Alternate temporal order in ribosomal RNA maturation

A small nucleolar RNA functions in rRNA processing in Caenorhabditis elegans

CeR-2 RNA is one of the newly identified Caenorhabditis elegans noncoding RNAs (ncRNAs). The characterization of CeR-2 by RNomic studies has failed to classify it into any known ncRNA family. In this study, we examined the spatiotemporal expression patterns of CeR-2 to gain insight into its function. CeR-2 is expressed in most cells from the early embryo to adult stages. The subcellular localization of this RNA is analogous to that of fibrillarin, a major protein of the nucleolus. It was observed that knockdown of C/D small nucleolar ribonucleoproteins (snoRNPs), but not of H/ACA snoRNPs, resulted in the aberrant nucleolar localization of CeR-2 RNA. A mutant worm with a reduced amount of cellular CeR-2 RNA showed changes in its pre-rRNA processing pattern compared with that of the wild-type strain N2. These results suggest that CeR-2 RNA is a C/D snoRNA involved in the processing of rRNAs.

U3 small nucleolar RNA is essential for cleavage at sites 1, 2 and 3 in pre-rRNA and determines which rRNA processing pathway is taken in Xenopus oocytes

A molecular dissection of U3 small nucleolar RNA (snoRNA) was performed in vivo in Xenopus oocytes and the effects on rRNA processing were analyzed. Oocyte injection of antisense oligonucleotides against parts of U3 snoRNA resulted in specific fragmentation of U3 by endogenous RNase H. Fragmentation of U3 domain II correlated with a decrease in 20 S pre-rRNA and a concomitant increase in 36 S pre-rRNA, indicating reduced cleavage at site 3. Conversely, fragmentation of U3 domain I completely blocked 18 S rRNA formation, increased the 20 S rRNA precursor, and decreased 36 S pre-rRNA, indicating inhibition of cleavage at sites 1+2. rRNA processing defects at sites 1+2 or 3 after destruction of intact endogenous U3 snoRNA were rescued by injection of in vitro transcripts of U3 snoRNA or certain U3 fragments. Thus, cleavage at sites 1+2 and 3 is U3 snoRNA dependent. Moreover, U3 snoRNA has two functional modules: domain I for sites 1+2 cleavage and domain II for site 3 cleavage. The data suggest that whichever of these U3 domains acts first determines which rRNA processing pathway will be taken: cleavage first at site 3 of pre-rRNA leads to pathway A, whereas cleavage first at sites 1+2 leads to pathway B for rRNA processing. Predictions of this model were validated by rescue of site 3 cleavage by injection of just domain II after U3 depletion. Rescue of sites 1+2 cleavage required covalent continuity of domain I with the hinge region and non-covalent association with domain II. We could experimentally shift which rRNA processing pathway was taken by injecting fragments of U3 to compete with endogenous U3 snoRNA.

Processing of precursor rRNA in Euglena gracilis: identification of intermediates in the pathway to a highly fragmented large subunit rRNA

We have identified and characterized the stable steady-state intermediates that appear during formation of the cytoplasmic rRNA in Euglena gracilis. A 10.2 kb RNA is the precursor to both the small subunit (SSU) rRNA and 14 discrete fragments that comprise the large subunit (LSU) rRNA. The SSU rRNA is produced via two intermediates of 4.4 kb and 3.2 kb, whereas the LSU rRNA is generated by way of two RNA species of 5.8 kb and 5.3 kb. A number of unique intermediates are associated with a novel processing pathway by which the 14 mature fragments of the LSU rRNA are produced. Analysis of transcripts mapping within ITS1, the internal transcribed spacer separating the SSU and LSU rRNA coding regions, revealed that the LSU1 (=5.8S) rRNA is heterogeneous at its 5'-end, with a major cluster of primer extension products terminating approx. 4-5 nucleotides upstream from the predominant, mature 5'-end and a second, low-level extension product appearing further upstream within ITS1. The results reported here define the pre-rRNA processing pathway in E. gracilis and provide the basis for further studies of the mechanism of excision of the novel ITSs in this system.

Localization and structure of endonuclease cleavage sites involved in the processing of the rat 32S precursor to ribosomal RNA

The initial endonuclease cleavage site in 32 S pre-rRNA (precursor to rRNA) is located within the rate rDNA sequence by S1-nuclease protection mapping of purified nucleolar 28 S rRNA and 12 S pre-rRNA. The heterogeneous 5'- and 3'-termini of these rRNA abut and map within two CTC motifs in tSi2 (internal transcribed spacer 2) located at 50-65 and 4-20 base-pairs upstream from the homogeneous 5'-end of the 28 S rRNA gene. These results show that multiple endonuclease cleavages occur at CUC sites in tSi2 to generate 28 S rRNA and 12 S pre-rRNA with heterogeneous 5'- and 3'-termini, respectively. These molecules have to be processed further to yield mature 28 S and 5.8 S rRNA. Thermal-denaturation studies revealed that the base-pairing association in the 12 S pre-rRNA:28 S rRNA complex is markedly stronger than that in the 5.8 S:28 S rRNA complex. The sequence of about one-quarter (1322 base-pairs) of the 5'-part of the rat 28 S rDNA was determined. A computer search reveals the possibility that the cleavage sites in the CUC motifs are single-stranded, flanked by strongly base-paired GC tracts, involving tSi2 and 28 S rRNA sequences. The subsequent nuclease cleavages, generating the termini of mature rRNA, seem to be directed by secondary-structure interactions between 5.8 S and 28 S rRNA segments in pre-rRNA. An analysis for base-pairing among evolutionarily conserved sequences in 32 S pre-rRNA suggests that the cleavages yielding mature 5.8 S and 28 S rRNA are directed by base-pairing between (i) the 3'-terminus of 5.8 S rRNA and the 5'-terminus of 28 S rRNA and (ii) the 5'-terminus of 5.8 S rRNA and internal sequences in domain I of 28 S rRNA. A general model for primary- and secondary-structure interactions in pre-rRNA processing is proposed, and its implications for ribosome biogenesis in eukaryotes are briefly discussed.

Complex endonucleolytic cleavage pattern during early events in the processing of pre-rRNA in the lower eukaryote, Tetrahymena thermophila

We have analysed nuclear RNA from T. thermophila by RNA transfer hybridization using cloned rDNA fragments. A very high number of in vivo intermediates and by-products of rRNA processing were identified. These include putative intermediates of the splicing process and alternative products resulting from temporal variability in various endonucleolytic cleavages. In addition, four small RNA species including only transcribed spacer sequences were detected. These are (1) the IVS RNA (approximately 400 bases), the by-product of the splicing process, (2) a fragment from the internal transcribed spacer (approximately 360 bases), possibly resulting from 3'-end processing of pre-17S rRNA, (3) a fragment comprising most or all of the external transcribed spacer (approximately 600 bases) obviously representing the major by-product of 5'-end processing, and, in addition, (4) a small fragment from the initiation region (approximately 230 bases) which might be a product of premature transcription termination.

Post-transcriptional regulation of ribosome formation in the nucleus of regenerating rat liver

Kinetic experiments on RNA labelling in vivo with [14C]orotate were performed with normal and 12h-regenerating rat liver. The specific radioactivities of nucleolar, nucleoplasmic and cytoplasmic rRNA species were analysed by computer according to the models of rRNA processing and nucleo-cytoplasmic migration given previously [Dudov, Dabeva, Hadjiolov & Todorov, Biochem. J. (1978) 171, 375-383]. The rates of formation and the half-lives of the individual pre-rRNA and rRNA species were determined in both normal and regenerating liver. The results show clearly that the formation of ribosomes in regenerating rat liver is post-transcriptionally activated: (a) the half-lives of all the nucleolar pre-rRNA and rRNA species are decreased by 30% on average; (b) the pre-rRNA processing is directed through the shortest maturation pathway: 45 S leads to 32 S + 18 S leads to 28 S; (c) the nucleo-cytoplasmic transfer of ribosomes is accelerated. As a consequence, the time for formation and appearance of ribosomes in the cytoplasm is shortened 1.5-fold for the large and 2-fold for the small subparticle. A new scheme for endonuclease cleavage of 45 S pre-rRNA is proposed, which explains the alterations in pre-rRNA processing in regenerating liver. Its validity for pre-rRNA processing in other eukaryotes is discussed. It is concluded that: (i) the control sites in the intranucleolar formation of 28 S and 18 S rRNA are the immediate precursor of 28 S rRNA, 32 S pre-rRNA, and the primary pre-rRNA, 45 S pre-rRNA, respectively; (ii) the limiting step in the post-transcriptional stages of ribosome biogenesis is the pre-rRNA maturation.

Regulation of rRNA synthesis and processing in animal cells. Effect of nucleoside analogues

The nucleoside analogues fluorouridine and fluorodeoxyuridine (both at 100 muM) and 8-azaguanine (at 500 muM) inhibit both rRNA transcription and processing in Ehrlich ascites cells. In BHK21 cells fluorodeoxyuridine has no effect on either rRNA maturation or transcription, whereas toyocamycin (at 2 microM) inhibits both processes in BHK21 cells and Ehrlich ascites cells. The drugs inhibit transcription in cells incubated in the complete medium, but have no effect on the decreased transcription in cells incubated in a medium without amino acids. This lack of effect cannot be explained by an altered uptake of the drugs in the amino acid-starved cells, since maturation of the rRNA precursor is affected in cells incubated in media with or without amino acids. The effect of the drugs on rRNA transcription is not the consequence of the inhibition of protein synthesis. The results lend support to the proposal that rRNA processing and transcription are co-ordinately controlled in cells with a high rate of rRNA synthesis.

Multiple ribosomal RNA cleavage pathways in mammalian cells

The sequence content of mouse L cell pre-rRNA was examined by RNA gel transfer and blot hybridization. Nuclear RNAs were separated by agarose gel electrophoresis, transferred to diazo-paper, and hybridized to twelve different restriction fragments that are complementary to various sections of 45S pre-rRNA. An abundant new 34S pre-rRNA and less abundant new 37S, 26S and 17S pre-rRNAs were detected. The presence of these new pre-rRNAs suggests the existence of at least two new pre-rRNA cleavage pathways. 34S and 26S pre-rRNAs were also detected in HeLa cells suggesting that these new cleavage pathways are characteristic of mammalian cells. Further, an abundant new 12S precursor to 5.8S rRNA was also detected and is common to all the proposed cleavage pathways. The previously identified 45S, 41S, 32S and 20S pre-rRNAs were readily detected and their general structure confirmed. The 20S pre-rRNA is characteristic of the known pathway used by HeLa and other cells, and its presence suggests that growing mouse L cells use this pre-rRNA cleavage pathway. The 36S pre-rRNA characteristic of the previously described mouse L cell cleavage pathway was not detected. In all these cleavage pathways pre-rRNA cleavage sites are apparently identical and occur at or near the termini of the mature 18S, 5.8S and 28S rRNA sequences. The pathways differ only in the temporal order of cleavage at these sites. The position of the 5.8S rRNA sequence was located within the internal transcribed spacer. The known and conserved sequence of 5.8S rRNA from several organisms predicts a characteristic pattern of restriction enzyme sites for 5.8S rDNA. Internal transcribed spacer rDNA was mapped with restriction enzymes, and the characteristic pattern was found near the midpoint of the internal transcribed spacer. This places the 5.8S rRNA sequence at or near the 5' terminus of 32S pre-rRNA.

Defect in polyamine metabolism in a BHK cell mutant temperature-sensitive for rRNA maturation

A mutant of BHK cells (ts422E) temperature-sensitive for processing 32S rRNA to 28S rRNA (Toniolo et al., '73) also loses the ability to synthesize polyamines and 5.8S rRNA when shifted to the non-permissive temperature (39 degrees). The activity of several enzymes not involved with polyamine synthesis, methylation of 32S rRNA, and small nuclear RNA production are apparently unaffected after at least 24 hours at 39 degrees. When cultures are returned to the permissive temperature (33 degrees), polyamine synthesizing capacity returns to normal as mature rRNA production resumes.

Processing and migration of ribosomal ribonculeic acids in the nucleolus and nucleoplasm of rat liver nuclei

Kinetic studies on the labelling in vivo with [14C]orotate of rat liver nucleolar and nucleoplasmic pre-rRNA (precursor of rRNA) and rRNA, isolated from detergent-purified nuclei, were carried out. The mathematical methods used for the computer analysis of specific-radioactivity curves are described. Evaluation of the experimental data permitted the selection of the most probable models for the processing of pre-rRNA and the nucleo-cytoplasmic transfer of rRNA. It was shown that considerable flexibility exists in the sequence of endonuclease attacks at critical sites of 45 and 41 S pre-rRNA chains, resulting in the simultaneous occurrence of several processing pathways. However, the phosphodiester bonds involved in the formation of mature 28 and 18 S rRNA appear to be protected until the generation of their immediate pre-rRNA. The turnover rates and half-lives of all pre-rRNA and rRNA pools were determined. The turnover rate of 45 S pre-rRNA corresponds to the formation of 1100 ribosomes/min per nucleus. The model for the nucleolus-nucleoplasm-cytoplasm migration of rRNA includes a 'nucleoplasm' compartment in which the small ribosomal subparticle is in rapid equilibrium with the respective cytoplasmic pool. At equimolar amounts of nuclear 28 and 18 S rRNA this model explains the faster appearance of labelled small ribosomal subparticles in the cytoplasm simultaneous with a lower labelling of nuclear 18 S rRNA as compared with 28 S rRNA.

Heterogeneity in Chinese hamster ribosomal DNA

A discrete heterogeneity has been detected in Chinese hamster ribosomal DNA after Eco R1 digestion of total DNA followed by a Southern transfer and hybridization with [125I]18S or [125I]28S ribosomal RNA. Digestion with Eco R1 produces three fragments, 4.3, 6.0 and 9.5 x 10(6) daltons respectively, which hybridize with 18S RNA. The smallest fragment also hybridizes with 28S RNA. Either length heterogeneity or sequence heterogeneity (i.e. presence of an additional Eco R1 site in some of the rDNA molecules) must be invoked to account for the two larger Eco R1 fragments that contain 18S but not 28S sequences. Eco R1 and Hind III maps, consistent with either length or sequence heterogeneity, are presented. The data at this time, however, do not distinguish between the two alternatives.

Intranuclear maturation pathways of rat liver ribosomal ribonucleic acids

The maturation of pre-rRNA (precursor to rRNA)in liver nuclei is studied by agar/ureagel electrophoresis, kinetics of labelling in vivo with [14C] orotate and electron-microscopic observation of secondary structure of RNA molecules. (1) Processing starts from primary pre-rRNA molecules with average mol. wt. 4.6X10(6)(45S) containing the segments of both 28S and 18S rRNA. These molecules form a heterogeneous peak on electrophoresis. The 28S rRNA segment is homogeneous in its secondary structure. However, the large transcribed spacer segment (presumably at the 5'-end) is heterogeneous in size and secondary structure. A minor early labelled RNA component with mol.wt. about 5.8X10(6) is reproducibly found, but its role as a pre-rRNA species remains to be determined. (2) The following intermediate pre-rRNA species are identified: 3.25X10(6) mol.wt.(41S), a precursor common to both mature rRNA species ; 2.60X10(6)(36S) and 2.15X10(6)(32S) precursors to 28S rRNA; 1.05X10(6) (21S) precursor to 18S rRNA. The pre-rRNA molecules in rat liver are identical in size and secondary structure with those observed in other mammalian cells. These results suggest that the endonuclease-cleavage sites along the pre-rRNA chain are identical in all mammalian cells. (3) Labelling kinetics and the simultaneous existence of both 36S and 21S pre-rRNA reveal that processing of primary pre-rRNA in adult rat liver occurs simultaneously by at least two major pathways: (i) 45S leads to 41S leads to 32S+21S leads to 28S+18S rRNA and (ii) 45S leads to 41S leads to 36S+18S leads to 32S leads to 28S rRNA. The two pathways differ by the temporal sequence of endonuclease attack along the 41 S pre-rRNA chain. A minor fraction (mol.wt.2.9X10(6), 39S) is identified as most likely originating by a direct split of 28S rRNA from 45S pre-rRNA. These results show that in liver considerable flexibility exists in the order of cleavage of pre-rRNA molecules during processing.