A nuclear 3'-5' exonuclease involved in mRNA degradation interacts with Poly(A) polymerase and the hnRNA protein Npl3p

Inactivation of poly(A) polymerase (encoded by PAP1) in Saccharomyces cerevisiae cells carrying the temperature-sensitive, lethal pap1-1 mutation results in reduced levels of poly(A)(+) mRNAs. Genetic selection for suppressors of pap1-1 yielded two recessive, cold-sensitive alleles of the gene RRP6. These suppressors, rrp6-1 and rrp6-2, as well as a deletion of RRP6, allow growth of pap1-1 strains at high temperature and partially restore the levels of poly(A)(+) mRNA in a manner distinct from the cytoplasmic mRNA turnover pathway and without slowing a rate-limiting step in mRNA decay. Subcellular localization of an Rrp6p-green fluorescent protein fusion shows that the enzyme residues in the nucleus. Phylogenetic analysis and the nature of the rrp6-1 mutation suggest the existence of a highly conserved 3'-5' exonuclease core domain within Rrp6p. As predicted, recombinant Rrp6p catalyzes the hydrolysis of a synthetic radiolabeled RNA in a manner consistent with a 3'-5' exonucleolytic mechanism. Genetic and biochemical experiments indicate that Rrp6p interacts with poly(A) polymerase and with Npl3p, a poly(A)(+) mRNA binding protein implicated in pre-mRNA processing and mRNA nuclear export. These findings suggest that Rrp6p may interact with the mRNA polyadenylation system and thereby play a role in a nuclear pathway for the degradation of aberrantly processed precursor mRNAs.     

Inactivation of cleavage factor I components Rna14p and Rna15p induces sequestration of small nucleolar ribonucleoproteins at discrete sites in the nucleus

Small nucleolar RNAs (snoRNAs) associate with specific proteins forming small nucleolar ribonucleoprotein (snoRNP) particles, which are essential for ribosome biogenesis. The snoRNAs are transcribed, processed, and assembled in snoRNPs in the nucleoplasm. Mature particles are then transported to the nucleolus. In yeast, 3'-end maturation of snoRNAs involves the activity of Rnt1p endonuclease and cleavage factor IA (CFIA). We report that after inhibition of CFIA components Rna14p and Rna15p, the snoRNP proteins Nop1p, Nop58p, and Gar1p delocalize from the nucleolus and accumulate in discrete nucleoplasmic foci. The U14 snoRNA, but not U3 snoRNA, similarly redistributes from the nucleolus to the nucleoplasmic foci. Simultaneous depletion of either Rna14p or Rna15p and the nuclear exosome component Rrp6p induces accumulation of poly(A)(+) RNA at the snoRNP-containing foci. We propose that the foci detected after CFIA inactivation correspond to quality control centers in the nucleoplasm.     

Regulation of the export of RNA from the nucleus

Transport of macromolecules across the nuclear envelope is an essential activity in eukaryotic cells. RNA molecules within cells are found complexed with proteins and the bound proteins likely contain signals for RNA export. RNAs microinjected into Xenopus oocyte nuclei are readily exported, and their export can be competed by self RNA but not by RNAs of other classes. This indicates that the rate-limiting step in RNA export is the interaction of RNAs with class-specific proteins, at least when substrate RNAs are present at saturating levels. Export of host mRNAs is inhibited following infection by some animal viruses, while the export of viral RNAs occurs. The HIV-1 RNA-binding protein, Rev, mediates the export of intron-containing viral RNAs that would normally be retained in nuclei. This requires a nuclear export signal (NES) within Rev and an element within the RNA to which Rev binds. In yeast, heat shock causes accumulation of poly(A)(+)RNA within nuclei but heat-shock mRNAs are transcribed and exported efficiently. This requires elements within heat shock mRNA that probably interact with a cellular protein to facilitate RNA export. In these cases, the proteins that recognize critical sequences in the RNAs probably direct the RNAs to an RNA export pathway not generally used for mRNA export. This would circumvent the general retention of most poly(A)(+)mRNAs following heat shock in yeast and the need for complete splicing of viral mRNAs that travel through the normal mRNA export pathway.     

Poly(A) tail-dependent exonuclease AtRrp41p from Arabidopsis thaliana rescues 5.8 S rRNA processing and mRNA decay defects of the yeast ski6 mutant and is found in an exosome-sized complex in plant and yeast cells

Eukaryotic 3'-->5' exonucleolytic activities are essential for a wide variety of reactions of RNA maturation and metabolism, including processing of rRNA, small nuclear RNA, and small nucleolar RNA, and mRNA decay. Two related but distinct forms of a complex containing 10 3'-->5' exonucleases, the exosome, are found in yeast nucleus and cytoplasm, respectively, and related complexes exist in human cells. Here we report on the characterization of the AtRrp41p, an Arabidopsis thaliana homolog of the Saccharomyces cerevisiae exosome subunit Rrp41p (Ski6p). Purified recombinant AtRrp41p displays a processive phosphorolytic exonuclease activity and requires a single-stranded poly(A) tail on a substrate RNA as a "loading pad." The expression of the Arabidopsis RRP41 cDNA in yeast rescues the 5.8 S rRNA processing and 3'-->5' mRNA degradation defects of the yeast ski6-100 mutant. However, neither of these defects can explain the conditional lethal phenotype of the ski6-100 strain. Importantly, AtRrp41p shares additional function(s) with the yeast Rrp41p which are essential for cell viability because it also rescues the rrp41 (ski6) null mutant. AtRrp41p is found predominantly in a high molecular mass complex in Arabidopsis and in yeast cells, and it interacts in vitro with the yeast Rrp44p and Rrp4p exosome subunits, suggesting that it can participate in evolutionarily conserved interactions that could be essential for the integrity of the exosome complex.     

A nuclear surveillance pathway for mRNAs with defective polyadenylation

The pap1-5 mutation in poly(A) polymerase causes rapid depletion of mRNAs at restrictive temperatures. Residual mRNAs are polyadenylated, indicating that Pap1-5p retains at least partial activity. In pap1-5 strains lacking Rrp6p, a nucleus-specific component of the exosome complex of 3'-5' exonucleases, accumulation of poly(A)+ mRNA was largely restored and growth was improved. The catalytically inactive mutant Rrp6-1p did not increase growth of the pap1-5 strain and conferred much less mRNA stabilization than rrp6delta. This may indicate that the major function of Rrp6p is in RNA surveillance. Inactivation of core exosome components, Rrp41p and Mtr3p, or the nuclear RNA helicase Mtr4p gave different phenotypes, with accumulation of deadenylated and 3'-truncated mRNAs. We speculate that slowed mRNA polyadenylation in the pap1-5 strain is detected by a surveillance activity of Rrp6p, triggering rapid deadenylation and exosome-mediated degradation. In wild-type strains, assembly of the cleavage and polyadenylation complex might be suboptimal at cryptic polyadenylation sites, causing slowed polyadenylation.     

Rrp47p is an exosome-associated protein required for the 3' processing of stable RNAs

Related exosome complexes of 3'-->5' exonucleases are present in the nucleus and the cytoplasm. Purification of exosome complexes from whole-cell lysates identified a Mg(2+)-labile factor present in substoichiometric amounts. This protein was identified as the nuclear protein Yhr081p, the homologue of human C1D, which we have designated Rrp47p (for rRNA processing). Immunoprecipitation of epitope-tagged Rrp47p confirmed its interaction with the exosome and revealed its association with Rrp6p, a 3'-->5' exonuclease specific to the nuclear exosome fraction. Northern analyses demonstrated that Rrp47p is required for the exosome-dependent processing of rRNA and small nucleolar RNA (snoRNA) precursors. Rrp47p also participates in the 3' processing of U4 and U5 small nuclear RNAs (snRNAs). The defects in the processing of stable RNAs seen in rrp47-Delta strains closely resemble those of strains lacking Rrp6p. In contrast, Rrp47p is not required for the Rrp6p-dependent degradation of 3'-extended nuclear pre-mRNAs or the cytoplasmic 3'-->5' mRNA decay pathway. We propose that Rrp47p functions as a substrate-specific nuclear cofactor for exosome activity in the processing of stable RNAs.     

Red1 promotes the elimination of meiosis-specific mRNAs in vegetatively growing fission yeast

Meiosis-specific mRNAs are transcribed in vegetative fission yeast, and these meiotic mRNAs are selectively removed from mitotic cells to suppress meiosis. This RNA elimination system requires degradation signal sequences called determinant of selective removal (DSR), an RNA-binding protein Mmi1, polyadenylation factors, and the nuclear exosome. However, the detailed mechanism by which meiotic mRNAs are selectively degraded in mitosis but not meiosis is not understood fully. Here we report that Red1, a novel protein, is essential for elimination of meiotic mRNAs from mitotic cells. A red1 deletion results in the accumulation of a large number of meiotic mRNAs in mitotic cells. Red1 interacts with Mmi1, Pla1, the canonical poly(A) polymerase, and Rrp6, a subunit of the nuclear exosome, and promotes the destabilization of DSR-containing mRNAs. Moreover, Red1 forms nuclear bodies in mitotic cells, and these foci are disassembled during meiosis. These results demonstrate that Red1 is involved in DSR-directed RNA decay to prevent ectopic expression of meiotic mRNAs in vegetative cells.     

Gle2p is essential to induce adaptation of the export of bulk poly(A)+ mRNA to heat shock in Saccharomyces cerevisiae

The export of bulk poly(A)(+) mRNA is blocked under heat-shocked (42 degrees C) conditions in Saccharomyces cerevisiae. We found that an mRNA export factor Gle2p rapidly dissociated from the nuclear envelope and diffused into the cytoplasm at 42 degrees C. However, in exponential phase cells pretreated with mild heat stress (37 degrees C for 1 h), Gle2p did not dissociate at 42 degrees C, and the export of bulk poly(A)(+) mRNA continued. Cells in stationary phase also continued with the export of bulk poly(A)(+) mRNA at 42 degrees C without the dissociation of Gle2p from the nuclear envelope. The dissociation of Gle2p was caused by increased membrane fluidity and correlated closely with blocking of the export of bulk poly(A)(+) mRNA. Furthermore, the mutants gle2Delta and rip1Delta could not induce such an adaptation of the export of bulk poly(A)(+) mRNA to heat shock. Our findings indicate that Gle2p plays a crucial role in mRNA export especially under heat-shocked conditions. Our findings also indicate that the nuclear pore complexes that Gle2p constitutes need to be stabilized for the adaptation and that the increased membrane integrity caused by treatment with mild heat stress or by survival in stationary phase is likely to contribute to the stabilization of the association between Gle2p and the nuclear pore complexes.