Characterization of an SNR gene locus in Saccharomyces cerevisiae that specifies both dispensible and essential small nuclear RNAs

The 3' end formation in small RNAs

Small RNAs are a major class of RNAs along with transfer RNAs, ribosomal RNAs, and messenger RNAs. They vary in size from less than 100 nucleotides to several thousand nucleotides and have been identified and characterized both in prokaryotes and eukaryotes. Small RNAs participate in a variety of cellular functions including regulating RNA synthesis, RNA processing, guiding modifications in RNA, and in transport of proteins. Small RNAs are generated by a series of posttranscriptional processing steps following transcription. While RNA 5' end structure, 5' cap formation, and RNA processing mechanisms have been fairly well characterized, the 3' end processing is poorly understood. Recent data point to an emerging theme in small RNAs metabolism in which the 3' end processing is mediated by the exosome, a large multienzyme complex. In addition to removal of nucleotides by the exosome, there is simultaneous rebuilding of the 3' end of some small RNA by adenylation and/or uridylation. This review presents a picture of both degradative and rebuilding reactions operative on the 3' end of some small RNA molecules in prokaryotes and eukaryotes.

A second base pair interaction between U3 small nucleolar RNA and the 5'-ETS region is required for early cleavage of the yeast pre-ribosomal RNA

In eukaryotes, U3 snoRNA is essential for pre-rRNA maturation. Its 5'-domain was found to form base pair interactions with the 18S and 5'-ETS parts of the pre-rRNA. In Xenopus laevis, two segments of U3 snoRNA form base-pair interactions with the 5'-ETS region and only one of them is essential to the maturation process. In Saccharomyces cerevisiae, two similar U3 snoRNA-5' ETS interactions are possible; but, the functional importance of only one of them had been tested. Surprisingly, this interaction, which corresponds to the non-essential one in X. laevis, is essential for cell growth and pre-rRNA maturation in yeast. In parallel with [Dutca et al. (2011) The initial U3 snoRNA:pre-rRNA base pairing interaction required for pre-18S rRNA folding revealed by in vivo chemical probing. Nucleic Acids Research, 39, 5164-5180], here we show, that the second possible 11-bp long interaction between the 5' domain of S. cerevisiae U3 snoRNA and the pre-rRNA 5'-ETS region (helix VI) is also essential for pre-rRNA processing and cell growth. Compensatory mutations in one-half of helix VI fully restored cell growth. Only a partial restoration of growth was obtained upon extension of compensatory mutations to the entire helix VI, suggesting sequence requirement for binding of specific proteins. Accordingly, we got strong evidences for a role of segment VI in the association of proteins Mpp10, Imp4 and Imp3.

The CCR4-NOT complex physically and functionally interacts with TRAMP and the nuclear exosome

Background

Ccr4-Not is a highly conserved multi-protein complex consisting in yeast of 9 subunits, including Not5 and the major yeast deadenylase Ccr4. It has been connected functionally in the nucleus to transcription by RNA polymerase II and in the cytoplasm to mRNA degradation. However, there has been no evidence so far that this complex is important for RNA degradation in the nucleus.

Methodology/Principal Findings

In this work we point to a new role for the Ccr4-Not complex in nuclear RNA metabolism. We determine the importance of the Ccr4-Not complex for the levels of non-coding nuclear RNAs, such as mis-processed and polyadenylated snoRNAs, whose turnover depends upon the nuclear exosome and TRAMP. Consistently, mutation of both the Ccr4-Not complex and the nuclear exosome results in synthetic slow growth phenotypes. We demonstrate physical interactions between the Ccr4-Not complex and the exosome. First, Not5 co-purifies with the exosome. Second, several exosome subunits co-purify with the Ccr4-Not complex. Third, the Ccr4-Not complex is important for the integrity of large exosome-containing complexes. Finally, we reveal a connection between the Ccr4-Not complex and TRAMP through the association of the Mtr4 helicase with the Ccr4-Not complex and the importance of specific subunits of Ccr4-Not for the association of Mtr4 with the nuclear exosome subunit Rrp6.

Conclusions/Significance

We propose a model in which the Ccr4-Not complex may provide a platform contributing to dynamic interactions between the nuclear exosome and its co-factor TRAMP. Our findings connect for the first time the different players involved in nuclear and cytoplasmic RNA degradation.

Functional importance of individual rRNA 2'-O-ribose methylations revealed by high-resolution phenotyping

Ribosomal RNAs contain numerous modifications at specific nucleotides. Despite their evolutionary conservation, the functional role of individual 2'-O-ribose methylations in rRNA is not known. A distinct family of small nucleolar RNAs, box C/D snoRNAs, guides the methylating complex to specific rRNA sites. Using a high-resolution phenotyping approach, we characterized 20 box C/D snoRNA gene deletions for altered growth dynamics under a wide array of environmental perturbations, encompassing intraribosomal antibiotics, inhibitors of specific cellular features, as well as general stressors. Ribosome-specific antibiotics generated phenotypes indicating different and long-ranging structural effects of rRNA methylations on the ribosome. For all studied box C/D snoRNA mutants we uncovered phenotypes to extraribosomal growth inhibitors, most frequently reflected in alteration in growth lag (adaptation time). A number of strains were highly pleiotropic and displayed a great number of sensitive phenotypes, e.g., deletion mutants of snR70 and snR71, which both have clear human homologues, and deletion mutants of snR65 and snR68. Our data indicate that individual rRNA ribose methylations can play either distinct or general roles in the workings of the ribosome.

Identifying effects of snoRNA-guided modifications on the synthesis and function of the yeast ribosome

The small nucleolar RNAs (snoRNAs) are associated with proteins in ribonucleoprotein complexes called snoRNPs ("snorps"). These complexes create modified nucleotides in preribosomal RNA and other RNAs and participate in nucleolytic cleavages of pre-rRNA. The various reactions occur in site-specific fashion, and the mature rRNAs are ultimately incorporated into cytoplasmic ribosomes. Most snoRNAs exist in two structural classes, and most members in each class are involved in nucleotide modification reactions. Guide snoRNAs in the "box C/D" class target methylation of the 2'-hydroxyl moiety, to form 2'-O-methylated nucleotides (Nm), whereas guide snoRNAs in the "box H/ACA" class target specific uridines for conversion to pseudouridine (Psi). The rRNA nucleotides modified in this manner are numerous, totaling approximately 100 in yeast and twice that number in humans. Although the chemistry of the modifications and the factors involved in their formation are largely explained, very little is known about the influence of the copious snoRNA-guided nucleotide modifications on rRNA activity and ribosome function. Among eukaryotic organisms the sites of rRNA modification and the corresponding guide snoRNAs have been best characterized in S. cerevisiae, making this a model organism for analyzing the consequences of modification. This chapter presents approaches to characterizing rRNA modification effects in yeast and includes strategies for evaluating a variety of specific rRNA functions. To aid in planning, a package of bioinformatics tools is described that enables investigators to correlate guide function with targeted ribosomal sites in several contexts. Genetic procedures are presented for depleting modifications at one or more rRNA sites, including ablation of all Nm or Psi modifications made by snoRNPs, and for introducing modifications at novel sites. Methods are also included for characterizing modification effects on cell growth, antibiotic sensitivity, rRNA processing, formation of various rRNP complexes, translation activity, and rRNA structure within the ribosome.

Kinetic analysis of ribozyme-substrate complex formation in yeast

Many RNA-mediated reactions in transcription, translation, RNA processing, and transport require assembly of RNA complexes, yet assembly pathways remain poorly understood. Assembly mechanisms can be difficult to assess in a biological context because many components interact in complex pathways and individual steps are difficult to isolate experimentally. Our previous studies of self-cleaving hairpin ribozymes showed that kinetic and equilibrium parameters measured in yeast agree well with parameters measured in vitro under ionic conditions that mimic the intracellular environment. We now report studies of intermolecular reactions with ribozyme and target sequences expressed in yeast as separate chimeric U3 snoRNAs. In this system, intracellular cleavage rates reflect the kinetics of ribozyme-substrate complex formation through annealing of base-paired helices. Second-order rate constants increased with increasing helix length for in vitro reactions with 2 mM MgCl(2) and 150 mM NaCl and in vivo but not in reactions with 10 mM MgCl(2). Thus, efficient RNA complex formation required a larger extent of complementarity in vivo than in vitro under conditions with high concentrations of divalent cations. The most efficient intracellular cleavage reactions exhibited second-order rate constants that were 15- to 30-fold below rate constants for cleavage of oligonucleotides in vitro. Careful analysis of structural features that influence cleavage efficiency points to substrate binding as the rate-determining step in the intracellular cleavage pathway. Second-order rate constants for intermolecular cleavage agree well with diffusion coefficients reported for U3 snoRNPs in vivo suggesting that complex formation between chimeric ribozyme and substrate snoRNPs in yeast nuclei is diffusion limited.

Identification and characterization of a novel U14 small nucleolar RNA gene cluster in Oryza sativa

Small nucleolar RNAs (snoRNAs) are required for ribose 2'-O-methylation of eukaryotic ribosomal RNA. Through computer search in international rice genome database, a novel U14 snoRNA gene cluster, consisting of two U14 snoRNA gene candidates, was found on rice chromosome II. They both have box C/D sequences and a 14 nucleotides (nt)-long complementarity to rice 18S ribosomal RNA (rRNA). Functional analysis of this gene cluster indicated that both were transcribed in vivo and might guide the methylations of C418 in rice 18S rRNA. By using primer extension, 5' and 3' rapid amplification of cDNA ends, the 5' and 3' ends of two snoRNAs were determined. The 52 nt long intergenic spacer of the gene cluster is rich in uridine. The absence of a conserved promoter element in this spacer, the proximity of the genes and the detection of transcripts containing linked U14 snoRNAs by reverse transcript polymerase chain reaction suggest that the rice U14 snoRNAs encoded in the cluster are transcribed as a polycistron under an upstream promoter, and individual U14 snoRNAs are released after processing of the precursor RNAs.

Differential accumulation of U14 snoRNA and hsc70 mRNA in Chinese hamster cells after exposure to various stress conditions

We have previously characterized the unique organization of the U14 small nucleolar ribonucleic acid (snoRNA) gene in Chinese hamster HA-1 cells. The single copy of the hsc70/U14 gene is the only source for the production of both U14 snoRNA species and hsc70 messenger ribonucleic acid (mRNA) in these cells. Here we report that the accumulations of U14 snoRNA and hsc70 mRNA are different in response to various stress conditions, although both of them are transcribed in a single primary transcript. Heat shock induced an increased accumulation of both U14 snoRNA and hsc70 mRNA. On the other hand, exposure to sodium arsenite or azetidine induced an increased accumulation of hsc70 mRNA, but did not lead to a concomitant increase in the level of U14 snoRNA. Under normal growth conditions, the variations in the levels of U14 snoRNA and hsc70 mRNA, in the different phases of the cell cycle, are correlated. The increased expression of U14 snoRNA and hsc70 mRNA, and the hsc70 protein induced specifically by heat shock suggest that they participate in the repair process of heat-induced damage to macromolecular complexes involved in the synthesis and processing of ribosomal RNA.

Unique features of Chinese hamster S13 gene relative to its human and Xenopus analogs

We have cloned and sequenced the ribosomal protein S13 gene from the Chinese hamster fibroblast HA-1 cells. The predicted protein encoded by this gene is identical to the human ribosomal protein S13, except for one amino acid substitution at residue 29, which is an alanine in the hamster protein and a threonine in that of humans. The physical organization of the six exons and five introns in the hamster S13 gene is also identical to that found in the human and Xenopus genes with respect to the amino acid codes, even though there are small differences in the lengths of the introns. The striking feature is that unlike its human and Xenopus counterparts, which encode two U14 snoRNAs in two separate introns, the hamster S13 gene encodes no U14 snoRNA. Instead, the hamster gene has a pseudo-U14 coding sequence in its third intron. Our data support the idea that the single copy of the hsc70/U14 gene, which we had previously characterized, is the only source for the production of both U14 snoRNA and hsc70 mRNA species in hamster HA-1 cells.

Splicing-independent processing of plant box C/D and box H/ACA small nucleolar RNAs

Small nucleolar RNAs (snoRNAs) are involved in various aspects of ribosome biogenesis and rRNA maturation. Plants have a unique organisation of snoRNA genes where multiple, different genes are tightly clustered at a number of different loci. The maize gene clusters studied here include genes from both of the two major classes of snoRNAs (box C/D and box H/ACA) and are transcribed as a polycistronic pre-snoRNA transcript from an upstream promoter. In contrast to vertebrate and yeast intron-encoded snoRNAs, which are processed from debranched introns by exonuclease activity, the particular organisation of plant snoRNA genes suggests a different mode of expression and processing. Here we show that single and multiple plant snoRNAs can be processed from both non-intronic and intronic transcripts such that processing is splicing-independent and requires endonucleolytic activity. Processing of these different snoRNAs from the same polycistronic transcript suggests that the processing machineries needed by each class are not spatially separated in the nucleolus/nucleus.

U14snoRNAs of the fern, Asplenium nidus, contain large sequence insertions compared with those of higher plants

Northern analyses of U14snoRNAs in different plant species showed the expected hybridising band of approximately 120 nt in monocotyledonous and dicotyledonous angiosperms. In the lower plant, Bird's nest fern (Asplenium nidus), U14s were larger and three hybridising RNAs of approximately 190, 210 and 250 nt were observed. RT-PCR cloning of all three size variants using primers to the conserved 5' and 3' ends of higher plant U14snoRNAs showed large insertions in one of the plant-specific regions corresponding in position to the yeast U14-specific Y-domain. The insertions are pyrimidine-rich in their 5' halves and purine-rich in their 3' halves and are likely to be sequestered in stem structures consistent with the proposed model of U14snoRNA secondary structure. The 5' flanking regions of one of the fern U14 variants was generated by PCR and lacked classical plant snRNA promoter elements.

In vitro assembly of the mouse U14 snoRNP core complex and identification of a 65-kDa box C/D-binding protein

The eukaryotic nucleolus contains a diverse population of small nucleolar RNAs (snoRNAs) that have been categorized into two major families based on evolutionarily conserved sequence elements. U14 snoRNA is a member of the larger, box C/D snoRNA family and possesses nucleotide box C and D consensus sequences. In previous studies, we have defined a U14 box C/D core motif that is essential for intronic U14 snoRNA processing. These studies also revealed that nuclear proteins that recognize boxes C/D are required. We have now established an in vitro U14 snoRNP assembly system to characterize protein binding. Electrophoretic mobility-shift analysis demonstrated that all the sequences and structures of the box C/D core motif required for U14 processing are also necessary for protein binding and snoRNP assembly. These required elements include a base paired 5',3' terminal stem and the phylogenetically conserved nucleotides of boxes C and D. The ability of other box C/D snoRNAs to compete for protein binding demonstrated that the box C/D core motif-binding proteins are common to this family of snoRNAs. UV crosslinking of nuclear proteins bound to the U14 core motif identified a 65-kDa mouse snoRNP protein that requires boxes C and D for binding. Two additional core motif proteins of 55 and 50 kDa were also identified by biochemical fractionation of the in vitro-assembled U14 snoRNP complex. Thus, the U14 snoRNP core complex is a multiprotein particle whose assembly requires nucleotide boxes C and D.

The U14 snoRNA is required for 2'-O-methylation of the pre-18S rRNA in Xenopus oocytes

We have studied the role of the U14 small nucleolar RNA (snoRNA) in pre-rRNA methylation and processing in Xenopus oocytes. Depletion of U14 in Xenopus oocytes was achieved by co-injecting two nonoverlapping antisense oligonucleotides. Focusing on the earliest precursor, depletion experiments revealed that the U14 snoRNA is essential for 2'-O-ribose methylation at nt 427 of the 18S rRNA. Injection of U14-depleted oocytes with specific U14 mutant snoRNAs indicated that conserved domain B, but not domain A, of U14 is required for the methylation reaction. When the effect of U14 on pre-rRNA processing is assayed, we find only modest effects on 18S rRNA levels, and no effect on the type or accumulation of 18S precursors, suggesting a role for U14 in a step in ribosome biogenesis other than cleavage of the pre-rRNA. Xenopus U14 is, therefore, a Box C/D fibrillarin-associated snoRNA that is required for site-specific 2'-O-ribose methylation of pre-rRNA.

Eukaryotic ribosomal RNA: the recent excitement in the nucleotide modification problem

Eukaryotic ribosomal RNA (rRNA) contains numerous modified nucleotides: about 115 methyl groups and some 95 pseudouridines in vertebrates; about 65 methyl groups and some 45 pseudouridines in Saccharomyces cerevisiae. All but about ten of the methyl groups are ribose methylations. The remaining ten are on heterocyclic bases. The ribose methylations occur very rapidly upon the primary rRNA transcript in the nucleolus, probably on nascent chains, and they appear to play an important role in ribosome maturation, at least in vertebrates. All of the methyl groups occur in the conserved core of rRNA. However, there is no consensus feature of sequence or secondary structure for the methylation sites; thus the nature of the signal(s) for site-specific methylations had until recently remained a mystery. The situation changed dramatically with the discovery that many of the ribose methylation sites are in regions that are precisely complementary to small nucleolar RNA (snoRNA) species. Experimental evidence indicates that structural motifs within the snoRNA species do indeed pinpoint the precise nucleotides to be methylated by the putative 2'-O-methyl transferase(s). Regarding base methylations, the gene DIM1, responsible for modification of the conserved dimethyladenosines near the 3' end of 18S rRNA, has been shown to be essential for viability in S. cerevisiae and is suggested to play a role in the nucleocytoplasmic transport of the small ribosomal subunit. Recently nearly all of the pseudouridines have also been mapped in the rRNA of several eukaryotic species. As is the case for ribose methylations, most pseudouridine modifications occur rapidly upon precursor rRNA, within core sequences, and in a variety of local primary and secondary structure environments. In contrast to ribose methylation, no potentially unifying process has yet been identified for the enzymic recognition of the many pseudouridine modification sites. However, the new data afford the basis for a search for any potential involvement of snoRNAs in the recognition process.

U14 small nucleolar RNA makes multiple contacts with the pre-ribosomal RNA

The small nucleolar RNA (snoRNA) U14 has two regions of extended primary sequence complementarity to the 18S rRNA. The 3' region (domain B) shows the consensus structure for the methylation guide class of snoRNAs, whereas base-pairing between the 5' region (domain A) and the 18S rRNA sequence is required for the formation of functional ribosomes. Between domains A and B lies another essential region (domain Y). Here we report that yeast U14 can be cross-linked in vivo to the pre-rRNA; cross-linking is detected exclusively with the 35S primary transcript. Many nucleotides in U14 that lie outside of domains A and B are cross-linked to the pre-rRNA; in particular the essential domain Y region is cross-linked at several sites. U14 is, therefore, in far more extensive contact with the pre-rRNA than predicted from simple base-pairing models. Moreover, U14 can be cross-linked to other small RNA species. The functional interactions made by U14 during ribosome synthesis are likely to be very complex.

Delocalization of some small nucleolar RNPs after actinomycin D treatment to deplete early pre-rRNAs

Retention of some components within the nucleolus correlates with the presence of rRNA precursors found early in the rRNA processing pathway. Specifically, after most 40S, 38S and 36S pre-rRNAs have been depleted by incubation of Xenopus kidney cells in 0.05 microg/ml actinomycin D for 4 h, only 69% U3 small nucleolar RNA (snoRNA), 68% U14 snoRNA and 72% fibrillarin are retained in the nucleolus as compared with control cells. These nucleolar components are important for processing steps in the pathway that gives rise to 18S rRNA. In contrast, U8 snoRNA, which is used for 5.8S and 28S rRNA production, is fully retained in the nucleolus after actinomycin D treatment. Therefore, U8 snoRNA is in a different category than U3 and U14 snoRNA and fibrillarin. It is proposed that U3 and U14 snoRNA and fibrillarin, but not U8 snoRNA, bind to the external transcribed spacer or internal transcribed spacer 1, and when these binding sites are lost after actinomycin D treatment some of these components cannot be retained in the nucleolus. Other binding sites may also exist, which would explain why only some and not all of these components are lost from the nucleolus.

Identification of specific nucleotide sequences and structural elements required for intronic U14 snoRNA processing

Vertebrate U14 snoRNAs are encoded within hsc70 pre-mRNA introns and U14 biosynthesis occurs via an intron-processing pathway. We have shown previously that essential processing signals are located in the termini of the mature U14 molecule and replacement of included boxes C or D with oligo C disrupts snoRNA synthesis. The experiments detailed here now define the specific nucleotide sequences and structures of the U14 termini that are essential for intronic snoRNA processing. Mutagenesis studies demonstrated that a 5', 3'-terminal stem of at least three contiguous base pairs is required. A specific helix sequence is not necessary and this stem may be extended to as many as 15 base pairs without affecting U14 processing. The spatial positioning of boxes C and D with respect to the terminal stem is also important. Detailed analysis of boxes C and D revealed that both consensus sequences possess essential nucleotides. Some, but not all, of these critical nucleotides correspond to those required for the stable accumulation of nonintronic yeast U14 snoRNA. The presence of box C and D consensus sequences flanking a terminal stem in many snoRNA species indicates the importance of this "terminal core motif" for snoRNA processing.

Sequence analysis of a 40.7 kb segment from the left arm of yeast chromosome X reveals 14 known genes and 13 new open reading frames including homologues of genes clustered on the right arm of chromosome XI

The complete nucleotide sequence of a 40.7 kb segment about 130 kb from the left end of chromosome X of Saccharomyces cerevisiae was determined from two overlapping cosmids. Computer analysis of that sequence revealed the presence of the previously known genes VPS35, INO1, SnR128, SnR190, MP12, YAK1, RPB4, YUR1, TIF2, MRS3 and URA2, three previously sequenced open reading frames (ORFs) of unknown function 5' of the INO1, 5' of the MP12 and 3' of the URA2 genes and 13 newly identified ORFs. One of the new ORFs is homologous to mammalian glycogenin glycosyltransferases and another has similarities to the human phospholipase D. Some others contain potential transmembrane regions or leucine zipper motifs. The existence of yeast expressed sequence tags for some of the newly identified ORFs indicates that they are transcribed. A cluster of six genes within 10 kb (YUR1, TIF2, two new ORFs, an RSP25 homologue and MRS3) have homologues arranged similarly within 28.5 kb on the right arm of chromosome XI.

Site-specific ribose methylation of preribosomal RNA: a novel function for small nucleolar RNAs

Eukaryotic cells contain many fibrillarin-associated small nucleolar RNAs (snoRNAs) that possess long complementarities to mature rRNAs. Characterization of 21 novel antisense snoRNAs from human cells followed by genetic depletion and reconstitution studies on yeast U24 snoRNA provides evidence that this class of snoRNAs is required for site-specific 2'-O-methylation of preribosomal RNA (pre-rRNA). Antisense sno-RNAs function through direct base-pairing interactions with pre-rRNA. The antisense element, together with the D or D' box of the snoRNA, provide the information necessary to select the target nucleotide for the methyltransfer reaction. The conclusion that sno-RNAs function in covalent modification of the sugar moieties of ribonucleotides demonstrates that eukaryotic small nuclear RNAs have a more versatile cellular function than earlier anticipated.

Elements essential for processing intronic U14 snoRNA are located at the termini of the mature snoRNA sequence and include conserved nucleotide boxes C and D

Essential elements for intronic U14 processing have been analyzed by microinjecting various mutant hsc70/Ul4 pre-mRNA precursors into Xenopus oocyte nuclei. Initial truncation experiments revealed that elements sufficient for U14 processing are located within the mature snoRNA sequence itself. Subsequent deletions within the U14 coding region demonstrated that only the terminal regions of the folded U14 molecule containing con- served nucleotide boxes C and D are required for processing. Mutagenesis of either box C or box D completely blocked U14 processing. The importance of boxes C and D was confirmed with the excision of appropriately sized U3 and U8 fragments containing boxes C and D from an hsc7O pre-mRNA intron. Competition studies indicate that a trans-acting factor (protein?) is binding this terminal motif and is essential for U14 processing. Competition studies also revealed that this factor is common to both intronic and non-intronic snoRNAs possessing nucleotide boxes C and D. Immunoprecipitation of full-length and internally deleted U14 snoRNA molecules demonstrated that the terminal region containing boxes C and D does not bind fibrillarin. Collectively, our results indicate that a trans-acting factor (different from fibrillarin) binds to the box C- and D-containing terminal motif of U14 snoRNA, thereby stabilizing the intronic snoRNA sequence in an RNP complex during processing.

Processing of pre-ribosomal RNA in Saccharomyces cerevisiae

Post-transcriptional processing of precursor-ribosomal RNA comprises a complex pathway of endonucleolytic cleavages, exonucleolytic digestion and covalent modifications. The general order of the various processing steps is well conserved in eukaryotic cells, but the underlying mechanisms are largely unknown. Recent analysis of pre-rRNA processing, mainly in the yeast Saccharomyces cerevisiae, has significantly improved our understanding of this important cellular activity. Here we will review the data that have led to our current picture of yeast pre-rRNA processing.

Trans-acting factors in yeast pre-rRNA and pre-snoRNA processing

The major intermediates in the pathway of pre-rRNA processing in yeast and other eukaryotes were originally identified by biochemical analyses. However, as a result of the analysis of the effects of mutations in trans-acting factors, the yeast pre-rRNA processing pathway is now characterized in far more detail than that of other eukaryotes. These analyses have led to the identification of processing sites and intermediates that were either too close in size or too short lived to detected by biochemical analyses alone. In addition, it was generally unclear whether pre-rRNA processing steps were endonucleolytic or exonucleolytic; analyses of trans-acting factors is now revealing a complex mixture of endonucleolytic and exonucleolytic processing steps. Many of the small nucleolar RNAs (snoRNAs) are excised from larger precursors. Analyses of trans-acting factors are also revealing details of pre-snoRNA processing in yeast. Interestingly, factors involved in pre-snoRNA processing turn out to be components that also function in pre-rRNA processing, suggesting a potential mechanism for the coregulation of rRNA and snoRNA synthesis. In general, very little is known about the regulation of pre-rRNA processing steps. The best candidate for a system regulating specific pre-rRNA processing reactions has recently been revealed by the analysis of a yeast pre-RNA methylase. Here we will review recent data on the trans-acting factors involved in yeast ribosome synthesis and discuss how these analyses have contributed to our current view of this complex process.

Small nucleolar RNA

A growing list of small nucleolar RNAs (snoRNAs) has been characterized in eukaryotes. They are transcribed by RNA polymerase II or III; some snoRNAs are encoded in the introns of other genes. The nonintronic polymerase II transcribed snoRNAs receive a trimethylguanosine cap, probably in the nucleus, and move to the nucleolus. snoRNAs are complexed with proteins, sometimes including fibrillarin. Localization and maintenance in the nucleolus of some snoRNAs requires the presence of initial precursor rRNA (pre-rRNA). Many snoRNAs have conserved sequence boxes C and D and a 3' terminal stem; the role of these features are discussed. Functional assays done for a few snoRNAs indicate their roles in rRNA processing for cleavage of the external and internal transcribed spacers (ETS and ITS). U3 is the most abundant snoRNA and is needed for cleavage of ETS1 and ITS1; experimental results on U3 binding sites in pre-rRNA are reviewed. 18S rRNA production also needs U14, U22, and snR30 snoRNAs, whereas U8 snoRNA is needed for 5.8S and 28S rRNA production. Other snoRNAs that are complementary to 18S or 28S rRNA might act as chaperones to mediate RNA folding. Whether snoRNAs join together in a large rRNA processing complex (the "processome") is not yet clear. It has been hypothesized that such complexes could anchor the ends of loops in pre-rRNA containing 18S or 28S rRNA, thereby replacing base-paired stems found in pre-rRNA of prokaryotes.

Antisense snoRNAs: a family of nucleolar RNAs with long complementarities to rRNA

A growing subset of small nucleolar RNAs (snoRNAs) contains long stretches of sequence complementarity to conserved sequences in mature ribosomal RNA (rRNA). This article reviews current knowledge about these complementarities and proposes that these antisense snoRNAs might function in pre-rRNA folding, base modification and ribosomal ribonucleoprotein assembly, in some cases acting as RNA chaperones.

Isolation and characterization of the small nucleolar ribonucleoprotein particle snR30 from Saccharomyces cerevisiae

The nucleolus of the yeast Saccharomyces cerevisiae contains the small nucleolar RNA snR30 (snoRNA), that is found associated with at least two proteins, NOP1 and GAR1. All three of these molecules are essential for the cell's viability and have been implicated in pre-rRNA maturation. NOP1 and GAR1 are believed to be general rRNA-processing factors or, alternatively, integral protein components of the small nucleolar ribonucleoprotein particle snR30 (snoRNP). In this paper, we describe procedures for the biochemical isolation of snR30 RNP, and we identify seven snR30 RNP proteins of molecular masses of 10, 23, 25, 38, 46, 48, and 65 kDa, including the previously reported GAR1 protein. Additional proteins, including NOP1, may also be components of snR30 RNP but are lost during our stringent isolation procedure. The 10-, 23-, and 25-kDa (GAR1) and 65-kDa proteins remain tightly associated with the snR30 RNA even after isopycnic sedimentation in cesium sulfate gradients. Electron microscopy of Mono Q-purified snR30 RNPs show a slightly elongated two-domain structure approximately 20 nm long and 14 nm wide.

Processing of U14 small nucleolar RNA from three different introns of the mouse 70-kDa-cognate-heat-shock-protein pre-messenger RNA

U14 is a small nucleolar RNA required for the processing of eukaryotic rRNA precursors. The U14 genes of mouse as well as rat, hamster, human, Xenopus and trout are encoded within introns of the constitutively expressed 70-kDa-cognate-heat-shock protein gene (hsc70). We demonstrate here that U14.6 and U14.8 snRNAs, in addition to the previously characterized U14.5, are processed from their respective introns when hsc70 pre-mRNA transcripts containing these intronic snRNAs are injected into Xenopus oocyte nuclei. Identical intermediates are observed in the processing of all three mouse U14 snRNAs indicating similar processing pathways. The production of U14 snRNA processing intermediates possessing either mature 5' or 3' termini demonstrated that processing can occur at either end independent of maturation at the other terminus. Processing of U14.6 from hsc70 intron 6 is not dependent upon the base pairing of intron sequences flanking the 5' and 3' termini of the encoded U14 snRNA molecule. Therefore, excision of an intronic snRNA does not require extending the 5',3' terminal helix of U14 snRNA secondary structure into flanking intron regions as originally suggested. Microinjection of the plasmid vector containing the mouse hsc70/U14.5 snRNA coding region revealed that undetermined plasmid sequences can serve as non-specific promoters to generate spurious RNA transcripts. The processing of these transcripts and examination of the plasmid-initiated transcriptional-start sites indicated that a U14-specific promoter is not present in or around the intron-encoded U14.5 gene. These results strongly suggest that biosynthesis of mouse U14 snRNA results from an intron-processing pathway.

Disruption of U8 nucleolar snRNA inhibits 5.8S and 28S rRNA processing in the Xenopus oocyte

The nucleoli of vertebrate cells contain several snRNPs, of which only one, U3, has been assigned a role in rRNA processing. We present the primary sequence of Xenopus U8, a fibrillarin-associated nucleolar snRNA, and examine its expression through oocyte development. Antisense deoxyoligonucleotides were microinjected into Xenopus oocytes to deplete the endogenous pool of U8 RNA. Analysis of the mature rRNAs and rRNA intermediates that accumulate in the U8-depleted oocytes indicate that the U8 snRNP is essential for correct maturation of the 5.8S and 28S rRNAs at both their 5' and 3' ends. U8 is therefore a nucleolar snRNA implicated in a nucleolytic rRNA processing step other than 18S maturation. Evidence for a long-lived 5.8S rRNA intermediate (12S) in Xenopus is also presented.

The nucleolar snRNAs: catching up with the spliceosomal snRNAs

Despite their early discovery, research into the small RNAs associated with the eukaryotic nucleolus (snoRNAs) has lagged behind that of their cousins, the small nuclear RNAs which are known to function in mRNA splicing (spliceosomal snRNAs). Recent progress has now shown that the snoRNAs also occupy a vital niche in the RNA world, participating in the processing of ribosomal RNA. Like the spliceosomal snRNAs, the snoRNAs exist as ribonucleoprotein (RNP) particles which appear to assemble into a large multi-RNA RNP complex for pre-rRNA maturation.

Temperature-sensitive mutations demonstrate roles for yeast fibrillarin in pre-rRNA processing, pre-rRNA methylation, and ribosome assembly

We have generated temperature-sensitive lethal point mutations in the small nucleolar RNA-associated protein fibrillarin (encoded by the NOP1 gene in yeast) and analyzed their effects on ribosome synthesis. The five alleles tested all prevent synthesis of normal ribosomes, but in dramatically different ways. At the non-permissive temperature, the nop1.2 and nop1.5 alleles prevent synthesis of both 18S and 25S rRNA and all pre-rRNA species except the 35S primary transcript. In contrast, the nop1.3, nop1.4, and nop1.7 alleles do not strongly impair processing. In nop1.3 strains, nucleolar methylation of pre-rRNA is strongly inhibited; late, cytoplasmic methylation of 18S rRNA and tRNA methylation continue. The nop1.4 and nop1.7 alleles result in the synthesis of cytoplasmic 60S ribosomal subunits with strongly aberrant mobilities on sucrose gradients even at the permissive temperature, owing to the impairment of a late step in ribosome assembly. Thus, all major posttranscriptional activities in ribosome synthesis, pre-rRNA processing, pre-rRNA modification, and ribosome assembly are dependent on fibrillarin.

Mouse U14 snRNA is a processed intron of the cognate hsc70 heat shock pre-messenger RNA

U14 snRNA is a small nucleolar RNA species essential for eukaryotic pre-rRNA processing. We have previously shown that the mouse U14 snRNA genes are positioned within introns 5, 6, and 8 on the coding strand of the constitutively expressed cognate hsc70 heat shock gene. This genomic organization suggested the possibility that U14 snRNAs are transcribed as part of the hsc70 pre-mRNA and then excised from the intron to yield mature U14 snRNA species. To test this hypothesis directly, we have microinjected Xenopus oocytes with hsc70 pre-mRNA transcripts possessing intron 5 and the encoded U14 snRNA sequence. Processing results demonstrate that, in addition to the splicing of upstream and downstream exons, a mature 87 nt U14 snRNA is excised from the intron. Accurate excision of U14 snRNA from hsc70 intron 5 can occur in the absence of splicing. These results demonstrate a biosynthetic pathway for an snRNA species and provide a novel example of a eukaryotic pre-mRNA intron that is processed to produce a stable, biologically functional RNA species.

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

Full-length precursor ribosomal RNA molecules were produced in vitro using as a template, a plasmid containing the yeast 35 S pre-rRNA gene under the control of the phage T3 promoter. The higher-order structure of the 5'-external transcribed spacer (5' ETS) sequence in the 35S pre-rRNA molecule was studied using dimethylsulfate, 1-cyclohexyl-3-(2-morpholinoethyl)-carbodiimide metho-p-toluenesulfonate, RNase T1 and RNase V1 as structure-sensitive probes. Modified residues were detected by primer extension. Data produced were used to evaluate several theoretical structure models predicted by minimum free-energy calculations. A model for the entire 5'ETS region is proposed that accommodates 82% of the residues experimentally shown to be in either base-paired or single-stranded structure in the correct configuration. The model contains a high degree of secondary structure with ten stable hairpins of varying lengths and stabilities. The hairpins are composed of the Watson-Crick A.T and G.C pairs plus the non-canonical G.U pairs. Based on a comparative analysis of the 5' ETS sequence from Saccharomyces cerevisiae and Schizosaccharomyces pombe, most of the base-paired regions in the proposed model appear to be phylogenetically supported. The two sites previously shown to be crosslinked to U3 snRNA as well as the previously proposed recognition site for processing and one of the early processing site (based on sequence homology to the vertebrate ETS cleavage site) are located in single-stranded regions in the model. The present folding model for the 5' ETS in the 35 S pre-rRNA molecule should be useful in the investigations of the structure, function and processing of pre-rRNA.

Determination of the nucleotide sequences in mouse U14 small nuclear RNA and 18S ribosomal RNA responsible for in vitro intermolecular base-pairing

U14 small nuclear RNA (snRNA) is an evolutionarily conserved RNA species that plays a role in rRNA processing. The conserved ability of fungal, amphibian and mammalian U14 snRNAs to hybridize with both homologous and heterologous eukaryotic 18S rRNAs indicates a potential role for this intermolecular RNA/RNA interaction in U14 snRNA function. To understand better the possible role of this intermolecular base-pairing in rRNA processing, we have defined those nucleotide sequences in mouse U14 snRNA and 18S rRNA responsible for the observed in vitro hybridization. We have constructed, using synthetic DNA oligonucleotides, a U14 snRNA gene which has been positioned behind a T7 RNA polymerase promoter site and then inserted into a plasmid. The presence of natural or engineered restriction endonuclease sites within this construct has permitted the in vitro transcription of full-length mouse U14 snRNA transcripts (an 87-nucleotide mouse U14 snRNA minus 5' or 3' leader sequences) or 3' terminally truncated U14 snRNA fragments. Hybridization of full-length or truncated fragments of U14 snRNA to mouse 18S rRNA demonstrated the utilization of a previously proposed 18S rRNA complementary sequence located near the 3' end of mouse U14 snRNA (nucleotides 65-78) for intermolecular hybridization. Conversely, RNase-T1-generated fragments of 18S rRNA capable of hybrid-selection by U14 snRNA have been isolated and sequenced. A nested set of hybrid-selected 18S rRNA fragments define a mouse 18S rRNA sequence (nucleotides 459-472) which exhibits perfect complementarity to the defined U14 snRNA sequence 65-78. Primer-extension/chain-termination mapping of mouse U14-snRNA.18S-rRNA hybrids has confirmed the formation of the proposed hybrid structure. A second set of observed complementary sequences in mouse U14 snRNA (nucleotides 25-38) and mouse 18S rRNA (nucleotides 82-95) are not used for the in vitro hybridization of these two RNAs. Presumably the involvement of this second 18S-rRNA-complementary sequence in the secondary/tertiary folding of mouse U14 snRNA prevents its base-pairing with 18S rRNA. However, the strong evolutionary conservation of both U14-snRNA.18S-rRNA hybrid structures and their juxtapositioning within the folded secondary structure of 18S rRNAs argues for a biological role for each in U14 snRNA function.

Functional analysis of internal transcribed spacer 2 of Saccharomyces cerevisiae ribosomal DNA

Using the previously described "tagged ribosome" (pORCS) system for in vivo mutational analysis of yeast rDNA, we show that small deletions in the 5'-terminal portion of ITS2 completely block maturation of 26 S rRNA at the level of the 29 SB precursor (5.8 S rRNA-ITS2-26 S rRNA). Various deletions in the 3'-terminal part, although severely reducing the efficiency of processing, still allow some mature 26 S rRNA to be formed. On the other hand, none of the ITS2 deletions affect the production of mature 17 S rRNA. Since all of the deletions severely disturb the recently proposed secondary structure of ITS2, these findings suggest an important role for higher order structure of ITS2 in processing. Analysis of the effect of complete or partial replacement of S. cerevisiae ITS2 with its counterpart sequences from Saccharomyces rosei or Hansenula wingei, points to helix V of the secondary structure model as an important element for correct and efficient processing. Direct mutational analysis shows that disruption of base-pairing in the middle of helix V does not detectably affect 26 S rRNA formation. In contrast, introduction of clustered point mutations at the apical end of helix V that both disrupt base-pairing and change the sequence of the loop, severely reduces processing. Since a mutant containing only point mutations in the sequence of the loop produces normal amounts of mature 26 S rRNA, we conclude that the precise (secondary and/or primary) structure at the lower end of helix V, but excluding the loop, is of crucial importance for efficient removal of ITS2.