RRP1, a Saccharomyces cerevisiae gene affecting rRNA processing and production of mature ribosomal subunits.

The Saccharomyces cerevisiae mutant ts351 had been shown to affect processing of 27S pre-rRNA to mature 25S and 5.8S rRNAs (C. Andrew, A. K. Hopper, and B. D. Hall, Mol. Gen. Genet. 144:29-37, 1976). We showed that this strain contains two mutations leading to temperature-sensitive lethality. The rRNA-processing defect, however, is a result of only one of the two mutations. We designated the lesion responsible for the rRNA-processing defect rrp1 and showed that it is located on the right arm of chromosome IV either allelic to or tightly linked to mak21. This rrp1 lesion also results in hypersensitivity to aminoglycoside antibiotics and a reduced 25S/18S rRNA ratio at semipermissive temperatures. We cloned the RRP1 gene and provide evidence that it encodes a moderately abundant mRNA which is in lower abundance and larger than most mRNAs encoding ribosomal proteins.     

Role of the yeast Rrp1 protein in the dynamics of pre-ribosome maturation

The Saccharomyces cerevisiae gene RRP1 encodes an essential, evolutionarily conserved protein necessary for biogenesis of 60S ribosomal subunits. Processing of 27S pre-ribosomal RNA to mature 25S rRNA is blocked and 60S subunits are deficient in the temperature-sensitive rrp1-1 mutant. We have used recent advances in proteomic analysis to examine in more detail the function of Rrp1p in ribosome biogenesis. We show that Rrp1p is a nucleolar protein associated with several distinct 66S pre-ribosomal particles. These pre-ribosomes contain ribosomal proteins plus at least 28 nonribosomal proteins necessary for production of 60S ribosomal subunits. Inactivation of Rrp1p inhibits processing of 27SA(3) to 27SB(S) pre-rRNA and of 27SB pre-rRNA to 7S plus 25.5S pre-rRNA. Thus, in the rrp1-1 mutant, 66S pre-ribosomal particles accumulate that contain 27SA(3) and 27SB(L) pre-ribosomal RNAs.     

Two mutant forms of the S1/TPR-containing protein Rrp5p affect the 18S rRNA synthesis in Saccharomyces cerevisiae.

The genetic depletion of yeast Rrp5p results in a synthesis defect of both 18S and 5.8S ribosomal RNAs (Venema J, Tollervey D. 1996. EMBO J 15:5701-5714). We have isolated the RRP5gene in a genetic approach aimed to select for yeast factors interfering with protein import into mitochondria. We describe here a striking feature of Rrp5p amino acid sequence, namely the presence of twelve putative S1 RNA-binding motifs and seven tetratricopeptide repeats (TPR) motifs. We have constructed two conditional temperature-sensitive alleles of RRP5 gene and analyzed them for associated rRNA-processing defects. First, a functional "bipartite gene" was generated revealing that the S1 and TPR parts of the protein can act independently of each other. We also generated a two amino acid deletion in TPR unit 1 (rrp5delta6 allele). The two mutant forms of Rrp5p were shown to cause a defect in 18S rRNA synthesis with no detectable effects on 5.8S rRNA production. However, the rRNA processing pathway was differently affected in each case. Interestingly, the ROK1 gene which, like RRP5, was previously isolated in a screen for synthetic lethal mutations with snR10 deletion, was here identified as a high copy suppressor of the rrp5delta6 temperature-sensitive allele. ROK1 also acts as a low copy suppressor but cannot bypass the cellular requirement for RRP5. Furthermore, we show that suppression by the Rok1p putative RNA helicase rescues the 18S rRNA synthesis defect caused by the rrp5delta6 mutation.     

Functional analysis of Rrp7p, an essential yeast protein involved in pre-rRNA processing and ribosome assembly.

During the functional analysis of open reading frames (ORFs) identified during the sequencing of chromosome III of Saccharomyces cerevisiae, the previously uncharacterized ORF YCL031C (now designated RRP7) was deleted. RRP7 is essential for cell viability, and a conditional null allele was therefore constructed, by placing its expression under the control of a regulated GAL promoter. Genetic depletion of Rrp7p inhibited the pre-rRNA processing steps that lead to the production of the 20S pre-rRNA, resulting in reduced synthesis of the 18S rRNA and a reduced ratio of 40S to 60S ribosomal subunits. A screen for multicopy suppressors of the lethality of the GAL::rrp7 allele isolated the two genes encoding a previously unidentified ribosomal protein (r-protein) that is highly homologous to the rat r-protein S27. When present in multiple copies, either gene can suppress the lethality of an RRP7 deletion mutation and can partially restore the ribosomal subunit ratio in Rrp7p-depleted cells. Deletion of both r-protein genes is lethal; deletion of either single gene has an effect on pre-rRNA processing similar to that of Rrp7p depletion. We believe that Rrp7p is required for correct assembly of rpS27 into the preribosomal particle, with the inhibition of pre-rRNA processing appearing as a consequence of this defect.     

The RNA catabolic enzymes Rex4p, Rnt1p, and Dbr1p show genetic interaction with trans-acting factors involved in processing of ITS1 in Saccharomyces cerevisiae pre-rRNA

Eukaryotes have two types of ribosomes containing either 5.8SL or 5.8SS rRNA that are produced by alternative pre-rRNA processing. The exact processing pathway for the minor 5.8SL rRNA species is poorly documented. We have previously shown that the trans-acting factor Rrp5p and the RNA exonuclease Rex4p genetically interact to influence the ratio between the two forms of 5.8S rRNA in the yeast Saccharomyces cerevisiae. Here we report a further analysis of ITS1 processing in various yeast mutants that reveals genetic interactions between, on the one hand, Rrp5p and RNase MRP, the endonuclease required for 5.8SS rRNA synthesis, and, on the other, Rex4p, the RNase III homolog Rnt1p, and the debranching enzyme Dbr1p. Yeast cells carrying a temperature-sensitive mutation in RNase MRP (rrp2-1) exhibit a pre-rRNA processing phenotype very similar to that of the previously studied rrp5-33 mutant: ITS2 processing precedes ITS1 processing, 5.8SL rRNA becomes the major species, and ITS1 is processed at the recently reported novel site A4 located midway between sites A2 and A3. As in the rrp5-Delta3 mutant, all of these phenotypical processing features disappear upon inactivation of the REX4 gene. Moreover, inactivation of the DBR1 gene in rrp2-1, or the RNT1 gene in rrp5-Delta3 mutant cells also negates the effects of the original mutation on pre-rRNA processing. These data link a total of three RNA catabolic enzymes, Rex4p, Rnt1p, and Dbr1p, to ITS1 processing and the relative production of 5.8SS and 5.8SL rRNA. A possible model for the indirect involvement of the three enzymes in yeast pre-rRNA processing is discussed.     

Deletions in the S1 domain of Rrp5p cause processing at a novel site in ITS1 of yeast pre-rRNA that depends on Rex4p

Rrp5p is the only protein so far known to be required for the processing of yeast pre-rRNA at both the early sites A0, A1 and A2 leading to 18S rRNA and at site A3, the first step specific for the pathway leading to 5.8S/25S rRNA. Previous in vivo mutational analysis of Rrp5p demonstrated that the first 8 of its 12 S1 RNA-binding motifs are involved in the formation of the 'short' form of 5.8S rRNA (5.8S(S)), which is the predominant species under normal conditions. We have constructed two strains in which the genomic RRP5 gene has been replaced by an rrp5 deletion mutant lacking either S1 motifs 3-5 (rrp5-Delta3) or 5-8 (rrp5-Delta4). The first mutant synthesizes almost exclusively 5.8S(L) rRNA, whereas the second one still produces a considerable amount of the 5.8S(S) species. Nevertheless, both mutations were found to block cleavage at site A3 completely. Instead, a novel processing event occurs at a site in a conserved stem-loop structure located between sites A2 and A3, which we have named A4. A synthetic lethality screen using the rrp5-Delta3 and rrp-Delta4 mutations identified the REX4 gene, which encodes a non-essential protein belonging to a class of related yeast proteins that includes several known 3'-->5' exonucleases. Inactivation of the REX4 gene in rrp5-Delta3 or rrp-Delta4 cells abolished cleavage at A4, restored cleavage at A3 and returned the 5.8S(S):5.8S(L) ratio to the wild-type value. The sl phenotype of the rrp5Delta/rex4(-) double mutants appears to be due to a severe disturbance in ribosomal subunit assembly, rather than pre-rRNA processing. The data provide direct evidence for a crucial role of the multiple S1 motifs of Rrp5p in ensuring the correct assembly and action of the processing complex responsible for cleavage at site A3. Furthermore, they clearly implicate Rex4p in both pre-rRNA processing and ribosome assembly, even though this protein is not essential for yeast.     

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.     

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.     

Deletion of the three distal S1 motifs of Saccharomyces cerevisiae Rrp5p abolishes pre-rRNA processing at site A(2) without reducing the production of functional 40S subunits

Yeast Rrp5p, one of the few trans-acting proteins required for the biogenesis of both ribosomal subunits, has a remarkable two-domain structure. Its C-terminal region consists of seven tetratricopeptide motifs, several of which are crucial for cleavages at sites A(0) to A(2) and thus for the formation of 18S rRNA. The N-terminal region, on the other hand, contains 12 S1 RNA-binding motifs, most of which are required for processing at site A(3) and thus for the production of the short form of 5.8S rRNA. Yeast cells expressing a mutant Rrp5p protein that lacks S1 motifs 10 to 12 (mutant rrp5Delta6) have a normal growth rate and wild-type steady-state levels of the mature rRNA species, suggesting that these motifs are irrelevant for ribosome biogenesis. Here we show that, nevertheless, in the rrp5Delta6 mutant, pre-rRNA processing follows an alternative pathway that does not include the cleavage of 32S pre-rRNA at site A(2). Instead, the 32S precursor is processed directly at site A(3), producing exclusively 21S rather than 20S pre-rRNA. This is the first evidence that the 21S precursor, which was observed previously only in cells showing a substantial growth defect or as a minor species in addition to the normal 20S precursor, is an efficient substrate for 18S rRNA synthesis. Maturation of the 21S precursor occurs via the same endonucleolytic cleavage at site D as that used for 20S pre-rRNA maturation. The resulting D-A(3) fragment, however, is degraded by both 5'-->3' and 3'-->5' exonuclease digestions, the latter involving the exosome, in contrast to the exclusively 5'-->3' exonucleolytic digestion of the D-A(2) fragment. We also show that rrp5Delta6 cells are hypersensitive to both hygromycin B and cycloheximide, suggesting that, despite their wild-type growth rate, their preribosomes or ribosomes may be structurally abnormal.     

Yeast NSR1 protein that has structural similarity to mammalian nucleolin is involved in pre-rRNA processing.

We have identified a yeast gene encoding a protein structurally similar to mammalian nucleolin. The gene was previously cloned as a cold shock-inducible gene and found to be identical to yeast NSR1 gene, which encodes a protein that has been reported to bind sequences required for nuclear localization of protein. The carboxyl-terminal half of NSR1, consisting of two tandemly repeated putative RNA-binding domains and a glycine/arginine-rich domain, has 37% amino acid sequence identity with the same part of mammalian nucleolin, while no sequence similarities are found between their amino-terminal regions. Although a null mutation of the NSR1 gene was not lethal, it caused a severe defect on growth. Pulse-labeling analysis revealed that the nsr1 strain had reduced levels of 18 S rRNA and accumulated 35 S pre-rRNA compared with the wild-type strain. The level of 25 S rRNA was also slightly reduced in the nsr1 strain. Pulse-chase labeling experiments showed slow processing of 35 S pre-rRNA and impaired methylation of 18 S rRNA. The ratio of 40 S to 60 S ribosomal subunits in the nsr1 strain is significantly reduced and is consistent with impaired synthesis of 18 S rRNA. The results indicate that NSR1 is involved in pre-rRNA processing and ribosome biosynthesis in yeast.     

Yeast Rrp14p is a nucleolar protein involved in both ribosome biogenesis and cell polarity

We previously cloned RRP14/YKL082c, whose product exhibits two-hybrid interaction with Ebp2p, a regulatory factor of assembly of 60S ribosomal subunits. Depletion of Rrp14p results in shortage of 60S ribosomal subunits and retardation of processing from 27S pre-rRNA to 25S rRNA. Furthermore, 35S pre-rRNA synthesis appears to decline in Rrp14p-depleted cells. Rrp14p interacts with regulatory factors of 60S subunit assembly and also with Utp11p and Faf1p, which are regulatory factors required for assembly of 40S ribosomal subunits. We propose that Rrp14p is involved in ribosome synthesis from the beginning of 35S pre-rRNA synthesis to assembly of the 60S ribosomal subunit. Disruption of RRP14 causes an extremely slow growth rate of the cell, a severe defect in ribosome synthesis, and a depolarized localization of cortical actin patches throughout the cell cycle. These results suggest that Rrp14p has dual functions in ribosome synthesis and polarized cell growth.     

Late cytoplasmic maturation of the small ribosomal subunit requires RIO proteins in Saccharomyces cerevisiae

Numerous nonribosomal trans-acting factors involved in pre-rRNA processing have been characterized, but few of them are specifically required for the last cytoplasmic steps of 18S rRNA maturation. We have recently demonstrated that Rrp10p/Rio1p is such a factor. By BLAST analysis, we identified the product of a previously uncharacterized essential gene, YNL207W/RIO2, called Rio2p, that shares 43% sequence similarity with Rrp10p/Rio1p. Rio2p homologues were identified throughout the Archaea and metazoan species. We show that Rio2p is a cytoplasmic-nuclear protein and that its depletion blocks 18S rRNA production, leading to 20S pre-rRNA accumulation. In situ hybridization reveals that in Rio2p-depleted cells, 20S pre-rRNA localizes in the cytoplasm, demonstrating that its accumulation is not due to an export defect. We also show that both Rio1p and Rio2p accumulate in the nucleus of crm1-1 cells at the nonpermissive temperature. Nuclear as well as cytoplasmic Rio2p and Rio1p cosediment with pre-40S particles. These results strongly suggest that Rio2p and Rrp10p/Rio1p are shuttling proteins which associate with pre-40S particles in the nucleus and they are not necessary for export of the pre-40S complexes but are absolutely required for the cytoplasmic maturation of 20S pre-rRNA at site D, leading to mature 40S ribosomal subunits.     

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.     

Processing of 20S pre-rRNA to 18S ribosomal RNA in yeast requires Rrp10p, an essential non-ribosomal cytoplasmic protein

Numerous non-ribosomal trans-acting factors involved in pre-ribosomal RNA processing have been characterized, but none of them is specifically required for the last cytoplasmic steps of 18S rRNA maturation. Here we demonstrate that Rio1p/Rrp10p is such a factor. Previous studies showed that the RIO1 gene is essential for cell viability and conserved from archaebacteria to man. We isolated a RIO1 mutant in a screen for mutations synthetically lethal with a mutant allele of GAR1, an essential gene required for 18S rRNA production and rRNA pseudouridylation. We show that RIO1 encodes a cytoplasmic non-ribosomal protein, and that depletion of Rio1p blocks 18S rRNA production leading to 20S pre-rRNA accumulation. In situ hybridization reveals that, in Rio1p depleted cells, 20S pre-rRNA localizes in the cytoplasm, demonstrating that its accumulation is not due to an export defect. This strongly suggests that Rio1p is involved in the cytoplasmic cleavage of 20S pre-rRNA at site D, producing mature 18S rRNA. Thus, Rio1p has been renamed Rrp10p (ribosomal RNA processing #10). Rio1p/Rrp10p is the first non-ribosomal factor characterized specifically required for 20S pre-rRNA processing.     

High dosage of the small nucleolar RNA snR10 specifically suppresses defects of a yeast rrp5 mutant

We have previously described a yeast strain in which cleavage at site A2 during processing of rRNA is absent and is functionally replaced by cleavage at site A3. This strain expresses a variant of the essential RRP5 gene that results in the synthesis of two noncontiguous segments of the protein. We have used the slow-growth phenotype of this strain to screen for revertants. The gene for the small nucleolar RNA snR10 was isolated as a multicopy suppressor of this "bipartite" RRP5 allele. Suppression by snR10 efficiently rescues the slow-growth (sg) and temperature-sensitive (ts) phenotypes of the mutant strain and is specific for this small nucleolar RNA. Deletion derivatives of snR10 were constructed and tested for the ability to suppress the sg and ts phenotypes of the RRP5 mutant, as well as for complementation of the cold sensitivity of a delta snr10 strain. The results indicate that the suppression effect is more sensitive to snR10 mutations than is complementation. The high dosage of wild-type snR10 does not restore cleavage at A2, but improves the rate of pre-rRNA processing and significantly increases the level of active ribosomes in the suppressed strain. These effects probably account for the suppression of the sg and ts phenotypes of the rrp5 mutant strain.     

Saccharomyces cerevisiae nucleolar protein Nop7p is necessary for biogenesis of 60S ribosomal subunits

To identify new gene products that participate in ribosome biogenesis, we carried out a screen for mutations that result in lethality in combination with mutations in DRS1, a Saccharomyces cerevisiae nucleolar DEAD-box protein required for synthesis of 60S ribosomal subunits. We identified the gene NOP7that encodes an essential protein. The temperature-sensitive nop7-1 mutation or metabolic depletion of Nop7p results in a deficiency of 60S ribosomal subunits and accumulation of halfmer polyribosomes. Analysis of pre-rRNA processing indicates that nop7 mutants exhibit a delay in processing of 27S pre-rRNA to mature 25S rRNA and decreased accumulation of 25S rRNA. Thus Nop7p, like Drs1p, is required for essential steps leading to synthesis of 60S ribosomal subunits. In addition, inactivation or depletion of Nop7p also affects processing at the A0, A1, and A2 sites, which may result from the association of Nop7p with 35S pre-rRNA in 90S pre-rRNPs. Nop7p is localized primarily in the nucleolus, where most steps in ribosome assembly occur. Nop7p is homologous to the zebrafish pescadillo protein necessary for embryonic development. The Nop7 protein contains the BRCT motif, a protein-protein interaction domain through which, for example, the human BRCA1 protein interacts with RNA helicase A.     

Rrp8p is a yeast nucleolar protein functionally linked to Gar1p and involved in pre-rRNA cleavage at site A2

Chemical modifications and processing of the 18S, 5.8S, and 25S ribosomal RNAs from the 35S pre-ribosomal RNA depend on an important set of small nucleolar ribonucleoprotein particles (snoRNPs). Genetic depletion of yeast Gar1p, an essential common component of H/ACA snoRNPs, leads to inhibition of uridine isomerizations to pseudo-uridines on the 35S pre-rRNA and of the early pre-rRNA cleavages at sites A1 and A2, resulting in a loss of mature 18S rRNA synthesis. To identify Gar1p functional partners, we screened for mutations that are synthetically lethal with a gar1 mutant allele encoding a Gar1p mutant protein lacking its two glycine/arginine-rich (GAR) domains. We identified a previously uncharacterized Saccharomyces cerevisiae open reading frame, YDR083W (now designated RRP8), that encodes a highly conserved protein containing motifs found in methyltransferases. Rrp8p localizes to the nucleolus. A yeast strain lacking this protein is viable at 30 degrees C but displays strong growth impairment at lower temperatures. In this strain, cleavage of the pre-rRNA at site A2 is strongly affected whereas cleavages at sites A0 and A1 are only slightly inhibited or delayed.     

RRP5 is required for formation of both 18S and 5.8S rRNA in yeast.

Three of the four eukaryotic ribosomal RNA molecules (18S, 5.8S and 25-28S) are synthesized as a single precursor which is subsequently processed into the mature rRNAs by a complex series of cleavage and modification reactions. In the yeast Saccharomyces cerevisiae, the early pre-rRNA cleavages at sites A0, A1 and A2, required for the synthesis of 18S rRNA, are inhibited in strains lacking RNA or protein components of the U3, U14, snR10 and snR30 small nucleolar ribonucleoproteins (snoRNPs). The subsequent cleavage at site A3, required for formation of the major, short form of 5.8S rRNA, is carried out by another ribonucleoprotein, RNase MRP. A screen for mutations showing synthetic lethality with deletion of the non-essential snoRNA, snR10, identified a novel gene, RRP5, which is essential for viability and encodes a 193 kDa nucleolar protein. Genetic depletion of Rrp5p inhibits the synthesis of 18S rRNA and, unexpectedly, also of the major short form of 5.8S rRNA. Pre-rRNA processing is concomitantly impaired at sites A0, A1, A2 and A3. This distinctive phenotype makes Rrp5p the first cellular component simultaneously required for the snoRNP-dependent cleavage at sites A0, A1 and A2 and the RNase MRP-dependent cleavage at A3 and provides evidence for a close interconnection between these processing events. Putative RRP5 homologues from Caenorhabditis elegans and humans were also identified, suggesting that the critical function of Rrp5p is evolutionarily conserved.