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.

Bypassing the rRNA processing endonucleolytic cleavage at site A2 in Saccharomyces cerevisiae.

Rrp5p is the only ribosomal RNA processing trans-acting factor that is required for the synthesis of both 18S and 5.8S rRNAs in Saccharomyces cerevisiae. Mutational analyses have characterized modified forms of Rrp5p that either affect formation of 18S rRNA by inhibiting cleavage at sites A0/A1/A2, or synthesis of 5.8S rRNA by inhibiting cleavage at site A3. Here, we examine the rRNA maturation process associated with a RRP5 bipartite allele that codes for two noncontiguous parts of the protein. This slow-growing bipartite mutant has a unique rRNA-processing phenotype that proceeds without endonucleolytic cleavage at site A2. In wild-type cells, the A2 cleavage takes place on the 32S pre-rRNA and is responsible for the formation of 20S and 27SA2 species, the precursors of mature 18S and 5.8S/25S rRNAs, respectively. In the bipartite strain, such precursors were not detectable as judged by Northern analysis or in vivo labeling. They were replaced by the aberrant 21S species and the bypassing 27SA3 precursor, both descended from direct cleavage of 32S pre-rRNA at site A3, which provides an alternative rRNA maturation pathway in this strain. The 21S pre-rRNA is the sole detectable and most likely available precursor of 18S rRNA in this particular strain, indicating that 18S rRNA can be directly produced from 21S. Furthermore, 21S species were found associated with 43S preribosomal particles as similarly observed for the 20S pre-rRNA in the wild-type cells.

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.

Yeast RAS2 mutations modulating the ras-guanine exchange factor interaction.

We have used a two-hybrid approach to test various forms of Saccharomyces cerevisiae Ras2p for their ability to interact with the human guanine nucleotide exchange factor HGRF55. We have previously shown that a strong two-hybrid interaction is found between the HGRF55p and the dominant negative Ras2p(G22A) form of ras [Camus et al. (1995) Oncogene 11, 951-959]. We show here that the substitution N123I which weakens the guanine nucleotide binding also promotes ras-GEF interaction. We demonstrate that the R80D substitution alone completely abolishes the interaction of Ras2p(G22A) with GEF, whereas substitutions at positions 81, 82 and 73 have only small effects. Since residue 73 is involved in the response of ras to GEF, we propose that it plays a role in the conformational change induced by the GEF rather than in its binding. Those results emphasize the role of the alpha2 helix of the switch II region in the recognition of the GEF family.

Identification of guanine exchange factor key residues involved in exchange activity and Ras interaction.

We have carried out a functional analysis of the human HGRF55 exchange factor in the yeast Saccharomyces cerevisiae. Twelve residues conserved among most of all known guanine exchange factors (GEFs) have been independently changed to alanine. Taking advantage of the ability of Hgrf55p to replace the yeast Cdc25p exchange factor, and using the two-hybrid system with RAS2ala22 allele, we have identified key residues for the interaction with Ras and/or its activation. Substitution of arginine 392 to alanine leads to a complete loss of interaction with Ras, though the protein remains stable. Substitution of Asp266 or Arg359 to alanine results in inactive proteins at 39 degrees C, still able however to interact with Ras. The other charged-to-alanine substitutions led to no detectable phenotype when present alone but most of them dramatically increased the temperature sensitive phenotype observed with [Asp266Ala] substitution. Surprisingly, the cysteine to alanine substitution in the highly conserved PCVPF/Y motif proved to be without effect, suggesting that the sulfhydryl group is not essential for stability or interaction with Ras.

A universally conserved region of the largest subunit participates in the active site of RNA polymerase III.

The largest subunits of the three eukaryotic nuclear RNA polymerase present extensive sequence homology with the beta' subunit of the bacterial enzymes over five major co-linear regions. Region d is the most highly conserved and contains a motif, (Y/F)NADFDGD(E/Q)M(N/A), which is invariant in all multimeric RNA polymerases. An extensive mutagenesis of that region in yeast RNA polymerase III led to a vast majority (16/22) of lethal single-site substitutions. A few conditional mutations were also obtained. One of them, rpc160-112, corresponds to a double substitution (T506I, N509Y) and has a slow growth phenotype at 25 degrees C. RNA polymerase III from the mutant rpc160-112 was severely impaired in its ability to transcribe a tRNA gene in vitro. The transcription defect did not originate from a deficiency in transcription complex formation and RNA chain initiation, but was mainly due to a reduced elongation rate. Under conditions of substrate limitation, the mutant enzyme showed increased pausing at the intrinsic pause sites of the SUP4 tRNA gene and an increased rate of slippage of nascent RNA, as compared with the wild-type enzyme. The enzyme defect was also detectable with poly[d(A-T)] as template, in the presence of saturating DNA, ATP and UTP concentrations. The mutant enzyme behavior is best explained by a distortion of the active site near the growing point of the RNA product.

Genetic analysis of the folded structure of yeast mitochondrial cytochrome b by selection of intragenic second-site revertants.

The mutations C133-->Y133, L282-->F282 and G340-->E340 in yeast mitochondrial cytochrome b each lead to a dysfunction of the cytochrome bc1 complex and, consequently, to the absence of growth on non-fermentable substrates. We isolated and characterized, from these mutants, fourteen different intragenic pseudo-revertants of various respiratory sufficient phenotypes. Both first-site and second-site suppressor mutations were found. A novel type of suppressor mutation consisted of the three-base-pair deletion of the parental mutated codon (E340 delta). The results provide, for the first time, evidence for the transmembrane disposition of helices F and G of the current eight-helix cytochrome b model. These two helices are presumably in contact with helix C in the folded protein. A simple modelisation study suggests that the packing of helices C, F and G in cytochrome b may be similar to that of helices I, II and VII in bacteriorhodopsin, respectively. We observed from the study of second-site revertants that compensation across the membrane never occurs. For each revertant, the suppressor mutation and the corresponding target mutation are on the same side of the membrane. This membrane sidedness strengthens the topological constraints imposed by the Q-cycle, namely the necessity of spatial separation of two catalytic reaction sites for ubiquinone.

[Yeast and the control of RAS by exchange factors]. / La levure et le contrôle de RAS par les facteurs d'échange.

Two isofunctional ras genes are present in the yeast Saccharomyces cerevisiae. Albeit their targets differ between mammals and yeast, they have conserved their regulators. The study of their positive regulators, guanine nucleotide exchange factors, have provided routes to the discovery of their regulatory elements in mammals. Ras are signal transducing proteins involved in the activation of the adenylate cyclase in yeast. They are activated by Cdc25p which has been shown to contain a Guanine Exchange Factor domain (GEF). SDC25, a gene partially homologous to CDC25, also contains a GEF domain but seems to be under a different regulation. It has been used to demonstrate the first guanine exchange activity on ras in vitro and was shown to be active by gene transfer in mammalian cells. Both Cdc25p and Sdc25p are associated to membrane and contain SH3 domains which are supposed to bind still unidentified proteins. Cdc25p is an unstable protein which contains a cyclin destruction box. Therefore activating effect on ras could be regulated by its level of expression. We have contributed to the isolation of a mammalian CDC25 homolog and we are analysing by directed mutagenesis key positions for ras activation of the human homolog HGRF55. That was performed by complementation analysis of yeast mutants as well as by use of two hybrid system. These approaches led us to the discovery of residues involved in ras interaction.

Suppression of yeast RNA polymerase III mutations by the URP2 gene encoding a protein homologous to the mammalian ribosomal protein S20.

URP2 was cloned as a multicopy suppressor of several temperature-sensitive mutations defective in RNA polymerase III-dependent transcription, but without effect on mutations affecting RNA polymerase I or II. This single-copy gene encodes a hydrophilic polypeptide of 121 amino acid residues with a predicted molecular mass of 13.9 kDa and a basic isoelectric point of 9.7. URP2 is a highly expressed gene, judging from its abundant messenger RNA and strong codon bias. The Urp2p protein is essential for cell growth, as shown by the lethal phenotype of the urp2::HIS3 null allele. Given its striking similarity to the S20 ribosomal polypeptide of rat (55% identical residues), Urp2p is in all likelihood the yeast form of this polypeptide. Both proteins are significantly related to S10, a component of the small ribosomal subunit of Escherichia coli that is known to operate as a transcriptional elongation factor. The latter observation suggests that the suppressor effect of URP2 may be due to a direct involvement of Urp2p in RNA polymerase III-dependent transcription. Alternatively, the overexpression of Urp2p could bypass a partial preribosomal RNA processing defect associated with RNA polymerase III mutants. URP2 was assigned to the left arm of chromosome VIII, and maps between DUR3 and YLF1. The latter gene product has homology to the E. coli gtp1 gene product, and may define a new family of putative GTP-binding proteins.

Suppression of yeast RNA polymerase III mutations by FHL1, a gene coding for a fork head protein involved in rRNA processing.

The FHL1 gene was isolated by screening for high-copy-number suppressors of conditional RNA polymerase III mutations. This gene is unique on the yeast genome and was located close to RPC40 and PRE2 on the right arm of chromosome XVI. It codes for a 936-amino-acid protein containing a domain similar to the fork head DNA-binding domain, initially found in the developmental fork head protein of Drosophila melanogaster and in the HNF-3 family of hepatocyte mammalian transcription factors. Null mutations caused a severe reduction in growth rate and a lower rRNA content that resulted from defective rRNA processing. There was no detectable effect on mRNA splicing. Thus, the Fhl1p protein plays a key role in the control of rRNA processing, presumably by acting as a transcriptional regulator of genes specifically involved in that process. Moreover, mutants carrying the RNA polymerase III mutations were slightly defective in rRNA processing. This accounts for the isolation of FHL1 as a dosage-dependent suppressor and suggests that rRNA processing depends on a still-unidentified RNA polymerase III transcript.

A general suppressor of RNA polymerase I, II and III mutations in Saccharomyces cerevisiae.

A multicopy genomic library of Saccharomyces cerevisiae (strain FL100) was screened for its ability to suppress conditionally defective mutations altering the 31 kDa subunit (rpc31-236) or the 53 kDa subunit (rpc53-254/424) of RNA polymerase III. In addition to allele-specific suppressors, we identified seven suppressor clones that acted on both mutations and also suppressed several other conditional mutations defective in RNA polymerases I or II. All these clones harbored a complete copy of the SSD1 gene. The same pleiotropic suppression pattern was found with the dominant SSD1-v allele present in some laboratory strains of S. cerevisiae. SSD1-v was previously shown to suppress mutations defective in the SIT4 gene product (a predicted protein phosphatase subunit) or in the regulatory subunit of the cyclic AMP-dependent protein kinase. We propose that the SSD1 gene product modulates the activity (or the level) of the three nuclear RNA polymerases, possibly by altering their degree of phosphorylation.

Effect of mutations in a zinc-binding domain of yeast RNA polymerase C (III) on enzyme function and subunit association.

The conserved amino-terminal region of the largest subunit of yeast RNA polymerase C is capable of binding zinc ions in vitro. By oligonucleotide-directed mutagenesis, we show that the putative zinc-binding motif CX2CX6-12CXGHXGX24-37CX2C, present in the largest subunit of all eukaryotic and archaebacterial RNA polymerases, is essential for the function of RNA polymerase C. All mutations in the invariant cysteine and histidine residues conferred a lethal phenotype. We also obtained two conditional thermosensitive mutants affecting this region. One of these produced a form of RNA polymerase C which was thermosensitive and unstable in vitro. This instability was correlated with the loss of three of the subunits which are specific to RNA polymerase C: C82, C34, and C31.