Tpa1p is part of an mRNP complex that influences translation termination, mRNA deadenylation, and mRNA turnover in Saccharomyces cerevisiae

In this report, we show that the Saccharomyces cerevisiae protein Tpa1p (for termination and polyadenylation) influences translation termination efficiency, mRNA poly(A) tail length, and mRNA stability. Tpa1p is encoded by the previously uncharacterized open reading frame YER049W. Yeast strains carrying a deletion of the TPA1 gene (tpa1Delta) exhibited increased readthrough of stop codons, and coimmunoprecipitation assays revealed that Tpa1p interacts with the translation termination factors eRF1 and eRF3. In addition, the tpa1Delta mutation led to a 1.5- to 2-fold increase in the half-lives of mRNAs degraded by the general 5'-->3' pathway or the 3'-->5' nonstop decay pathway. In contrast, this mutation did not have any affect on the nonsense-mediated mRNA decay pathway. Examination of mRNA poly(A) tail length revealed that poly(A) tails are longer than normal in a tpa1Delta strain. Consistent with a potential role in regulating poly(A) tail length, Tpa1p was also found to coimmunoprecipitate with the yeast poly(A) binding protein Pab1p. These results suggest that Tpa1p is a component of a messenger ribonucleoprotein complex bound to the 3' untranslated region of mRNAs that affects translation termination, deadenylation, and mRNA decay.     

The SpGAR1 gene of Schizosaccharomyces pombe encodes the functional homologue of the snoRNP protein GAR1 of Saccharomyces cerevisiae.

GAR1 is a nucleolar protein which is associated with small nucleolar RNAs (snoRNAs) and which is required for pre-ribosomal RNA processing. In Saccharomyces cerevisiae, the GAR1 gene is essential for cell viability. We have cloned and sequenced the GAR1 gene from the distantly related yeast Schizosaccharomyces pombe. The SpGAR1 gene, which contains two small introns, codes for a 194 amino-acid protein of 20 kDa. A protein sequence comparison indicates that SpGAR1 is 65% identical to ScGAR1. Anti-ScGAR1 antibodies recognize SpGAR1, emphasizing the structural conservation of the protein. Immunostaining of S.pombe cells with these antibodies reveals that SpGAR1 is localized in the nucleolus, as is the case in S.cerevisiae. Moreover, SpGAR1 can substitute for GAR1 in S.cerevisiae, indicating that the two proteins are functionally equivalent. These results suggest a parallel evolutionary conservation of proteins and RNAs with which GAR1 interacts in mediating its pre-rRNA processing and viability functions. After fibrillarin, GAR1 is the second protein of the snoRNPs shown to have been conserved throughout evolution.     

A functional homologue of the RNA1 gene product in Schizosaccharomyces pombe: purification, biochemical characterization, and identification of a leucine-rich repeat motif.

The RNA1 gene from Saccharomyces cerevisiae is defined by the temperature-sensitive rna1-1 mutation that interferes with the maturation and/or nucleocytoplasmic transport of RNA. We describe the purification of a 44-kDa protein from the evolutionary distant fission yeast Schizosaccharomyces pombe and the cloning and sequence analysis of the corresponding gene. Although this protein shares only 42% sequence identity with the RNA1 gene product, it represents a functional homologue because the expression of the S. pombe gene in S. cerevisiae complements the rna1-1 defect. Disruption in S. pombe of the gene encoding the 44-kDa protein, for which we propose the name S. pombe rna1p, reveals that it is essential for growth. Our analysis of purified S. pombe rna1p represents the first biochemical characterization of an RNA1 gene product and reveals that it is a monomeric protein of globular shape. Cell fractionation and immunofluorescence microscopy indicate that rna1p is a cytoplasmic protein possibly enriched in the nuclear periphery. We identify a sequence motif of 29 residues, which is rich in leucine and repeated eight times both in S. pombe and in S. cerevisiae rna1p. Similar leucine-rich repeats present in a series of other proteins, e.g., the mammalian ribonuclease/angiogenin inhibitor, adenylyl cyclase from S. cerevisiae, the toll protein from Drosophila melanogaster, and the sds22 protein phosphatase regulatory subunit from S. pombe, are thought to be involved in protein-protein interactions. Thus rna1p may act as a scaffold protein possibly interacting in the nuclear periphery with a protein ligand that could be associated with exported RNA.     

Sequence divergence of the RNA polymerase shared subunit ABC14.5 (Rpb8) selectively affects RNA polymerase III assembly in Saccharomyces cerevisiae.

ABC14.5 (Rpb8) is a eukaryotic subunit common to all three nuclear RNA polymerases. In Saccharomyces cerevisiae, ABC14.5 (Rpb8) is essential for cell viability, however its function remains unknown. We have cloned and characterised the Schizosaccharomyces pombe rpb8(+) cDNA. We found that S.pombe rpb8, unlike the similarly diverged human orthologue, cannot substitute for S.cerevisiae ABC14. 5 in vivo. To obtain information on the function of this RNA polymerase shared subunit we have used S.pombe rpb8 as a naturally altered molecule in heterologous expression assays in S.cerevisiae. Amino acid residue differences within the 67 N-terminal residues contribute to the functional distinction of the two yeast orthologues in S.cerevisiae. Overexpression of the S.cerevisiae largest subunit of RNA polymerase III C160 (Rpc1) allows S.pombe rpb8 to functionally replace ABC14.5 in S.cerevisiae, suggesting a specific genetic interaction between the S.cerevisiae ABC14.5 (Rpb8) and C160 subunits. We provide further molecular and biochemical evidence showing that the heterologously expressed S.pombe rpb8 molecule selectively affects RNApolymerase III but not RNA polymerase I complex assembly. We also report the identification of a S.cerevisiae ABC14.5-G120D mutant which affects RNA polymerase III.     

A Role for Saccharomyces cerevisiae Tpa1 Protein in Direct Alkylation Repair

Alkylating agents induce cytotoxic DNA base adducts. In this work, we provide evidence to suggest, for the first time, that Saccharomyces cerevisiae Tpa1 protein is involved in DNA alkylation repair. Little is known about Tpa1 as a repair protein beyond the initial observation from a high-throughput analysis indicating that deletion of TPA1 causes methyl methane sulfonate sensitivity in S. cerevisiae. Using purified Tpa1, we demonstrate that Tpa1 repairs both single- and double-stranded methylated DNA. Tpa1 is a member of the Fe(II) and 2-oxoglutarate-dependent dioxygenase family, and we show that mutation of the amino acid residues involved in cofactor binding abolishes the Tpa1 DNA repair activity. Deletion of TPA1 along with the base excision repair pathway DNA glycosylase MAG1 renders the tpa1Δmag1Δ double mutant highly susceptible to methylation-induced toxicity. We further demonstrate that the trans-lesion synthesis DNA polymerase Polζ (REV3) plays a key role in tolerating DNA methyl-base lesions and that tpa1Δmag1revΔ3 triple mutant is extremely susceptible to methylation-induced toxicity. Our results indicate a synergism between the base excision repair pathway and direct alkylation repair by Tpa1 in S. cerevisiae. We conclude that Tpa1 is a hitherto unidentified DNA repair protein in yeast and that it plays a crucial role in reverting alkylated DNA base lesions and cytotoxicity.     

Dis3, implicated in mitotic control, binds directly to Ran and enhances the GEF activity of RCC1.

Using the two-hybrid method, we isolated a Saccharomyces cerevisiae cDNA encoding a protein homologous to Schizosaccharomyces pombe protein Dis3sp, using as bait, human GTPase Ran. The DIS3 gene is essential for viability and complements S.pombe mutant dis3-54 which is defective in mitosis. Although Dis3sc has no homology to RanBP1, it bound directly to Ran and the S.cerevisiae Ran homologue Cnr1, but not to the S.cerevisiae RCC1 homologue Srm1. Upon binding to Ran with a 1:1 molar ratio, Dis3sc enhanced a nucleotide-releasing activity of RCC1 on Ran. In the presence of Dis3sc, the K(m) of RCC1 on Ran decreased by half, while the kcat was unchanged. In vivo, Dis3sp was present as oligomers of M(r) 670-200 kDa as previously reported, and the 200 kDa oligomer of Dis3sp was found to include Spi1 and Pim1, the S.pombe homologues of Ran and RCC1, respectively. Although the biological function of the heterotrimeric oligomer consisting of Dis3, Spi1 and Pim1 is unknown, our results indicate that Dis3 is a component of the RCC1-Ran pathway.     

C-terminal interaction of translational release factors eRF1 and eRF3 of fission yeast: G-domain uncoupled binding and the role of conserved amino acids.

Translation termination in eukaryotes requires a stop codon-responsive (class-I) release factor, eRF1, and a guanine nucleotide-responsive (class-II) release factor, eRF3. Schizosaccharomyces pombe eRF3 has an N-terminal polypeptide similar in size to the prion-like domain of Saccharomyces cerevisiae eRF3 in addition to the EF-1alpha-like catalytic domain. By in vivo two-hybrid assay as well as by an in vitro pull-down analysis using purified proteins of S. pombe as well as of S. cerevisiae, eRF1 bound to the C-terminal one-third domain of eRF3, named eRF3C, but not to the N-terminal two-thirds, which was inconsistent with the previous report by Paushkin et al. (1997, Mol Cell Biol 17:2798-2805). The activity of S. pombe eRF3 in eRF1 binding was affected by Ala substitutions for the C-terminal residues conserved not only in eRF3s but also in elongation factors EF-Tu and EF-1alpha. These single mutational defects in the eRF1-eRF3 interaction became evident when either truncated protein eRF3C or C-terminally altered eRF1 proteins were used for the authentic protein, providing further support for the presence of a C-terminal interaction. Given that eRF3 is an EF-Tu/EF-1alpha homolog required for translation termination, the apparent dispensability of the N-terminal domain of eRF3 for binding to eRF1 is in contrast to importance, direct or indirect, in EF-Tu/EF-1alpha for binding to aminoacyl-tRNA, although both eRF3 and EF-Tu/EF-1alpha share some common amino acids for binding to eRF1 and aminoacyl-tRNA, respectively. These differences probably reflect the independence of eRF1 binding in relation to the G-domain function of eRF3 (i.e., probably uncoupled with GTP hydrolysis), whereas aminoacyl-tRNA binding depends on that of EF-Tu/EF-1alpha(i.e., coupled with GTP hydrolysis), which sheds some light on the mechanism of eRF3 function.     

A common 40 amino acid motif in eukaryotic RNases H1 and caulimovirus ORF VI proteins binds to duplex RNAs.

Eukaryotic RNases H from Saccharomyces cerevisiae , Schizosaccharomyces pombe and Crithidia fasciculata , unlike the related Escherichia coli RNase HI, contain a non-RNase H domain with a common motif. Previously we showed that S.cerevisiae RNase H1 binds to duplex RNAs (either RNA-DNA hybrids or double-stranded RNA) through a region related to the double-stranded RNA binding motif. A very similar amino acid sequence is present in caulimovirus ORF VI proteins. The hallmark of the RNase H/caulimovirus nucleic acid binding motif is a stretch of 40 amino acids with 11 highly conserved residues, seven of which are aromatic. Point mutations, insertions and deletions indicated that integrity of the motif is important for binding. However, additional amino acids are required because a minimal peptide containing the motif was disordered in solution and failed to bind to duplex RNAs, whereas a longer protein bound well. Schizosaccharomyces pombe RNase H1 also bound to duplex RNAs, as did proteins in which the S.cerevisiae RNase H1 binding motif was replaced by either the C.fasciculata or by the cauliflower mosaic virus ORF VI sequence. The similarity between the RNase H and the caulimovirus domain suggest a common interaction with duplex RNAs of these two different groups of proteins.     

Telomere binding of the Rap1 protein is required for meiosis in fission yeast.

Telomeres are essential for chromosome integrity, protecting the ends of eukaryotic linear chromosomes during cell proliferation. Telomeres also function in meiosis; a characteristic clustering of telomeres beneath the nuclear membrane is observed during meiotic prophase in many organisms from yeasts to plants and humans, and the role of the telomeres in meiotic pairing and the recombination of homologous chromosomes has been demonstrated in the fission yeast Schizosaccharomyces pombe and in the budding yeast Saccharomyces cerevisiae. Here we report that S. pombe Rap1 is a telomeric protein essential for meiosis. While Rap1 is conserved in budding yeast and humans, schemes for telomere binding vary among species: human RAP1 binds to the telomere through interaction with the telomere binding protein TRF2; S. cerevisiae Rap1, however, binds telomeric DNA directly, and no orthologs of TRF proteins have been identified in this organism. In S. pombe, unlike in S. cerevisiae, an ortholog of human TRF has been identified. This ortholog, Taz1, binds directly to telomere repeats [18] and is necessary for telomere clustering in meiotic prophase. Our results demonstrate that S. pombe Rap1 binds to telomeres through interaction with Taz1, similar to human Rap1-TRF2, and that Taz1-mediated telomere localization of Rap1 is necessary for telomere clustering and for the successful completion of meiosis. Moreover, in taz1-disrupted cells, molecular fusion of Rap1 with the Taz1 DNA binding domain recovers telomere clustering and largely complements defects in meiosis, indicating that telomere localization of Rap1 is a key requirement for meiosis.     

Mitochondrial translation: elongation factor tu is essential in fission yeast and depends on an exchange factor conserved in humans but not in budding yeast

The translation elongation factor EF-Tu is a GTPase that delivers amino-acylated tRNAs to the ribosome during the elongation step of translation. EF-Tu/GDP is recycled by the guanine nucleotide exchange factor EF-Ts. Whereas EF-Ts is lacking in S. cerevisiae, both translation factors are found in S. pombe and H. sapiens mitochondria, consistent with the known similarity between fission yeast and human cell mitochondrial physiology. We constructed yeast mutants lacking these elongation factors. We show that mitochondrial translation is vital for S. pombe, as it is for human cells. In a genetic background allowing the loss of mitochondrial functions, a block in mitochondrial translation in S. pombe leads to a major depletion of mtDNA. The relationships between EF-Ts and EF-Tu from both yeasts and humans were investigated through functional complementation and coexpression experiments and by a search for suppressors of the absence of the S. pombe EF-Ts. We find that S. cerevisiae EF-Tu is functionally equivalent to the S. pombe EF-Tu/EF-Ts couple. Point mutations in the S. pombe EF-Tu can render it independent of its exchange factor, thereby mimicking the situation in S. cerevisiae.