David S. Goldfarb

Minimal nuclear pore complexes define FG repeat domains essential for transport

Translocation through nuclear pore complexes (NPCs) requires interactions between receptor–cargo complexes and phenylalanine-glycine (FG) repeats in multiple FG domain-containing NPC proteins (FG-Nups). We have systematically deleted the FG domains of 11 Saccharomyces cerevisiae FG-Nups in various combinations. All five asymmetrically localized FG domains deleted together were non-essential. However, specific combinations of symmetrically localized FG domains were essential. Over half the total mass of FG domains could be deleted without loss of viability or the NPCs normal permeability barrier. Significantly, symmetric deletions caused mild reductions in Kap95–Kap60-mediated import rates, but virtually abolished Kap104 import. These results suggest the existence of multiple translocation pathways.

Facilitated nuclear transport of histone H1 and other small nucleophilic proteins

Upon microinjection into the cytoplasm, three small nonnuclear (extracellular or mitochondrial) proteins diffused into nuclei of chilled or energy-depleted cells. In contrast, the facilitated transport of two large nuclear localization signal (NLS)-containing proteins was reversibly arrested by chilling or energy depletion. Surprisingly, the transport of two small nucleophilic proteins, histone H1 and P(Lys)-cytochrome c (cytochrome c cross-linked with synthetic peptide NLSs), was also arrested by either chilling or energy depletion. In situ titration studies indicate that the transport arrest of H1 in chilled cells is mediated by a cytoplasmic receptor. Therefore, even though they are potentially able to diffuse into nuclei, histones and other small NLS-containing proteins are localized by a receptor-mediated process that precludes their diffusion through the nuclear pores.

Regulation of RNA processing and transport by a nuclear guanine nucleotide release protein and members of the Ras superfamily.

The RCC1 gene of mammals encodes a guanine nucleotide release protein (GNRP). RCC1 and a homolog in Saccharomyces cerevisiae (MTR1/PRP20/SRM1) have previously been implicated in control of mRNA metabolism and export from the nucleus. We here demonstrate that a temperature‐sensitive fission yeast mutant which has a mutation in a homologous gene, and two of three additional (mtr1/prp20/srm1) mutants accumulate nuclear poly(A)+ RNA at 37 degrees C. In S.cerevisiae, maturation of rRNA and tRNA is also inhibited at 37 degrees C. Nevertheless, studies with the corresponding BHK‐21 cell mutant indicate that protein import into the nucleus continues. MTR1 homologs regulate RNA processing at a point which is distinct from their regulation of chromosome condensation since: (i) poly(A)+ RNA accumulation in the fission yeast mutant precedes chromosome condensation, and (ii) unlike chromosome condensation, accumulation of nuclear poly(A)+ RNA does not require p34cdc28 kinase activation or protein synthesis. Moreover, experiments involving inhibition of DNA synthesis indicate that the S.cerevisiae homolog does not govern cell cycle checkpoint control. Since RCC1p acts as GNRP for Ran, a small nuclear GTPase of the ras superfamily, we have identified two homologs of Ran in S.cerevisiae (CNR1 and CNR2). Only CNR1 is essential, but both code for proteins extremely similar to Ran and can suppress mtr1 mutations in allele‐specific fashion. Thus, MTR1 and its homologs appear to act as GNRPs for a family of conserved GTPases in controlling RNA metabolism and transport. Their role in governing checkpoint control appears to be restricted to higher eukaryotes.

Nvj1p is the outer-nuclear-membrane receptor for oxysterol-binding protein homolog Osh1p in Saccharomyces cerevisiae

OSH1 belongs to a seven-member gene family in yeast that is related to mammalian oxysterol-binding protein (OSBP). Here, we investigate the targeting of Osh1p to nucleus-vacuole (NV) junctions in Saccharomyces cerevisiae. NV junctions are interorganelle interfaces mediated by Nvj1p in the nuclear envelope and Vac8p on the vacuole membrane. Together, Nvj1p and Vac8p form Velcro-like patches through which teardrop-like portions of the nucleus are pinched off into the vacuolar lumen and degraded by a process termed piecemeal microautophagy of the nucleus (PMN). Osh1p is targeted to NV junctions proportional to NVJ1 expression through a physical association with Nvj1p. NV junctions per se are not required for this targeting because Osh1p colocalizes with Nvj1p in the absence of Vac8p. NV-junction-associated Osh1p is also a substrate for PMN degradation. Although OSH1 is not required for NV-junction formation or PMN, PMN is defective in cells lacking the yeast OSBP family (Osh1p to Osh7p). By contrast, the vesicular targeting of aminopeptidase I to the vacuole by macroautophagy is not dependent on the Osh protein family. We conclude the formation of nuclear PMN vesicles requires the overlapping activities of Osh1p and other Osh family members.

Saccharomyces cerevisiae Nip7p is required for efficient 60S ribosome subunit biogenesis.

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.

Nip7p Interacts with Nop8p, an Essential Nucleolar Protein Required for 60S Ribosome Biogenesis, and the Exosome Subunit Rrp43p

ABSTRACT NIP7 encodes a conserved Saccharomyces cerevisiae nucleolar protein that is required for 60S subunit biogenesis (N. I. T. Zanchin, P. Roberts, A. DeSilva, F. Sherman, and D. S. Goldfarb, Mol. Cell. Biol. 17:5001–5015, 1997). Rrp43p and a second essential protein, Nop8p, were identified in a two-hybrid screen as Nip7p-interacting proteins. Biochemical evidence for an interaction was provided by the copurification on immunoglobulin G-Sepharose of Nip7p with protein A-tagged Rrp43p and Nop8p. Cells depleted of Nop8p contained reduced levels of free 60S ribosomes and polysomes and accumulated half-mer polysomes. Nop8p-depleted cells also accumulated 35S pre-rRNA and an aberrant 23S pre-rRNA. Nop8p-depleted cells failed to accumulate either 25S or 27S rRNA, although they did synthesize significant levels of 18S rRNA. These results indicate that 27S or 25S rRNA is degraded in Nop8p-depleted cells after the section containing 18S rRNA is removed. Nip7p-depleted cells exhibited the same defects as Nop8p-depleted cells, except that they accumulated 27S precursors. Rrp43p is a component of the exosome, a complex of 3′-to-5′ exonucleases whose subunits have been implicated in 5.8S rRNA processing and mRNA turnover. Whereas both green fluorescent protein (GFP)-Nop8p and GFP-Nip7p localized to nucleoli, GFP-Rrp43p localized throughout the nucleus and to a lesser extent in the cytoplasm. Distinct pools of Rrp43p may interact both with the exosome and with Nip7p, possibly both in the nucleus and in the cytoplasm, to catalyze analogous reactions in the multistep process of 60S ribosome biogenesis and mRNA turnover.

Binding dynamics of structural nucleoporins govern nuclear pore complex permeability and may mediate channel gating.

ABSTRACT The nuclear pore complex (NPC) is a permeable sieve that can dilate to facilitate the bidirectional translocation of a wide size range of receptor-cargo complexes. The binding of receptors to FG nucleoporin docking sites triggers channel gating by an unknown mechanism. Previously, we used deoxyglucose and chilling treatments to implicate Nup170p and Nup188p in the control of NPC sieving in Saccharomyces cerevisiae. Here, we report that aliphatic alcohols increase the permeability of wild-type and nup170Δ NPCs. In conjunction with increases in permeability, aliphatic alcohols, deoxyglucose, and chilling trigger the reversible dissociation of several nucleoporins from nup170Δ NPCs. These results are consistent with the hypothesis that NPC gating occurs when molecular latches composed of FG repeats and structural nucleoporins dissociate.

Nucleus-Vacuole Junctions and Piecemeal Microautophagy of the Nucleus in S. cerevisiae

Various modes of autophagy conspire to degrade virtually every compartment of the eukaryotic cell. In Saccharomyces cerevisiae, a process called “piecemeal microautophagy of the nucleus” (PMN) even pinches off and degrades nonessential portions of the nucleus. PMN is a constitutive process induced to high levels by starvation or rapamycin, an inhibitor of TOR kinase. PMN occurs at nucleus-vacuole (NV) junctions, which are Velcro-like patches formed by interactions between the vacuole membrane protein Vac8p and the outer-nuclear-membrane protein Nvj1p. In response to nutrient depletion, Nvj1p increasingly binds and sequesters two proteins with roles in lipid metabolism, Osh1p and Tsc13p. Tsc13p is required for the normal biogenesis of PMN vesicles. The sequestration of Osh1p by Nvj1p likely serves to negatively regulate the trafficking of tryptophan permease(s) to the plasma membrane. Thus, NV junctions and PMN orchestrate novel and sophisticated responses to nutrient limitation.

Evolution of the Metazoan-Specific Importin α Gene Family

Importin αs are import receptors for nuclear localization signal-containing proteins. Most animal importin αs assort into α1, α2, and α3 groups. Studies in Drosophila melanogaster, Caenorhabditis elegans, and mouse suggest that the animal importin α gene family evolved from ancestral plant-like genes to serve paralog-specific roles in gametogenesis. To explore this hypothesis we extended the phylogenetic analysis of the importin α gene family to nonbilateral animals and investigated whether animal-like genes occur in premetazoan taxa. Maximum likelihood analysis suggests that animal-like importin α genes occur in the Choanoflaggelate Monosiga brevicollis and the amoebozoan Dictyostelium; however, both of these results are caused by long-branch attraction effects. The absence of animal-like α genes in premetazoan taxa is consistent with the hypothesis that they duplicated and then specialized to function in animal gametogenesis. The gene structures of the importin αs provide insight into how the animal importin α gene family may have evolved from the most likely ancestral gene. Interestingly, animal α1s are more similar to plant and fungal α1-like sequences than they are to animal α2s or α3s. We show that animal α1 genes share most of their introns with plant α1-like genes, and α2s and α3s share many more intron positions with each other than with the α1s. Together, phylogenetics and gene structure analysis suggests a parsimonious path for the evolution of the mammalian importin α gene family from an ancestral α1-like progenitor. Finally, these results establish a rational basis for a unified nomenclature of the importin α gene family.

The nucleoporins Nup170p and Nup157p are essential for nuclear pore complex assembly

We have established that two homologous nucleoporins, Nup170p and Nup157p, play an essential role in the formation of nuclear pore complexes (NPCs) in Saccharomyces cerevisiae. By regulating their synthesis, we showed that the loss of these nucleoporins triggers a decrease in NPCs caused by a halt in new NPC assembly. Preexisting NPCs are ultimately lost by dilution as cells grow, causing the inhibition of nuclear transport and the loss of viability. Significantly, the loss of Nup170p/Nup157p had distinct effects on the assembly of different architectural components of the NPC. Nucleoporins (nups) positioned on the cytoplasmic face of the NPC rapidly accumulated in cytoplasmic foci. These nup complexes could be recruited into new NPCs after reinitiation of Nup170p synthesis, and may represent a physiological intermediate. Loss of Nup170p/Nup157p also caused core and nucleoplasmically positioned nups to accumulate in NPC-like structures adjacent to the inner nuclear membrane, which suggests that these nucleoporins are required for formation of the pore membrane and the incorporation of cytoplasmic nups into forming NPCs.