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.     

Evolutionarily conserved structural features in the ITS2 of mammalian pre-rRNAs and potential interactions with the snoRNA U8 detected by comparative analysis of new mouse sequences.

Mechanisms of ITS2 excision from pre-rRNA remain largely elusive. In mammals, at least two endonucleolytic cleavages are involved, which result in the transient accumulation of precursors to 5.8S rRNA termed 8S and 12S RNAs. We have sequenced ITS2 in four new species of the Mus genus and investigated its secondary structure using thermodynamic prediction and comparative approach. Phylogenetic evidence supports an ITS2 folding organized in four domains of secondary structure extending from a preserved structural core. This folding is also largely conserved for the previously available mammalian ITS2 sequences, rat and human, despite their extensive sequence divergence relative to the Mus species. Conserved structural features include the structural core, containing the 3' end of 8S pre-rRNA within a single-stranded sequence, and a stem containing the 3' end of the 12S pre-rRNA species. A putative, phylogenetically preserved pseudoknot has been detected 1 nt downstream from the 12S 3' end. Two long complementarities have also been identified, in sequences conserved among vertebrates, between the pre-rRNA 32S and the snoRNA (small nucleolar RNA) U8 which is required for the excision of Xenopus ITS2. The first complementarity involves the 5.8S-ITS2 junction and 13 nt at the 5' end of U8, whereas the other one occurs between a mature 28S rRNA segment known to be required for ITS2 excision and positions 15-25 of snoRNA U8. These two potential interactions, in combination with ITS2 folding, could organize a functional pocket containing three cleavage sites and key elements for pre-rRNA processing, suggesting a chaperone role for the snoRNA U8.     

A 12 S precursor to 5.8 S rRNA associated with rat liver nucleolar 28 S rRNA

The pre-rRNA and rRNA components of rat and mouse liver nucleolar RNA were analysed. It was shown that upon denaturation, part of the 32 S pre-rRNA is converted into 28 S rRNA and 12 S RNA. The 12 S RNA from mouse (Mr, 0.36 X 10(6)) is larger than the one from rat (Mr, 0.32 X 10(6). The 12 S RNA chain is intact and resists denaturation treatment. The non-covalent binding of this RNA with nucleolar 28 S rRNA is stronger than that of 5.8 S rRNA with 28 S rRNA. Hybridization with a rat internal-transcribed spacer rDNA fragment identifies 12 S RNA as corresponding to the 5'-end non-conserved segment of 32 S pre-rRNA, including 5.8 S rRNA. The significance of the formation of a 12 S precursor to 5.8 S rRNA in the biogenesis of ribosomes in mammalian cells is discussed.     

The structure of the ITS2-proximal stem is required for pre-rRNA processing in yeast.

Accurate and efficient processing of pre-rRNA is critical to the accumulation of mature functional ribosomal subunits for maintenance of cell growth. Processing requires numerous factors which act in trans as well as RNA sequence/ structural elements which function in cis. To examine the latter, we have used directed mutagenesis and expression of mutated pre-rRNAs in yeast. Specifically, we tested requirements for formation of an ITS2-proximal stem on processing, a structure formed by an interaction between sequences corresponding to the 3' end of 5.8S rRNA and the 5' end of 25S. Pre-rRNA processing is inhibited in templates encoding mutations that prevent the formation of the ITS2-proximal stem. Compensatory, double mutations, which alter the sequence of this region but restore the structure of the stem, also restore processing, although at lower efficiency. This reduction in efficiency is reflected in decreased levels of mature 5.8S and 25S rRNA and increased levels of 35S pre-rRNA and certain processing intermediates. This phenotype is reminiscent of the biochemical depletion of U8 snoRNA in vertebrates for which the ITS2-proximal stem has been proposed as a potential site for interaction with U8 RNP. Thus, formation of the ITS2-proximal stem may be a requirement common to yeast and vertebrate pre-rRNA processing.     

Recognition signals for mouse pre-rRNA processing

In order to identify signals for rRNA processing in eukaryotes, mouse pre-rRNA sequence features around four cleavage sites have been analyzed. No consensus sequence can be recognized when the four boundary regions are examined. Unlike mature rRNA termini, distal sequences of precursor-specific domains cannot participate in stable duplex with adjacent regions. The extensive divergence of precursor-specific sequences during evolution also applies to nucleotides adjacent to cleavage sites, with a significant exception for a conserved segment immediately downstream 5.8S rRNA. A specific role is proposed for U3 nucleolar RNA in the conversion of 32S pre-rRNA into mature 28S rRNA, through base-pairing with precursor-specific sequences at the boundaries of excised domains.     

The evolutionarily conserved protein Las1 is required for pre-rRNA processing at both ends of ITS2

Ribosome synthesis entails the formation of mature rRNAs from long precursor molecules, following a complex pre-rRNA processing pathway. Why the generation of mature rRNA ends is so complicated is unclear. Nor is it understood how pre-rRNA processing is coordinated at distant sites on pre-rRNA molecules. Here we characterized, in budding yeast and human cells, the evolutionarily conserved protein Las1. We found that, in both species, Las1 is required to process ITS2, which separates the 5.8S and 25S/28S rRNAs. In yeast, Las1 is required for pre-rRNA processing at both ends of ITS2. It is required for Rrp6-dependent formation of the 5.8S rRNA 3' end and for Rat1-dependent formation of the 25S rRNA 5' end. We further show that the Rat1-Rai1 5'-3' exoribonuclease (exoRNase) complex functionally connects processing at both ends of the 5.8S rRNA. We suggest that pre-rRNA processing is coordinated at both ends of 5.8S rRNA and both ends of ITS2, which are brought together by pre-rRNA folding, by an RNA processing complex. Consistently, we note the conspicuous presence of ~7- or 8-nucleotide extensions on both ends of 5.8S rRNA precursors and at the 5' end of pre-25S RNAs suggestive of a protected spacer fragment of similar length.     

Secondary structure of pre-rRNA 41S spacers and its possible role in determining the processing sites

The mechanism of pre-rRNA processing is still unknown. In this paper we discuss a possible role of the secondary structure of the internal transcribed spacer region (ITS-1 and ITS-2) in processing of 41S pre-rRNA. Potential possibilities for double strand structure formation in ITS-1 and ITS-2 and its rearrangement in the course of processing of 41S pre-rRNA with involvement of U3 RNA were analyzed for a number of species. We have concluded that this rearrangement is the necessary stage in 41S pre-rRNA processing when every functionally designated area (for mature 18S, 28S and 5,8S rRNAs, for ITS-1, ITS-2 and 21S pre-rRNA) has to be organized into an individual domain. In these strongly structured domains 5'- and 3'-ends are spatially brought together whereas processing sites are localized between these compactised areas.     

Structural analysis of the internal transcribed spacer 2 of the precursor ribosomal RNA from Saccharomyces cerevisiae

Full-length precursor ribosomal RNA molecules (6440 bases) were produced in vitro using a plasmid containing the yeast 35 S pre-rRNA operon under the control of phage T7 promoter. The higher-order structure of the internal transcribed spacer 2 (ITS-2) region (between the 5.8 S and 25 S rRNA sequence) in the pre-rRNA molecule was investigated using a combination of enzymatic and chemical structural probes. The data were used to evaluate several structural models predicted by a minimum free-energy calculation. The results supported a model in which the 3' end of the 5.8 S rRNA and the 5' end of the 25 S rRNA are hydrogen-bonded better than the one in which the ends are not. The model contains a high degree of secondary structure with several stable hairpins. Similar structural models for the ITS-2 regions of Schizosaccharomyces pombe, Saccharomyces carlsbergensis, mung bean and Xenopus laevis were derived. Certain common folding features appear to be conserved, in spite of extensive sequence divergence. The yeast model should be useful as a prototype in future investigations of the structure, function and processing of pre-rRNA.     

The spacing between functional Cis-elements of U3 snoRNA is critical for rRNA processing

The sequences and structural features of Xenopus laevis U3 small nucleolar RNA (snoRNA) necessary for pre-rRNA cleavage at sites 1 and 2 to form 18 S rRNA were assayed by depletion/rescue experiments in Xenopus oocytes. Mutagenesis results demonstrated that the putative stem of U3 domain I is unnecessary for 18 S rRNA processing. A model consistent with earlier experimental data is proposed for the structure of domain I when U3 is not yet bound to pre-rRNA. For its function in rRNA processing, a newly discovered element (5' hinge) was revealed to be important but not as critical as the 3' hinge region in Xenopus U3 snoRNA for 18 S rRNA formation. Base-pairing is proposed to occur between the U3 5' hinge and 3' hinge and complementary regions in the external transcribed spacer (ETS); these interactions are phylogenetically conserved, and are homologous to those previously described in yeast (5' hinge-ETS) and trypanosomes (3' hinge-ETS). A model is presented where the base-pairing of the 5' hinge and 3' hinge of U3 snoRNA with the ETS of pre-rRNA helps to correctly position U3 boxes A'+A for their function in rRNA processing. Like an earlier proposal for yeast, boxes A' and A of Xenopus may base-pair with 18 S sequences in pre-rRNA. We present the first direct experimental evidence in any system that box A' is essential for U3 snoRNA function in 18 S rRNA formation. The analysis of insertions and deletions indicated that the spacing between the U3 elements is important, suggesting that they base-pair with the ETS and 18 S regions of pre-rRNA at the same time.     

The sequence of the 5' end of the U8 small nucleolar RNA is critical for 5.8S and 28S rRNA maturation.

Ribosome biogenesis in eucaryotes involves many small nucleolar ribonucleoprotein particles (snoRNP), a few of which are essential for processing pre-rRNA. Previously, U8 snoRNA was shown to play a critical role in pre-rRNA processing, being essential for accumulation of mature 28S and 5.8S rRNAs. Here, evidence which identifies a functional site of interaction on the U8 RNA is presented. RNAs with mutations, insertions, or deletions within the 5'-most 15 nucleotides of U8 do not function in pre-rRNA processing. In vivo competitions in Xenopus oocytes with 2'O-methyl oligoribonucleotides have confirmed this region as a functional site of a base-pairing interaction. Cross-species hybrid molecules of U8 RNA show that this region of the U8 snoRNP is necessary for processing of pre-rRNA but not sufficient to direct efficient cleavage of the pre-rRNA substrate; the structure or proteins comprising, or recruited by, the U8 snoRNP modulate the efficiency of cleavage. Intriguingly, these 15 nucleotides have the potential to base pair with the 5' end of 28S rRNA in a region where, in the mature ribosome, the 5' end of 28S interacts with the 3' end of 5.8S. The 28S-5.8S interaction is evolutionarily conserved and critical for pre-rRNA processing in Xenopus laevis. Taken together these data strongly suggest that the 5' end of U8 RNA has the potential to bind pre-rRNA and in so doing, may regulate or alter the pre-rRNA folding pathway. The rest of the U8 particle may then facilitate cleavage or recruitment of other factors which are essential for pre-rRNA processing.     

Xenopus U3 snoRNA docks on pre-rRNA through a novel base-pairing interaction

U3 small nucleolar RNA (snoRNA) is essential for rRNA processing to form 18S ribosomal RNA (rRNA). Previously, it has been shown that nucleolin is needed to load U3 snoRNA on pre-rRNA. However, as documented here, this is not sufficient. We present data that base-pairing between the U3 hinges and the external transcribed spacer (ETS) is critical for functional alignment of U3 on its pre-rRNA substrate. Additionally, the interaction between the U3 hinges and the ETS is proposed to serve as an anchor to hold U3 on the pre-rRNA substrate, while box A at the 5' end of U3 snoRNA swivels from ETS contacts to 18S rRNA contacts. Compensatory base changes revealed base-pairing between the 3' hinge of U3 snoRNA and region E1 of the ETS in Xenopus pre-rRNA; this novel interaction is required for 18S rRNA production. In contrast, base-pairing between the 5' hinge of U3 snoRNA and region E2 of the ETS is auxiliary, unlike the case in yeast where it is required. Thus, higher and lower eukaryotes use different interactions for functional association of U3 with pre-rRNA. The U3 hinge sequence varies between species, but covariation in the ETS retains complementarity. This species-specific U3-pre-rRNA interaction offers a potential target for a new class of antibiotics to prevent ribosome biogenesis in eukaryotic pathogens.     

Mapping of the major early endonuclease cleavage site of the rat precursor to rRNA within the internal transcribed spacer sequence of rDNA

The endonuclease cleavage of 41 S pre-rRNA to yield 32 S and 21 S pre-rRNA constitutes a major early step in the processing of pre-rRNA in rat liver. The 5'-terminus of 32 S pre-rRNA and the 3'-terminus of 21 S pre-rRNA were precisely located within the rDNA sequence by S1 nuclease protection mapping and use of appropriate rDNA restriction fragments. The 5'-terminus of 12 S pre-rRNA, an initial product of 32 S pre-rRNA processing, was also mapped within the rDNA sequence. The 5'-termini of 32 S and 12 S pre-rRNA coincide and map within a 14-residue T-tract (non-coding strand) at 161-163 bp upstream from the 5'-end of the 5.8 S rRNA gene. The 3'-terminus of 21 S pre-rRNA maps within the same T-tract. These results show that the endonuclease cleavage occurs within a U-tract in the internal transcribed spacer 1 sequence of 41 S pre-rRNA. The homogeneity of the 5'- or 3'-termini of 32 S, 12 S and 21 S pre-rRNA indicates also that the terminal processing of these molecules, if any, is markedly slower. The coincidence in the location of 32 S and 12 S pre-rRNA 5'-termini shows further that the endonuclease cleavage of 32 S pre-rRNA precedes the removal of its 5'-terminal segment to yield 5.8 S rRNA. The absence in the whole pre-rRNA internal transcribed spacer of sequences complementary to the target U-tract suggests that the endonuclease cleavage, generating 32 S and 21 S pre-rRNA, occurs in a single-stranded loop of U-residues.     

A temperature sensitive mutant of Saccharomyces cerevisiae defective in pre-rRNA processing.

A recessive temperature sensitive mutant has been isolated that is defective in ribosomal RNA processing. By Northern analysis, this mutant was found to accumulate three novel rRNA species: 23S', 18S' and 7S', each of which contains sequences from the spacer region between 25S and 18S rRNA. 35S pre-rRNA accumulates, while the level of the 20S and 27S rRNA processing intermediates is depressed. Pulse-chase analysis demonstrates that the processing of 35S pre-rRNA is slowed. The defect in the mutant appears to be at the first processing step, which generates 20S and 27S rRNA. 7S' RNA is a form of 5.8S RNA whose 5' end is extended by 149 nucleotides to a position just 5 nucleotides downstream of the normal cleavage site that produces 20S and 27S rRNA. 7S' RNA can assemble into 60S ribosomal subunits, but such subunits are relatively ineffective in joining polyribosomes. A single lesion is responsible for the pre-rRNA processing defect and the temperature sensitivity. The affected gene is designated RRP2.     

Bypassing the rRNA processing endonucleolytic cleavage at site A2 in Saccharomyces cerevisiae

Rrp5p is the only ribosomal RNA processing trans-acting factor that is required for the synthesis of both 18S and 5.8S rRNAs in Saccharomyces cerevisiae. Mutational analyses have characterized modified forms of Rrp5p that either affect formation of 18S rRNA by inhibiting cleavage at sites A0/A1/A2, or synthesis of 5.8S rRNA by inhibiting cleavage at site A3. Here, we examine the rRNA maturation process associated with a RRP5 bipartite allele that codes for two noncontiguous parts of the protein. This slow-growing bipartite mutant has a unique rRNA-processing phenotype that proceeds without endonucleolytic cleavage at site A2. In wild-type cells, the A2 cleavage takes place on the 32S pre-rRNA and is responsible for the formation of 20S and 27SA2 species, the precursors of mature 18S and 5.8S/25S rRNAs, respectively. In the bipartite strain, such precursors were not detectable as judged by Northern analysis or in vivo labeling. They were replaced by the aberrant 21S species and the bypassing 27SA3 precursor, both descended from direct cleavage of 32S pre-rRNA at site A3, which provides an alternative rRNA maturation pathway in this strain. The 21S pre-rRNA is the sole detectable and most likely available precursor of 18S rRNA in this particular strain, indicating that 18S rRNA can be directly produced from 21S. Furthermore, 21S species were found associated with 43S preribosomal particles as similarly observed for the 20S pre-rRNA in the wild-type cells.     

Depletion of U3 small nucleolar RNA inhibits cleavage in the 5'' external transcribed spacer of yeast pre-ribosomal RNA and impairs formation of 18S ribosomal RNA.

Multiple processing events are required to convert a single eukaryotic pre-ribosomal RNA (pre-rRNA) into mature 18S (small subunit), 5.8S and 25-28S (large subunit) rRNAs. We have asked whether U3 small nucleolar RNA is required for pre-rRNA processing in vivo by depleting Saccharomyces cerevisiae of U3 by conditional repression of U3 synthesis. The resulting pattern of accumulation and depletion of specific pre-rRNAs indicates that U3 is required for multiple events leading to the maturation of 18S rRNA. These include an initial cleavage within the 5' external transcribed spacer, resembling the U3 dependent initial processing event of mammalian pre-rRNA. Formation of large subunit rRNAs is unaffected by U3 depletion. The similarity between the effects of U3 depletion and depletion of U14 small nucleolar RNA and the nucleolar protein fibrillarin (NOP1) suggests that these could be components of a single highly conserved processing complex.     

In vivo disruption of Xenopus U3 snRNA affects ribosomal RNA processing.

DNA oligonucleotide complementary to sequences in the 5' third of U3 snRNA were injected into Xenopus oocyte nuclei to disrupt endogenous U3 snRNA. The effect of this treatment on rRNA processing was examined. We found that some toads have a single rRNA processing pathway, whereas in other toads, two rRNA processing pathways can coexist in a single oocyte. U3 snRNA disruption in toads with the single rRNA processing pathway caused a reduction in 20S and '32S' pre-rRNA. In addition, in toads with two rRNA processing pathways, an increase in '36S' pre-rRNA of the second pathway is observed. This is the first in vivo demonstration that U3 snRNA plays a role in rRNA processing. Cleavage site #3 is at the boundary of ITS 1 and 5.8S and links all of the affected rRNA intermediates: 20S and '32S' are the products of site #3 cleavage in the first pathway and '36S' is the substrate for cleavage at site #3 in the second pathway. We postulate that U3 snRNP folds pre-rRNA into a conformation dictating correct cleavage at processing site #3.     

Preribosomal RNA processing in Xenopus oocytes does not include cleavage within the external transcribed spacer as an early step.

Recently it has been reported that U3 snRNA is necessary for: (a) internal cleavage at +651/+657 within the external transcribed spacer (ETS) of mouse precursor ribosomal RNA (pre-rRNA); and (b) cleavage at the 5' end of 5.8S rRNA in Xenopus oocytes. To study if U3 snRNA plays a role at more than one processing site in the same system, we have investigated whether internal cleavage sites exist within the ETS of Xenopus oocyte pre-rRNA. The ETS of Xenopus pre-rRNA contains the consensus sequence for the mammalian early processing site (+651/+657 in mouse pre-rRNA), but freshly prepared RNA from Xenopus oocytes has no cuts in this region. The only putative cleavage sites we found in the ETS of Xenopus oocyte pre-rRNA are a cluster further downstream of the mouse early processing site consensus sequence. This cluster is not homologous to the mouse +651/+657 sites because unlike the latter it is (a) not abolished by disruption of U3 snRNA, (b) not cleaved during early steps of pre-rRNA processing, and (c) lacks sequence similarity to the +651/+657 consensus. Therefore, pre-rRNA of Xenopus oocytes does not cleave within the ETS as an early step in rRNA processing. We conclude that cleavage within the ETS is not an obligatory early step needed for the rest of rRNA maturation.     

5'ETS rRNA processing facilitated by four small RNAs: U14, E3, U17, and U3.

The nucleolus, the compartment in which the large ribosomal RNA precursor (pre-rRNA) is synthesized, processed through a series of nucleolytic cleavages and modifications into the mature 18S, 5.8S, and 28S rRNAs, and assembled with proteins to form ribosomal subunits, also contains many small nucleolar RNAs (snoRNAs). We present evidence that the first processing event in mouse rRNA maturation, cleavage within the 5' external transcribed spacer, is facilitated by at least four snoRNAs: U14, U17(E1), and E3, as well as U3. These snoRNAs do not augment this processing by directing 2'-O-methylation of the pre-rRNA. A macromolecular complex in which this 5'ETS processing occurs may then function in the processing of 18S rRNA.     

Primary structure of the 5.8S gene of rRNA and internal transcribed spacers of rDNA in diploid wheat Triticum urartu thum. ex. gandil

Nucleotide sequences of 5.8S rRNA gene and rDNA internal transcribed spacers ITS-1 and ITS-2 were determined in diploid wheat Triticum urartu. It was shown that 5.8S rRNA gene of this wheat species consists of 163 base pairs and GC-content is 59.5%. When comparing 5.8S rRNA sequences in diploid wheat, rice and lupine and also 5.8S rRNA in hexaploid wheat and horse beans a high evolutional conservatism of its structure was revealed. The size of ITS-1 and ITS-2 in Tr. urartu is 219 and 225 base pairs long correspondingly. While comparing structures of similar rDNA regions of Tr. urartu, rice and maize a high level of homology was found only between nucleotides adjoining genes of high molecular rRNAs. In ITS-1 of Tr. urartu an insertion of 5'-GACGACGACATTGTCCGTC-3' was found, which is absent in maize and rice.