Nucleus-vacuole (NV) junctions in Saccharomyces cerevisiae are formed through specific interactions between Vac8p on the vacuole membrane and Nvj1p in the nuclear envelope. Herein, we report that NV junctions in yeast promote piecemeal microautophagy of the nucleus (PMN). During PMN, teardrop-like blebs are pinched from the nucleus, released into the vacuole lumen, and degraded by soluble hydrolases. PMN occurs in rapidly dividing cells but is induced to higher levels by carbon and nitrogen starvation and is under the control of the Tor kinase nutrient-sensing pathway. Confocal and biochemical assays demonstrate that Nvj1p is degraded in a PMN-dependent manner. PMN occurs normally in apg7-⌬ cells and is, therefore, not dependent on macroautophagy. Transmission electron microscopy reveals that portions of the granular nucleolus are often sequestered into PMN structures. These results introduce a novel mode of selective microautophagy that targets nonessential components of the yeast nucleus for degradation and recycling in the vacuole. INTRODUCTIONAutophagy functions in dividing cells to recycle the cytoplasm and is essential for cell viability during extended periods of starvation (Klionsky and Ohsumi, 1999). Autophagy in yeast and mammals occurs by various modes, including morphologically distinct macro-and microautophagic pathways. Macroautophagy in Saccharomyces cerevisiae is induced by starvation and involves the formation of double membrane autophagosomes around bulk cytoplasm and organelles (Takeshige et al., 1992;Baba et al., 1994). Vesicular targeting factors mediate the fusion of the outer autophagosomal membrane with the vacuole (Darsow et al., 1997;Sato et al., 1998), and an autophagic body is subsequently released into the vacuole lumen (Baba et al., 1994) where it is degraded by acid hydrolases (Jones et al., 1997). Most vacuolar hydrolases are synthesized as inactive proenzymes, which are activated in the vacuole by Pep4p and Prb1p proteinases. Thus, autophagic bodies accumulate in the vacuoles of pep4 or prb1 mutant cells (Takeshige et al., 1992;Woolford et al., 1993;Baba et al., 1994;Jones et al., 1997) due to their slower degradation rates (Jones et al., 1982;Zubenko et al., 1983).Many of the factors necessary for the formation of autophagosomes are used in the cytosol-to-vacuole targeting (Cvt) of proaminopeptidase I to the vacuole lumen (Scott et al., 1996;Teter and Klionsky, 2000). APG/AUT/CVT genes, which are required for the formation of Cvt vesicles and their conversion into larger autophagosomes (Abeliovich et al., 2000;Kim et al., 2001a), also comprise components of a novel system of ubiquitin-like conjugation reactions (Klionsky and Ohsumi, 1999). Common to these reactions is Apg7p, a conserved E1-like enzyme (Mizushima et al., 1998a,b) that is required both for the conjugation of Apg12p to Apg5p and of Aut7p/Apg8p to phosphatidylethanolamine (Ichimura et al., 2000). Recently, it was shown that some Apg proteins, including Apg5p and Aut7p/Apg8p, are required for early steps in the fo...
Vac8p is a vacuolar membrane protein that is required for efficient vacuole inheritance and fusion, cytosol-to-vacuole targeting, and sporulation. By analogy to other armadillo domain proteins, including β-catenin and importin α, we hypothesize that Vac8p docks various factors at the vacuole membrane. Two-hybrid and copurfication assays demonstrated that Vac8p does form complexes with multiple binding partners, including Apg13p, Vab2p, and Nvj1p. Here we describe the surprising role of Vac8p-Nvj1p complexes in the formation of nucleus–vacuole (NV) junctions. Nvj1p is an integral membrane protein of the nuclear envelope and interacts with Vac8p in the cytosol through its C-terminal 40–60 amino acids (aa). Nvj1p green fluorescent protein (GFP) concentrated in small patches or rafts at sites of close contact between the nucleus and one or more vacuoles. Previously, we showed that Vac8p-GFP concentrated in intervacuole rafts, where is it likely to facilitate vacuole-vacuole fusion, and in “orphan” rafts at the edges of vacuole clusters. Orphan rafts of Vac8p red-sifted GFP (YFP) colocalize at sites of NV junctions with Nvj1p blue-sifted GFP (CFP). GFP-tagged nuclear pore complexes (NPCs) were excluded from NV junctions. In vac8-Δ cells, Nvj1p-GFP generally failed to concentrate into rafts and, instead, encircled the nucleus. NV junctions were absent in both nvj1-Δ andvac8-Δ cells. Overexpression of Nvj1p caused the profound proliferation of NV junctions. We conclude that Vac8p and Nvj1p are necessary components of a novel interorganelle junction apparatus.
Abstract. The transport of proteins into the nucleus is a receptor-mediated process that is likely to involve between 50-100 gene products, including many that comprise the nuclear pore complex. We have developed an assay in Saccharomyces cerevisiae for the nuclear transport of green fluorescent protein fused to the SV-40 large T antigen nuclear localization signal (NLS-GFP). This assay allows the measurement of relative NLS-GFP nuclear import rates in wild-type and mutant cells under various physiological conditions. Probably the best understood component of the nuclear transport apparatus is Srplp, the NLS receptor, which binds NLS-cargo in the cytoplasm and accompanies it into the nucleus. When compared to SRP1 + cells, NLS-GFP import rates in temperature-sensitive srp1-31 cells were slower and showed a lower temperature optimum. The in vivo transport defect of the srp1-31 cells was correlated with the purified protein's thermal sensitivity, as assayed by in vitro NLS peptide binding. We show that the kinetics of NLS-directed nuclear transport in wildtype cells is stimulated by the elevated expression of SSA1, which encodes a cytoplasmic heat shock protein 70 (Hsp70). Elevated Hsp70 levels are sufficient to suppress the NLS-GFP import defects in srpl-31 and nup82-3 cells, NUP82 encodes a protein that functions within the nuclear pore complex subsequent to docking. These results provide genetic evidence that Hsp70 acts during both targeting and translocation phases of nuclear transport, possibly as a molecular chaperone to promote the formation and stability of the Srplp-NLScargo complex.
The Saccharomyces cerevisiae temperature-sensitive (ts) allele nip7-1 exhibits phenotypes associated with defects in the translation apparatus, including hypersensitivity to paromomycin and accumulation of halfmer polysomes. The cloned NIP7؉ gene complemented the nip7-1 ts growth defect, the paromomycin hypersensitivity, and the halfmer defect. NIP7 encodes a 181-amino-acid protein (21 kDa) with homology to predicted products of open reading frames from humans, Caenorhabditis elegans, and Arabidopsis thaliana, indicating that Nip7p function is evolutionarily conserved. Gene disruption analysis demonstrated that NIP7 is essential for growth. A fraction of Nip7p cosedimented through sucrose gradients with free 60S ribosomal subunits but not with 80S monosomes or polysomal ribosomes, indicating that it is not a ribosomal protein. Nip7p was found evenly distributed throughout the cytoplasm and nucleus by indirect immunofluorescence; however, in vivo localization of a Nip7p-green fluorescent protein fusion protein revealed that a significant amount of Nip7p is present inside the nucleus, most probably in the nucleolus. Depletion of Nip7-1p resulted in a decrease in protein synthesis rates, accumulation of halfmers, reduced levels of 60S subunits, and, ultimately, cessation of growth. Nip7-1p-depleted cells showed defective pre-rRNA processing, including accumulation of the 35S rRNA precursor, presence of a 23S aberrant precursor, decreased 20S pre-rRNA levels, and accumulation of 27S pre-rRNA. Delayed processing of 27S pre-rRNA appeared to be the cause of reduced synthesis of 25S rRNA relative to 18S rRNA, which may be responsible for the deficit of 60S subunits in these cells.Eukaryotic ribosome biogenesis takes place mainly in the nucleolus, where approximately 80 ribosomal proteins (rproteins) and 4 rRNAs assemble into 40S and 60S subunits (reviewed in reference 66). In eukaryotes, synthesis of rRNAs is not achieved by transcription of the individual species. Instead, three of the four rRNAs (18S, 5.8S, and 25 to 28S) are produced from a single RNA polymerase I transcript (35S in yeast), which, in addition to the mature rRNAs, contains two external transcribed spacers, the 5Ј ETS and 3Ј ETS, and two internal transcribed spacers, ITS1 and ITS2 (66). The 35S pre-rRNA, which is covalently modified by methylation and pseudouridinylation, serves as a template onto which a number of rproteins and non-rproteins associate and is processed by endo-and exonucleases. The fourth rRNA species (5S) is transcribed independently by RNA polymerase III (66). Following assembly in the nucleolus, ribosomal subunits are selectively exported to the cytoplasm (39).Ribosome biogenesis has been studied in many eukaryotic organisms but is best characterized in Saccharomyces cerevisiae. In yeast, although the level of total rproteins changes during various stages of growth, stoichiometric ratios of 40S rproteins and 60S rproteins are independently maintained. Intrasubunit stoichiometry is maintained primarily by the coordinate transcription...
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