Structure analysis of the 5' external transcribed spacer of the precursor ribosomal RNA from Saccharomyces cerevisiae

Structural Probing with MNase Tethered to Ribosome Assembly Factors Resolves Flexible RNA Regions within the Nascent Pre-Ribosomal RNA

The synthesis of ribosomes involves the correct folding of the pre-ribosomal RNA within pre-ribosomal particles. The first ribosomal precursor or small subunit processome assembles stepwise on the nascent transcript of the 35S gene. At the earlier stages, the pre-ribosomal particles undergo structural and compositional changes, resulting in heterogeneous populations of particles with highly flexible regions. Structural probing methods are suitable for resolving these structures and providing evidence about the architecture of ribonucleoprotein complexes. Our approach used MNase tethered to the assembly factors Nan1/Utp17, Utp10, Utp12, and Utp13, which among other factors, initiate the formation of the small subunit processome. Our results provide dynamic information about the folding of the pre-ribosomes by elucidating the relative organization of the 5′ETS and ITS1 regions within the 35S and U3 snoRNA around the C-terminal domains of Nan1/Utp17, Utp10, Utp12, and Utp13.

Functional regions in the 5' external transcribed spacer of yeast pre-rRNA

Ribosomal subunits are assembled on a precursor rRNA that includes four spacers in addition to mature rRNA sequences. The 5' external transcribed spacer (5' ETS) is the most prominent one that recruits U3 snoRNA and a plethora of proteins during the early assembly of 90S small subunit preribosomes. Here, we have conducted a comprehensive mutational analysis of 5' ETS by monitoring the processing and assembly of a plasmid-expressed pre-18S RNA. Remarkably, nearly half of the 5' ETS sequences, when depleted individually, are dispensable for 18S rRNA processing. The dispensable elements largely bind at the surface of the 90S structure. Defective assembly of 5' ETS completely blocks the last stage of 90S formation yet has little effect on the early assembly of 5' and central domains of 18S rRNA. Our study reveals the functional regions of 5' ETS and provides new insight into the assembly hierarchy of 90S preribosomes.

Maturation of the 90S pre-ribosome requires Mrd1 dependent U3 snoRNA and 35S pre-rRNA structural rearrangements

In eukaryotes, ribosome biogenesis requires folding and assembly of the precursor rRNA (pre-rRNA) with a large number of proteins and snoRNPs into huge RNA-protein complexes. In spite of intense genetic, biochemical and high-resolution cryo-EM studies in Saccharomyces cerevisiae, information about the structure of the 35S pre-rRNA is limited. To overcome this, we performed high-throughput SHAPE chemical probing on the 35S pre-rRNA within 90S pre-ribosomes. We focused our analyses on external (5′ETS) and internal (ITS1) transcribed spacers as well as the 18S rRNA region. We show that in the 35S pre-rRNA, the central pseudoknot is not formed and the central core of the 18S rRNA is in an open configuration but becomes more constrained in 20S pre-rRNA. The essential ribosome biogenesis protein Mrd1 influences the structure of the 18S rRNA region locally and is involved in organizing the central pseudoknot and surrounding structures. We demonstrate that U3 snoRNA dynamically interacts with the 35S pre-rRNA and that Mrd1 is required for disrupting U3 snoRNA base pairing interactions in the 5′ETS. We propose that the dynamic U3 snoRNA interactions and Mrd1 are essential for establishing the structure of the central core of 18S rRNA that is required for processing and 40S subunit function.

Proteins and RNA sequences required for the transition of the t-Utp complex into the SSU processome

Ribosomes are synthesized by large ribonucleoprotein complexes cleaving and properly assembling highly structured rRNAs with ribosomal proteins. Transcription and processing of pre-rRNAs are linked by the transcription-Utp sub-complex (t-Utps), a sub-complex of the small subunit (SSU) processome and prompted the investigations for the requirements of t-Utp formation and transition into the SSU processome. The rDNA promoter, the first 44 nucleotides of the 5΄ETS, and active transcription by pol I were sufficient to recruit the t-Utps to the rDNA. Pol5, accessory factor, dissociated as t-Utps matured into the UtpA complex which permitted later recruitment of the UtpB, U3 snoRNP and the Mpp10 complex into the SSU processome. The t-Utp complex associated with short RNAs 121 and 138 nucleotides long transcribed from the 5΄ETS. These transcripts were not present when pol II transcribed the rDNA or in nondividing cells. Depletion of a t-Utp, but not of other SSU processome components led to decreased levels of the short transcripts. However, ectopic expression of the short transcripts slowed the growth of yeast with impaired rDNA transcription. These results provide insight into how transcription of the rRNA primes the assemble of t-Utp complex with the pre-rRNA into the UtpA complex and the later association of SSU processome components.

Molecular architecture of the 90S small subunit pre-ribosome

Eukaryotic small ribosomal subunits are first assembled into 90S pre-ribosomes. The complete 90S is a gigantic complex with a molecular mass of approximately five megadaltons. Here, we report the nearly complete architecture of Saccharomyces cerevisiae 90S determined from three cryo-electron microscopy single particle reconstructions at 4.5 to 8.7 angstrom resolution. The majority of the density maps were modeled and assigned to specific RNA and protein components. The nascent ribosome is assembled into isolated native-like substructures that are stabilized by abundant assembly factors. The 5' external transcribed spacer and U3 snoRNA nucleate a large subcomplex that scaffolds the nascent ribosome. U3 binds four sites of pre-rRNA, including a novel site on helix 27 but not the 3' side of the central pseudoknot, and crucially organizes the 90S structure. The 90S model provides significant insight into the principle of small subunit assembly and the function of assembly factors.

DOI:http://dx.doi.org/10.7554/eLife.22086.001

Architecture of the 90S Pre-ribosome: A Structural View on the Birth of the Eukaryotic Ribosome

The 90S pre-ribosome is an early biogenesis intermediate formed during co-transcriptional ribosome formation, composed of ∼70 assembly factors and several small nucleolar RNAs (snoRNAs) that associate with nascent pre-rRNA. We report the cryo-EM structure of the Chaetomium thermophilum 90S pre-ribosome, revealing how a network of biogenesis factors including 19 β-propellers and large α-solenoid proteins engulfs the pre-rRNA. Within the 90S pre-ribosome, we identify the UTP-A, UTP-B, Mpp10-Imp3-Imp4, Bms1-Rcl1, and U3 snoRNP modules, which are organized around 5'-ETS and partially folded 18S rRNA. The U3 snoRNP is strategically positioned at the center of the 90S particle to perform its multiple tasks during pre-rRNA folding and processing. The architecture of the elusive 90S pre-ribosome gives unprecedented structural insight into the early steps of pre-rRNA maturation. Nascent rRNA that is co-transcriptionally folded and given a particular shape by encapsulation within a dedicated mold-like structure is reminiscent of how polypeptides use chaperone chambers for their protein folding.

Architecture of the yeast small subunit processome

The small subunit (SSU) processome, a large ribonucleoprotein particle, organizes the assembly of the eukaryotic small ribosomal subunit by coordinating the folding, cleavage, and modification of nascent pre-ribosomal RNA (rRNA). Here, we present the cryo-electron microscopy structure of the yeast SSU processome at 5.1-angstrom resolution. The structure reveals how large ribosome biogenesis complexes assist the 5' external transcribed spacer and U3 small nucleolar RNA in providing an intertwined RNA-protein assembly platform for the separate maturation of 18S rRNA domains. The strategic placement of a molecular motor at the center of the particle further suggests a mechanism for mediating conformational changes within this giant particle. This study provides a structural framework for a mechanistic understanding of eukaryotic ribosome assembly in the model organism Saccharomyces cerevisiae.

Processing of preribosomal RNA in Saccharomyces cerevisiae

Most, if not all RNAs, are transcribed as precursors that require processing to gain functionality. Ribosomal RNAs (rRNA) from all organisms undergo both exo- and endonucleolytic processing. Also, in all organisms, rRNA processing occurs inside large preribosomal particles and is coupled to nucleotide modification, folding of the precursor rRNA (pre-rRNA), and assembly of the ribosomal proteins (r-proteins). In this review, we focus on the processing pathway of pre-rRNAs of cytoplasmic ribosomes in the yeast Saccharomyces cerevisiae, without doubt, the organism where this pathway is best characterized. We summarize the current understanding of the rRNA maturation process, particularly focusing on the pre-rRNA processing sites, the enzymes responsible for the cleavage or trimming reactions and the different mechanisms that monitor and regulate the pathway. Strikingly, the overall order of the various processing steps is reasonably well conserved in eukaryotes, perhaps reflecting common principles for orchestrating the concomitant events of pre-rRNA processing and ribosome assembly.

Imp3 unfolds stem structures in pre-rRNA and U3 snoRNA to form a duplex essential for small subunit processing

Eukaryotic ribosome biogenesis requires rapid hybridization between the U3 snoRNA and the pre-rRNA to direct cleavages at the A0, A1, and A2 sites in pre-rRNA that liberate the small subunit precursor. The bases involved in hybridization of one of the three duplexes that U3 makes with pre-rRNA, designated the U3-18S duplex, are buried in conserved structures: box A/A' stem-loop in U3 snoRNA and helix 1 (H1) in the 18S region of the pre-rRNA. These conserved structures must be unfolded to permit the necessary hybridization. Previously, we reported that Imp3 and Imp4 promote U3-18S hybridization in vitro, but the mechanism by which these proteins facilitate U3-18S duplex formation remained unclear. Here, we directly addressed this question by probing base accessibility with chemical modification and backbone accessibility with ribonuclease activity of U3 and pre-rRNA fragments that mimic the secondary structure observed in vivo. Our results demonstrate that U3-18S hybridization requires only Imp3. Binding to each RNA by Imp3 provides sufficient energy to unfold both the 18S H1 and the U3 box A/A' stem structures. The Imp3 unfolding activity also increases accessibility at the U3-dependent A0 and A1 sites, perhaps signaling cleavage at these sites to generate the 5' mature end of 18S. Imp4 destabilizes the U3-18S duplex to aid U3 release, thus differentiating the roles of these proteins. Protein-dependent unfolding of these structures may serve as a switch to block U3-pre-rRNA interactions until recruitment of Imp3, thereby preventing premature and inaccurate U3-dependent pre-rRNA cleavage and folding events in eukaryotic ribosome biogenesis.

Ribosomal RNA processing in Candida albicans

Ribosome assembly begins with conversion of a polycistronic precursor into 18S, 5.8S, and 25S rRNAs. In the ascomycete fungus Candida albicans, rRNA transcription starts 604 nt upstream of the 18S rRNA junction (site A1). One major internal processing site in the 5' external transcribed spacer (A0) occurs 108 nt from site A1. The A0-A1 fragment persists as a stable species during log phase growth and can be used to assess proliferation rates. Separation of the small and large subunit pre-rRNAs occurs at sites A2 and A3 in internal transcribed spacer-1 Saccharomyces cerevisiae pre-rRNA. However, the 5' end of the 5.8S rRNA is represented by only a 5.8S (S) form, and a 7S rRNA precursor of the 5.8S rRNA extends into internal transcribed spacer 1 to site A2, which differs from S. cerevisiae. External transcribed spacer 1 and internal transcribed spacers 1 and 2 show remarkable structural similarity with S. cerevisiae despite low sequence identity. Maturation of C. albicans rRNA resembles other eukaryotes in that processing can occur cotranscriptionally or post-transcriptionally. During rapid proliferation, U3 snoRNA-dependent processing occurs before large and small subunit rRNA separation, consistent with cotranscriptional processing. As cells pass the diauxic transition, the 18S pre-rRNA accumulates into stationary phase as a 23S species, possessing an intact 5' external transcribed spacer extending to site A3. Nutrient addition to starved cells results in the disappearance of the 23S rRNA, indicating a potential role in normal physiology. Therefore, C. albicans reveals new mechanisms that regulate post- versus cotranscriptional rRNA processing.

The initial U3 snoRNA:pre-rRNA base pairing interaction required for pre-18S rRNA folding revealed by in vivo chemical probing

The synthesis of ribosomal subunits in the nucleolus is a conserved, essential process that results in cytoplasmic ribosomes with precisely processed and folded rRNAs assembled with ribosomal proteins. It has been proposed, but never directly demonstrated, that the U3 small nucleolar RNA (snoRNA), a nucleolar component required for ribosome biogenesis, is a chaperone for pre-18S rRNA folding. To test this, we used in vivo chemical probing with dimethyl sulfate to detect changes in pre-rRNA structure upon genetic manipulation of the yeast, Saccharomyces cerevisiae. Based on changes in nucleotide reactivity, we found that the U3 snoRNA is indeed required for folding of the pre-18S rRNA. Furthermore, we detected a new essential base pairing interaction that is likely the initial anchor that recruits the U3 snoRNA to the pre-rRNA, is a prerequisite for the subsequent interactions, and is required for the small subunit processome formation. Substitution of the 5′-ETS nucleotides of the pre-rRNA involved in this initial base pairing interaction is lethal, but growth is restored when a complementary U3 snoRNA is expressed. The U3 snoRNP, via base pairing, and its associated proteins, are part of the required machinery that orchestrates the folding of pre-rRNA that results in the assembly of the small ribosomal subunit.

Comparative study of the evolution of nuclear ribosomal spacers incorporating secondary structure analyzes within Dodonaeoideae, Hippocastanoideae and Xanthoceroideae (Sapindaceae)

Ribosomal DNA internal transcribed spacers (ITS) and partial external transcribed spacers (ETSf) are popularly used to infer evolutionary hypotheses. However, there is generally little consideration given to the secondary structures of these small RNA molecules and their potential effects on sequence alignment and phylogenetic analyzes. Intergeneric relationships amongst three of the four major lineages in the Sapindaceae, the Dodonaeoideae, Hippcastanoideae and Xanthoceroideae were assessed by firstly, generating secondary structure predictions for ITS and partial ETSf sequences, and then these predictions were used to assist alignment of the sequences. Secondly, the alignment was analyzed using RNA specific models of sequence evolution that account for the variation in nucleotide evolution in the independent loops and covariating stems regions of the ribosomal spacers. These models and phylogeny drawn from these analyzes were compared with that from analyzes using 'traditional' 4-state models and previous plastid analyzes. These analyzes identified that paired-site models developed to deal specifically with stem structures in RNA encoding sequences more appropriately account for the evolutionary history of the sequences than traditional 4-state substitution models.

Molecular characterization of ribosomal intergenic spacer in the tadpole shrimp Triops cancriformis (Crustacea, Branchiopoda, Notostraca)

Nuclear ribosomal DNA constitutes a multigene family, with tandemly arranged units linked by an intergenic spacer (IGS), which contains initiation/termination transcription signals and usually tandemly arranged subrepeats. The structure and variability of the IGS region are analyzed here in hermaphroditic and parthenogenetic populations of the "living fossil" Triops cancriformis (Branchiopoda, Notostraca). The results indicate the presence of concerted evolution at the population level for this G+C-rich IGS region as a whole, with the major amount of genetic variability found outside the subrepeat region. The subrepeats region is composed of 3 complete repeats (a, c, d) intermingled with 3 repeat fragments (b, e, f) and unrelated sequences. The most striking datum is the absolute identity of subrepeats (except type d) occupying the same position in different individuals/populations. A putative promoter sequence is present upstream of the 18S rRNA gene, but not in subrepeats, which is at variance with other arthropod IGSs. The absence of a promoter sequence in the subrepeats and subrepeat sequence conservation suggests that this region acts as an enhancer simply by its repetitive nature, as observed in some vertebrates. The putative external transcribed spacer (840 bp) shows hairpin structures, as in yeasts, protozoans, Drosophila, and vertebrates.

Rrp5p, a trans-acting factor in yeast ribosome biogenesis, is an RNA-binding protein with a pronounced preference for U-rich sequences

Rrp5p is a trans-acting factor important for biogenesis of both the 40S and 60S subunit of the Saccharomyces cerevisiae ribosome. The protein contains 12 tandemly repeated S1 RNA binding motifs in its N-terminal region, suggesting the ability to interact directly with the pre-rRNA. In vitro binding studies, using immunopurified Rrp5p and in vitro transcribed, 32P-UTP-labeled RNA fragments, revealed that Rrp5p is a general RNA-binding protein with a strong preference for single-stranded sequences rich in uridines. Co-immunoprecipitation studies in yeast cells expressing ProtA-tagged Rrp5p showed that the protein is still associated with pre-ribosomal particles containing 27SA2 pre-rRNA but not with particles containing the 27SB precursor. Thus, Rrp5p appears to dissociate from the 66S pre-ribosome upon or immediately after further processing of 27SA2 pre-rRNA, suggesting the presence of (an) important binding site(s) within the 3'-terminal portion of ITS1. The location of these possible binding site(s) was further delimited using rrp2-1 mutant cells, which accumulate the 5'-extended 5.8S pre-rRNA species. The results indicate that association of Rrp5p with the pre-ribosome is abolished upon removal of a 30-nt region downstream from site A2, which contains two short, single-stranded U stretches. Sequence comparison shows that only the most 5' of these two U-rich stretches is conserved among yeast species whose ITS1 can functionally replace the S. cerevisiae spacer. The implications for the role of Rrp5p in yeast ribosome biogenesis are discussed.

A Phylogenetically Based Secondary Structure for the Yeast Telomerase RNA

BACKGROUND

Telomerase is a ribonucleoprotein complex whose RNA moiety dictates the addition of specific simple sequences onto chromosomes ends. While relevant for certain human genetic diseases, the contribution of the essential telomerase RNA to RNP assembly still remains unclear. Phylogenetic analyses of vertebrate and ciliate telomerase RNAs revealed conserved elements that potentially organize protein subunits for RNP function. In contrast, the yeast telomerase RNA could not be fitted to any known structural model, and the limited number of known sequences from Saccharomyces species did not permit the prediction of a yeast specific conserved structure.

RESULTS

We cloned and analyzed the complete telomerase RNA loci (TLC1) from all known Saccharomyces species belonging to the "sensu stricto" group. Complementation analyses in S. cerevisiae and end mappings of mature RNAs ensured the relevance of the cloned sequences. By using phylogenetic comparative analysis coupled with in vitro enzymatic probing, we derived a secondary structure prediction of the Saccharomyces cerevisiae TLC1 RNA. This conserved secondary structure prediction includes a central domain that is likely to orchestrate DNA synthesis and at least two accessory domains important for RNA stability and telomerase recruitment. The structure also reveals a potential tertiary interaction between two loops in the central core.

CONCLUSIONS

The predicted secondary structure of the TLC1 RNA of S. cerevisiae reveals a distinct folding pattern featuring well-separated but conserved functional elements. The predicted structure now allows for a detailed and rationally designed study to the structure-function relationships within the telomerase RNP-complex in a genetically tractable system.

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.

Ribosomal DNA, species structure, and biogeography of the cactophilic yeast Clavispora opuntiae

The ribosomal DNA of the cactophilic yeast species Clavispora opuntiae was studied in order to clarify the global distribution of the yeast. Over 500 strains, including isolates from several new localities worldwide, were characterized by rDNA restriction mapping. An unusual restriction pattern previously encountered only in one strain, from Conception Island in the Bahamas, was found in several Brazilian isolates. Sequences of the D1/D2 and D7/D8 divergent domains of the large subunit (LSU) and of the intergenic spacers (IGS) confirmed that these strains represent a genetically distinct variety of Clavispora opuntiae. This divergence had previously been hypothesized on the basis of reduced genetic recombination in inter-varietal crosses and the presence of a polymorphic ApaI restriction site located in the LSU. The exact position of the ApaI site in the D8 divergent domain and the nature of the variation that it reveals were determined. The complete sequences of 12 intergenic spacers clarified the significance of the species-wide variation uncovered by restriction mapping. Most of the polymorphic sites occur in the IGS1 and IGS2 regions, on either side of the 5S gene, and the variation is largely due to differences in the numbers and the sequences of internal repeats. Two other polymorphic sites are located in the external transcribed spacer (ETS) region. The reliability of various sites as indicators of overall spacer sequence divergence differed from one case to another. Variety-specific probes were devised and used to screen 120 strains for the presence of recombinant rDNA spacers. Three strains gave ambiguous results, but these did not constitute evidence that inter-varietal recombination has taken place in nature. The hypothesis that the global movement of Clavispora opuntiae has been influenced by the worldwide biological control of prickly pear with Cactoblastis cactorum, a moth of Argentinian origin, has received additional support from the demonstration that Argentinian strains have rDNAs similar to those found where the moth has been introduced. A dramatic founder effect was identified in a yeast population collected in cacti (Maui, Hawaii) in a site where the moth had been recently introduced.

Two 5'-ETS regions implicated in interactions with U3 snoRNA are required for small subunit rRNA maturation in Trypanosoma brucei

Early pre-rRNA processing events were examined in the ancient protozoan parasite Trypanosoma brucei and found to have both distinctive and conserved features. Two 5'-ETS cleavages occur: A' and the newly discovered A0. A' and A0 appear related to vertebrate and yeast primary pre-RNA cleavage sites, respectively. However, trypanosomatid primary rRNA transcripts can first be processed at the ITS1/5.8S boundary and 5'-ETS sequences then removed by consecutive cleavages at A', A0 and A1 at the 5'-ETS/SSU rRNA junction. 5'-ETS sequences previously crosslinked to U3 snoRNA were tested for their roles in rRNA processing using our new tagged rRNA system. Two distinct A'-adjacent sequence elements, which may pair with U3 hinge bases, were specifically required for SSU rRNA production, as was a downstream element. The latter element appears conserved with the yeast 5'-ETS U3 binding sequence, required for A0, A1 and A2 cleavages, in that they both share 10 bases complementary with U3 hinge sequences and lie upstream from A0 and A1 sites located in a potential stem-loop structure. The distinctive positioning of putative trypanosomatid U3 binding sites with respect to A" and A0 cleavages suggests that different U3-dependent mechanisms may direct each processing event.

Essential structural features in the Schizosaccharomyces pombe pre-rRNA 5' external transcribed spacer

The proximal region in the 5' external transcribed spacer (5'ETS) of the genes encoding ribosomal RNAs in Schizosaccharomyces pombe was examined with respect to structural features which underlie rRNA maturation. Computer analyses and partial digestion with nuclease probes indicate a crucifix-like structure composed primarily of three extended hairpins which are more highly ordered than previously proposed in Saccharomyces cerevisiae. A re-evaluation of the same region in S. cerevisiae indicates a conserved core structure, including the U3 snoRNA binding site within this higher-order structure. The sequences encoding the individual hairpins were deleted by PCR-mediated mutagenesis and the mutant rDNAs were expressed in vivo to determine the effect of these features on rRNA maturation. Quantitative hybridization analyses indicate that the first hairpin only has modest effects on 18 S rRNA maturation, but the other two regions are critical and no mature 18 S rRNA was observed. When smaller changes were systematically introduced into the critical regions, strong correlations were observed with known or putative events in rRNA maturation. Changes associated with an intermediate cleavage site in helix II and with the putative U3 snoRNA binding site were again critical to 18 S rRNA production. In each case, the effects were sequence dependent and not simply the result of disrupted structure. Further analyses of the 5.8 S rRNA indicate that the large ribosomal subunit RNA can be properly processed in each case but the efficiency is reduced by as much as 60 %, an observation which provides new evidence of interdependency in the maturation process. The results illustrate that rRNA processing is more critically dependent on the 5'ETS than previously believed.

The chaperonin of the archaeon Sulfolobus solfataricus is an RNA-binding protein that participates in ribosomal RNA processing

The 60 kDa molecular chaperones (chaperonins) are high molecular weight protein complexes having a characteristic double-ring toroidal shape; they are thought to aid the folding of denatured or newly synthesized polypeptides. These proteins exist as two functionally similar, but distantly related families, one comprising the bacterial and organellar chaperonins and another (the so-called CCT-TRiC family) including the chaperonins of the archaea and the eukaryotes. Although some evidence exists that the archaeal chaperonins are implicated in protein folding, much remains to be learned about their precise cellular function. In this work, we report that the chaperonin of the thermophilic archaeon Sulfolobus solfataricus is an RNA-binding protein that interacts specifically in vivo with the 16S rRNA and participates in the maturation of its 5' extremity in vitro. We further show that the chaperonin binds RNA as the native heterooligomeric complex and that RNA binding and processing are inhibited by ATP. These results agree with previous reports indicating a role for the bacterial/organellar chaperonins in RNA protection or processing and suggest that all known chaperonin families share specific and evolutionarily ancient functions in RNA metabolism.

Dob1p (Mtr4p) is a putative ATP-dependent RNA helicase required for the 3' end formation of 5.8S rRNA in Saccharomyces cerevisiae

The temperature-sensitive mutation, dob1-1, was identified in a screen for dependence on overexpression of the yeast translation initiation factor eIF4B (Tif3p). Dob1p is an essential putative ATP-dependent RNA helicase. Polysome analyses revealed an under accumulation of 60S ribosomal subunits in the dob1-1 mutant. Pulse-chase labelling of pre-rRNA showed that this was due to a defect in the synthesis of the 5.8S and 25S rRNAs. Northern and primer extension analyses in the dob1-1 mutant, or in a strain genetically depleted of Dob1p, revealed a specific inhibition of the 3' processing of the 5.8S rRNA from its 7S precursor. This processing recently has been attributed to the activity of the exosome, a complex of 3'-->5' exonucleases that includes Rrp4p. In vivo depletion of Dob1p also inhibits degradation of the 5' external transcribed spacer region of the pre-rRNA. A similar phenotype was observed in rrp4 mutant strains and, moreover, the dob1-1 and rrp4-1 mutations show a strong synergistic growth inhibition. We propose that Dob1p functions as a cofactor for the exosome complex that unwinds secondary structures in the pre-rRNA that otherwise block the progression of the 3'-->5' exonucleases.

The ribosomal-RNA-processing pathway in Schizosaccharomyces pombe

In all cells, a long precursor RNA is processed into mature rRNAs for ribosome biogenesis. In eukaryotes, the complexity and speed of the overall process often has made it difficult to establish finer details of the maturation pathway. Since phylogenetic comparisons can provide evidence for critical events, the major rRNA processing pathway for the yeast Schizosaccharomyces pombe was determined using primer extension, nuclease protection and Northern-hybridisational analyses. Transcript mapping of the 5' external transcribed spacer revealed six cleavage sites which occur upstream of the mature 18S termini. Two of these sites as well as a site adjacent to the 18S termini are complementary to conserved Box sequences in the S. pombe U3 small nucleolar RNA. Transcript mapping of the internal transcribed spacers (1 and 2) suggest similar maturation schemes for the two spacers, in which an initial endonuclease cleavage is followed by processing to the mature termini. The mature 5' termini of 25S rRNA appear to be heterogeneous in S. pombe, as has been demonstrated for 5.8S rRNA, suggesting an essential limiting structure in the ribosome-integrated mature RNA. Together with our previous analysis of the 3' external spacer region, the results reveal the major processing pathway for S. pombe and further support a maturation process which acts as a quality assurance mechanism.

RNase III cleaves eukaryotic preribosomal RNA at a U3 snoRNP-dependent site

A yeast gene homologous to bacterial RNase III (RNT1) encodes a double-strand-specific endoribonuclease essential for ribosome synthesis. Two rRNA processing events are blocked in cells temperature sensitive for RNT1: cleavage at the snoRNA-dependent AO site in the 5' ETS and cleavage in the 3' ETS. Recombinant RNT1 protein accurately cleaves a synthetic 5' ETS RNA at AO site in vitro, in the absence of snoRNA or other factors. A synthetic 3' ETS substrate is specifically cleaved at a site 21 nt downstream of the 3' end 28S rRNA. These observations show that a protein endonuclease collaborates with snoRNAs in eukaryotic rRNA processing and exclude a catalytic role for snoRNAs at certain pre-rRNA cleavage.

Genetic and biochemical analyses of yeast RNase MRP

RNase MRP cleaves the yeast pre-rRNA at a site in internal transcribed spacer 1 (ITS1) and this cleavage can be reproduced in vitro by the highly purified enzyme. Two protein components (Pop1p and Pop2p) have been identified which are common to yeast RNase MRP and RNase P. Moreover, purified RNase P can also cleave the pre-rRNA substrate in vitro, underlining the similarities between these particles. Genetic evidence suggests that RNase MRP functionally interacts with the snoRNPs which are required for other pre-RNA processing reactions.

Processing of eukaryotic pre-rRNA: the role of the transcribed spacers

The 17-18S, 5.8S, and 25-28S rRNA species of eukaryotic cells are produced by a series of nucleolytic reactions that liberate the mature rRNAs from the large primary precursor transcript synthesized by RNA polymerase 1. Whereas the order of the cleavage reactions has long been established, until recently little information was available on their molecular details, such as the nature of the proteins, including the nucleolytic enzymes, involved and the signals directing the processing machinery to the correct sites. This situation is now rapidly changing, in particular where yeast is concerned. The use of recently developed systems for in vivo mutational analysis of yeast rDNA has considerably enhanced our knowledge of cis-acting structural features within the pre-rRNA, in particular the transcribed spacer sequences, that are critical for correct and efficient removal of these spacers. The same systems also allow a link to be forged between trans-acting processing factors and these cis-acting elements. In this paper, we will focus predominantly on the nature and role of the cis-acting processing elements as identified in the transcribed spacer regions of Saccharomyces cerevisiae pre-rRNA.

Mutational analysis of an essential binding site for the U3 snoRNA in the 5' external transcribed spacer of yeast pre-rRNA

The small nucleolar RNA U3 is essential for viability in yeast. We have previously shown that U3 can be cross-linked in vivo to the pre-rRNA in the 5' external transcribed spacer (ETS), at +470. This ETS region contains 10 nucleotides of perfect complementarity to U3. In a genetic background where the mutated rDNA is the only transcribed rDNA repeat, the deletion of the 10 nt complementary to U3 is lethal. Cells lacking the U3 complementary sequence in pre-rRNA fail to accumulate 18S rRNA: pre-rRNA processing is inhibited at sites A0 in the 5' ETS, A1 at the 5' end of 18S rRNA and A2 in ITS1. We show here that effects on processing at site A0 are specific for U3 and its associated proteins and are not seen on depletion of other snoRNP components. The deletion of the sequence complementary to U3 in the ETS therefore mimics all the known effects of the depletion of U3 in trans. This indicates that we have identified an essential U3 binding site on pre-rRNA, required in cis for the maturation of 18S rRNA.

Mutational analysis of an essential binding site for the U3 snoRNA in the 5' external transcribed spacer of yeast pre-rRNA

The small nucleolar RNA U3 is essential for viability in yeast. We have previously shown that U3 can be cross-linked in vivo to the pre-rRNA in the 5' external transcribed spacer (ETS), at +470. This ETS region contains 10 nucleotides of perfect complementarity to U3. In a genetic background where the mutated rDNA is the only transcribed rDNA repeat, the deletion of the 10 nt complementary to U3 is lethal. Cells lacking the U3 complementary sequence in pre-rRNA fail to accumulate 18S rRNA: pre-rRNA processing is inhibited at sites A0 in the 5' ETS, A1 at the 5' end of 18S rRNA and A2 in ITS1. We show here that effects on processing at site A0 are specific for U3 and its associated proteins and are not seen on depletion of other snoRNP components. The deletion of the sequence complementary to U3 in the ETS therefore mimics all the known effects of the depletion of U3 in trans. This indicates that we have identified an essential U3 binding site on pre-rRNA, required in cis for the maturation of 18S rRNA.

Processing of eukaryotic ribosomal RNA

In summary, it can be argued that the understanding of eukaryotic rRNA processing is no less important than the understanding of mRNA maturation, since the capacity of a cell to carry out protein synthesis is controlled, in part, by the abundance of ribosomes. Processing of pre-rRNA is highly regulated, involving many cellular components acting either alone or as part of a complex. Some of these components are directly involved in the modification and cleavage of the precursor rRNA, while others direct the packaging of the rRNA into ribosome subunits. As is the case for pre-mRNA processing, snoRNPs are clearly involved in eukaryotic rRNA processing, and have been proposed to assemble with other proteins into at least one complex called a "processosome" (17), which carries out the ordered processing of the pre-rRNA and its assembly into ribosomes. The formation of a processing complex clearly makes possible the regulation required to coordinate the abundance of ribosomes with the physiological and developmental changes of a cell. It may be that eukaryotic rRNA processing is even more complex than pre-mRNA maturation, since pre-rRNA undergoes extensive nucleotide modification and is assembled into a complex structure called the ribosome. Undoubtedly, features of the eukaryotic rRNA-processing pathway have been conserved evolutionarily, and the genetic approach available in yeast research (6) should provide considerable knowledge that will be useful for other investigators working with higher eukaryotic systems. Interestingly, it was originally hoped that the extensive work and understanding of bacterial ribosome formation would provide a useful paradigm for the process in eukaryotes. However, although general features of ribosome structure and function are highly conserved between bacterial and eukaryotic systems, the basic strategy in ribosome biogenesis seems to be, for the most part, distinctly different. Thus, the detailed molecular mechanisms for rRNA processing in each kingdom will have to be independently deciphered in order to elucidate the features and regulation of this important process for cell survival.