Ribosome biogenesis in yeast

Porphyra (Bangiophyceae) Transcriptomes Provide Insights Into Red Algal Development And Metabolism

The red seaweed Porphyra (Bangiophyceae) and related Bangiales have global economic importance. Here, we report the analysis of a comprehensive transcriptome comprising ca. 4.7 million expressed sequence tag (EST) reads from P. umbilicalis (L.) J. Agardh and P. purpurea (Roth) C. Agardh (ca. 980 Mbp of data generated using 454 FLX pyrosequencing). These ESTs were isolated from the haploid gametophyte (blades from both species) and diploid conchocelis stage (from P. purpurea). In a bioinformatic analysis, only 20% of the contigs were found to encode proteins of known biological function. Comparative analysis of predicted protein functions in mesophilic (including Porphyra) and extremophilic red algae suggest that the former has more putative functions related to signaling, membrane transport processes, and establishment of protein complexes. These enhanced functions may reflect general mesophilic adaptations. A near-complete repertoire of genes encoding histones and ribosomal proteins was identified, with some differentially regulated between the blade and conchocelis stage in P. purpurea. This finding may reflect specific regulatory processes associated with these distinct phases of the life history. Fatty acid desaturation patterns, in combination with gene expression profiles, demonstrate differences from seed plants with respect to the transport of fatty acid/lipid among subcellular compartments and the molecular machinery of lipid assembly. We also recovered a near-complete gene repertoire for enzymes involved in the formation of sterols and carotenoids, including candidate genes for the biosynthesis of lutein. Our findings provide key insights into the evolution, development, and biology of Porphyra, an important lineage of red algae.

Performance of the COX1 gene as a marker for the study of metabolically active Pezizomycotina and Agaricomycetes fungal communities from the analysis of soil RNA

In temperate forest soils, filamentous ectomycorrhizal and saprotrophic fungi affiliated to the Agaricomycetes and Pezizomycotina contribute to key biological processes. The diversity of soil fungal communities is usually estimated by studying molecular markers such as nuclear ribosomal gene regions amplified from soil-extracted DNA. However, this approach only reveals the presence of the corresponding genomic DNA in the soil sample and may not reflect the diversity of the metabolically active species. To circumvent this problem, we investigated the performance of the mitochondrial cytochrome c oxidase 1 (COX1)-encoding gene as a fungal molecular marker for environmental RNA-based studies. We designed PCR primers to specifically amplify Agaricomycetes and Pezizomycotina COX1 partial sequences and amplified them from both soil DNA and reverse-transcribed soil RNA. As a control, we also amplified the nuclear internal transcribed spacer ribosomal region from soil DNA. Fungal COX1 sequences were readily amplified from soil-extracted nucleic acids and were not significantly contaminated by nontarget sequences. We show that the relative abundance of fungal taxonomic groups differed between the different sequence data sets, with for example ascomycete COX1 sequences being more abundant among sequences amplified from soil DNA than from soil cDNAs.

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.

Eukaryotic ribosomal RNA determinants of aminoglycoside resistance and their role in translational fidelity

Recent studies of prokaryotic ribosomes have dramatically increased our knowledge of ribosomal RNA (rRNA) structure, functional centers, and their interactions with antibiotics. However, much less is known about how rRNA function differs between prokaryotic and eukaryotic ribosomes. The core decoding sites are identical in yeast and human 18S rRNAs, suggesting that insights obtained in studies with yeast rRNA mutants can provide information about ribosome function in both species. In this study, we examined the importance of key nucleotides of the 18S rRNA decoding site on ribosome function and aminoglycoside susceptibility in Saccharomyces cerevisiae cells expressing homogeneous populations of mutant ribosomes. We found that residues G577, A1755, and A1756 (corresponding to Escherichia coli residues G530, A1492, and A1493, respectively) are essential for cell viability. We also found that residue G1645 (A1408 in E. coli) and A1754 (G1491 in E. coli) both make significant and distinct contributions to aminoglycoside resistance. Furthermore, we found that mutations at these residues do not alter the basal level of translational accuracy, but influence both paromomycin-induced misreading of sense codons and readthrough of stop codons. This study represents the most comprehensive mutational analysis of the eukaryotic decoding site to date, and suggests that many fundamental features of decoding site function are conserved between prokaryotes and eukaryotes.

Translational machinery of the chaetognath Spadella cephaloptera: a transcriptomic approach to the analysis of cytosolic ribosomal protein genes and their expression

Background

Chaetognaths, or arrow worms, are small marine, bilaterally symmetrical metazoans. The objective of this study was to analyse ribosomal protein (RP) coding sequences from a published collection of expressed sequence tags (ESTs) from a chaetognath (Spadella cephaloptera) and to use them in phylogenetic studies.

Results

This analysis has allowed us to determine the complete primary structures of 23 out of 32 RPs from the small ribosomal subunit (SSU) and 32 out of 47 RPs from the large ribosomal subunit (LSU). Ten proteins are partially determined and 14 proteins are missing. Phylogenetic analyses of concatenated RPs from six animals (chaetognath, echinoderm, mammalian, insect, mollusc and sponge) and one fungal taxa do not resolve the chaetognath phylogenetic position, although each mega-sequence comprises approximately 5,000 amino acid residues. This is probably due to the extremely biased base composition and to the high evolutionary rates in chaetognaths. However, the analysis of chaetognath RP genes revealed three unique features in the animal Kingdom. First, whereas generally in animals one RP appeared to have a single type of mRNA, two or more genes are generally transcribed for one RP type in chaetognath. Second, cDNAs with complete 5'-ends encoding a given protein sequence can be divided in two sub-groups according to a short region in their 5'-ends: two novel and highly conserved elements have been identified (5'-TAATTGAGTAGTTT-3' and 5'-TATTAAGTACTAC-3') which could correspond to different transcription factor binding sites on paralog RP genes. And, third, the overall number of deduced paralogous RPs is very high compared to those published for other animals.

Conclusion

These results suggest that in chaetognaths the deleterious effects of the presence of paralogous RPs, such as apoptosis or cancer are avoided, and also that in each protein family, some of the members could have tissue-specific and extra-ribosomal functions. These results are congruent with the hypotheses of an allopolyploid origin of this phylum and of a ribosome heterogeneity.

The exonuclease ISG20 mainly localizes in the nucleolus and the Cajal (Coiled) bodies and is associated with nuclear SMN protein-containing complexes

We have previously shown that ISG20, an interferon (IFN)-induced gene, encodes a 3' to 5' exoribonuclease member of the DEDD superfamily of exonucleases. ISG20 specifically degrades single-stranded RNA. In this report, using immunofluorescence analysis, we demonstrate that in addition to a diffuse cytoplasmic and nucleoplasmic localization, the endogenous ISG20 protein was present in the nucleus both in the nucleolus and in the Cajal bodies (CBs). In addition, we show that the ectopic expression of the CBs signature protein, coilin, fused to the red fluorescent protein (coilin-dsRed) increased the number of nuclear dots containing both ISG20 and coilin-dsRed. Using electron microcopy analysis, ISG20 appeared principally concentrated in the dense fibrillar component of the nucleolus, the major site for rRNA processing. We also present evidences that ISG20 was associated with survival of motor neuron (SMN)-containing macromolecular nuclear complexes required for the biogenesis of various small nuclear ribonucleoproteins. Finally, we demonstrate that ISG20 was associated with U1 and U2 snRNAs, and U3 snoRNA. The accumulation of ISG20 in the CBs after IFN treatment strongly suggests its involvement in a new route for IFN-mediated inhibition of protein synthesis by modulating snRNA and rRNA maturation.

Genetic and forma specialis diversity in Blumeria graminis of cereals and its implications for host-pathogen co-evolution

SUMMARY The grass powdery mildew fungus, Blumeria graminis is classified into eight formae speciales (ff.spp.) based on strict host specialization. However, evidence suggests that host ranges extend to more than one genus and are particularly diverse among samples from the Middle East, the proposed centre of origin and diversification of crop plants. This study investigated whether geographical origin, host species or both determine the genetic variation in B. graminis that is found in cereals, sampled from Europe, Asia and North America, and whether there is any evidence for co-evolution between pathogen and host. Phylogenetic analysis of nucleotide sequence variation within the ribosomal DNA Internal Transcribed Spacer (ITS) regions and the beta-tubulin (tub2) gene gives rise to two dendrograms with different topologies. In both trees, isolates of B. graminis from cultivated cereals are grouped according to their principal host genus. This grouping was supported by amplified fragment length polymorphism (AFLP) analysis and cross-infectivity tests. However, there was no evidence of co-evolution. There was far greater divergence between ff.spp. in tub2 sequences than ITS regions and a faster rate of mutation of tub2, especially in the third base position of exons. It is proposed that variation in the rDNA-ITS regions is constrained either by their functional role in the processing of rDNA precursor molecules or by concerted evolution, hence limiting their use in phylogenetic studies. AFLP data suggests an overall lack of correlation between geographical and genetic distances. This may be related to the long distance dispersal exhibited by B. graminis.

Identification and analysis of over 2000 ribosomal protein pseudogenes in the human genome

Mammals have 79 ribosomal proteins (RP). Using a systematic procedure based on sequence-homology, we have comprehensively identified pseudogenes of these proteins in the human genome. Our assignments are available at http://www.pseudogene.org or http://bioinfo.mbb.yale.edu/genome/pseudogene. In total, we found 2090 processed pseudogenes and 16 duplications of RP genes. In relation to the matching parent protein, each of the processed pseudogenes has an average relative sequence length of 97% and an average sequence identity of 76%. A small number (258) of them do not contain obvious disablements (stop codons or frameshifts) and, therefore, could be mistaken as functional genes, and 178 are disrupted by one or more repetitive elements. On average, processed pseudogenes have a longer truncation at the 5' end than the 3' end, consistent with the target-primed-reverse-transcription (TPRT) mechanism. Interestingly, on chromosome 16, an RPL26 processed pseudogene was found in the intron region of a functional RPS2 gene. The large-scale distribution of RP pseudogenes throughout the genome appears to result, chiefly, from random insertions with the numbers on each chromosome, consequently, proportional to its size. In contrast to RP genes, the RP pseudogenes have the highest density in GC-intermediate regions (41%-46%) of the genome, with the density pattern being between that of LINEs and Alus. This can be explained by a negative selection theory as we observed that GC-rich RP pseudogenes decay faster in GC-poor regions. Also, we observed a correlation between the number of processed pseudogenes and the GC content of the associated functional gene, i.e., relatively GC-poor RPs have more processed pseudogenes. This ranges from 145 pseudogenes for RPL21 down to 3 pseudogenes for RPL14. We were able to date the RP pseudogenes based on their sequence divergence from present-day RP genes, finding an age distribution similar to that for Alus. The distribution is consistent with a decline in retrotransposition activity in the hominid lineage during the last 40 Myr. We discuss the implications for retrotransposon stability and genome dynamics based on these new findings.

A novel conserved RNA-binding domain protein, RBD-1, is essential for ribosome biogenesis

Synthesis of the ribosomal subunits from pre-rRNA requires a large number of trans-acting proteins and small nucleolar ribonucleoprotein particles to execute base modifications, RNA cleavages, and structural rearrangements. We have characterized a novel protein, RNA-binding domain-1 (RBD-1), that is involved in ribosome biogenesis. This protein contains six consensus RNA-binding domains and is conserved as to sequence, domain organization, and cellular location from yeast to human. RBD-1 is essential in Caenorhabditis elegans. In the dipteran Chironomus tentans, RBD-1 (Ct-RBD-1) binds pre-rRNA in vitro and anti-Ct-RBD-1 antibodies repress pre-rRNA processing in vivo. Ct-RBD-1 is mainly located in the nucleolus in an RNA polymerase I transcription-dependent manner, but it is also present in discrete foci in the interchromatin and in the cytoplasm. In cytoplasmic extracts, 20-30% of Ct-RBD-1 is associated with ribosomes and, preferentially, with the 40S ribosomal subunit. Our data suggest that RBD-1 plays a role in structurally coordinating pre-rRNA during ribosome biogenesis and that this function is conserved in all eukaryotes.

The nucle(ol)ar Tif6p and Efl1p are required for a late cytoplasmic step of ribosome synthesis

Deletion of elongation factor-like 1 (Efl1p), a cytoplasmic GTPase homologous to the ribosomal translocases EF-G/EF-2, results in nucle(ol)ar pre-rRNA processing and pre-60S subunits export defects. Efl1p interacts genetically with Tif6p, a nucle(ol)ar protein stably associated with pre-60S subunits and required for their synthesis and nuclear exit. In the absence of Efl1p, 50% of Tif6p is relocated to the cytoplasm. In vitro, the GTPase activity of Efl1p is stimulated by 60S, and Efl1p promotes the dissociation of Tif6p-60S complexes. We propose that Tif6p binds to the pre-60S subunits in the nucle(ol)us and escorts them to the cytoplasm where the GTPase activity of Efl1p triggers a late structural rearrangement, which facilitates the release of Tif6p and its recycling to the nucle(ol)us.

Phosphorylation and N-terminal region of yeast ribosomal protein P1 mediate its degradation, which is prevented by protein P2

The stalk proteins P1 and P2, which are fundamental for ribosome activity, are the only ribosomal components for which there is a cytoplasmic pool. Accumulation of these two proteins is differentially regulated in Saccharomyces cerevisiae by degradation. In the absence of P2, the amount of P1 is drastically reduced; in contrast, P2 proteins are not affected by a deficiency in P1. However, association with P2 protects P1 proteins. The half-life of P1 is a few minutes, while that of P2 is several hours. The proteasome is not involved in the degradation of P1 proteins. The different sensitivity to degradation of these two proteins is associated with two structural features: phosphorylation and N-terminus structure. A phosphorylation site at the C-terminus is required for P1 proteolysis. P2 proteins, despite being phosphorylated, are protected by their N-terminal peptide. An exchange of the first five amino acids between the two types of protein makes P1 resistant and P2 sensitive to degradation.

RNase L-independent specific 28S rRNA cleavage in murine coronavirus-infected cells

We characterized a novel 28S rRNA cleavage in cells infected with the murine coronavirus mouse hepatitis virus (MHV). The 28S rRNA cleavage occurred as early as 4 h postinfection (p.i.) in MHV-infected DBT cells, with the appearance of subsequent cleavage products and a decrease in the amount of intact 28S rRNA with increasing times of infection; almost all of the intact 28S rRNA disappeared by 24 h p.i. In contrast, no specific 18S rRNA cleavage was detected in infected cells. MHV-induced 28S rRNA cleavage was detected in all MHV-susceptible cell lines and all MHV strains tested. MHV replication was required for the 28S rRNA cleavage, and mature cytoplasmic 28S rRNA underwent cleavage. In certain combination of cells and viruses, pretreatment of virus-infected cells with interferon activates a cellular endoribonuclease, RNase L, that causes rRNA degradation. No interferon was detected in the inoculum used for MHV infection. Addition of anti-interferon antibody to MHV-infected cells did not inhibit 28S rRNA cleavage. Furthermore, 28S rRNA cleavage occurred in an MHV-infected mouse embryonic fibroblast cell line derived from RNase L knockout mice. Thus, MHV-induced 28S rRNA cleavage was independent of the activation of RNase L. MHV-induced 28S rRNA cleavage was also different from apoptosis-related rRNA degradation, which usually occurs concomitantly with DNA fragmentation. In MHV-infected 17Cl-1 cells, 28S rRNA cleavage preceded DNA fragmentation by at least 18 h. Blockage of apoptosis in MHV-infected 17Cl-1 cells by treatment with a caspase inhibitor did not block 28S rRNA cleavage. Furthermore, MHV-induced 28S rRNA cleavage occurred in MHV-infected DBT cells that do not show apoptotic signs, including activation of caspase-3 and DNA fragmentation. Thus, MHV-induced 28S rRNA cleavage appeared to differ from any rRNA degradation mechanism described previously.

Inheritance of suppressors of the drug sensitivity of a NSR1 deleted yeast strain

The NSR1 gene product is involved in ribosomal RNA production and ribosome assembly in Saccharomyces cerevisiae. Yeast strains carrying a deletion of the NSR1 gene have a defect in rRNA processing, an aberrant ribosome profile and are sensitive to the drug paromomycin. This paper reports the isolation and characterization of spontaneous suppressors of the paromomycin sensitivity. Such suppressors could be isolated at very high frequency and do not exhibit straightforward single-gene inheritance patterns. The suppressors are not influenced by non-Mendelian factors such as psi or rho. Through a replacement of chromosomal rDNA with a plasmid rDNA system, I show that suppression of paromomycin sensitivity is mediated by rDNA. Swapping wild-type plasmid rDNA for chromosomal rDNA can reverse the suppression, but the effect does not appear to be due to amplification of rDNA or amplification of a pre-existing mutant rDNA copy.

The complete external transcribed spacer of 18S-26S rDNA: amplification and phylogenetic utility at low taxonomic levels in asteraceae and closely allied families

For molecular phylogenetic reconstruction of some intrageneric groups of plants, a DNA region is needed that evolves more rapidly than the internal transcribed spacer (ITS) of the 18S-26S nuclear ribosomal DNA (nrDNA) repeat. If the region identified is nuclear, it would also be desirable for it to undergo rapid concerted evolution to eliminate problems with coalescence. The external transcribed spacer (ETS) of the nrDNA repeat has shown promise for intrageneric phylogenetic reconstruction, but only the 3' end of the region has been utilized for phylogenetic reconstruction and "universal" primers for PCR amplification have been elusive. We present a method for reliably amplifying and sequencing the entire ETS throughout Asteraceae and some closely allied families. We also show that the ETS is more variable and phylogenetically informative than the ITS in three disparate genera of Asteraceae-Argyranthemum (tribe Anthemideae), Asteriscus (tribe Inuleae), and Helianthus (tribe Heliantheae). The full ETS was amplified using a primer (ETS1f) within the intergenic spacer in combination with a primer (18S-2L) in the 5' end of the highly conserved 18S gene. ETS1f was designed to correspond to a highly conserved region found in Helianthus and Crepis, which are in separate subfamilies of Asteraceae. ETS1f/18S-2L primed in all of the tribes of Asteraceae as well as exemplar taxa from Campanulaceae, Goodeniaceae, and Calyceraceae. For both Argyranthemum and Asteriscus, we were able to directly sequence the ETS PCR products when a single band was produced. When multiple bands were produced, we gel-purified and occasionally cloned the band of interest before sequencing. Although PCR produced single bands for Helianthus species, it was necessary to clone Helianthus amplifications prior to sequencing due to multiple intragenomic ETS repeat types. Alignment of ETS sequences for Argyranthemum and Asteriscus was straightforward and unambiguous despite some subrepeat structure in the 5' end. For Helianthus, different numbers of large tandem subrepeats in different species required analysis of the orthology of the subrepeats prior to alignment. In all three genera, the ETS provided more informative variation for phylogenetic reconstruction and allowed better resolution of relationships than the ITS. Although cloned sequences from Helianthus differed, intragenomic clones consistently formed clades. This result indicated that concerted evolution was proceeding rapidly enough in ETS that species-specific phylogenetic signal was retained. It should be now be possible to use the entire ETS for phylogenetic reconstruction of recently diverged lineages in Asteraceae and at least three other families (approximately 26,000 species or about 8% of all angiosperms).

Structural equivalence in the transcribed spacers of pre-rRNA transcripts in Schizosaccharomyces pombe

The structure of the internal transcribed spacer 2 (ITS2) in Schizosaccharomyces pombe was re-evaluated with respect to phylogenetically conserved features in yeasts, features in other transcribed spacer regions as well as the binding of transacting factors which potentially play a role in ribosomal maturation. Computer analyses and probes for nuclease protection indicate a very simple core structure consisting of a single extended hairpin which includes the interacting termini of the mature 5.8S and 25S rRNAs. Comparisons with ITS2 sequences in greatly diverging organisms indicate that the same feature also can be recognized. This is especially clear in organisms that contain very short sequences in which the putative structures are much less ambiguous. Diversity between organisms is the result of changes in hairpin length as well as the addition of branched helices. Protein binding and gel retardation studies with the S.pombe ITS2 further indicate that, as observed in the 3" external transcribed spacer (ETS) and ITS1 regions, 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 suggest that the spacer regions all may act in a similar fashion, not only to organize the maturing terminal sequences, but also serve to organize specific soluble factors possibly acting with snoRNAs or in a manner which is analogous with that of the free snoRNPs.

Nucleolar localization of early tRNA processing

There is little information as to the location of early tRNA biosynthesis. Using fluorescent in situ hybridization in the budding yeast, Saccharomyces cerevisiae, examples of nuclear pre-tRNAs are shown to reside primarily in the nucleoli. We also probed the RNA subunit of RNase P. The majority of the signal from RNase P probes was nucleolar, with less intense signals in the nucleoplasm. These results demonstrate that a major portion of the tRNA processing pathway is compartmentalized in nucleoli with rRNA synthesis and ribosomal assembly. The spatial juxtaposition suggests the possibility of direct coordination between tRNA and ribosome biosynthesis.

Reconstitution of functional eukaryotic ribosomes from Dictyostelium discoideum ribosomal proteins and RNA

40 and 60 S ribosomal subunits have been reconstituted in vitro from purified ribosomal RNA and ribosomal proteins of Dictyostelium discoideum. The functionality of the reconstituted ribosomes was demonstrated in in vitro mRNA-directed protein synthesis. The reassembly proceeded well with immature precursors of ribosomal RNA but poorly if at all with mature cytoplasmic RNA species. Reassembly also required a preparation of small nuclear RNA(s), acting as morphopoietic factor(s).

Synthesis of functional eukaryotic ribosomal RNAs in trans: development of a novel in vivo rDNA system for dissecting ribosome biogenesis

Active 18S and 25S ribosomal RNAs were produced in trans in yeast, from plasmids containing RNA polymerase II transcription signals and rDNA fragments with unique hybridization tags. Analyses were carried out in cells with temperature-sensitive RNA polymerase I. Functional rRNAs were derived from separate 18S and 5.8/25S rRNA coding units, however, active 25S rRNA could be produced only by cotranscription with 5.8S rRNA. The results demonstrate that the polycistronic organization of the large rDNA operon is not required for successful processing of rRNA or assembly of functional ribosomes. The split operon system should facilitate future efforts to dissect eukaryotic ribosome biogenesis.

RIC1, a novel gene required for ribosome synthesis in Saccharomyces cerevisiae

We isolated a temperature-sensitive mutant of Saccharomyces cerevisiae in which transcription both of ribosomal protein genes and of ribosomal RNA is defective at the non-permissive temperature. Temperature-sensitivity for growth is recessive and segregates 2:2. The wild type gene, termed RIC1 (for ribosome control) was cloned by complementation of the temperature-sensitive phenotype from a genomic DNA library based on the CEN plasmid. RIC1 encodes a protein of 1056 amino acid (aa) residues including a putative nuclear localization sequence. Data base searches revealed that RIC1 is a novel gene and predicted aa sequence share some sequence similarity with viral transcriptional regulatory proteins.

Cytokinin induction of RNA polymerase I transcription in Arabidopsis thaliana

RNA polymerase I (pol I) transcribes the repeated genes that encode the precursor of 17-18, 5.8, and 25-28 S ribosomal RNA (rRNA). Pol I transcription is up-regulated in growing cells and down-regulated in quiescent cells, presumably reflecting the demand for ribosomes and protein synthesis. However, the signal transduction pathways responsible for pol I regulation are poorly understood. We tested the effects of exogenously applied plant hormones on promoter-dependent rRNA transcription in Arabidopsis thaliana. Gibberellic acid, abscisic acid, auxin, and ethylene had no detectable effect on rRNA transcription, but kinetin (a cytokinin) stimulated rRNA transcription within 1 h of treatment. Increased steady-state levels of accurately initiated rRNA transcripts, detected by S1 nuclease protection, were paralleled by increased levels of nascent rRNA transcripts in isolated nuclei. Therefore, the primary effect of cytokinin appears to be at the level of transcription initiation rather than rRNA stability. Pol I accounts for approximately 34% of total nuclear transcription in untreated plants and approximately 60% following cytokinin treatment. The specific responsiveness of pol I transcription to kinetin suggests that cytokinins may act as general regulators of protein synthetic capacity and growth status in plant cells.

18S rRNA processing requires the RNA helicase-like protein Rrp3

We report the identification of a new gene, RRP3 (rRNA processing), which is required for pre-rRNA processing. Rrp3 is a 60.9 kDa protein that is required for maturation of the 35S primary transcript of pre-rRNA and is required for cleavages leading to mature 18S RNA. RRP3 was identified in a PCR screen for DEAD box genes. DEAD box genes are part of a large family of proteins homologous to the eukaryotic transcription factor elF-4a. Most of these proteins are RNA-dependent ATPases and some of them have RNA helicase activity. This is the third yeast DEAD box protein that has been shown to be involved in rRNA assembly, but the only one required for the processing of 18S RNA. Mutants of the two other putative helicases, Spb4 and Drsl, both show processing defects in 25S rRNA maturation. In strains where Rrp3 is depleted, 35S precursor RNA is improperly processed. Cleavage normally occurs at sites A0O, Al and A2, but in the Rrp3 depletion stain cleavage occurs between A2 and B1. Rrp3 has been purified to homogeneity and has a weak RNA-dependent ATPase activity which is not specific for rRNA.

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.

Nuclear and nucleolar targeting of human ribosomal protein S6

Chimeric proteins were constructed to define the nuclear localization signals (NLSs) of human ribosomal protein S6. The complete cDNA sequence, different cDNA fragments and oligonucleotides of the human ribosomal proteins S6, respectively, were joined to the 5' end of the entire LacZ gene of Escherichia coli by using recombinant techniques. The hybrid genes were transfected into L cells, transiently expressed, and the intracellular location of the fusion proteins was determined by their beta-galactosidase activity. Three NLSs were identified in the C-terminal half of the S6 protein. Deletion mutagenesis demonstrated that a single NLS is sufficient for targeting the corresponding S6-beta-galactosidase chimera into the nucleus. Removal of all three putative NLSs completely blocked the nuclear import of the resulting S6-beta-galactosidase fusion protein, which instead became evenly distributed in the cytoplasm. Chimeras containing deletion mutants of S6 with at least one single NLS or unmodified S6 accumulated in the nucleolus. Analysis of several constructs reveals the existence of a specific domain that is essential but not sufficient for nucleolar accumulation of S6.

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.

The accuracy center of a eukaryotic ribosome

Mutations in yeast ribosomal proteins and ribosomal RNAs have been shown to affect translational fidelity. These mutations include: proteins homologous to Escherichia coli's S4, S5, and S12; a eukaryote specific ribosomal protein; yeast ribosomal rRNA alterations at positions corresponding to 517, 912, and 1054 in 16S E. coli rRNA and to 2658 in the sarcin-ricin domain of 23S E. coli rRNA. Overall there appears to be a remarkable conservation of the accuracy center throughout evolution.

The 18S rRNA dimethylase Dim1p is required for pre-ribosomal RNA processing in yeast

The m6(2)A1779m6(2)A1780 dimethylation at the 3' end of the small subunit rRNA has been conserved in evolution from bacteria to eukaryotes. The yeast 18S rRNA dimethylase gene DIM1 was cloned previously by complementation in Escherichia coli and shown to be essential for viability in yeast. A conditional GAL10::dim1 strain was constructed to allow the depletion of Dim1p from the cell. During depletion, dimethylation of the pre-rRNA is progressively inhibited and pre-rRNA processing at cleavage sites A1 and A2 is concomitantly lost. In consequence, the mature 18S rRNA and its 20S precursor drastically underaccumulate. This has the effect of preventing the synthesis of nonmethylated rRNA. To test whether the processing defect is a consequence of the absence of the dimethylated nucleotides or of the Dim1p dimethylase itself, a cis-acting mutation was created in which both dimethylated adenosines are replaced by guanosine residues. Methylation cannot occur on this mutant pre-rRNA, but no clear pre-rRNA processing defect is seen. Moreover, methylation of the wild-type pre-rRNA predominantly occurs after cleavage at sites A1 and A2. This shows that formation of the m6(2)A1779m6(2)A1780 dimethylation is not required for pre-rRNA processing. We propose that the binding of Dim1p to the pre-ribosomal particle is monitored to ensure that only dimethylated pre-rRNA molecules are processed to 18S rRNA.

Sequence analysis of a 30 kb DNA segment from yeast chromosome XIV carrying a ribosomal protein gene cluster, the genes encoding a plasma membrane protein and a subunit of replication factor C, and a novel putative serine/threonine protein kinase gene

We have determined the nucleotide sequence of a 30 kb fragment of chromosome XIV of Saccharomyces cerevisiae. The sequence revealed the presence of 19 open reading frames (ORFs) longer than 300 bp. NO422 and NO425 correspond to the split ribosomal protein genes encoding S16A and rp28, respectively, NO450 displays a striking similarity with serine/threonine protein kinase genes, in particular with STE20, and therefore may encode a novel member of this protein family. NO453 is the longest ORF in this DNA segment, having a size of 4908 bp, but its function is not yet known. NO530 encodes the plasma membrane protein Mid1p and NO533 corresponds to the gene coding for a 40 kDa subunit of replication factor C. The remaining ORFs show weak or no homology with proteins in the data bases.

Sequence analysis of a 78.6 kb segment of the left end of Saccharomyces cerevisiae chromosome II

We report the sequence analysis of a 78,601 bp DNA segment on the left arm of chromosome II of Saccharomyces cerevisiae. This 78.6 kb segment spans the region from the start of a subtelomeric Y' element up to the ILS1 gene. It contains 49 open reading frames (ORFs) with more than 100 amino acids length including 14 internal and five overlapping ORFs. The gene density, excluding the internal ORFs, was calculated as one ORF per 2.2 kb. Eight ORFs (PKC1, TyA, TyB, ATP1, ROX3, RPL17a, PET112 and ILS1) correspond to previously characterized genes. ORF YBL0718 was identified as CDC27; YBL0706 as TEL1. Four other ORFs show strong similarities to already known genes. The gene product of YBL0838 is 60% identical to the ribosomal protein RPL32 from rat, mouse and man. YBL0701 encodes a protein with significant similarity to the initiation factor eIF2 associated p67 glycoprotein from rat. Eight ORFs were disrupted and the resulting yeast strains analysed with respect to their phenotype.

The duplicated Saccharomyces cerevisiae gene SSM1 encodes a eucaryotic homolog of the eubacterial and archaebacterial L1 ribosomal proteins

A previously unknown Saccharomyces cerevisiae gene, SSM1a, was isolated by screening for high-copy-number suppressors of thermosensitive mutations in the RNA14 gene, which encodes a component from the polyadenylation complex. The SSM1 a gene codes for a 217-amino-acid protein, Ssm1p, which is significantly homologous to eubacterial and archaebacterial ribosomal proteins of the L1 family. Comparison of the Ssm1p amino acid sequence with that of eucaryotic polypeptides with unknown functions reveals that Ssm1p is the prototype of a new eucaryotic protein family. Biochemical analysis shows that Ssm1p is a structural protein that forms part of the largest 60S ribosomal subunit, which does not exist in a pool of free proteins. SSM1 a is duplicated. The second gene copy, SSM1b, is functional and codes for an identical and functionally interchangeable Ssm1p protein. In wild-type cells, SSM1b transcripts accumulate to twice the level of SSM1a transcripts, suggesting that SSM1b is responsible for the majority of the Ssm1p pool. Haploid cells lacking both SSM1 genes are inviable, demonstrating that, in contrast with its Escherichia coli homolog, Ssm1p is an essential ribosomal protein. Deletion of the most expressed SSM1b gene leads to a severe decrease in the level of SSM1 transcript, associated with a reduced growth rate. Polysome profile analysis suggests that the primary defect caused by the depletion in Ssm1p is at the level of translation initiation.

Cytoplasmic mRNA-protein interactions in eukaryotic gene expression

Post-transcriptional mechanisms contribute in many important ways to the overall control and regulation of gene expression, and in doing so employ a veritable army of proteins that bind a wide range of targets in messenger RNA (mRNA). The full range of these RNA-protein interactions is only just beginning to emerge, and much remains to be learned about the mechanisms underlying the rapidly increasing number of regulatory systems now being described.

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

We have extended the system of Nogi et al. (Proc. Natl. Acad. Sci. USA 88, 1991, 3962-3966) for transcription of rRNA from an RNA polymerase II promoter in strains lacking functional RNA polymerase I. In our strains two differentially marked rRNA transcription units can be expressed alternately. Using this system we have shown that the A2 processing site in the internal transcribed spacer 1 (ITS1) of the pre-rRNA is dispensable. According to the accepted processing scheme, the A2 site serves to separate the parts of the primary rRNA transcript that are destined for incorporation into the two ribosomal subunits. However, we have found that, when A2 is impaired, separation of the small and large subunit rRNAs occurs at a processing site further downstream in ITS1, indicating that alternate pathways for ITS1 processing exist. Short deletions in the A2 region still allow residual processing at the A2 site. Mapping of the cleavage sites in such deletion transcripts suggests that sequences downstream of the A2 site are used for determining the position of the cleavage.

Yeast NOP2 encodes an essential nucleolar protein with homology to a human proliferation marker

We have isolated a gene (NOP2) encoding a nucleolar protein during a search for previously unidentified nuclear proteins in the yeast Saccharomyces cerevisiae. The protein encoded by NOP2 (Nop2p) has a predicted molecular mass of 70 kD, migrates at 90 kD by SDS-PAGE, and is essential for cell viability. Nop2p shows significant amino acid sequence homology to a human proliferation-associated nucleolar protein, p120. Approximately half of Nop2p exhibits 67% amino acid sequence identity to p120. Analysis of subcellular fractions indicates that Nop2p is located primarily in the nucleus, and nuclear fractionation studies suggest that Nop2p is associated with the nucleolus. Indirect immunofluorescence localization of Nop2p shows a nucleolar-staining pattern, which is heterogeneous in appearance, and a faint staining of the cytoplasm. The expression of NOP2 during the transition from stationary phase growth arrest to rapid growth was measured, and compared to the expression of TCM1, which encodes the ribosomal protein L3. Nop2p protein levels are markedly upregulated during the onset of growth, compared to the levels of ribosomal protein L3, which remain relatively constant. NOP2 mRNA levels also increase during the onset of growth, accompanied by a similar increase in the levels of TCM1 mRNA. The consequences of overexpressing NOP2 from the GAL10 promoter on a multicopy plasmid were investigated. Although NOP2 overexpression produced no discernible growth phenotype and had no effect on ribosome subunit synthesis, overexpression was found to influence the morphology of the nucleolus, as judged by electron microscopy. Overexpression caused the nucleolus to become detached from the nuclear envelope and to become more rounded and/or fragmented in appearance. These findings suggest roles for NOP2 in nucleolar function during the onset of growth, and in the maintenance of nucleolar structure.

Sequence and structural elements critical for U8 snRNP function in Xenopus oocytes are evolutionarily conserved

We have generated mutants in Xenopus U8 RNA, a nucleolar snRNA required for the maturation of 5.8S and 28S rRNAs, to identify sequences and structural domains essential for RNA stability, particle assembly, and function of the U8 RNP. Activity of the mutants was assayed by microinjection of in vitro-synthesized U8 RNAs into the cytoplasm of Xenopus oocytes. Most of the mutant RNAs were stable, bound fibrillarin, a protein common to several of the nucleolar-specific snRNPs, and became hypermethylated. Although hypermethylation of the 5' cap of U8 RNA and fibrillarin binding can occur in either the cytoplasmic or nuclear compartment of Xenopus oocytes, neither is required for nuclear import. We find that the trimethylguanosine cap, although present on the endogenous U8 RNA, is not essential for stability, particle assembly, or functioning of U8 in the coordinate processing of pre-rRNA at sites 3' of 28S and 5' of 5.8S RNA. Several conserved single- and double-stranded sequences within the 5' domain of U8 RNA are essential for function.

Transcription regulation of ribosomal protein genes at different growth rates in continuous cultures of Kluyveromyces yeasts

We have investigated the relationship between the growth rate of two Kluyveromyces strains that differ in their maximum growth rate, namely K. lactis (mumax = 0.5 h-1) and K. marxianus (mumax = 1.1 h-1), and the transcription rate of ribosomal protein (rp) genes in these strains. The growth rate of either strain was varied by culturing the cells in a chemostat under conditions of glucose limitation at different dilution rates. Although the steady-state levels of transcription of the rp-genes of both Kluyveromyces strains were tightly coupled to the cellular growth rate, no clear relationship between the level of rp-gene transcription and the amount of in vitro binding of the RAP1- and ABF1-like proteins to the promoters of these rp-genes was observed. Upon a sudden increase in the growth rate of a steady-state culture, the transcription of rp-genes of K. lactis showed a different response from that in K. marxianus. Whereas a substantial overexpression of the K. lactis rp-genes was found during at least 4-5 h, the level of expression of the K. marxianus rp-genes was almost immediately adjusted to the new growth rate.

Separate structural elements within internal transcribed spacer 1 of Saccharomyces cerevisiae precursor ribosomal RNA direct the formation of 17S and 26S rRNA

Structural features of Internal Transcribed Spacer 1 (ITS1) that direct its removal from Saccharomyces cerevisiae pre-rRNA during processing were identified by an initial phylogenetic approach followed by in vivo mutational analysis of specific structural elements. We found that S. cerevisiae ITS1 can functionally be replaced by the corresponding regions from the yeasts Torulaspora delbrueckii, Kluyveromyces lactis and Hansenula wingei, indicating that structural elements required in cis for processing are evolutionarily conserved. Despite large differences in size, all ITS1 regions conform to the secondary structure proposed by Yeh et al. [Biochemistry 29 (1990) 5911-5918], showing five domains (I-V; 5'-->3') of which three harbour an evolutionarily highly conserved element. Removal of most of domain II, including its highly conserved element, did not affect processing. In contrast, highly conserved nucleotides directly downstream of processing site A2 in domain III play a major role in production of 17S, but not 26S rRNA. Domain IV and V are dispensable for 17S rRNA formation although an alternative, albeit inefficient, processing route to mature 17S rRNA may be mediated by a conserved region in domain IV. Each of these two domains is individually sufficient for efficient production of 26S rRNA, suggesting two independent processing pathways. We conclude that ITS1 is organized into two functionally and structurally distinct halves.

The RNA of RNase MRP is required for normal processing of ribosomal RNA

We have isolated clones which complement the temperature sensitivity and abnormal rRNA processing pattern of the rrp2-2 mutant of Saccharomyces cerevisiae we previously described. DNA sequencing and restriction analysis demonstrated that all clones contain the NME1 gene encoding the RNA of the ribonucleprotein particle RNase MRP. Deletion analysis showed that the NME1 gene is responsible for the complementation of the rrp2-2 phenotype. A single base change was identified in the nme1 gene in the rrp2 mutant, confirming that the RRP2 and NME1 genes are identical. Our experiments therefore indicate that RNase MRP, in addition to its previously reported role in formation of RNA primers for mitochondrial DNA replication [Clayton, D. A. (1991) Trends Biochem. Sci. 16, 107-111], is involved in rRNA processing.

Expression and inheritance of the yeast extrachromosomal element psi do not depend on RNA polymerase I

The extrachromosomal element psi affects translation fidelity in the yeast Saccharomyces cerevisiae by increasing the efficiency of tRNA-mediated ochre suppression. The nature of the psi factor is unknown, although there is evidence that 3-microns circles from psi+ strains can be used to transform psi- cells to psi+. The 3-microns circles are extrachromosomal copies of the repeating ribosomal DNA unit, which is organized into two transcription units: the 35s rRNA precursor transcribed by RNA polymerase I, and the 5s rRNA transcribed by RNA polymerase III. We used a strain containing a mutation in RNA polymerase I to test whether psi expression and inheritance depended on RNA polI. Neither expression nor inheritance of psi requires intact RNA polI.

SnR31, snR32, and snR33: three novel, non-essential snRNAs from Saccharomyces cerevisiae

Genes for three novel yeast snRNAs have been identified and tested for essentiality. Partial sequence information was developed for RNA extracted from isolated nuclei and the respective gene sequences were discovered by screening a DNA sequence database. The three RNAs contain 222, 188 and 183 nucleotides and are designated snR31, snR32 and snR33, respectively. Each RNA is derived from a single copy gene. The SNR31 gene is adjacent to a gene for an unnamed protein associated with the cap-binding protein eIF-4E. The SNR32 gene is next to a gene for ribosomal protein L41 and the gene for SNR33 is on chromosome III, between two open reading frames with no known function. Genetic disruption analyses showed that none of the three snRNAs is required for growth. The new RNAs bring the number of non-spliceosomal snRNAs characterized thus far in S. cerevisiae to 14, of which only three are essential.

Known heat-shock proteins are not responsible for stress-induced rapid degradation of ribosomal protein mRNAs in yeast

We have previously shown that the heat-induced enhanced decay of yeast mRNAs encoding ribosomal proteins (rp-mRNAs) requires ongoing transcription during the heat treatment [Herruer et al. (1988) Nucl. Acids Res. 16, 7917]. In order to determine whether this requirement reflects the need for heat-shock protein (hsp), we analysed the effect of heat shock on rp-mRNA levels in several yeast strains in which each of the heat-shock genes encoding hsp26, hsp35 or hsp83 had been individually disrupted. In all three strains we still observed increased degradation of rp-mRNAs immediately after the temperature shift, demonstrating that hsp26, hsp35 and hsp83 are not required for this effect. Accelerated turnover of rp-mRNA was also found to occur upon raising the growth temperature of a mutant strain that contains a disruption of the gene specifying the heat-shock transcription factor and in wild-type yeast cells treated with canavanine, an arginine analogue that will be incorporated into all known hsps and that is known to cause misfolding of the polypeptide chain. Latter observation suggests that enhanced rp-mRNA decay is a more general stress-related phenomenon. Taken together, these data strongly indicate that the trans-acting factor required for the increase in the rate of degradation of rp-mRNAs upon stress is not one of the known yeast hsps.

Chromatin structures and transcription of rDNA in yeast Saccharomyces cerevisiae

The chromatin structure of yeast ribosomal DNA was analyzed in vivo by crosslinking intact cells with psoralen. We found that in exponentially growing cultures the regions coding for the 35S rRNA precursor fall into two distinct classes. One class was highly accessible to psoralen and associated with nascent RNAs, characteristic for transcriptionally active rRNA genes devoid of nucleosomes, whereas the other class showed a crosslinking pattern indistinguishable from that of bulk chromatin and was interpreted to represent the inactive rRNA gene copies. By crosslinking the same strain growing in complex or minimal medium, we have shown that yeast cells can modulate the proportion of active (non-nucleosomal) and inactive (nucleosomal) rRNA gene copies in response to variations in environmental conditions which suggests that yeast can regulate rRNA synthesis by varying the number of active gene copies, in contrast to the vertebrate cells studied so far. Whereas intergenic spacers flanking inactive rRNA gene copies are packaged in a regular nucleosomal array, spacers flanking active genes show an unusual crosslinking pattern suggesting a complex interaction of regulatory factors and histones with DNA.

Molecular cloning of a gene involved in glucose sensing in the yeast Saccharomyces cerevisiae

Cells of the yeast Saccharomyces cerevisiae display a wide range of glucose-induced regulatory phenomena, including glucose-induced activation of the RAS-adenylate cyclase pathway and phosphatidylinositol turnover, rapid post-translational effects on the activity of different enzymes as well as long-term effects at the transcriptional level. A gene called GGS1 (for General Glucose Sensor) that is apparently required for the glucose-induced regulatory effects and several ggs1 alleles (fdp1, byp1 and cif1) has been cloned and characterized. A GGS1 homologue is present in Methanobacterium thermoautotrophicum. Yeast ggs1 mutants are unable to grow on glucose or related readily fermentable sugars, apparently owing to unrestricted influx of sugar into glycolysis, resulting in its rapid deregulation. Levels of intracellular free glucose and metabolites measured over a period of a few minutes after addition of glucose to cells of a ggs1 delta strain are consistent with our previous suggestion of a functional interaction between a sugar transporter, a sugar kinase and the GGS1 gene product. Such a glucose-sensing system might both restrict the influx of glucose and activate several signal transduction pathways, leading to the wide range of glucose-induced regulatory phenomena. Deregulation of these pathways in ggs1 mutants might explain phenotypic defects observed in the absence of glucose, e.g. the inability of ggs1 diploids to sporulate.

Study of multiple fibrillarin mRNAs reveals that 3' end formation in Schizosaccharomyces pombe is sensitive to cold shock

Fibrillarin is a nucleolar protein which is associated with small nucleolar RNAs, and is required for pre-rRNA processing. We have cloned and characterized the gene encoding fibrillarin in the fission yeast Schizosaccharomyces pombe and we have followed its expression under various conditions. Fission yeast fibrillarin is a 305 amino-acid protein which appears to be highly conserved throughout evolution. In Xenopus, human or Saccharomyces cerevisiae, a single fibrillarin mRNA is detected while, in S. pombe a single copy gene encodes different mRNAs which differ at the 3' ends. Under normal growth conditions, two mRNAs of 1.1 and 1.35 kb are detected with the 1.1 kb being the most abundant. Both the total amount and relative abundance of these two mRNAs are strongly affected by exposure to low temperature, namely the 1.1 kb mRNA almost disappears while the 1.35 kb is less markedly diminished. A new species of 3.2 kb accumulates in the cell, which contains an unusually long 3' untranslated region of 2 kb. We have found that exposure of the cells to a cold shock has a profound effect on 3' end formation in S.pombe since the transcription of several other mRNAs is also capable of skipping the normal 3' end site to terminate at a further downstream site.

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.

Structural and putative regulatory sequences of Kluyveromyces ribosomal protein genes

The transcription of the majority of the ribosomal protein (rp) genes of Saccharomyces cerevisiae is activated by cis-acting elements, designated RPG boxes, which specifically bind the multifunctional protein RAP1 in vitro. To investigate to what extent this global system of transcription regulation has been conserved, we have isolated a number of rp genes of the related yeast species Kluyveromyces lactis and Kluyveromyces marxianus, whose counterparts in Saccharomyces are controlled by RAP1. The coding regions of these genes showed a sequence similarity of about 90% when compared to their Saccharomyces counterparts. In contrast, little or no sequence similarity was found between the upstream regions and the intervening sequences of Kluyveromyces and Saccharomyces homologs. However, the occurrence and the position of the introns is conserved. The sequence data also show that the physical linkage that exists in S. cerevisiae between the rp genes encoding RP59 (CRY1), S24 and L46 is conserved in Kluyveromyces. Northern analysis demonstrated that each of the isolated Kluyveromyces genes is transcriptionally active. By sequence comparison we identified a number of conserved sequences in the upstream region of each of the Kluyveromyces rp genes, which we designated the X, Z and RPGK boxes. The last one is highly similar, though not identical, to the S. cerevisiae RPG box. Functional analysis of the intergenic region between the genes encoding Kluyveromyces ribosomal proteins S24 and L46 showed that the RPGK box (+Z box) functions as a transcriptional activator, while the X box acts as a transcriptional repressor. Band-shift assays confirmed the existence of a RAP1-like protein in Kluyveromyces that binds to the RPGK box but not to the S. cerevisiae RPG box. In contrast, S. cerevisiae RAP1 did recognize the RPGK box.

Structure and expression of the ABF1-regulated ribosomal protein S33 gene in Kluyveromyces

The abundant multifunctional protein ABF1 of Saccharomyces cerevisiae binds to the upstream region of several genes, including some ribosomal protein genes like the one encoding protein S33. Deletion of the ABF1-binding sequence lowers the transcription of these genes three- to more than ten-fold. We have isolated the S33 genes of two related yeast species, Kluyveromyces lactis and Kluyveromyces marxianus. Comparison of the nucleotide sequences of these S33 genes with their counterpart from S. cerevisiae shows a strong sequence similarity covering the whole of the coding regions. In contrast, little or no sequence similarity is found in the 5'-flanking regions of the three genes. Also the trailer regions differ considerably in both length and sequence from one species to another. An ABF1-binding site is present in the upstream region of the S33 gene of K. marxianus. Retardation analyses showed that this sequence is able to bind a protein present in Kluyveromyces cells with a molecular mass somewhat lower than that of S. cerevisiae ABF1. Functional analyses, using a beta-glucuronidase reporter system, showed that the ABF1-binding site is indeed involved in transcription activation of the K. marxianus S33 gene in Kluyveromyces cells. A S. cerevisiae ABF1-gene-specific probe showed only weak hybridization with Kluyveromyces DNA and Northern blots did not show a signal. These results indicate that S. cerevisiae and Kluyveromyces contain functionally related but structurally dissimilar ABF1-type proteins.

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.