Molecular Architecture of the Yeast Nuclear Pore Complex: Localization of Nsp1p Subcomplexes

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© The Rockefeller University Press, 0021-9525/1998//577 $5.00
The Journal of Cell Biology, Volume 143, Number 3, , 1998 577-588

Regular Articles

Molecular Architecture of the Yeast Nuclear Pore Complex: Localization of Nsp1p Subcomplexes

Birthe Fahrenkrog^*, Eduard C. Hurt, Ueli Aebi^*, and Nelly Panté^*

^* M.E. Müller Institute for Microscopy, Biozentrum, University of Basel, CH-4056 Basel, Switzerland; and University of Heidelberg, Biochemie-Zentrum Heidelberg, D-69120 Heidelberg, Germany

The nuclear pore complex (NPC), a supramolecular assembly of $~$ 100 different proteins (nucleoporins), mediates bidirectionaltransport of molecules between the cytoplasm and the cell nucleus. Extensive structural studies have revealed the three- dimensional(3D) architecture of Xenopus NPCs, and eight of the $~$ 12 clonedand characterized vertebrate nucleoporins have been localizedwithin the NPC. Thanks to the power of yeast genetics, 30 yeastnucleoporins have recently been cloned and characterized at the molecular level. However, the localization of these nucleoporinswithin the 3D structure of the NPC has remain elusive, mainlydue to limitations of preparing yeast cells for electron microscopy(EM). We have developed a new protocol for preparing yeast cellsfor EM that yielded structurally well-preserved yeast NPCs.A direct comparison of yeast and Xenopus NPCs revealed thatthe NPC structure is evolutionarily conserved, although yeastNPCs are 15% smaller in their linear dimensions. With this preparationprotocol and yeast strains expressing nucleoporins tagged withprotein A, we have localized Nsp1p and its interacting partners Nup49p, Nup57p, Nup82p, and Nic96p by immuno-EM. Accordingly,Nsp1p resides in three distinct subcomplexes which are locatedat the entry and exit of the central gated channel and at theterminal ring of the nuclear basket.

Key Words: colloidal gold • Nsp1p • nuclear pore complex • nucleoporin • yeast

Abbreviations used in this paper: 3D, three-dimensional; DHFR, dihydrofolate reductase; GFP, green fluorescent protein; MDa, megadaltons (10⁶ daltons); NE, nuclear envelope; NLS, nuclear localization signal; NPC, nuclear pore complex; Nups, nucleoporins; ProtA, protein A.

THE nuclear pore complex (NPC),¹ a supramolecular assemblyof proteins embedded in the double membrane of the nuclear envelope(NE), mediates the bidirectional transport of molecules betweenthe cytoplasm and the nucleus of eukaryotic cells (for reviewsee Görlich and Mattaj, 1996; Panté and Aebi, 1996a;Nigg, 1997; Ohno et al., 1998). Extensive electron microscopy (EM) studies using amphibian NEs have revealed a consensusmodel of the three-dimensional (3D) structure of the NPC (forreview see Davis, 1995; Panté and Aebi, 1996b). Accordingly,the NPC consists of an eightfold symmetric basic framework(also called the spoke complex), sandwiched between a cytoplasmicand a nuclear ring. The cytoplasmic ring is decorated witheight $~$ 50-nm- long fibrils, whereas the nuclear ring is cappedwith a cage-like assembly, called the nuclear basket. The ring-likebasic framework embraces the central gated channel which is implicated in signal- and energy-mediated bidirectional transportof macromolecules between the cytoplasm and the nucleus. Thiscentral gated channel is often plugged with a particle (calledcentral plug or transporter) of highly variable appearancewhose ultimate structure and functional role remain to be established.

Based on its molecular mass of $~$ 120 megadaltons (MDa) (Reichelt et al., 1990)and on the high degree of symmetry of the basic framework (8,2, 2), it is assumed that the NPC is composed of multiple copies(i.e., 8 or 16) of $~$ 100 different proteins, called nucleoporins(Nups). Whereas in vertebrates only 11 nucleoporins have been identified and molecularly characterized to date, in yeast the number of known Nups has now reached 30 (for review seePanté and Aebi, 1996b; Doye and Hurt, 1997; Fabre and Hurt, 1997).This rapid progress in identifying and characterizing yeastNups is due to (a) the development of a biochemical procedureto bulk isolate yeast NPCs (Rout and Blobel, 1993), (b) theuse of genetic screens designed both to identify proteins interactingwith a known Nup (i.e., synthetic lethal screens) and to isolatetransport defected mutants (for review see Fabre and Hurt, 1997),and (c) the recent completion of the yeast genome project.It is expected that in the near future all yeast Nups willbe identified.

Biochemical and genetic interactions among nucleoporins haveindicated that within the NPC different sets of nucleoporinsare organized in subcomplexes which may be isolated as such.The first identified and molecularly characterized NPC subcomplexwas the vertebrate p62 complex, consisting of the nucleoporinsp62, p58, p54, and p45 (Dabauvalle et al., 1990; Finlay et al., 1991;Kita et al., 1993; Guan et al., 1995; Hu et al., 1996). InXenopus egg lysates, p62 was also found engaged in a secondsubcomplex together with CAN/Nup214 (Macaulay et al., 1995).In addition, three other vertebrate NPC subcomplexes have alsobeen identified but not yet well characterized. These are theNup153 homo-oligomer, and the CAN/Nup214– Nup84 complexwith molecular masses of 1 MDa and 1.5– 2.0 MDa, respectively(Panté et al., 1994), and the Nup93– p205 complex(Grandi et al., 1997). These results indicate that Nups canbe organized in multiple subcomplexes. In yeast, Nsp1p (theputative homologue of p62; Carmo-Fonseca et al., 1991) has alsobeen isolated in two distinct subcomplexes. One subcomplex consistsof Nsp1p interacting with Nup49p, Nup57p, and Nic96p (Grandi et al., 1993), and the second complex contains Nsp1p and Nup82p (Grandi et al., 1995b).The first subcomplex may represent the yeast homologue of thevertebrate p62 complex, and in the following we will referto it as the Nsp1p complex. Another identified yeast subcomplexis the so-called Nup84p complex, consisting of the nucleoporinsNup84p, Nup85p, Nup120p, and Nup145p, and the proteins Sec13p(a protein involved in ER to Golgi transport) and Seh1p (a Sec13p homologue; Siniossoglou et al., 1996).

From the three yeast NPC subcomplexes described above, onlythe Nsp1p complex has been characterized at the molecular level(Schlaich et al., 1997). Accordingly, as shown by in vitroreconstitution experiments, purified recombinant Nsp1p, Nup49p,and Nup57p form a 150-kD complex containing one copy each ofthese three nucleoporins. Nup57p is the organizing center ofthis complex to which Nsp1p and Nup49p individually can bind.Although Nic96p does not bind to individual Nsp1p, Nup49p,and Nup57p, it associates to the fully assembled Nsp1p–Nup49p–Nup57p core complex (Schlaich et al., 1997). A common feature of the primary structure of Nsp1p and its interactingnucleoporins is the presence of heptad repeats that are predictedto form ${alpha}$ -helical coiled-coil segments. These heptad repeatsegments reside in the COOH-terminal domain of Nsp1p, Nup49p,and Nup57p, and are involved in the interactions among theseproteins. Moreover, full-length Nic96p, but not a mutant formlacking the NH₂-terminal coiled-coil domain of Nic96p, associateswith the Nsp1p core complex (Grandi et al., 1995b; Schlaich et al., 1997).Similarly, the Nsp1p–Nup82p complex is held together by ${alpha}$ -helical coiled-coil interactions between these two proteins(Grandi et al., 1995a).

In addition to the ${alpha}$ -helical coiled-coil domains, the Nups ofthe Nsp1p core complex also contain repetitive FXFG and GLFGsequence motifs whose specific role in nuclear transport isstill speculative (e.g., Radu et al., 1995). Similarly, otheryeast nucleoporins and a number of vertebrate nucleoporinscontain FXFG sequence motifs. However, the relationship betweenthese vertebrate FXFG repeat nucleoporins and the yeast FXFGrepeat nucleoporins is unclear. Except for the Nsp1p core complexwhich is considered to be the yeast homologue of the vertebratep62 complex, p62 and Nsp1p reveal 31% identity and 50% homologyin their COOH-terminal regions (Carmo-Fonseca et al., 1991),and Nup49p and Nup57p share homology with rat p58/45 and ratp54 respectively (Doye and Hurt, 1997; Fabre and Hurt, 1997).Recently, vertebrate Nic96p homologues, called Nup93, havebeen identified which share 27% identity and 50% similaritywith yeast Nic96p (Allende et al., 1996; Grandi et al., 1997).As Nic96p is interacting with Nsp1p, Nup93 interacts with asmall fraction of the p62 moiety. Similar to the p62 complex,the two Nsp1p complexes are directly implicated in nucleartransport: whereas mutation or deletion of the NSP1 or the NIC96 gene led to import defects (Mutvei et al., 1992; Nehrbass et al., 1993;Grandi et al., 1993), NUP57, NUP49, and NUP82 mutant strainsare defective in both protein import and mRNA export (Sharma et al., 1996;Grandi et al., 1995b; Hurwitz and Blobel, 1995). Moreover,synthetic lethal screens indicated genetic interactions of Nsp1p with several nucleoporins, nearly all of them being involvedin mRNA export (for review see Doye and Hurt, 1997; Fabre and Hurt, 1997).

Little is known about how Nups interact with each other tobuild the NPC, and about the participation of different Nupsin nuclear import and export. To obtain a more detailed insightinto the molecular architecture of the NPC that may allow todeduce Nup function, it is necessary to map nucleoporins withinthe 3D structure of the NPC. In vertebrates these localizationstudies are limited because only few nucleoporins have beenidentified and molecularly characterized. Nevertheless, eightvertebrate nucleoporins have now been localized within the 3Darchitecture of the NPC by immuno-EM (Panté et al., 1994;Guan et al., 1995; Grandi et al., 1997). Yeast will be an excellent system for mapping Nups and studying the functional roles of nucleoporins, because 30 Nups have already been identifiedand molecularly characterized, and several mutant strains thataffect both import of nuclear proteins and export of RNA havebeen created. Although these Nups have been localized to theNE rim by immunofluorescence microscopy, none of them have beenlocalized within the 3D NPC architecture. This is in part dueto limitations in EM sample preparation of yeast cells, andto the high cross-reactivity of anti-Nup antibodies caused bythe presence of highly antigenic repetitive sequence motifswithin the amino acid sequence of nucleoporins (e.g., the FXFGsequence motifs). The yeast system also offers the advantage of introducing genetic manipulations. Thus, knowing the moleculararchitecture of yeast NPCs will open the possibility to combinegenetic with structural and functional studies. These typeof studies could yield a more detailed picture of how NPCstransport macromolecules into and out of the nucleus.

Here we have developed a new EM sample preparation protocolthat yields structurally well-preserved yeast NPCs. Using thisnew protocol in combination with yeast strains expressing nucleoporinstagged with protein A, we have mapped five yeast nucleoporinswithin the 3D architecture of the NPC. Specifically, we reportthe localization of Nsp1p and its interacting proteins Nup49p,Nup57p, Nup82p, and Nic96p within the 3D architecture of yeast NPCs by immuno-EM. Interestingly, our localization studiesindicate that Nsp1p resides in three distinct subcomplexes withinthe NPC which are located at NPC sites where cargo or transportligands can be arrested during nuclear protein import (Panté and Aebi, 1995,1996c; Görlich et al., 1996). Thus, we proposed that thesesubcomplexes are directly involved in protein import.

Materials and Methods

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Abstract
Materials and Methods
Results
Discussion
References

Yeast Strains and Plasmids
The yeast strains and plasmids used in this study are listedin Table III and shown in Fig. 2, respectively. Yeast cellswere grown in complete medium (YPAD; 1% yeast extract, 2% bacto-peptone,2% glucose, 0.003% adenine sulfate) at 30°C.

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Table III Yeast Strains

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Figure 2 Schematic diagram of the fusion constructs used in this study: (A) Four IgG-binding domains derived from S. aureus protein A (ProtA) and the essential NSP1 COOH-terminal domain. (B) Two IgG-binding domains of ProtA and the NIC96 gene under control of the NOP1 promoter and URA3 selection. (C) Four IgG-binding domains of ProtA and the NUP49 gene. (D) Two IgG-binding domains of ProtA and the NUP57 gene under control of the NOP1 promotor and HIS3 selection. (E) Two IgG-binding domains of ProtA and the NUP82 gene under control of the NOP1 promotor and HIS3 selection. (F) Two IgG-binding domains of ProtA and the PUS1 gene under control of the NOP1 promotor and HIS3 selection. (g) Two IgG-binding domains of ProtA and the DHFR gene under control of the NOP1 promotor and URA3 selection. Right, abbreviations for the yeast strains carrying protein A–tagged nucleoporins used in this paper.

Epitope Tagging Yeast Nups with Protein A
The tagging of Nups with the IgG binding domain from Staphylococcus aureus protein A was described elsewhere (NSP1, NIC96, andDHFR: Grandi et al., 1993; NUP49: Wimmer et al., 1992; NUP57:Grandi et al., 1993; NUP82: Grandi et al., 1995b; PUS1: Simos et al., 1996).

Thin Section Electron Microscopy of Yeast Cells
Yeast cells were grown to an OD₆₀₀ from 1 to 2, and all procedureswere performed at room temperature unless otherwise stated.The cells were fixed by adding paraformaldehyde, pH 6.5, toa final concentration of 2% followed by incubation for 1 h.After fixation, the cells were centrifuged for 2 min at 1,000g, washed once in water, and then incubated for 3 min in 0.1M Tris, pH 9.5, 10 mM DTT. After washing in SP buffer (1.2 Msorbitol, 20 mM potassium phosphate buffer, pH 7.4), the cellswere resuspended in this buffer to 5 OD₆₀₀/ml. Spheroplastswere obtained by adding 5 U/ml zymolyase 20T (Seikagaku Corporation,Tokyo, Japan) and a 1:100 dilution of solution P (87 mg PMSFand 1.5 mg pepstatin A in 5 ml dry absolute ethanol) to thecells, followed by a 20-min incubation at 30°C while shakingwith 200 rpm. The spheroplasts were then washed twice by adding5 ml of KPi buffer (0.1 M potassium phosphate buffer, pH 6.5),followed by centrifugation at 4,000 rpm for 2 min. Samples wereprefixed with 2% glutaraldehyde in KPi for 1 h, washed twotimes with KPi, embedded in low melting agarose, and postfixedwith 1% OsO₄ in KPi for 1 h. Next the fixed spheroplasts werewashed two times in KPi, dehydrated with 50% ethanol for 10min, and bloc stained in 70% ethanol/2% uranyl acetate for1 h. The samples were further dehydrated with 90% ethanol for10 min, followed by three times 100% ethanol (each for 10 min),and finally with 100% acetone for 10 min. Next the sampleswere infiltrated with mixtures of Epon (Fluka, Buchs, Switzerland)and acetone 1:1 for 1 h, 2:1 for 1 h, and finally in pure Eponfor 3–4 h. Samples were placed into gelatin capsulesfilled with fresh pure Epon resin and polymerized over nightat 60°C.

Thin sections were cut on a Reichert Ultracut microtome (Reichert-JungOptische Werke, Vienna, Austria) using a diamond knife. Thesections were collected on pallodion-coated copper EM gridsand stained with 6% uranyl acetate for 1 h and 2% lead citratefor 2 min. Electron micrographs were recorded with a HitachiH-7000 transmission electron microscope (Hitachi Ltd., Tokyo,Japan) operated at an acceleration voltage of 100 kV.

Immunogold Localization of Yeast Nups
Colloidal gold particles, $~$ 8 nm in diameter, were prepared byreduction of tetrachloroauric acid with sodium citrate in thepresence of tannic acid (Slot and Geuze, 1985). The polyclonalanti–protein A antibody (Sigma Chemical Co., St. Louis,MO) was conjugated to colloidal gold particles as describedby Baschong and Wrigley (1990). After conjugation, the complexeswere centrifuged at 32,000 g for 15 min. The soft pellet wasresuspended in KPi buffer containing 0.1% BSA (Merck, Darmstadt,Germany) and used for labeling spheroplasted yeast cells.

Yeast cells were grown and spheroplasted as described above.1.5 ml of spheroplasted yeast cells were transferred in anEppendorf tube, washed two times in 1 ml KPi, resuspended in1 ml KPi containing 0.05% Triton X-100, and spun down immediately.The Triton X-100–extracted yeast cells were washed fourtimes in KPi, resuspended in 100 µl anti–proteinA antibody labeled with 8-nm colloidal gold (75 µg/ml)and incubated for 3 h at 30°C while shaking with 200 rpm.Next, the cells were washed twice in KPi containing 0.1% BSA,fixed, dehydrated, Epon-embedded, and then prepared for EMas described above.

Quantitation of Gold Labeling at the NPC
The position of gold particles associated with NPCs were measuredfrom electron micrographs of cross sections along the NE. Distancesof gold particles perpendicular to the central plane of theNPC and from the eightfold symmetry axis of the NPC were determined.

Stereology
Quantitation of the antibody labeling in the wild-type strainand the control strains ProtA-DHFR and ProtA-Pus1p were doneby a stereological counting method described by Lucocq (1992).In brief, ultrathin sections were selected at random and mountedon an EM grid. Electron micrographs of ultrathin sections wererecorded and printed on photographic paper with a final magnificationof 50,000. The area of the cytoplasm and the nucleus and thegold particle per cell were estimated with a square latticegrid of 20-mm spacing. 22, 18, and 15 cells for the wild-type,ProtA-Pus1p and, ProtA-DHFR were analyzed, respectively.

Isolation of Xenopus Oocyte Nuclei and Preparation of NEs
Nuclei were isolated from mature (stage six) Xenopus oocytes,and embedded and thin-sectioned exactly as described by Panté et al. (1994).

Fluorescence Microscopy
The in vivo location of GFP-C-Nsp1p was analyzed according toSegref et al. (1997) in the thermosensitive mutant nup49-313(Doye et al., 1994) and NUP49⁺ cells which were transformedwith plasmid SM666 (provided by S. Bailer, BZH, Heidelberg,Germany). SM666 is an ADE2-containing ARS/CEN plasmid containinga fusion construct between the genes encoding GFP and the Nsp1pCOOH-terminal domain. Cells were examined in the fluoresceinchannel of a Zeiss Axioskop fluorescence microscope (Carl Zeiss,Inc., Thornwood, NY). Pictures were taken with a Xillix Microimagercharge-coupled device camera (Xillix Technology Corp., BritishColumbia, Canada). Digital pictures were processed by modulesof the software Openlab (Improvision, Coventry, UK).

Results

Top
Abstract
Materials and Methods
Results
Discussion
References

Structural Analysis of Yeast NPCs
To establish the molecular architecture of the yeast NPC, wehave first developed an EM sample preparation protocol thatyields structurally well-preserved yeast NPCs (Fig. 1 A). Ourstrategy was to systematically test preparation conditionsto remove the yeast cell wall. For this purpose, we used differentcombinations of chemical prefixation and enzyme-digestion conditions.The best results were found with 2% paraformaldehyde prefixationand digestion with zymolyase 20T (see Materials and Methodsfor details). Good results were also obtained when the yeast cells were prefixed with 0.125% glutaraldehyde for 5 min atroom temperature instead (Fig. 1 A, top). However, in combinationwith Triton X-100 detergent extraction (a step that is necessaryfor pre-embedding immunolabeling, see below), the glutaraldehydeprefixation was not strong enough so that the yeast cells werecompletely destroyed. On the other hand, increasing the glutaraldehydeconcentration (i.e., 0.25 or 0.5%) interfered with the zymolyase activity so that the cell wall was not removed. Hence, we invariably used 2% paraformaldehyde or 0.125% glutaraldehydeprefixation for structural studies, but always 2% paraformaldehydefor immunolabeling.

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Figure 1 Yeast NPCs. (A) Cross section through the NE and a gallery of selected electron micrographs of NPC cross sections. Large arrowheads, nuclear baskets; small arrowheads, cytoplasmic fibrils; c, cytoplasm; n, nucleus. (B) Schematic comparison of Xenopus and yeast NPCs. Bar, 100 nm.

As shown in Fig. 1 A, similar to amphibian NPCs, our preparationprotocol reveals the existence of peripheral NPC structuressuch as the cytoplasmic fibrils (small arrowheads) and the nuclearbaskets (large arrowheads). Direct comparison of yeast and XenopusNPCs (the best structurally characterized higher eukaryoticNPC) after using the same Epon embedding protocol, revealedthat although the overall architecture of the NPC is ratherconserved, yeast NPCs appear typically 15% smaller in their linear dimensions than Xenopus NPCs. As documented in Fig.1 B and Table I, the vertical distance between the cytoplasmicand nuclear ring, the lumenal space of the NE, and the lengthof the cytoplasmic fibrils appear very similar in the two species,whereas the total diameter of the NPC and the height of thenuclear baskets appear significantly smaller in yeast as comparedwith Xenopus.

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Table I Size of Xenopus NPC in Comparison with Yeast NPC

Nsp1p Is Found at Three Distinct NPC Sites
After having succeeded to prepare structurally well-preservedyeast NPCs, we next wanted to examine in detail the locationof yeast Nups within the 3D architecture of the NPC. Sinceanti-Nup antibodies frequently cross-react on the EM level,for our localization studies, we used yeast strains expressingNups tagged with protein A in combination with a colloidal gold-conjugatedanti–protein A antibody (see Materials and Methods). Theselocation studies were started with Nsp1p, the first yeast Nupthat has been identified and molecularly characterized (Hurt, 1988; Nehrbass et al., 1990). For this purpose we used a yeast straindisrupted for the chromosomal NSP1 gene, and complemented byplasmid-borne (single copy ARS/CEN plasmid) Nsp1p tagged withprotein A (ProtA–Nsp1p; see Fig. 2). We have not integratedProtA–NSP1 into the genome to guarantee chromosomal expressionlevels. However, we found that the amount of Nsp1p expressedfrom a centromeric plasmid is similar to the expression level when the NSP1 gene expression is driven by the chromosomalNSP1 gene copy (data not shown).

By immunogold EM we found that the anti–protein A antibodysignificantly labeled the NPC on both the cytoplasmic and thenuclear face of ProtA–Nsp1p cells (Fig. 3 A). To identifythe NPC sites labeled by the antibody we performed quantitativeanalysis of the gold particle distribution along the two symmetryaxis of the NPC (i.e., the central plane of the NPC and theeightfold symmetry axis). As indicated in Fig. 3 B, the distributionof the gold particles relative to the central plane of the NPCrevealed three major peaks at vertical distances of $~$ 20, –20,and –80 nm from the central plane of the NPC which correspondto the cytoplasmic and the nuclear periphery of the centralgated channel, and to the terminal ring of the nuclear basket.As these NPC components are located about the center of the eightfold symmetry axis, 93% of the gold particles were foundwithin a radius of 30 nm from this symmetry axis (see Fig.3 B). The quantitative analysis also revealed that the labelingof the cytoplasmic site was more abundant than the labelingof the two distinct nuclear sites (see Fig. 3 B). This is probablydue to the fact that with the pre-embedding labeling techniquethat we used the antibody first reaches the cytoplasmic epitope,where it is bound before it can diffuse through the permeabilizedNE to the nuclear epitopes.

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Figure 3 Immunogold localization of Nsp1p in ProtA–Nsp1p cells. (A) Triton X-100– extracted spheroplasts from ProtA–Nsp1p cells were pre-immunolabeled with a polyclonal anti–protein A antibody conjugated to 8-nm colloidal gold, and prepared for EM by Epon embedding and thin sectioning. Shown is a view along a cross sectioned NE stretch with labeled NPCs (arrowheads), together with a gallery of selected examples of gold-labeled NPC cross sections. The antibody labeled the cytoplasmic periphery and the nuclear periphery of the central gated channel, and the terminal ring of the nuclear baskets. c, cytoplasm; n, nucleus. (B) Quantitative analysis of the gold particles associated with the NPCs in the ProtA–Nsp1p strain after labeling with gold-conjugated anti–protein A antibody. 88 gold particles were scored. Bars, 100 nm.

To demonstrate that the gold-conjugated anti–protein A antibody specifically labeled the NPCs of ProtA–Nsp1p cells, we carried out similar labeling experiments with controlstrains expressing either a cytosolic or nuclear reporter proteintagged with protein A. For a cytosolic protein, a strain expressingthe cytosolic mouse dihydrofolate reductase (DHFR) tagged withprotein A (ProtA–DHFR, see Fig. 2, Grandi et al., 1993),whereas for a nuclear protein a strain expressing Pus1p, a proteininvolved in tRNA biogenesis, tagged with protein A (ProtA–Pus1p,see Fig. 2; Simos et al., 1996) were used. As expected, forProtA– DHFR we obtained gold labeling predominantly inthe cytoplasm with a very small nuclear background, and for ProtA–Pus1p the gold particles accumulated in the nucleuswith some cytoplasmic background (Table II). As a control,we also used a wild-type strain expressing no protein A–taggedproteins. When these wild-type cells were prepared for immunolabelingby exactly the same protocol as the mutant strains, no goldlabeling of these cells was found except for a small cytoplasmicbackground (Table II). In neither wild-type control nor ProtA-DHFRand ProtA-Pus1p strains we could detect any significant goldlabeling of the NPCs. In addition, an antibody against Nsp1p (Hunter et al., 1998) labeled exactly the same NPC sites of wild-type cells as the anti–protein A antibody in ProtA–Nsp1p cells (Fahrenkrog, B., N. Panté, and J. Aris, unpublishedresults). Therefore, our immuno-EM protocol using yeast strainscarrying protein A–tagged Nups is able to reveal the locationof yeast Nups at the ultrastructural level.

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Table II Quantitation of Antibody Labeling in Yeast Control Strains

Nic96p Colocalizes with Nsp1p
As described in the Introduction, biochemical studies have demonstrated the existence of two Nsp1p complexes. To identifythese Nsp1p complexes within the architecture of the yeastNPC, we next localized the Nsp1p-interacting proteins. Usingour immuno-EM protocol and a yeast strain expressing Nic96ptagged with protein A (ProtA-Nic96p, see Fig. 2), we found thatthe location of this Nup coincides with that of Nsp1p (i.e.,at the cytoplasmic and nuclear periphery of the central gatedchannel and the terminal ring of the nuclear baskets; Fig. 4A) with a preference of the cytoplasmic epitope (see Fig. 4B). However, unlike for ProtA–Nsp1p, there was more abundantlabeling at the nuclear baskets than at the nuclear peripheryof the central channel (compare Fig. 3 B with Fig. 4 B). As with ProtA–Nsp1p, $~$ 90% of the gold particles were found within a radius of 30 nm from the eightfold symmetry axis of the NPC (Fig. 4 B).

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Figure 4 Localization of Nic96p in the ProtA–Nic96p strain. (A) Gallery of selected NPC cross sections showing labeling with the anti–protein A antibody conjugated to 8-nm colloidal gold in Triton X-100–extracted spheroplasts form ProtA–Nic96p cells. Similar to Nsp1p (see Fig. 3), Nic96p is localized at the cytoplasmic (top) and the nuclear periphery (middle) of the central gated channel, and at the terminal ring of the nuclear baskets (bottom). c, cytoplasm; n, nucleus. (B) Quantitation of the gold particle distribution associated with NPCs in the ProtA–Nic96p strain. 80 gold particles were scored. Bar, 100 nm.

Nup49p and Nup57p Reside Both at the Cytoplasmic and the Nuclear Periphery of the Central Gated Channel
Our locations of ProtA–Nsp1p and ProtA–Nic96p (Figs.3 and 4) suggest that the Nsp1p–Nup49p–Nup57p–Nic96p subcomplex may reside in three distinct NPC sites. To confirmthis further, we localized Nup49p and Nup57p, again using yeaststrains expressing these Nups tagged with protein A (see Fig.2). As illustrated in Fig. 5, A and C, we localized ProtA–Nup49pand Nup57p–ProtA at both the cytoplasmic and the nuclearperiphery of the central gated channel. However, based on ourlabeling data, neither Nup49p nor Nup57p were located at theterminal ring of the nuclear baskets. As already found forProtA–Nsp1p and ProtA–Nic96p (see Fig. 3 B andFig. 4 B), quantitative analysis of the gold particle distributionwith regard to the central plane of the NPC (Fig. 5, B andD) indicates the same preference for the cytoplasmic epitope(see Fig. 5 A, top). Quantitation of the gold labeling withrespect to the central plane of the NPC revealed that for Nup57p–ProtA, almost 100% of the cytoplasmic gold particles were detectedin a range of 5–35 nm from this plane (see Fig. 5 D), whereas for ProtA–Nup49p, ProtA–Nsp1p, and ProtA–Nic96p, most of the gold particles were found in a range of 20–45 nm from the central pane (see Fig. 3 B, Fig. 4B, and Fig. 5 B). Hence, Nsp1p, Nic96p, and Nup49p are located more peripherally than Nup57p. In fact, our immunolocalizationdata are in agreement with data obtained by in vitro reconstitutionexperiments, indicating that Nup57p is the organizing centerof the Nsp1p–Nup57p–Nup49p core complex (Schlaich et al., 1997).

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Figure 5 Nup49p (A) and Nup57p (C) are located at the cytoplasmic and the nuclear periphery of the central gated channel. Triton X-100–extracted spheroplasts from the ProtA–Nup49p and Nup57p–ProtA strains were incubated with an anti– protein A antibody conjugated to 8-nm colloidal gold (B and D). c, cytoplasm; n, nucleus. Distribution of the gold particles associated with NPCs in the ProtA–Nup49p and Nup57p–ProtA strains, respectively. 79 and 93 gold particles were scored, respectively. Bars, 100 nm.

Nup82p Resides Exclusively at the Cytoplasmic Periphery of the Central Gated Channel
Nup82p, a fourth Nsp1p-interacting protein, occurs in an independentsubcomplex with Nsp1p lacking Nup49p, Nup57p, and Nic96p (seeIntroduction). To localize Nup82p, pre-embedding labeling immuno-EMusing a yeast strain expressing Nup82p tagged with proteinA (ProtA–Nup82p, see Fig. 2) was carried out. As documentedin Fig. 6, we found that Nup82p has only cytoplasmic epitopeswith 95% of the gold particles at 38.3 ± 9.9 nm fromthe central plane of the NPC (Fig. 6 B). This finding mightsuggest that Nup82p is a constituent of the cytoplasmic fibrils. However, the analysis of the gold particle distribution alongthe eightfold symmetry axis revealed that 90% of the gold particleswere located within a radius of 0–30 nm NPC (Fig. 6 B).As the cytoplasmic fibrils are located up to 50 nm from theeightfold symmetry axis, we concluded that Nup82p is locatedat the cytoplasmic periphery of the central gated channel.Since Nsp1p, Nic96p, Nup49p, and Nup57p were predominatelydetected within a distance of 5–30 nm from the centralplane of the NPC, Nup82p is located more peripheral than thesenucleoporins (compare Fig. 3 B, Fig. 4 B, and Fig. 5, B andD with Fig. 6 B).

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Figure 6 Nup82p is found only at the cytoplasmic periphery of the central gated channel. (A) Triton X-100–extracted spheroplasts from ProtA–Nup82p cells were pre-immunolabeled with an anti–protein A antibody directly conjugated to 8-nm gold. Shown are a stretch along the NE and a gallery of selected examples of gold-labeled NPC cross sections. c, cytoplasm; n, nucleus. Bars, 100 nm. (B) The quantitative analysis of the gold particle distribution revealed that Nup82p resides in the center of the NPC in a distance of $~$ 40 nm from the central plane of the NPC. 106 gold particles were scored for the quantitative analysis.

In Vivo GFP–Nsp1p Location in the Nup49-313 Thermosensitive Mutant
To find out whether the association of Nsp1p with the NPCsis altered if one of the interacting Nup is mutated, the invivo location of green fluorescent protein (GFP)- tagged Nsp1pwas analyzed in thermosensitive nup49-313 cells (Doye et al., 1994).Therefore, NUP49⁺ and nup49-313 cells were transformed witha plasmid harboring a fusion construct between GFP and theNsp1p COOH-terminal domain. In NUP49⁺ cells, GFP–Nsp1pexhibits a typical NPC labeling (i.e., punctate staining ofthe NE) at both permissive and restrictive temperatures (Fig.7). In contrast, the in vivo location of Nsp1p drasticallychanged when nup49-313 cells were shifted for 6 h to 37°C.Cells largely lost the characteristic ring- and dot-like stainingof the nuclear periphery and GFP–Nsp1p accumulated inthe cytoplasm (Fig. 7). However, a residual ring-like staining of the NE remained in nup49-313 cells under restrictive conditionswhich could be the pool of Nsp1p associated with Nup82p (Grandi et al., 1995b).When nup49-313 cells were shifted back from 37° to 20°C,a distinct and prominent ring-like and punctate NE stainingof GFP–Nsp1p reappeared. This shows that the in vivo targetingof a significant pool of Nsp1p to the NPCs requires the intactnessof the other members (e.g., Nup49p) of the Nsp1p–Nup49p–Nup57p complex.

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Figure 7 In vivo location of GFP-tagged Nsp1p in nup49-313 cells. NUP49⁺ and nup49-313 cells transformed with a single copy ARS/CEN/ADE2 plasmid harboring a fusion construct between GFP and the Nsp1p COOH-terminal domain were grown at permissive temperature (20°C) or shifted for 6 h to restrictive temperature (37°C). In the case of the nup49-313 strain, cells were regrown after a 6-h shift to 37°C for a further 2 h at the permissive temperature (20°C). Cells were inspected in the fluorescence microscope to detect the GFP fusion protein and also viewed by Nomarski optics.

	Discussion

Top Abstract Materials and Methods Results Discussion References

Although significant progress has been made to elucidate the3D architecture of the NPC and to clone and molecularly characterizeNups, the 3D location of many of the known Nups has remainedelusive. This is in part due to the high cross-reactivity ofthe available anti-Nup antibodies. Because yeast is an excellentsystem to combine biochemical and genetic manipulations withfunctional assays, and because most of the nucleoporins identifiedto date are from yeast NPCs, we have started to dissect themolecular architecture of the yeast NPC. In the present investigation, we have structurally analyzed yeast NPCs by developing anEM sample preparation protocol that for the first time reproduciblyyields structurally well-preserved yeast NPCs. We then adaptedthis sample preparation protocol to localize Nsp1p and itsinteracting nucleoporins Nup49p, Nup57p, Nup82p, and Nic96pwithin the 3D architecture of the yeast NPC.

Our method revealed that yeast NPCs are built according to avery similar architecture as vertebrate NPCs (e.g., Xenopus,Chironomus, rat). Specifically, we have documented the existenceof cytoplasmic fibrils and a nuclear basket within the yeastNPC (see Fig. 1 A). Strikingly, our analysis revealed thatalthough yeast and Xenopus NPCs exhibit very much the samestructural organization, yeast NPCs are about 15% smaller intheir linear dimensions than Xenopus NPCs (see Fig. 1 B, andTable I). Hence, it appears that the overall 3D architectureof the NPC is evolutionarily conserved from yeast to highereukaryotes (e.g., Xenopus, Chironomus, rat). The peripheralcomponents of the yeast NPC have not been completely and reproduciblyvisualized in previous structural studies (Rout and Blobel, 1993;Yang et al., 1998). This is probably because these studies wereperformed with highly enriched, detergent-extracted yeast NPCs,a procedure that might damage or dissociate peripheral componentssuch as the cytoplasmic fibrils and the nuclear baskets. Infact, it has been well documented that in Xenopus oocytes detergent extraction of their NE releases (nonquantitatively) the cytoplasmicand nuclear ring with attached cytoplasmic fibrils and nuclearbasket from the basic framework or spoke complex (Reichelt et al., 1990;Jarnik and Aebi, 1991). Hence, it is most likely that the isolatedyeast NPCs reported previously (Rout and Blobel, 1993; Yang et al., 1998)only represent their basic framework rather than the intactyeast NPC.

To map nucleoporins within the 3D structure of the yeast NPC,we have used our new sample preparation protocol of yeast cellsin combination with immuno-EM. However, to avoid the high degreeof cross-reactivity commonly encountered with anti-Nup antibodies(see Introduction), we used yeast strains disrupted for a givenNup gene and complemented by this Nup tagged with protein A, in combination with a high-affinity anti–protein Aantibody directly conjugated to 8-nm-diam colloidal gold. Withthis approach, we have localized Nsp1p together with its interactingNups: Nup49p, Nup57p, Nup82p, and Nic96p. As illustrated inFig. 8, these location studies revealed that Nsp1p residesin three subcomplexes located at distinct NPC sites: the Nsp1p–Nup49p–Nup57p–Nic96pcomplex (i.e., the Nsp1p complex) located at both the cytoplasmic and the nuclear periphery of the central channel, the Nsp1p–Nup82pcomplex exclusively located at the cytoplasmic periphery ofthe central gated channel, and the Nsp1p–Nic96p complexlocated near or at the terminal ring of the nuclear basket.Biochemical evidence for the latter complex has not been achievedso far.

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Figure 8 Schematic representation of the yeast NPC with the 3D localization of three Nsp1p subcomplexes. The Nsp1p–Nup49p–Nup57p– Nic96p complex (i.e., the Nsp1p complex) is localized at both the cytoplasmic and nuclear periphery of the central gated channel, and the Nsp1p–Nup82p complex resides only at the cytoplasmic periphery of the central gated channel. In addition, a third Nsp1p complex consisting of Nsp1p interacting with Nic96p is located at the terminal ring of the nuclear baskets. c, cytoplasmic, and n, nuclear side of the NE.

The location of the Nsp1p complex within the 3D architectureof the yeast NPC is similar to that of the p62 complex (Guan et al., 1995),its putative homologue within the vertebrate NPC. Moreover,similar to Nsp1p, p62 was also found near or at the terminalring of the nuclear baskets of Xenopus oocyte NPCs (Panté and Aebi, 1993).The location of Nic96p is somewhat similar to that of its vertebrate homologue Nup93, which resides at the nuclear periphery ofthe central gated channel and the terminal ring of the nuclearbaskets, but, unlike Nic96p, Nup93 is absent from the cytoplasmicperiphery of the central gated channel (Grandi et al., 1997).This difference in the location between Nic96p and Nup93 maybe a reflection of the limited sequence homology between thesetwo Nups. These limited homologies, in turn, may result insimilar but not identical function(s) of these Nups. For Nic96pand Nup93, at least, this appears to be the case: both proteinsare required for nuclear pore biogenesis, but only Nic96p was shown to be involved in protein import (Zabel et al., 1996; Grandi et al., 1997).

We found Nup82p to be the most peripheral Nsp1p-interactingprotein on the cytoplasmic side of the NPC. Very recently,Nup159p, a third member of the Nsp1p– Nup82p subcomplex,was identified (Belgareh et al., 1998). This Nup was previouslylocalized to the cytoplasmic face of the yeast NPC (Kraemer et al., 1995),where it preferentially resided at a distance of $~$ 40 nm fromthe central plane of the NPC, in good agreement with our localization of Nup82p.

Since the multiple locations of Nsp1p and Nic96p represent NPCsites at which cargo or transport ligands can be arrested duringnuclear protein import (Panté and Aebi, 1995, 1996c;Görlich et al., 1996), our data provide further evidencethat Nsp1p and Nic96p play central roles in nucleocytoplasmictransport. For example, Nsp1p may interact with the cargo atthese three NPC sites while it crosses the NPC. Alternatively,Nsp1p may be directly involved in nuclear transport by bindingtransport ligands or transport factors on one side of the NPCand accompanying them to the other side of the NPC, for example,by interacting with nucleoporins which, contrary to Nsp1p,have fixed positions. Thus, for import of a protein containinga nuclear localization signal (NLS) into the nucleus, the NLSprotein first binds to the import receptor complex (importin ${alpha}$ /β in vertebrate cells, Srp1p/Kap95p in yeast) in thecytoplasm. Subsequently this NLS protein–receptor complex(i.e., the cargo) docks to a cytoplasmic fibril, before itis delivered to the cytoplasmic periphery of the central gatedchannel. This interaction may involve interaction of importinβ with FXFG repeat sequences of Nsp1p, Nup49p, and Nup57p(for review see Fabre and Hurt, 1997), or a direct associationof the NLS protein with Nsp1p (Barth and Stochaj, 1996). Alternatively,Nsp1p may interact with the cargo via NTF2, a Ran-binding proteinthat has been implicated in the translocation of nuclear proteinsthrough the NPC (Clarkson et al., 1996).

In summary, we have visualized the cytoplasmic fibrils andthe nuclear baskets of yeast NPCs, and we have for the firsttime localized five yeast nucleoporins to distinct NPC components.Our immuno-EM data suggest that Nsp1p resides in three distinctcomplexes within the 3D architecture of the yeast NPC. Thefirst complex consists of Nsp1p, Nup82p, and possibly othernucleoporins (Belgareh et al., 1998) (Bailer, S., and E.C. Hurt,unpublished data), and it is located exclusively at the cytoplasmicperiphery of the central gated channel. The second complex consists of Nsp1p, Nup49p, Nup57p, and Nic96p, and it residesnear or at the cytoplasmic/nuclear entry/exit of the centralgated channel. Finally, the third complex containing at leastNsp1p and Nic96p is located at the terminal ring of the nuclearbasket. Whether Nsp1p resides permanently at this distinct sitesor, in association with cargo, can sequentially move from oneto the next site, remains to be established.

Acknowledgments

We thank A. Mandinova and C.-A. Schoenenberger (Muller Institute, Basel, Switzerland) for helpful suggestions concerning theexperimental procedures, S. Bailer (BZH, Heidelberg, Germany)for providing the plasmid SM666, J. Aris (University of Florida,Gainesville, FL) for providing the antibody against Nsp1p, R.Wyss (Muller Institute) for help with Figs. 1 B and 8, andH. Frefel and M. Zoller (Blozentrum, Basel, Switzerland) fortheir expert photographic work.

This work was supported by grants from the Swiss National Science Foundation (4036-044061 and 3100-053034), by the Kanton Basel-Stadt, and by the M.E. Müller Foundation of Switzerland.

Submitted: 4 June 1998

Revised: 28 August 1998

Address all correspondence to N. Panté, Institute ofBiochemistry, Swiss Federal Institute of Technology, Universitätsstrasse16, CH-8092 Zürich, Switzerland. Tel.: (41) 1-6323134.Fax: (41) 1-6321269. E-mail: nelly.pante{at}bc.biol.ethz.ch

References

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Abstract
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