Alternate pathways for processing in the internal transcribed spacer 1 in pre-rRNA of Saccharomyces cerevisiae

A Novel Model for the RNase MRP-Induced Switch between the Formation of Different Forms of 5.8S rRNA

Processing of the RNA polymerase I pre-rRNA transcript into the mature 18S, 5.8S, and 25S rRNAs requires removing the "spacer" sequences. The canonical pathway for the removal of the ITS1 spacer involves cleavages at the 3' end of 18S rRNA and at two sites inside ITS1. The process can generate either a long or a short 5.8S rRNA that differs in the number of ITS1 nucleotides retained at the 5.8S 5' end. Here we document a novel pathway to the long 5.8S, which bypasses cleavage within ITS1. Instead, the entire ITS1 is degraded from its 5' end by exonuclease Xrn1. Mutations in RNase MRP increase the accumulation of long relative to short 5.8S rRNA. Traditionally this is attributed to a decreased rate of RNase MRP cleavage at its target in ITS1, called A3. However, results from this work show that the MRP-induced switch between long and short 5.8S rRNA formation occurs even when the A3 site is deleted. Based on this and our published data, we propose that the link between RNase MRP and 5.8S 5' end formation involves RNase MRP cleavage at unknown sites elsewhere in pre-rRNA or in RNA molecules other than pre-rRNA.

The small and large ribosomal subunits depend on each other for stability and accumulation

The 1:1 balance between the numbers of large and small ribosomal subunits can be disturbed by mutations that inhibit the assembly of only one of the subunits. Here, we have investigated if the cell can counteract an imbalance of the number of the two subunits. We show that abrogating 60S assembly blocks 40S subunit accumulation. In contrast, cessation of the 40S pathways does not prevent 60S accumulation, but does, however, lead to fragmentation of the 25S rRNA in 60S subunits and formation of a 55S ribosomal particle derived from the 60S. We also present evidence suggesting that these events occur post assembly and discuss the possibility that the turnover of subunits is due to vulnerability of free subunits not paired with the other subunit to form 80S ribosomes.

The pathway to maturity: processing of ribosomal RNA in Saccharomyces cerevisiae

The 17-18S, 5.8S, and 25-28S rRNA species of eukaryotic cells are transcribed by RNA polymerase I into a single precursor molecule, from which external and internal spacer sequences are subsequently removed in an order series of nucleolytic reactions. Whereas the order of the cleavage reactions has long been established, only recently has significant progress been made in detailing the cis-acting elements and the trans-acting factors involved in this process. The use of recently developed systems for in vivo mutational analysis of yeast rDNA has greatly enhanced our knowledge of cis-acting structural features within the pre-rRNA, which are critical for correct and efficient removal of the spacer sequences. The same systems also allow a link to be forged between trans-acting processing factors and these cis-acting elements. In this review the newly obtained information will be summarized, focused predominantly on pre-rRNA processing in the yeast Saccharomyces cerevisiae.

The Reb1-homologue Ydr026c/Nsi1 is required for efficient RNA polymerase I termination in yeast

Several DNA cis-elements and trans-acting factors were described to be involved in transcription termination and to release the elongating RNA polymerases from their templates. Different models for the molecular mechanism of transcription termination have been suggested for eukaryotic RNA polymerase I (Pol I) from results of in vitro and in vivo experiments. To analyse the molecular requirements for yeast RNA Pol I termination, an in vivo approach was used in which efficient termination resulted in growth inhibition. This led to the identification of a Myb-like protein, Ydr026c, as bona fide termination factor, now designated Nsi1 (NTS1 silencing protein 1), since it was very recently described as silencing factor of ribosomal DNA. Possible Nsi1 functions in regard to the mechanism of transcription termination are discussed.

Rcl1 protein, a novel nuclease for 18 S ribosomal RNA production

In all forms of life, rRNAs for the small and large ribosomal subunit are co-transcribed as a single transcript. Although this ensures the equimolar production of rRNAs, it requires the endonucleolytic separation of pre-rRNAs to initiate rRNA production. In yeast, processing of the primary transcript encoding 18 S, 5.8 S, and 25 S rRNAs has been studied extensively. Nevertheless, most nucleases remain to be identified. Here, we show that Rcl1, conserved in all eukaryotes, cleaves pre-rRNA at so-called site A(2), a co-transcriptional cleavage step that separates rRNAs destined for the small and large subunit. Recombinant Rcl1 cleaves pre-rRNA mimics at site A(2) in a reaction that is sensitive to nearby RNA mutations that inhibit cleavage in vivo. Furthermore, mutations in Rcl1 disrupt rRNA processing at site A(2) in vivo and in vitro. Together, these results demonstrate that the role of Rcl1 in eukaryotic pre-rRNA processing is identical to that of RNase III in bacteria: to co-transcriptionally separate the pre-rRNAs destined for the small and large subunit. Furthermore, because Rcl1 has no homology to other known endonucleases, these data also establish a novel class of nucleases.

An RNA conformational switch regulates pre-18S rRNA cleavage

To produce mature ribosomal RNAs (rRNAs), polycistronic rRNA transcripts are cleaved in an ordered series of events. We have uncovered the molecular basis for the ordering of two essential cleavage steps at the 3'-end of 18S rRNA. Using in vitro and in vivo structure probing, RNA binding and cleavage experiments, and yeast genetics, we demonstrate that a conserved RNA sequence in the spacer region between the 18S and 5.8S rRNAs base-pairs with the decoding site of 18S rRNA in early assembly intermediates. Nucleolar cleavage at site A(2) excises this sequence element, leading to a conformational switch in pre-18S rRNA, by which the ribosomal decoding site is formed. This conformational switch positions the nuclease Nob1 for cytoplasmic cleavage at the 3'-end of 18S rRNA and is required for the final maturation step of 18S rRNA in vivo and in vitro. More generally, our data show that the intrinsic ability of RNA to form stable structural switches is exploited to order and regulate RNA-dependent biological processes.

Derivation of the Secondary Structure of the ITS-1 Transcript in Volvocales and its Taxonomic Correlations

Knowledge of secondary structure, formed by the gene spacer regions of the primary transcript of nuclear rDNA cistrons, is lacking for most phyla of eukaryotes. We have sequenced the first internal transcribed spacer region (ITS-1) of multiple representatives of the Volvocales, and from comparisons of these, derived a secondary structure common to the entire group. The secondary structure model is supported by numerous compensating base pair changes located within the paired regions of the stem-loops. Within the morphological species, such as those of Astrephomene and Gonium, the three basal nucleotide pairs of helices are highly conserved in primary sequence, and the single stranded region rich in CCAA is identical in sequence, even when isolates come from all continents of the earth. In other Volvocacean species known to include many pairs of mating types, this same level of conservation is found to correlate with the mating subgroups of the species. Thus a comparable degree of sequence similarity appears to characterize all isolates of a "biological" species; this is valid for taxonomic species only where the biological and taxonomic species levels coincide. In addition, the ITS-1 contains information useful for population analyses, and spacer secondary structure may have additional phylogenetic utility at the level of class or subclass when that information becomes available for other protistan groups.

RNase MRP is required for entry of 35S precursor rRNA into the canonical processing pathway

RNase MRP is a nucleolar RNA-protein enzyme that participates in the processing of rRNA during ribosome biogenesis. Previous experiments suggested that RNase MRP makes a nonessential cleavage in the first internal transcribed spacer. Here we report experiments with new temperature-sensitive RNase MRP mutants in Saccharomyces cerevisiae that show that the abundance of all early intermediates in the processing pathway is severely reduced upon inactivation of RNase MRP. Transcription of rRNA continues unabated as determined by RNA polymerase run-on transcription, but the precursor rRNA transcript does not accumulate, and appears to be unstable. Taken together, these observations suggest that inactivation of RNase MRP blocks cleavage at sites A0, A1, A2, and A3, which in turn, prevents precursor rRNA from entering the canonical processing pathway (35S > 20S + 27S > 18S + 25S + 5.8S rRNA). Nevertheless, at least some cleavage at the processing site in the second internal transcribed spacer takes place to form an unusual 24S intermediate, suggesting that cleavage at C2 is not blocked. Furthermore, the long form of 5.8S rRNA is made in the absence of RNase MRP activity, but only in the presence of Xrn1p (exonuclease 1), an enzyme not required for the canonical pathway. We conclude that RNase MRP is a key enzyme for initiating the canonical processing of precursor rRNA transcripts, but alternative pathway(s) might provide a backup for production of small amounts of rRNA.

Alterations in the intracellular level of a protein subunit of human RNase P affect processing of tRNA precursors

The human ribonucleoprotein ribonuclease P (RNase P), processing tRNA, has at least 10 distinct protein subunits. Many of these subunits, including the autoimmune antigen Rpp38, are shared by RNase MRP, a ribonucleoprotein enzyme required for processing of rRNA. We here show that constitutive expression of exogenous, tagged Rpp38 protein in HeLa cells affects processing of tRNA precursors. Alterations in the site-specific cleavage and in the steady-state level of 3' sequences of the internal transcribed spacer 1 of rRNA are also observed. These processing defects are accompanied by selective shut-off of expression of Rpp38 and by low expression of the tagged protein. RNase P purified from these cells exhibits impaired activity in vitro. Moreover, inhibition of Rpp38 by the use of small interfering RNA causes accumulation of the initiator methionine tRNA precursor. Expression of other protein components, but not of the H1 RNA subunit, is coordinately inhibited. Our results reveal that normal expression of Rpp38 is required for the biosynthesis of intact RNase P and for the normal processing of stable RNA in human cells.

Utilization of the internal transcribed spacer regions as molecular targets to detect and identify human fungal pathogens

Advances in molecular technology show great potential for the rapid detection and identification of fungi for medical, scientific and commercial purposes. Numerous targets within the fungal genome have been evaluated, with much of the current work using sequence areas within the ribosomal DNA (rDNA) gene complex. This section of the genome includes the 18S, 5.8S and 28S genes which code for ribosomal RNA (rRNA) and which have a relatively conserved nucleotide sequence among fungi. It also includes the variable DNA sequence areas of the intervening internal transcribed spacer (ITS) regions called ITS1 and ITS2. Although not translated into proteins, the ITS coding regions have a critical role in the development of functional rRNA, with sequence variations among species showing promise as signature regions for molecular assays. This review of the current literature was conducted to evaluate clinical approaches for using the fungal ITS regions as molecular targets. Multiple applications using the fungal ITS sequences are summarized here including those for culture identification, phylogenetic research, direct detection from clinical specimens or the environment, and molecular typing for epidemiological investigations. The breadth of applications shows that ITS regions have great potential as targets in molecular-based assays for the characterization and identification of fungi. Development of rapid and accurate amplification-based ITS assays to diagnose invasive fungal infections could potentially impact care and improve outcome for affected patients.

Identification of cis-acting elements involved in 3'-end formation of Saccharomyces cerevisiae 18S rRNA

In yeast, the 3' end of mature 18S rRNA is generated by endonucleolytic cleavage of the 20S precursor at site D. Available data indicate that the major cis-acting elements required for this processing step are located in relatively close proximity to the cleavage site. To identify these elements, we have studied the effect of mutations in the mature 18S and ITS1 sequences neighboring site D on pre-rRNA processing in vivo. Using clustered point mutations, we found that alterations in the sequence spanning site D from position -5 in 18S rRNA to +6 in ITS1 reduced the efficiency of processing at this site to different extents as demonstrated by the lower level of the mature 18S rRNA and the increase in 20S pre-rRNA in cells expressing only mutant rDNA units. More detailed analysis revealed an important role for the residue located 2 nt upstream from site D (position -2), whereas sequence changes at position -1, +1, and +2 relative to site D had no effect. The data further demonstrate that the proposed base pairing between the 3' end of 18S rRNA and the 5' end of ITS1 is not important for efficient and accurate processing at site D, nor for the formation of functional 40S ribosomal subunits. These results were confirmed by analyzing the accumulation of the D-A2 fragment derived from the mutant 20S pre-rRNA in cells that lack the Xrn1p exonuclease responsible for its degradation. The latter results also showed that the accuracy of cleavage was affected by altering the spacer sequence directly downstream of site D but not by mutations in the 18S rRNA sequence preceding this site.

The final step in the formation of 25S rRNA in Saccharomyces cerevisiae is performed by 5'-->3' exonucleases

The final stage in the formation of the two large subunit rRNA species in Saccharomyces cerevisiae is the removal of internal transcribed spacer 2 (ITS2) from the 27SB precursors. This removal is initiated by endonucleolytic cleavage approximately midway in ITS2. The resulting 7S pre-rRNA, which is easily detectable, is then converted into 5.8S rRNA by the concerted action of a number of 3'-->5' exonucleases, many of which are part of the exosome. So far the complementary precursor to 25S rRNA resulting from the initial cleavage in ITS2 has not been detected and the manner of its conversion into the mature species is unknown. Using various yeast strains that carry different combinations of wild-type and mutant alleles of the major 5'-->3' exonucleases Rat1p and Xrn1p, we now demonstrate the existence of a short-lived 25.5S pre-rRNA whose 5' end is located closely downstream of the previously mapped 3' end of 7S pre-rRNA. The 25.5S pre-rRNA is converted into mature 25S rRNA by rapid exonucleolytic trimming, predominantly carried out by Rat1p. In the absence of Rat1p, however, the removal of the ITS2 sequences from 25.5S pre-rRNA can also be performed by Xrn1p, albeit somewhat less efficiently.

Ribosome synthesis in Saccharomyces cerevisiae

The synthesis of ribosomes is one of the major metabolic pathways in all cells. In addition to around 75 individual ribosomal proteins and 4 ribosomal RNAs, synthesis of a functional eukaryotic ribosome requires a remarkable number of trans-acting factors. Here, we will discuss the recent, and often surprising, advances in our understanding of ribosome synthesis in the yeast Saccharomyces cerevisiae. These will underscore the unexpected complexity of eukaryotic ribosome synthesis.

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.

Conserved core structure in the internal transcribed spacer 1 of the Schizosaccharomyces pombe precursor ribosomal RNA

The structure of the internal transcribed spacer 1 (ITS1) in Schizosaccharomyces pombe was examined with respect to phylogenetically conserved features in yeasts as well as the binding of transacting factors that potentially play a role in ribosomal maturation. Computer analyses and probes for nuclease protection indicate a compact, more highly organized structure than previously proposed in Saccharomyces cerevisiae, with distinct structural features which can be recognized in S. cerevisiae. These include a central extended hairpin structure as well as smaller hairpins immediately adjacent to the maturing termini. Comparisons with ITS sequences in more diverse organisms indicate that the same features also can be recognized. This is especially clear in organisms which contain very short sequences in which the putative structures are much less ambiguous. Again nuclease protection analyses in one of these, Verticillium albo-atrum, confirm a central hairpin with additional hairpins linked to the maturing termini. Protein binding and gel retardation studies with the S. pombe ITS1 further indicate that, as observed in the 3' external transcripted spacer (ETS) region, the extended hairpin is not only the site of intermediate RNA cleavage during rRNA processing, but also a site for specific interactions with one or more soluble factors. Taken together with other analyses on transcribed spacer regions, the present data provide evidence that the spacer regions act not only to organize the maturing terminal sequences but also may serve to organize specific soluble factors, possibly acting in a manner which is analogous with that of the free small nucleolar ribonucleo protein particles (snoRNPs).

The yeast nucleolar protein Cbf5p is involved in rRNA biosynthesis and interacts genetically with the RNA polymerase I transcription factor RRN3

Yeast Cbf5p was originally isolated as a low-affinity centromeric DNA binding protein (W. Jiang, K. Middleton, H.-J. Yoon, C. Fouquet, and J. Carbon, Mol. Cell. Biol. 13:4884-4893, 1993). Cbf5p also binds microtubules in vitro and interacts genetically with two known centromere-related protein genes (NDC10/CBF2 and MCK1). However, Cbf5p was found to be nucleolar and is highly homologous to the rat nucleolar protein NAP57, which coimmunoprecipitates with Nopp140 and which is postulated to be involved in nucleolar-cytoplasmic shuttling (U. T. Meier, and G. Blobel, J. Cell Biol. 127:1505-1514, 1994). The temperature-sensitive cbf5-1 mutant demonstrates a pronounced defect in rRNA biosynthesis at restrictive temperatures, while tRNA transcription and pre-rRNA and pre-tRNA cleavage processing appear normal. The cbf5-1 mutant cells are deficient in cytoplasmic ribosomal subunits at both permissive and restrictive temperatures. A high-copy-number yeast genomic library was screened for genes that suppress the cbf5-1 temperature-sensitive growth phenotype. SYC1 (suppressor of yeast cbf5-1) was identified as a multicopy suppressor of cbf5-1 and subsequently was found to be identical to RRN3, an RNA polymerase I transcription factor. A cbf5delta null mutant is not rescued by plasmid pNOY103 containing a yeast 35S rRNA gene under the control of a Pol II promoter, indicating that Cbf5p has one or more essential functions in addition to its role in rRNA transcription.

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 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 MRP and rRNA processing

RNase MRP is a ribonucleoprotein enzyme with a structure similar to RNase P. It is required for normal processing of precursor rRNA, cleaving it in the Internal Transcribed Spacer 1.

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.

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.