavage at the known intermediate processing sites was dependent on the integrity of the helical structure at these sites as well as a more distal upper stem region in the conserved extended hairpin structure of the 3′ETS. The cleavage of mutant 3′ETS sequences also generally correlated with the known effects of these mutations on rRNA production, in vivo. One mutant, however, was efficiently processed in vivo but was not a substrate for the Pac1 nuclease, in vitro. In contrast, in the presence of RAC protein, the same RNA remained susceptible to Pac1 nuclease cleavage at the 3′-end of the 25 rRNA sequence, indicating that the removal of the 3′ETS does not require cleavage at the intermediate sites. These results suggest that basic maturation pathways may be less complex than previously reported raising similar questions about other intermediate processing sites, which have been identified by analyses of termini, and/or processing, in vitro.