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.     

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.     

The differential regulation of the synthesis of ribosomal RNA, 5 S RNA, and 4 S RNA in the polytenic salivary gland cells of the blowfly, Calliphora erythrocephala

Third-instar larvae of the blowfly Calliphora erythrocephala were injected with [2-³H]adenosine, and its flow into the salivary gland ATP pool and each of several electrophoretically resolved salivary gland RNA species were quantitated. From these data, the individual in vivo rates of synthesis, accumulation, and processing of salivary gland ribosomal RNA (rRNA), 4 S RNA, and 5 S RNA have been measured at several different developmental stages. These results indicate that the synthesis of 5 S RNA and rRNA are coordinate, developmentally regulated, and independent of the synthesis of 4 S RNA. A nonribosomal, heterodisperse RNA component (hdRNA) was also identified. This species contributes to both the rapidly turning over pulse-labeled RNA and the accumulating pulse-labeled RNA populations. Indirect measurements suggest that the developmental pattern of regulation of this RNA species is also independent of 5 S RNA and rRNA synthesis. The rate of synthesis and accumulation of each of these RNA species either remained constant or declined during the first three-fourths of the instar, despite a six- to sevenfold increase in the content of cellular DNA.     

Characteristics and intracellular distribution of messengerlike RNA in encysted embryos of Artemia salina

Homogenates of dormant cysts of Artemia salina were fractionated by differential centrifugation. RNA was prepared from the various fractions and tested for stimulatory activity in a [¹⁴C]leucine incorporating Escherichia coli system. The highest specific activity was found in the RNA extracted from a cytoplasmic fraction sedimenting at 15,000 g. Some activity was associated with the soluble and crude ribosomal fractions, while the RNA extracted from the crude nuclear fraction was less active.The 15,000 g sediment was purified by centrifugation in a sucrose density gradient. The active material formed a characteristic, colored band at a buoyant density of about 1.17 g/ml. The banding fraction was mainly composed of endoplasmic vesicles and mitochondria. The specific activity of the extracted RNA was further increased when the 15,000 g sediment was treated with buffered 20–100 mM EDTA (with or without 0.1% Triton X-100) before banding.Sedimentation analysis of the active RNA from the purified 15,000 g fractions revealed three distinct absorption peaks at 28 S, 18 S, and 16 S, apparently representing cytoplasmic and mitochondrial rRNA. The 28 S and 18 S peaks were reduced by EDTA treatment, but only to a certain limit. By gel electrophoresis a number of additional components were resolved, including 4 S and 5 S RNA. The template activity showed a heterodisperse distribution with a maximum at 17–20 S, not correlated with the 16 S peak. Isolated 18 S and 28 S rRNA had very low activity.The experiments suggest that in Artemia cysts an appreciable amount of messengerlike RNA is associated with mitochondria and/or endoplasmic vesicles carrying ribosomal monomers.     

Secondary structure maps of ribosomal RNA and DNA: I. Processing of Xenopus laevis ribosomal RNA and structure of single-stranded ribosomal DNA

Precursor and mature ribosomal RNA molecules from Xenopus laevis were examined by electron microscopy. A reproducible arrangement of hairpin loops was observed in these molecules. Maps based on this secondary structure were used to determine the arrangement of sequences in precursor RNA molecules and to identify the position of mature rRNAs within the precursors. A processing scheme was derived in which the 40 S rRNA is cleaved to 38 S RNA, which then yields 34 S plus 18 S RNA. The 34 S RNA is processed to 30 S, and finally to 28 S rRNA. The pathway is analogous to that of L-cell rRNA but differs from HeLa rRNA in that no 20 S rRNA intermediate was found. X. laevis 40 S rRNA (M_r = 2.7 × 10⁶) is much smaller than HeLa or L-cell 45 8 rRNA (M_r = 4.7 × 10⁶), but the arrangement of mature rRNA sequences in all precursors is very similar. Experiments with ascites cell 3′-exonuclease show that the 28 S region is located at or close to the 5′-end of the 40 S rRNA.Secondary structure maps were obtained also for single-stranded molecules of ribosomal DNA. The region in the DNA coding for the 40 S rRNA could be identified by its regular structure, which closely resembles that of the RNA. Regions corresponding to the 40 S RNA gene alternate with non-transcribed spacer regions along strands of rDNA. The latter have a large amount of irregular secondary structure and vary in length between different repeating units. A detailed map of the rDNA repeating unit was derived from these experiments.Optical melting studies are presented, showing that rRNAs with a high (G + C) content exhibit significant hypochromicity in the formamide/urea-containing solution that was used for spreading.     

The action of α-amanitin in vivo on the synthesis and maturation of mouse liver ribonucleic acids

α-Amanitin acts in vitro and in vivo as a selective inhibitor of nucleoplasmic RNA polymerases. Treatment of mice with low doses of α-amanitin causes the following changes in the synthesis, maturation and nucleocytoplasmic transfer of liver RNA species. 1. The synthesis of the nuclear precursor of mRNA is strongly inhibited and all electrophoretic components are randomly affected. The labelling of cytoplasmic mRNA is blocked. These effects may be correlated with the rapid and lasting inhibition of nucleoplasmic RNA polymerase. 2. The synthesis and maturation of the nuclear precursor of rRNA is inhibited within 30min. (a) The initial effect is a strong (about 80%) inhibition of the early steps of 45S precursor rRNA maturation. (b) The synthesis of 45S precursor rRNA is also inhibited and the effect increases from about 30% at 30min to more than 70% at 150min. (c) The labelling of nuclear and cytoplasmic 28S and 18S rRNA is almost completely blocked. The labelling of nuclear 5S rRNA is inhibited by about 50%, but that of cytoplasmic 5S rRNA is blocked. (d) The action of α-amanitin on the synthesis of precursor rRNA cannot be correlated with the slight gradual decrease of nucleolar RNA polymerase activity (only 10–20% inhibition at 150min). (e) The inhibition of precursor rRNA maturation and synthesis precedes the ultrastructural lesions of the nucleolus detected by standard electron microscopy. 3. The synthesis of nuclear 4.6S precursor of tRNA is not affected by α-amanitin. However, the labelling of nuclear and cytoplasmic tRNA is decreased by about 50%, which indicates an inhibition of precursor tRNA maturation. The results of this study suggest that the synthesis and maturation of the precursor of rRNA and the maturation of the precursor of tRNA are under the control of nucleoplasmic gene products. The regulator molecules may be either RNA or proteins with exceedingly fast turnover.     

Synthesis and transport of various RNA species in developing embryos of Xenopus laevis.

Embryonic cells of Xenopus laevis were labeled for varying lengths of time, and their nuclear and cytoplasmic RNAs were analyzed, with the following results. (1) The synthesis of small nuclear RNAs (snRNAs) is detected from blastula stage on. (2) The initiation of 4 S and 5 S RNA syntheses occurs at blastula stage. However, while the former is transported into the cytoplasm immediately after its synthesis, the latter remains within the nucleus, until its transport starts later, concomitantly with that of 28 S rRNA. (3) As soon as “blastula” cells start to synthesize 40 S rRNA precursor at 5th hr of cultivation, 18 S rRNA is transported first; the transport of 28 S rRNA begins 2 hr later. (4) On a per-cell basis, poly(A)-RNA is synthesized in blastula stage at a much higher rate than in the later stages. About one-third of the total blastula poly(A)-RNA, and about one-fifth in the case of tailbud cells, is transported quickly into the cytoplasm. Then, it appears that the RNAs which are synthesized at early embryonic stages are transported to the cytoplasm without delays, except for 5 S RNA and snRNAs.     

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.     

Inhibitor of ribosomal RNA synthesis in Xenopus laevis embryos. V. Inability of inhibitor to repress 5S RNA synthesis.

A specific inhibitor of ribosomal RNA (rRNA) synthesis was partially purified from an acid-soluble fraction of Xenopus laevis blastulae. Effects of this inhibitor on 5S rRNA synthesis of isolated neurula cells of the same species were investigated. The results show that the synthesis of both 5S rRNA and 4S RNA proceeds normally when both 18 and 28S rRNA are almost completely inhibited. Failure of the inhibitor to suppress 5S rRNA synthesis suggests that it plays an important role in the regulation of 18 and 28S rRNA synthesis during development and that the synthesis of 5S rRNA is not coordinated to that of 18 and 28S rRNA.     

Functional characterization of the Drosophila MRP (mitochondrial RNA processing) RNA gene

MRP RNA is a noncoding RNA component of RNase mitochondrial RNA processing (MRP), a multi-protein eukaryotic endoribonuclease reported to function in multiple cellular processes, including ribosomal RNA processing, mitochondrial DNA replication, and cell cycle regulation. A recent study predicted a potential Drosophila ortholog of MRP RNA (CR33682) by computer-based genome analysis. We have confirmed the expression of this gene and characterized the phenotype associated with this locus. Flies with mutations that specifically affect MRP RNA show defects in growth and development that begin in the early larval period and end in larval death during the second instar stage. We present several lines of evidence demonstrating a role for Drosophila MRP RNA in rRNA processing. The nuclear fraction of Drosophila MRP RNA localizes to the nucleolus. Further, a mutant strain shows defects in rRNA processing that include a defect in 5.8S rRNA processing, typical of MRP RNA mutants in other species, as well as defects in early stages of rRNA processing.     

Changes in rate of RNA synthesis and ribosomal gene number during oogenesis of Drosophila melanogaster.

A new method for separating Drosophila egg chambers into different developmental classes (Jacobs-Lorena and Crippa, 1977) made it possible to study changes in the rate of ribosomal RNA (rRNA), 5S RNA, and tRNA synthesis and the changes in ribosomal gene number during oogenesis. Synthesis of RNA was measured by [³H]uridine incorporation in vivo and subsequent analysis on sucrose gradients or gel electrophoresis. Specific radioactivity of nucleotide pools has also been determined. Ribosomal gene number has been measured by hybridization of egg chamber DNA to rRNA of high specific radioactivity. Our findings led us to conclude that in Drosophila melanogaster: (i) rRNA, 5S RNA, and tRNA are synthesized in all stages of oogenesis. (ii) In every stage, rRNA is the main RNA species synthesized. (iii) The rate of rRNA, 5S RNA, and tRNA synthesis increases greatly during oogenesis and is paralleled by a similar increase in ribosomal gene number resulting from the polyploidization of the nurse cell nuclei.     

Methylation damage to RNA induced in vivo in Escherichia coli is repaired by endogenous AlkB as part of the adaptive response

Cytotoxic 1-methyladenine (1-meA) and 3-methylcytosine (3-meC) lesions induced in DNA and RNA in vitro and in pre-damaged DNA and RNA bacteriophages in vivo are repaired by the Escherichia coli (E. coli) protein AlkB and a human homolog, ALKBH3. However, it is not known whether endogenous RNA is repaired in vivo by repair proteins present at physiological concentrations. The concept of RNA repair as a biologically relevant process has therefore remained elusive. Here, we demonstrate AlkB-mediated repair of endogenous RNA in vivo by measuring differences in lesion-accumulation in two independent AlkB-proficient and deficient E. coli strains during exposure to methyl methanesulfonate (MMS). Repair was observed both in AlkB-overproducing strains and in the wild-type strains after AlkB induction. RNA repair appeared to be highest in RNA species below 200 nucleotides in size, mainly comprising tRNAs. Strikingly, at least 10-fold more lesions were repaired in RNA than in DNA. This may be a consequence of some 30-fold higher levels of aberrant methylation in RNA than in DNA after exposure to MMS. A high primary kinetic isotope effect (>10) was measured using a deuterated methylated RNA substrate, D₃-1me(rA), demonstrating that it is the catalytic step, and not the search step that is rate-limiting. Our results demonstrate that RNA repair by AlkB takes place in endogenous RNA as part of an adaptive response in wild-type E. coli cells.     

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.