Functional Analysis of the Hydrophobic Patch on Nuclear Transport Factor 2 Involved in Interactions with the Nuclear Pore in Vivo

doi:10.1074/jbc.M105054200

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Functional Analysis of the Hydrophobic Patch on Nuclear Transport Factor 2 Involved in Interactions with the Nuclear Pore in Vivo^*

B. Booth Quimby^§, Sara W. Leung, Richard Bayliss^¶, Michelle T. Harreman, Geetha Thirumala, Murray Stewart^¶, and Anita H. Corbett^**

From the Department of Biochemistry, Emory University School of Medicine, Atlanta, Georgia 30322 and ^¶ Medical Research Council Laboratory of Molecular Biology, Hills Road, Cambridge CB2 2QH, United Kingdom

Received for publication, June 1, 2001, and in revised form, July 6, 2001

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Nuclear transport factor 2 (NTF2) is a small homodimeric protein that interacts simultaneously with both RanGDP and FxFG nucleoporins.The interaction between NTF2 and Ran is essential for the importof Ran into the nucleus. Here we use mutational analysis to dissectthe in vivo role of the interaction between NTF2 and nucleoporins.We identify a series of surface residues that form a hydrophobicpatch on NTF2, which when mutated disrupt the NTF2-nucleoporininteraction. Analysis of these mutants in vivo demonstrates thatthe strength of this interaction can be significantly reducedwithout affecting cell viability. However, cells cease to be viableif the interaction between NTF2 and nucleoporins is abolishedcompletely, indicating that this interaction is essential forthe function of NTF2 in vivo. In addition, we have isolated adominant negative mutant of NTF2, N77Y, which has increased affinityfor nucleoporins. Overexpression of the N77Y protein blocks nuclearprotein import and concentrates Ran at the nuclear rim. Thesedata support a mechanism in which NTF2 interacts transiently withFxFG nucleoporins to translocate through the pore and import RanGDPinto thenucleus.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Nucleocytoplasmic transport occurs through nuclear pore complexes (NPCs),¹ large proteinaceous channels that perforate the nuclear membrane.Protein cargoes to be imported into the nucleus contain internalsequences, termed nuclear localization signals (NLS), that targetthem to the nucleus (1-3). However, cargo does not interact directlywith the NPC but is transported bound to soluble transport receptorsof the importin- $beta$ family of proteins (4, 5). The recentpurification and analysis of the yeast NPC indicates that themajority of the ~40 proteins that make up the NPC, collectivelytermed nucleoporins, are localized symmetrically throughout thepore complex (6). A subset of these proteins contains a phenylalanine-glycine(FG) repeat motif. These proteins appear to line the nuclear porechannel and can be subdivided further into either GLFG repeat-containingproteins or FxFG proteins (6, 7). Although the precise mechanismby which the transport receptor-cargo complex translocates throughthe NPC is largely unknown, importin- $beta$ family transport receptorshave been shown to interact with both the GLFG repeat and theFxFG repeat nucleoporins (8-16) suggesting that these proteinsare involved directly in the translocationprocess.

The small GTPase Ran is central to nucleocytoplasmic transport. Although Ran is localized throughout the cell, ~80% is concentratedwithin the nucleus (17). The Ran guanine nucleotide exchangefactor is tethered to DNA in the nucleus (18, 19), suggestingthat the majority of nuclear Ran is GTP-bound. On the other hand,RanGAP (Ran GTPase-activating protein) is predominantly cytoplasmic(20-22), suggesting that the majority of cytoplasmic Ran is GDP-bound.Thus, the nucleotide bound state of Ran may act as a cellularmarker that allows the transport machinery to distinguish betweenthe nuclear and cytoplasmic compartments of the cell. This strictcompartmentalization of the Ran effectors also suggests that Ranmust shuttle between the nucleus and cytoplasm to undergo a completeround of GTP hydrolysis. It is hypothesized that RanGTP exitsthe nucleus complexed with importin- $beta$ -like transport receptors,and RanGDP is then re-imported into the nucleus by the small homodimericprotein NTF2 (23-25) to replenish the nuclear stores ofRan.

NTF2 was first identified as a factor required for efficient import of proteins into the nucleus (26). Consistent with therole of NTF2 in importing Ran into the nucleus, NTF2 has beenshown to interact at non-overlapping sites with both Ran and asubset of nuclear pore proteins containing FxFG repeats (27).NTF2 specifically interacts with the GDP-bound form of Ran, andthis interaction has been extensively characterized through mutationalanalysis of both NTF2 and Ran (27-31) as well as analysis of theNTF2-Ran co-crystal structure (32). These studies indicate thatthe interaction between NTF2 and Ran is required to concentrateRan in the nucleus and consequently for protein transport betweenthe nucleus and the cytoplasm (33).

The interaction between NTF2 and nucleoporins is predicted to be more complex than the Ran-NTF2 interaction because NTF2 iscapable of interacting with multiple FxFG nucleoporins that linethe central channel of the pore (34). Recent in vitro bindingstudies indicate that the interaction between NTF2 and nucleoporinsis relatively weak (35, 36). This suggests a model in whichNTF2 transiently interacts with nucleoporins enabling the NTF2-RanGDPcomplex to move through the pore by hopping from one repeat toanother (37). If this is the case, one would predict that decreasingor increasing the affinity of NTF2 for FxFG nucleoporins couldhave a detrimental effect on NTF2 function. However, the lackof an NTF2-FxFG co-crystal structure has made it difficult toengineer mutants crucial to testing thishypothesis.

Bayliss et al. (35) utilized the crystal structure of NTF2 bound to RanGDP to predict which residues in NTF2 might be involvedin binding to nucleoporins. They identified residue Trp-7 as apotential site for FxFG binding and engineered a mutation in therat NTF2 protein, W7A NTF2, with a reduced affinity for FxFG nucleoporins.They went on to demonstrate that the W7A NTF2 protein only weaklystimulates nuclear import of RanGDP in vitro. However, a recentstudy by Ribbeck and Görlich (38) that examined the rate oftranslocation of both NTF2 and W7R NTF2 showed that W7R NTF2 entersthe nucleus quite rapidly compared with a control green fluorescentprotein (GFP). This led these authors (38) to suggest that thereare other residues in NTF2 in addition to Trp-7 that are criticalfor mediating the interaction withNPCs.

The transport receptor importin- $beta$ also interacts with FxFG nucleoporins (8-16) presumably to allow the translocation of importin- $beta$ -cargocomplexes through the NPC. One could envision that the importof RanGDP by NTF2 via the ability of NTF2 to interact with nucleoporinsis analogous to the import of protein cargo by importin- $beta$ . Ifso, the recent co-crystal structure of importin- $beta$ bound to fiveFxFG nucleoporin repeats from Nsp1p (37) might give some cluesabout how NTF2 and FxFG nucleoporins interact. The importin- $beta$ -FxFGstructure revealed that the phenylalanines of the FxFG repeatcores are buried in a hydrophobic pocket on importin- $beta$ , with thephenylalanines of the FxFG repeat core forming stacking interactionswith themselves and hydrophobic residues in importin- $beta$ . This observationis consistent with the finding that a hydrophobic residue, Trp-7,is involved in the NTF2-FxFG nucleoporin interaction. However,mutations in Trp-7 appear only to weaken and not eliminate theinteraction between NTF2 and nucleoporins (35, 38), suggestingthat other hydrophobic residues in NTF2 are also involved in thisinteraction. To fully understand the function of NTF2, it is imperativeto define all residues that are critical for NTF2-nucleoporininteractions in vivo.

In this study, we have used mutational analysis to probe the interaction between NTF2 and FxFG nucleoporins in vivo. First,we engineered a series of mutant NTF2 proteins that disrupt theinteraction between NTF2 and FxFG nucleoporins to varying extents.Our data show that the strength of NTF2 binding to nucleoporinscan be reduced significantly without reducing cell viability.However, if this interaction is abolished completely, cells canno longer survive. Second, we isolated a mutant of NTF2 that hasan increased affinity for FxFG nucleoporins. This mutation rendersthe NTF2 protein nonfunctional in vivo, and overexpression ofthis mutant protein blocks NLS-mediated protein import. Together,these results support a model in which the interaction betweenNTF2 and FxFG nucleoporins occurs at a sufficiently low affinityto enable NTF2 to move freely from one FxFG repeat to anotheras it translocates through the pore complex. Furthermore, ourdata demonstrate that the fine-tuned interaction between NTF2and FxFG nucleoporins is critical in vivo.

MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

All chemicals were obtained from Sigma or United States Biological unless otherwise noted. All DNA manipulations were performedaccording to standard methods (39), and all media were preparedby standard procedures (40). All plasmids used in this studyare described in Table I. The wild-type (PSY580) and NTF2 deletionstrains (ACY114) used in this study have been described (41).

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Table I
Plasmids used

Mutagenesis-- Site-directed mutagenesis was performed on pBS-NTF2 (pAC240) using the QuickChange PCR-based mutagenesis kit from Stratagene(La Jolla, CA). Mutated sequences were confirmed by DNA sequencing. $Delta$ 6NTF2 was made using a PCR-based strategy. The NTF2 promoterwas amplified from pAC117 with 5'-GGC ACC GGT CAT TAT AAA GATAAT AGT ATT AAA ACC-3' and 5'-GCG AGC TCC CCT TTC ATA TTG TTCGGC TA-3' as primers. The resulting PCR product was digested withAgeI and SacI and subcloned into pAC715 (pRS314YRB1) digestedwith AgeI and SacI. The Ntf2p coding region from Gln-10 to thestop codon including the 3'-untranslated region was amplifiedfrom pAC117 with 5'-GCG ACC GGT CAA AAC TTC ACC CAG TTT TAC TA-3'and 5'-CCC TCG AGC GCT ATC GCC TTA TAC ATC G-3' as primers. Theresulting PCR product was digested with AgeI and XhoI and subclonedinto pAC715 containing the NTF2 promoter digested with AgeI andXhoI. The six-amino acid deletion was confirmed by DNA sequencingthen subcloned into the SacI and XhoI sites of pPS315 (CEN, LEUplasmid).

Localization of Ntf2 Proteins and scRan in Vivo-- Wild-type and mutant Ntf2p-GFP fusion proteins were transformed into the NTF2 deletion strain, ACY114, maintained by a wild-typecopy of GSP1 (scRan) (pAC78). scRan-GFP was transformed into ACY114expressing each of the mutant alleles of NTF2 as the only copyof NTF2. The GFP fusion proteins were localized by viewing theGFP signal directly in living cells through a GFP-optimized filter(Chroma Technology) using an Olympus BX60 epifluorescence microscopeequipped with a Photometrics Quantix digitalcamera.

NLS-GFP Import Assay-- The NLS-GFP import assay was performed as described previously (42). Briefly, cells were grown to early mid-log phase insynthetic media containing 2% glucose (w/v) at 25 °C, pelleted,resuspended in 1 ml of 10 mM sodium azide, 10 mM 2-deoxy-D-glucosein glucose-free synthetic media, and incubated at 25 °C for 45min. The cells were then pelleted, washed with 1 ml of ice-coldddH₂0, repelleted, resuspended in 100 µl of glucose-containingsynthetic media prewarmed to 37 °C, and incubated at 37 °C. Forscoring, 2-µl samples were removed every 2.5 min, and cells wereobserved and counted through a GFP-optimized filter (Chroma Technology)using an Olympus BX60 epifluorescence microscope. Cells were scoredas "nuclear" if the nucleus was both brighter than the surroundingcytoplasm and a nuclear-cytoplasmic boundary was visible. At least100 cells were counted at each timepoint.

Functional Analysis of NTF2 Mutant Alleles-- The in vivo function of each of the Ntf2 mutant proteins was tested by using a plasmid shuffle technique. The NTF2 deletionstrain, ACY114, was transformed with plasmids encoding each ofthe Ntf2 mutant proteins. Single transformants were grown in liquidculture to saturation. The saturated cultures were serially diluted(1:10) and spotted on fluoroorotic acid (5-FOA) plates to eliminatethe URA3 plasmid-encoded wild-type Ntf2p (43). This resultsin cells that express each of the mutant Ntf2 proteins on a lowcopy centromeric plasmid as the sole copy ofNtf2p.

Ntf2p Purification and Immobilization-- All Ntf2 proteins were purified from Escherichia coli essentially as described (25) with the following changes. After lysisand clarification, E. coli lysates were applied to DEAE ion exchangecolumn pre-equilibrated with 10 mM Tris-HCl, pH 8.0. Ntf2p waseluted from the column with a gradient of 0 to 1 M NaCl. Fractionscontaining Ntf2p were pooled, concentrated using a Centriprep-10(Amicon) concentrator, and applied to a column of Sephacryl SR100pre-equilibrated in 20 mM Tris-HCl, pH 7.5. Fractions containingpurified Ntf2p were collected, pooled, and stored at $-$ 80 °C in10% glycerol. Purified Ntf2 proteins were cross-linked to cyanogenbromide-Sepharose beads as described previously (25).

Bead-binding Assays-- Yeast cell extracts were prepared as described (25). Two mg of BQY65 (MAT $alpha$ ura3-52 trp1 $Delta$ 63 leu2 $Delta$ 1 his3 $Delta$ 200 GSP1 $Delta$ ::HIS3 GSP2 $Delta$ ::HIS3myc-GSP1) cell extract was incubated with 50 µl of Ntf2p-Sepharosebeads. For the competition experiment, either 300 µg of wild-typeNtf2p or 300 µg of bovine serum albumin was added in additionto the yeast cell extract. Binding was carried out in PBSM (PBS,2.5 mM MgCl₂) in a total volume of 500 µl at 4 °C for 1 h. Followingthe binding, the beads were pelleted, and unbound lysate was removedfrom the beads. This fraction was designated the unbound sample,and 20 µg of total protein, corresponding to 1% of the total unboundvolume, was analyzed. After the unbound sample was removed, beadswere washed once for 10 min in 1 ml of PBSM and twice for 10 minin PBSMT (PBS, 2.5 mM MgCl₂, 0.5% Triton X-100). The beads thatcontained the bound fraction were then boiled in sample loadingbuffer (100 µl total volume), 10% of the total bound proteins(10 µl) was loaded onto an SDS-polyacrylamide gel. Because thebound proteins were eluted directly into sample buffer, it wasimpossible to quantitate the total amount of bound sample. However,within each experiment the percentage of total bound protein loadedwas equal, so direct comparisons could be made between each ofthe bound lanes within each experiment. This is also the casefor the unbound samples. Samples (bound and unbound) were resolvedby polyacrylamide gel electrophoresis, and transferred to nitrocelluloseforimmunoblotting.

For many of the experiments some low level of nonspecific or low affinity binding of Nup2p to the beads (whether they werecharged with Ntf2 protein or not) was observed. This Nup2p wasreadily washed from the beads by the PBSM/PBSMT washes used inour protocol and could be recovered in a wash fraction by trichloroaceticacid precipitation (data not shown). This means that in some experiments,the amount of total protein (summing the unbound and bound lanes)is not equal despite the fact that the same lysates with identicalamounts of Nup2p were used for each sample within the experiment.For all experiments the amount of unbound (1% of total unboundvolume) and bound (10% of total bound volume) sample loaded ineach lane was identical, and therefore direct comparisons canbe made between the bound lanes shown for all samples and betweenthe unbound lanes shown for allsamples.

Immunoblot Analysis-- Immunoblot analysis was performed essentially as described (44). Ntf2p-GFP was detected by incubation with 1:10,000 dilutionof rabbit anti-GFP polyclonal antibody. Nup2p was detected byincubation with 1:3000 dilution of mAb414 (Babco). Myc-Gsp1p wasdetected with 1:500 dilution of mouse anti-Myc monoclonal antibody(Santa CruzBiotechnology).

Dominant Negative Screen-- Dominant negative alleles of NTF2 were generated using random PCR mutagenesis. A 4.0-kilobase pair PCR product that includedthe entire NTF2 open reading frame was generated using Taq polymeraseunder mutagenic conditions (7 mM MgCl₂) and purified on a QiaquickPCR column from Qiagen (Chatsworth, CA). The plasmid pAC82 waslinearized with BamHI and SalI to remove a 475-base pair insertcontaining the coding region of NTF2. Gap repair ligation (56)was achieved by co-transforming the wild-type strain PSY580 withthe PCR product and linearized the GAL1-NTF2 plasmid (pAC82).Colonies were selected on synthetic complete media plus 2% (w/v)glucose lacking leucine (SD $-$ Leu). The plates were then replicaplated to synthetic complete media plus 2% galactose (w/v) lackingleucine (Sgal $-$ Leu) supplemented with 7.5 mg of the vital dyeerythrocin B/liter and incubated at 30 °C. Addition of galactoseto the media initiates the overexpression of the plasmid encodedNtf2 protein. Uptake of the erythrocin B dye by dead cells, whichresults in a pink colony, was used to identify colonies that diedupon overexpression of the Ntf2 protein. Plasmids were rescuedfrom dominant negative colonies and retransformed into wild-typecells (PSY580) to confirm plasmid linkage and the dominant negativephenotype. Plasmids that retested were sequenced to identify themutations.

Growth and Viability-- Cells were grown in SD $-$ Leu overnight at 30 °C, diluted 1:200 into synthetic complete media supplemented with 2% raffinose(w/v) lacking leucine, grown at 30 °C to ~10⁷ cells/ml, and induced with 2% galactose (w/v). Cells were countedevery 2 h. Two hundred cells were plated at each time point onSD $-$ Leu media and incubated for 2 days at 30 °C. Viability wasdetermined by counting the number of colonies that arose fromthe 200 cellsplated.

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Modeling of Saccharomyces cerevisiae Ntf2p Reveals a Surface Patch of Hydrophobic Residues-- As the two phenylalanines in the FxFG repeat core have a very hydrophobic nature, one would anticipate that their bindingsite on NTF2 would also be hydrophobic, analogous to the hydrophobicFxFG binding site identified on importin- $beta$ (37). Previous workconsistent with this hypothesis has shown that residue Trp-7 ofrNTF2 contributes to the interaction between rNTF2 and FxFG nucleoporins(35) and that mutation of Trp-7 of rNTF2 to alanine reducesbinding to FxFG nucleoporins (35). Moreover, in crystal structuresof both wild-type and mutant rNTF2 (35, 45), the hydrophobicpatch surrounding Trp-7 is often involved in hydrophobic crystalcontacts between adjacent molecules in the crystal lattice (29,45). In particular, close interactions between the aromaticring of Phe-126 and both Trp-7 and Trp-112 are found in the crystalpacking of the W7A-rNTF2 mutant (35). Although these two residuesare not strictly conserved between yNTF2 and rNTF2 (Fig. 1A),they are conservatively substituted and remain hydrophobic. Toidentify residues in S. cerevisiae Ntf2p (yNTF2) that could potentiallybe involved in the interaction with FxFG nucleoporins, we constructeda model structure of S. cerevisiae Ntf2p based on the crystalstructure of rat NTF2 (rNTF2) (45). As shown in Fig. 1B, bothchains in the NTF2 dimer have a substantial hydrophobic patchon their surface (indicated by the black shading) that includesresidues Phe-5 and Tyr-112 in yNTF2, which are analogous to Trp-7and Trp-112 in rNTF2. This hydrophobic patch therefore appearedto be an attractive candidate for the FxFG nucleoporin bindingsite on NTF2. To test this hypothesis, we mutated both Phe-5 andTyr-112 to alanine and also generated the F5A/Y112A double mutant.As a more drastic change, we mutated the Tyr-112 to an asparticacid, thus changing a hydrophobic aromatic residue to a chargednonaromatic residue. As a more severe change to the hydrophobicpatch, we constructed a deleted form of yNTF2 ( $Delta$ 6Ntf2), whichdeletes residues 2-8 including Phe-5 and the surrounding residues(See Fig. 1A).

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Fig. 1. A, amino acid sequence alignment of rat and S. cerevisiae NTF2 proteins. Underlined blue residues (Phe-5 and Tyr-112) indicate amino acids in S. cerevisiae proposed to be involved in the interaction with nucleoporins. The residues deleted in the Ntf2 $Delta$ 6 mutant protein (L3-L8) are boxed. Residues in red (Asn-77 and Asp-21) indicate the amino acids residues mutated in the dominant negative mutants of NTF2. B, space-filling representation of modeled yeast Ntf2p structure showing positions of residues mutated in this study. Both chains of the scNTF2 dimer are shown (in pink and blue), and thus two copies of all described features are visible. Residues Phe-5 and Tyr-112 form part of a hydrophobic patch (F5, Y112, black) exposed on the surface of both chains. Residue Asn-77 (N77, yellow) is located in close proximity to the dimerization interface and between the two hydrophobic patches. Residue Asp-21 (D21) is also identified.

Mutations in Hydrophobic Residues Alter the Localization of Ntf2p in Vivo-- To analyze the effect the engineered mutants have on binding to nucleoporins in vivo, each mutant Ntf2 protein was fused atthe C terminus to the GFP, and the localization of these mutantproteins examined in living cells. Ntf2p is a homodimeric proteinthat is required for viability in S. cerevisiae (41); however,overexpression of yeast Ran, GSP1, can compensate for the deletionof NTF2 (46). Therefore, to eliminate the possibility that anyof the engineered mutants might dimerize with endogenous wild-typeNtf2p, plasmids expressing each of the GFP fusion Ntf2 proteinswere transformed into the NTF2 deletion strain maintained by aplasmid-encoded Gsp1p. As shown in Fig. 2A, although Ntf2p-GFPwas concentrated at the nuclear rim, the engineered mutants ofNtf2p showed a range of localization patterns from Ntf2pF5A, whichshows only a slight diminution of nuclear rim staining, to $Delta$ 6Ntf2p,which localizes diffusely throughout the cell.

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Fig. 2. Ntf2p mutants with decreased affinity for FXFG nucleoporins. A, localization of the engineered mutants of Ntf2p. The NTF2 deletion strain, ACY114 (41), maintained by a plasmid encoding Gsp1p (pAC78), was transformed with a 2µ plasmid encoding either wild-type or mutant Ntf2 proteins fused at the C terminus to GFP. Transformants were grown in liquid media to log phase at 30 °C, and Ntf2p-GFP was viewed directly in living cells. B and C, the engineered Ntf2p mutants maintain binding to Gsp1p but vary widely in their ability to interact with the FxFG nucleoporins. Interactions with Gsp1p and Nup2p were examined using bead-binding assays as described under "Materials and Methods." B, blots probed with mAb414, which detects Nup2p (54), are shown. In the upper panel, U indicates the unbound fraction (1% of total unbound), and B indicates the bound fraction (10% of total bound). In the lower panel, three times more bound fraction was loaded (30% of total bound fraction) for each sample. C, a blot probed with anti-Myc antibody to detect Myc-tagged Gsp1p is shown. Only the bound samples are shown.

To determine whether the engineered mutations specifically affect the ability of Ntf2p to bind FxFG nucleoporins without disruptingthe binding to Gsp1p, we performed in vitro binding assays. Eachof the mutant proteins (with the exception of Y112D, which wefound encoded an unstable protein (see Fig. 3B)) was expressedand purified from bacteria and attached to Sepharose beads asdescribed under "Materials and Methods." The beads were then incubatedwith yeast lysates expressing Myc-tagged Gsp1p (BQY65). Afterseveral washes, proteins that bound to the Ntf2p-beads (10% oftotal bound sample, Fig. 2B, upper panel, or 30% of total boundsample, Fig. 2B, lower panel) as well as 1% of the total unboundsample (Fig. 2B, upper panel) were analyzed by immunoblot analysisusing anti-Myc antibodies to detect Gsp1p and mAb414 to detectnucleoporins. mAb414 was originally isolated from antisera raisedagainst Triton X-100-treated rat liver nuclei (47) and has beenshown to cross-react with two yeast nuclear envelope proteins,p110, which corresponds to the FxFG nucleoporin Nup2p,² and p95 (48). Consistent with the in vivo localization data,the mutants varied significantly in their extent of binding toNup2p (Fig. 2B). Although the interaction between Ntf2pF5A andNup2p was comparable with the interaction observed for wild-typeNtf2p, Ntf2pY112A, Ntf2pF5A/Y112A, and $Delta$ 6Ntf2p, all exhibitedreduced Nup2p binding. As shown in Fig. 2C, all of the mutantproteins retained the ability to interact with Gsp1p, indicatingthat their reduced affinity for FxFG nucleoporins was not becausethey had failed to fold correctly. In summary, the engineeredseries of mutant Ntf2 proteins showed varying degrees of reductionin binding to FxFG nucleoporins without affecting binding to Gsp1p.Therefore, these mutants can be used to examine the interactionbetween Ntf2p and nucleoporins in vivo.

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Fig. 3. Functional analysis of the engineered NTF2 mutants. A, the NTF2 deletion strain, ACY114, maintained by a plasmid encoding wild-type Ntf2p was transformed with CEN plasmids encoding either wild-type or mutant Ntf2 proteins. Cultures were grown to saturation, serially diluted (1:10), and spotted on plates. For each plasmid, the URA plate illustrates that each of the strains can grow in the presence of a wild-type copy of NTF2. The 5-FOA plate demonstrates that when the wild-type copy of NTF2 is eliminated from the strain, F5A and Y112A are fully functional. Growth of the F5A/Y112A double mutant is slightly retarded compared with wild-type. The Y112D mutant grows slowly, and the $Delta$ 6NTF2 is unable to grow at all. Vector alone is shown as a control to demonstrate that, as shown previously (41), the deletion strain $Delta$ NTF2 requires a functional copy of NTF2 for viability. All plates were grown at 30 °C. B, levels of Ntf2p expressed in cells were examined by immunoblotting with an anti-GFP antibody. Ntf2p-GFP transformants were grown at 30 °C to log phase, and yeast lysates were prepared by standard methods (25). Ten µg of total yeast protein was loaded in each lane. Ntf2p-GFP proteins were detected with a polyclonal anti-GFP antibody (14).

The Interaction between Ntf2p and FxFG Nucleoporins Is Essential in Vivo-- To address whether the binding of Ntf2p to nucleoporins is crucial for the function of Ntf2p in vivo, a plasmid shuffle approachwas used to determine whether each of the mutant proteins couldfunction as the sole copy of the essential Ntf2 protein in cells.An NTF2 deletion strain, ACY114 (41), maintained by a wild-typecopy of NTF2 on a URA3 plasmid was transformed with genomic clonesof each of the ntf2 mutants. Cells that contain both the wild-typeand the mutant plasmid are viable regardless of which mutant isanalyzed, as demonstrated by growth of serially diluted (1/10)cells on the URA plate (Fig. 3A, left panel). Cells were also serially dilutedon to 5-FOA plates to select against the URA3 plasmid (43) thatencodes wild-type Ntf2p. Thus, the right panel in Fig. 3A (5-FOA)shows the growth of cells that contain only the mutant NTF2 plasmids(or control plasmids) indicated in the absence of any other copyof NTF2. Results from this experiment indicated that growth ofthe ntf2F5A and ntf2Y112A mutants was comparable with the wild-typecontrol and growth of the ntf2F5A/Y112A double mutant was onlyslowed slightly compared with wild-type control cells. In contrast,the ntf2Y112D mutant grew slowly, and the $Delta$ 6ntf2 mutant was notviable in the absence of wild-type Ntf2 protein. Similar resultswere observed at 16, 25, and 37 °C. The phenotypes observed wereconfirmed through the analysis of growth in liquid media (datanot shown). We performed immunoblots using lysates from cellsexpressing each of the mutant GFP proteins to ensure that eachof the mutant proteins was expressed at a comparable level. Althoughall of the mutant proteins were expressed (Fig. 3B), Ntf2pY112Dwas expressed at a significantly lower level than wild-type Ntf2p,suggesting that the Y112D mutation affects the stability of theNtf2 protein in vivo; therefore, we excluded the Y112D mutantprotein from subsequent analyses. However, the $Delta$ 6Ntf2 proteinwas expressed at comparable levels to wild-type Ntf2p, indicatingthat its loss of in vivo function was not the result of instabilityor low levels ofexpression.

The Strength of the Interaction between Ntf2p and FxFG Nucleoporins Influences Protein Import into the Nucleus-- The generation of a series of Ntf2 mutant proteins that varied in the strength of their binding to nuclear pores but remainedviable (with the exception of $Delta$ 6Ntf2p, which cannot be includedin the following analysis because cells expressing this mutantprotein as the sole copy of Ntf2p are not viable (See Fig. 3A))allowed us to assess how the strength of the interaction withFxFG nucleoporins affected the in vivo nuclear transport functionof Ntf2p. To examine nuclear import, a kinetic assay that monitorsnuclear import of an NLS-GFP reporter protein was employed (42).The F5A/Y112A mutation, which had a severe effect on the bindingof Ntf2p to Nup2p, significantly reduced the import of labeledNLS protein into the nucleus (Fig. 4A, filled squares). In contrast,Ntf2pY112A, which reduced the interaction with nucleoporins lessdramatically, appeared to have no detectable effect on proteinimport (Fig. 4A, open circles). These results suggest that theinteraction between Ntf2p and nucleoporins can be reduced substantiallywithout producing a significant decrease in the rate of NLS-mediatedprotein import.

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Fig. 4. Analysis of nuclear transport defects. A, analysis of protein import. A standard import assay (42) was used to analyze nuclear import rates of an NLS-GFP reporter protein. Results are plotted as the percentage of cells showing nuclear signal versus time. B, localization of Ran-GFP. NTF2, F5A, Y112A, and F5A/Y112A cells were transformed with a 2µ plasmid encoding Ran-GFP (pAC410). Transformants were grown to log phase at 30 °C, and Ran-GFP was viewed directly in living cells.

Ntf2p is required for the import of Ran (Gsp1p) into the nucleus (23-25). To determine the importance of the Ntf2p-nucleoporininteraction on RanGDP nuclear import, we examined Ran-GFP localizationin each mutant NTF2 strain. In wild-type cells, Ran-GFP localizedthroughout the cell, with a clear concentration in the nucleusas observed previously (25). Similar to the effects of the mutationson nuclear protein import, ntf2F5A and ntf2Y112A had little effecton Ran localization, although ntf2F5A showed marginally higherlevels of cytoplasmic Ran than wild type. However, in cells expressingNtf2pF5A/Y112A, a greater amount of Ran-GFP was mislocalized tothe cytoplasm (Fig. 4B) indicating that Ran import into the nucleusis less efficient in these cells than in wild-type cells. It shouldbe noted that although the Ntf2pF5A/Y112A cells are larger thanwild-type cells, they consistently showed a more cytoplasmic distributionof Ran-GFP than any of the other cellsanalyzed.

In summary, we have identified several residues within a hydrophobic patch on the surface of the yNTF2 protein that are involvedin Ntf2p binding to FxFG nucleoporins and have shown that whentwo of these hydrophobic residues are mutated, a more significanteffect on both the strength of Ntf2p binding to FxFG nucleoporinsin vitro and the function of Ntf2p in RanGDP nuclear import invivo is observed. The strength of the Ntf2-nucleoporin interactioncan be reduced substantially with little effect on cell viability,although cells do not survive if the interaction is eliminatedcompletely. Although these data indicate that the Ntf2p-FxFG interactionis essential in vivo, they also suggest that this interactioncan be substantially weakened without producing a serious effecton cell viability consistent with a model in which Ntf2p onlyinteracts with nucleoporins transiently (with a low binding affinity)so that it may pass from one nucleoporin to the next to traversethe NPC (37).

Isolation of a Dominant Negative Mutant of NTF2 with Increased Binding to FxFG Nucleoporins-- Our experiments make two predictions about Ntf2p-mediated nuclear import of Ran. First, Ntf2p must interact with nucleoporinsto mediate Ran import in vivo. Second, a functional interactionbetween Ntf2p and nucleoporins can occur with low affinity. Thisraises the question of whether the low affinity interaction betweenNtf2p and nucleoporins is critical for the in vivo function ofNtf2p. To test whether increasing the affinity of Ntf2p for nucleoporinsinterferes with Ntf2p function, we devised a genetic screen forNTF2 mutations that alter the Ntf2p-nucleoporin interaction. Wehypothesized that overexpression of a mutant Ntf2 protein withincreased affinity for nucleoporins would block nucleocytoplasmictransport in vivo and inhibit cell growth. Therefore we conducteda screen to identify dominant negative mutants of Ntf2p that inhibitedcell growth when expressed at high levels from a galactose-induciblepromoter. Mutants identified in this screen were then tested toidentify those with altered binding to nucleoporins. We identifiedone mutation that met the criteria of the screen. This mutationresults in a change from asparagine to tyrosine at residue 77(N77Y).

Overexpression of Ntf2N77Y inhibits cell growth in vivo (Fig. 5A). It should be noted that the overexpression of wild-typeNTF2 is slightly dominant negative (compare vector and NTF2 inFig. 5A). To further characterize the growth inhibitory phenotypeof the N77Y mutant, growth in liquid medium was analyzed. As shownin Fig. 5B, overexpression of the N77Y mutant protein resultsin a strong growth-inhibitory effect (~30% of wild-type growthafter 10 h).

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Fig. 5. Analysis of dominant negative mutants of NTF2. A, wild-type cells (PSY580) were transformed with a 2µ plasmid encoding wild-type or mutant Ntf2p under the control of the galactose-inducible GAL1 promoter. Cultures were grown to saturation in minimal media containing 2% raffinose (w/v), serially diluted (1:10), and spotted on plates. For each plasmid, the glucose plate illustrates the uninduced cells, and the galactose plate represents overexpression of the protein. B, growth was analyzed in liquid galactose media. A single transformant was inoculated into SD $-$ Leu media, incubated overnight at 30 °C, diluted into synthetic complete media supplemented with 2% raffinose lacking leucine, grown at 30 °C to ~10⁷ cells/ml, and induced with 2% galactose. Samples were removed every 2 h and counted, and 200 cells were plated onto SD $-$ Leu media and incubated for 2 days at 30 °C. The results are plotted as cell number versus time after induction. At 10 h, growth of the N77Y mutant is ~30% of the wild-type control, and growth of D21A is 42% of wild-type. C, expression of the mutant Ntf2 proteins. Levels of Ntf2p expressed in ACY114 maintained with a CEN plasmid encoding Gsp1p transformed with wild-type or mutant Ntf2p fused at the C terminus to GFP were examined by immunoblotting for GFP. Ntf2p-GFP transformants were grown at 30 °C to log phase, and yeast lysates were made as described (41). Ten µg of total yeast protein was loaded in each lane, and Ntf2p-GFP was detected with anti-GFP (1:10,000 dilution) antibody.

During the course of our work, it was reported that a mutation in mammalian NTF2, D23A NTF2, exhibited a dominant negativephenotype (49). These studies indicated that the D23A NTF2 proteinmaintained the ability to interact with Ran while binding FxFGnucleoporins more efficiently. In addition, when the D23A NTF2protein was added in excess in in vitro nuclear protein importassays, importin- $beta$ -mediated protein import was blocked (49).To analyze the in vivo affect of this mutation on cellular function,we made the complementary mutation in yeast NTF2, ntf2D21A (SeeFig. 1). As shown in Fig. 5, A and B, this mutation indeed causeda dominant negative effect on growth in vivo, although slightlyless of an effect was observed (~42% of wild-type growth after10 h) than with the N77Y mutant protein (~30% of wild-type).

To ensure that the dominant negative mutant proteins were expressed to comparable levels and to determine the effect, if any,these mutations have on the stability of the Ntf2 protein, eachof the mutant proteins was fused at the C terminus to GFP. Thesefusion proteins were introduced into the NTF2 deletion strain,ACY114, maintained by a plasmid containing GSP1 (to prevent thepossible dimerization with endogenous wild-type Ntf2p). Lysatesfrom individual transformants were analyzed by immunoblottingwith anti-GFP. As shown in Fig. 5C, the mutant proteins were expressedto comparable levels that were slightly higher than those observedwith wild-type protein. Because overexpression of wild-type Ntf2pis slightly toxic, it was possible that the higher expressionlevels of the mutant proteins could contribute to their toxicity.However, this was thought to be unlikely because although eachmutant protein was expressed at approximately the same level,we observed a difference in the level of toxicity between thetwomutants.

To determine why overexpression of the N77Y mutant protein inhibits cell growth, we first examined the effect that overexpressionhad on protein import. Overexpression of wild-type Ntf2p had aslight effect on the localization of an NLS-GFP reporter. Cellsthat overexpress wild-type Ntf2p showed a small increase in cytoplasmicGFP fluorescence (Fig. 6A) consistent with the observation thathigh levels of wild-type Ntf2p are slightly toxic to cells (SeeFig. 5A). Overexpression of the N77Y protein caused significantmislocalization of the NLS reporter protein to the cytoplasm.

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Fig. 6. Analysis of NLS-mediated protein import and Ran import into the nucleus of cells overexpressing N77Y Ntf2p. Wild-type cells (PSY580) were co-transformed with a 2µ plasmid encoding wild-type or mutant Ntf2 proteins under the control of the galactose-inducible GAL1 promoter and a plasmid encoding either an NLS-GFP reporter protein (A) or Ran-GFP (B). A single transformant was inoculated into SD $-$ Leu media, incubated overnight at 30 °C, diluted into synthetic complete media supplemented with 2% raffinose (w/v) lacking leucine, grown at 30 °C to ~10⁷ cells/ml, and induced with 2% galactose (w/v). GFP fluorescence was viewed directly in living cells at 0 and 3 h after induction. In B, the arrows indicate the punctate nuclear rim staining observed for Ran-GFP following a 3-h induction of the N77Y Ntf2p mutant.

To determine whether the block in NLS-mediated protein import was secondary to the inability of the N77Y protein to importRanGDP into the nucleus, we analyzed the localization of Ran-GFPin cells overexpressing the N77Y mutant protein. Overexpressionof wild-type Ntf2p results in a slight increase in cytoplasmicRan-GFP (Fig. 6B). Overexpression of the N77Y proteins resultedin a brighter punctate nuclear rim signal (see arrows in Fig.6B) together with a decrease in nuclear staining. The effect observedis subtle but is reproducible in numerous independent experiments.These results suggest that Ran may accumulate at NPCs, possiblybecause of an increased affinity of the N77Y mutant proteins fornucleoporins, thus resulting in a reduced rate of transport ofRanGDP through the pore. Alternatively, the N77Y protein may havean increased affinity for RanGDP resulting in less efficient releaseof RanGDP into the nucleus at the nucleocytoplasmic face of thepore.

Fig. 7A shows that, like wild-type Ntf2p, the N77Y protein localizes to the nuclear rim. This observation suggests that N77Yretains its interaction with the nuclear pore but cannot distinguishwhether it might have enhanced affinity for the pore. To examinethe interaction of the N77Y protein with the nucleoporins, N77Ywas expressed and purified from bacteria and attached to beads.The beads were incubated with yeast lysate and washed, and proteinsthat bound were eluted and analyzed by immunoblot analysis forNup2p and Gsp1p binding as described under "Materials and Methods."In this bead binding assay, the N77Y protein exhibited a slightincrease in binding to Nup2p as compared with wild-type Ntf2p(Fig. 7B). However, a comparison of the unbound and bound lanesin this experiment indicated that the beads bound virtually allof the available Nup2p in the lysate. Therefore, even if the N77Yprotein bound to nucleoporins more efficiently than wild-typeNtf2p, this assay would not reflect this increased affinity. Asa more sensitive assay for nucleoporin binding to the N77Y protein,the assay was carried out in the presence of excess wild-typeNtf2 protein. If the N77Y protein has an increased affinity forNup2p, then it should be able to compete more efficiently forNup2p binding than the added excess of wild-type Ntf2p. As shownin Fig. 7C, the N77Y-beads still bound Nup2p even in the presenceof excess soluble wild-type Ntf2p. In contrast, Nup2p was competedaway from the wild-type Ntf2-beads by the added soluble wild-typeNtf2 protein. The N77Y Ntf2 protein retained wild-type bindingto Gsp1p (Fig. 7D), indicating that this mutation did not significantlydisrupt the structure of the protein. These results demonstratethat the N77Y mutation increases the affinity of Ntf2p for nucleoporinswithout profoundly affecting binding to Ran.

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Fig. 7. The N77Y mutation increases the affinity of Ntf2p for nucleoporins. A, localization of Ntf2p-GFP. A 2µ plasmid encoding either wild-type or mutant Ntf2p fused at the C terminus to GFP was transformed into the NTF2 deletion strain ACY114 maintained with a CEN plasmid encoding Gsp1p. Single transformants were inoculated into Ura liquid and grown to log phase at 30 °C. Ntf2p-GFP was viewed directly in living cells. Interactions with liquid Nup2p (B and C) were examined using bead-binding assays as described under "Materials and Methods." B, Ntf2 proteins were bound to beads and incubated with wild-type yeast lysate. Bound and unbound samples were resolved by gel electrophoresis and transferred by standard methods (see "Materials and Methods"). Blots were probed with mAb414 to detect Nup2p. U indicates the unbound fraction (1% of total unbound), and B indicates the bound fraction (10% of total bound). C, Nup2p competition assay. Bead-binding assays were performed (see "Materials and Methods") in the presence of 300 µg of either bovine serum albumin or competitor wild-type Ntf2p. Unbound (U) and bound (B) fractions were probed for Nup2p. D, binding to Gsp1p. Bound samples in panel B were probed for Myc-tagged Gsp1p using an anti-Myc antibody. Both N77Y and D21A bound Gsp1p at levels comparable with wild-type Ntf2p. E, functional analysis of N77Y Ntf2p. The NTF2 deletion strain, ACY114, maintained by a plasmid encoding wild-type Ntf2p was transformed with a CEN plasmid encoding either wild-type or N77Y Ntf2p. Cultures were grown to saturation, serially diluted (1:10), and spotted on plates. For each plasmid, the Ura plate illustrates that each of the strains can grow in the presence of a wild-type copy of NTF2. The 5-FOA plate demonstrates that the ntf2N77Y is unable to grow in the absence of a wild-type copy of NTF2. Vector alone is shown as a control to demonstrate that the deletion strain requires a functional copy of NTF2 for viability. Plates were grown at 30 °C.

Because residue 77 resides in a putative surface loop and the amino acid sequence is not strongly conserved between the yeastand rat protein in this region (see Fig. 1A), some caution isrequired when modeling the precise structural consequences ofthis mutation. However, regardless of the detailed conformationtaken up by this residue in the yeast Ntf2p structure, it is clearfrom our model that the N77Y mutation introduces a new aromaticside chain in close proximity to the hydrophobic patch that ourresults indicate forms a major component of the interaction sitefor FxFG nucleoporins (see Fig. 1B). This mutation is approximatelyequidistant from Phe-5 and Tyr-112, suggesting that it could forma hydrophobic bridge between the nucleoporin binding sites onboth chains of Ntf2p, resulting in the increased affinity we observedfor FxFGnucleoporins.

Increasing the Affinity of Ntf2p for FxFG Nucleoporins Is Detrimental to Cellular Function-- To test the effect of increasing the affinity of Ntf2p for FxFG nucleoporin on the in vivo function of Ntf2p, we transformeda plasmid-borne copy of ntf2N77Y into the yeast NTF2 deletionstrain and asked whether these transformants could grow in theabsence of wild-type NTF2. As shown in Fig. 7E, cells expressingthe N77Y protein as the sole form of Ntf2p were not viable. Thus,increasing the affinity of Ntf2p for FxFG nucleoporins is detrimentalto cells. These data support the hypothesis that the interactionbetween Ntf2p and nucleoporins must be weak enough so that theinteraction is sufficiently transient to allow Ntf2p to traversethe NPC (36).

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The recent analysis of the co-crystal structure of residues 1-442 of importin- $beta$ with a peptide containing five tandem FxFGrepeats from the nucleoporin Nsp1p showed a primary and a secondarybinding site for the FxFG repeats (37). Both binding sites arehydrophobic pockets that permit hydrophobic contacts between importin- $beta$ and the phenylalanines of the FxFG repeat cores as well as stackingof the core phenylalanines themselves. Our modeling of the S.cerevisiae NTF2 protein based on the crystal structure of ratNTF2 showed an analogous hydrophobic patch on the surface of yeastNTF2. This hydrophobic patch is separate and distinct from theRanGDP binding site on NTF2. Two amino acids residues in thispatch were thought to be likely candidates to form hydrophobiccontacts with the phenylalanines of FxFG nucleoporins: Phe-5,which corresponds to Trp-7 in the rat NTF2 protein, and Tyr-112that, by analogy with Trp-112 in rNTF2, probably protrudes intothis hydrophobic pocket in yNTF2 (Fig. 1B). Ribbeck and Görlich(38) recently reported that mutating Trp-7 to arginine in ratNTF2 significantly reduces the rate of transport passage of NTF2through the NPC (38). However, this protein still traversesthe NPC 30 times faster than the similarly sized control protein,GFP (38). This supports the hypothesis that residues in additionto Trp-7 (Phe-5 in yeast) are involved in the interaction betweenNTF2 and nucleoporins. Our structural model of yeast NTF2 andour experimental results with a range of mutants are consistentwith this hypothesis and indicate that Tyr-112, Phe-12, and Leu-8are probably involved in addition to Phe-5. This is supportedby our observation that a double mutation (F5A/Y112A) is requiredto effect a significant reduction in binding to FxFG nucleoporinsand consequential decrease of in vivo NTF2function.

Both importin- $beta$ and NTF2 bind to a range of FxFG nucleoporins (8-16) that are located at both faces of NPCs and also linethe central transport channel (6, 34, 50). One can envisionthat these two transporters traverse the NPC in a similar manner.Several models of translocation have been suggested for importin- $beta$ .Rout et al. (6) have proposed that entry to the pore is controlledby a Brownian affinity gating mechanism, where the small sizeof the nuclear pore channel occludes most molecules unless itbinds directly to nucleoporins. Once a transporter is bound tonucleoporins on one face of the NPC, Brownian motion (diffusion)moves the transporter complex through the pore after which theybind to nucleoporins on the other face (6). This transportfrom one face of the NPC to the other has been proposed to possiblyinvolve an affinity gradient of binding to nucleoporins (51,52) that could be generated by the linker regions between theFxFG repeats or by the local concentration of FxFG repeats withina given nucleoporin. A second model, termed the "selective phasemodel," expands on this model and proposes that translocationproceeds through a homogeneous medium in the central plug thatallows movement by increasing the solubility of transport receptorsvia their specific interactions with FxFG nucleoporins (38).A third model suggests that importin- $beta$ may simply hop from oneFxFG repeat to another to traverse the pore complex (37). Oncea transporter reaches the nuclear face of the NPC, translocationis terminated either by interacting with RanGTP, in the case ofimportin- $beta$ (9, 53), or in the case of NTF2, by encounteringRan guanine nucleotide exchange factor, which exchanges GDP forGTP to produce RanGTP, for which NTF2 has no detectable affinity(27, 28, 32).

NTF2 has a 100 nM binding affinity for RanGDP (27, 32) and a µM binding affinity for FxFG nucleoporins (35, 36). Asour results demonstrate, reducing the affinity of NTF2 for nucleoporinsdoes not significantly affect the function of NTF2 in vivo, andonly when we significantly reduce the affinity do we observe aneffect on the function of NTF2. This is consistent with the reportby Ribbeck and Görlich (38) that although the rat W7R NTF2significantly slows NTF2 translocation through the NPC, it isstill able to move through the pore in a facilitated manner (38).However, if the affinity of NTF2 for nucleoporins is increased(as with the N77Y mutant), we see a dramatic effect; NTF2 is renderednonfunctional and overexpression blocks both Ran import and NLS-mediatedprotein import. This finding is consistent with the hypothesisthat NTF2 translocation in cells is mediated by very low affinityinteractions with nucleoporins that, because they imply a rapidoff-rate, enable material to be translocated quickly through aNPC.

Based on their analysis of the D23A mutation in mammalian NTF2, Lane et al. (49) have suggested that NTF2 and importin- $beta$ compete for shared binding sites at the NPC. Our results demonstratingthat overexpression of the N77Y dominant negative protein blocksNLS-mediated protein import are consistent with the hypothesisthat NTF2 and importin- $beta$ compete for binding sites at or withinthe NPC. This hypothesis would also predict that overexpressionof wild-type NTF2 would compete for binding to nucleoporins andresult in less efficient NLS-mediated protein import. Indeed,our results demonstrate that overexpression of wild-type Ntf2pis slightly toxic to cells over time (>5 h, Fig. 5C) althoughwe did not observe any effect on NLS-mediated protein import 3h after induction (Fig. 6B).

A central question outstanding in nuclear transport is how molecules actually traverse through nuclear pores. Addressing thiscomplex question will probably require a higher resolution structureof the nuclear pore than currently exists, but mapping the protein-proteininteractions that occur between soluble transport factors andthe pore, and that are likely to mediate this process, is alsoan important prerequisite to understanding the molecular mechanismof nuclear trafficking. In the present study we have identifieda hydrophobic patch on NTF2 that is crucial for the NTF2-NPC interactionboth in vivo and in vitro and have used this information to engineermutants to dissect the functional significance of this interaction.This is an important step toward understanding the pathway thatNTF2 takes in the course of transporting RanGDP through the nuclearpore to maintain the RanGTP gradient. Furthermore, our work suggeststhat both NTF2 and importin- $beta$ are probably translocated throughNPCs by analogous hydrophobic interactions involving the coresof FxFGnucleoporins.

ACKNOWLEDGEMENTS

We are grateful to members of the Corbett and Stewart laboratories for helpful discussions and comments on the manuscript.We thank Drs. K. Marfatia and P. Fanara for extremely helpfulcomments on themanuscript.

	FOOTNOTES

^* This work was supported by a grant from the National Institutes of Health (to A. H. C.) and a collaborative grant from theHuman Frontiers in Science Foundation.The costs of publicationof this article were defrayed in part by the payment of page charges.The article must therefore be hereby marked "advertisement" inaccordance with 18 U.S.C. Section 1734 solely to indicate thisfact.

^§ Supported by a post-doctoral fellowship from the National Institutes ofHealth.

Supported by a summer undergraduate research experience (SURE) grant funded by the Howard HughesInstitute.

^** To whom correspondence should be addressed: Dept. of Biochemistry, Emory University School of Medicine, 1510 Clifton Rd.,N. E., Atlanta, GA 30322. Tel.: 404-727-4546; Fax: 404-727-3954;E-mail: acorbe2@emory.edu.

Published, JBC Papers in Press, August 6, 2001, DOI 10.1074/jbc.M105054200

² B. B. Quimby and A. H. Corbett, unpublisheddata.

ABBREVIATIONS

The abbreviations used are: NPC, nuclear pore complex; NTF2, nuclear transport factor 2; rNTF2 and yNTF2, rat and yeast NTF2; NLS, nuclear localization signal; GFP, green fluorescent protein; PCR, polymerase chain reaction; PBSM, phosphate-buffered saline with 2.5 mM MgCl₂; PBSMT, phosphate-buffered saline with 2.5 mM MgCl₂ and 0.5% Triton X-100; mAb414, monoclonal antibody 414; SD, synthetic dextrose media; 5-FOA, 5-fluoroorotic acid.

	REFERENCES

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

1.	Görlich, D., and Kutay, U. (1999) Annu. Rev. Cell Dev. Biol. 15, 607-660[CrossRef][Medline] [Order article via Infotrieve]
2.	Adam, S. A. (1999) Curr. Opin. Cell Biol. 11, 402-406[CrossRef][Medline] [Order article via Infotrieve]
3.	Bayliss, R., Corbett, A. H., and Stewart, M. (2000) Traffic 1, 448-456[CrossRef][Medline] [Order article via Infotrieve]
4.	Görlich, D. (1998) EMBO J. 17, 2721-2727[CrossRef][Medline] [Order article via Infotrieve]
5.	Melchior, F., and Gerace, L. (1998) Trends Cell Biol. 8, 175-179[CrossRef][Medline] [Order article via Infotrieve]
6.	Rout, M. P., Aitchison, J. D., Suprapto, A., K., Hjertaas, Zhao, Y., and Chait, B. T. (2000) J. Cell Biol. 148, 635-652[Abstract/Free Full Text]
7.	Rout, M. P., and Wente, S. R. (1994) Trends Cell Biol. 4, 357-365[CrossRef][Medline] [Order article via Infotrieve]
8.	Radu, A., Blobel, G., and Moore, M. S. (1995) Proc. Natl. Acad. Sci. U. S. A. 92, 1769-1773[Abstract/Free Full Text]
9.	Rexach, M., and Blobel, G. (1995) Cell 83, 683-692[CrossRef][Medline] [Order article via Infotrieve]
10.	Chi, N. C., Adam, J. H. E., and Adam, S. A. (1995) J. Cell Biol 130, 265-274[Abstract/Free Full Text]
11.	Hu, T., Guan, T., and Gerace, L. (1996) J. Cell Biol 134, 589-601[Abstract/Free Full Text]
12.	Shah, S., and Forbes, D. J. (1998) Curr. Biol 8, 1376-1386[CrossRef][Medline] [Order article via Infotrieve]
13.	Kose, S., Imamoto, N., and Yoneda, Y. (1999) FEBS Lett. 463, 327-330[CrossRef][Medline] [Order article via Infotrieve]
14.	Seedorf, M., Damelin, M., Kahana, J., Taura, T., and Silver, P. A. (1999) Mol. Cell. Biol. 19, 1547-1557[Abstract/Free Full Text]
15.	Kehlenbach, R. H., Dickmanns, A., Kehlenbach, A., Guan, T., and Gerace, L. (1999) J. Cell Biol 145, 645-657[Abstract/Free Full Text]
16.	Damelin, M., and Silver, P. A. (2000) Mol. Cell 5, 133-140[CrossRef][Medline] [Order article via Infotrieve]
17.	Moore, M. S. (1998) J. Biol. Chem. 273, 22857-22860[Free Full Text]
18.	Ohtsubo, M., Okazaki, H., and Nishimoto, T. (1989) J. Cell Biol 109, 1389-1397[Abstract/Free Full Text]
19.	Nemergut, M. E., Mizzen, C. A., Stukenberg, T., Allis, C. D., and Macara, I. G. (2001) Science 292, 1540-1543[Abstract/Free Full Text]
20.	Hopper, A. K., Traglia, H. M., and Dunst, R. W. (1990) J. Cell Biol 111, 309-321[Abstract/Free Full Text]
21.	Melchior, F., Weber, K., and Gerke, V. (1993) Mol. Biol. Cell 4, 569-581[Abstract]
22.	Matunis, M. J., Coutavas, E., and Blobel, G. (1996) J. Cell Biol. 135, 1457-1470[Abstract/Free Full Text]
23.	Ribbeck, K., Lippowsky, G., Kent, H. M., Stewart, M., and Görlich, D. (1998) EMBO J 17, 6587-6598[CrossRef][Medline] [Order article via Infotrieve]
24.	Smith, A., Brownawell, A., and Macara, I. G. (1998) Curr. Biol. 8, 1403-1406[CrossRef][Medline] [Order article via Infotrieve]
25.	Quimby, B. B., Lamtina, T., L'Hernault, S., and Corbett, A. H. (2000) J. Biol. Chem. 275, 28575-28582[Abstract/Free Full Text]
26.	Moore, M. S., and Blobel, G. (1994) Proc. Natl. Acad. Sci. U. S. A. 91, 10212-10216[Abstract/Free Full Text]
27.	Clarkson, W. D., Kent, H. M., and Stewart, M. (1996) J. Mol. Biol. 263, 517-524[CrossRef][Medline] [Order article via Infotrieve]
28.	Paschal, B. M., and Gerace, L. (1995) J. Cell Biol. 129, 925-937[Abstract/Free Full Text]
29.	Clarkson, W. D., Corbett, A. H., Paschal, B. M., Kent, H. M., McCoy, A. J., Gerace, L., Silver, P. A., and Stewart, M. (1997) J. Mol. Biol. 272, 716-730[CrossRef][Medline] [Order article via Infotrieve]
30.	Kent, H. M., Moore, M. S., Quimby, B. B., Baker, A. M., McCoy, A. J., Murphy, G. A., Corbett, A. H., and Stewart, M. (1999) J. Mol. Biol. 289, 565-577[CrossRef][Medline] [Order article via Infotrieve]
31.	Quimby, B. B., Wilson, C. A., and Corbett, A. H. (2000) Mol. Biol. Cell 11, 2617-2629[Abstract/Free Full Text]
32.	Stewart, M., Kent, H., and McCoy, A. (1998) J. Mol. Biol 277, 635-646[CrossRef][Medline] [Order article via Infotrieve]
33.	Stewart, M. (2000) Cell Struct. Funct. 25, 217-225[CrossRef][Medline] [Order article via Infotrieve]
34.	Grote, M., Kubitscheck, U., Reichelt, R., and Peters, R. (1995) J. Cell Sci. 108, 2963-2972[Abstract]
35.	Bayliss, R., Ribbeck, K., Akin, D., Kent, H. M., Feldherr, C. M., Görlich, D., and Stewart, M. (1999) J. Mol. Biol. 293, 579-593[CrossRef][Medline] [Order article via Infotrieve]
36.	Chaillan-Huntington, C., Braslavsky, C. V., Kuhlmann, J., and Stewart, M. (2000) J. Biol. Chem. 275, 5874-5879[Abstract/Free Full Text]
37.	Bayliss, R., Littlewood, T., and Stewart, M. (2000) Cell 102, 99-108[CrossRef][Medline] [Order article via Infotrieve]
38.	Ribbeck, K., and Görlich, D. (2001) EMBO J. 20, 1320-1330[CrossRef][Medline] [Order article via Infotrieve]
39.	Sambrook, J., Fritsch, E. F., and Maniatis, T. (1989) Molecular Cloning: A Laboratory Manual , 2nd Ed. , Cold Spring Harbor Laboratory Press, Cold Spring Harbor, NY
40.	Rose, M. D., Winston, F., and Hieter, P. (1990) Methods in Yeast Genetics: A Laboratory Course Manual , Cold Spring Harbor Laboratory Press, Cold Spring Harbor, NY
41.	Corbett, A. H., and Silver, P. A. (1996) J. Biol. Chem. 271, 18477-18484[Abstract/Free Full Text]
42.	Shulga, N., Roberts, P., Gu, Z., Spitz, L., Tabb, M. M., Nomura, M., and Goldfarb, D. S. (1996) J. Cell Biol. 135, 329-339[Abstract/Free Full Text]
43.	Boeke, J. D., Truehart, J., Natsoulis, G., and Fink, G. (1987) Methods Enzymol. 154, 164-175[Medline] [Order article via Infotrieve]
44.	Towbin, H., Staehelin, T., and Gordon, J. (1979) Proc. Natl. Acad. Sci. U. S. A. 76, 4350-4354[Abstract/Free Full Text]
45.	Bullock, T. L., Clarkson, W. D., Kent, H. M., and Stewart, M. (1996) J. Mol. Biol. 260, 422-431[CrossRef][Medline] [Order article via Infotrieve]
46.	Paschal, B. M., Delphin, C., and Gerace, L. (1996) Proc. Natl. Acad. Sci. U. S. A. 93, 7679-7683[Abstract/Free Full Text]
47.	Davis, L. I., and Blobel, G. (1986) Cell 45, 699-709[CrossRef][Medline] [Order article via Infotrieve]
48.	Aris, J. P., and Blobel, G. (1989) J. Cell Biol. 108, 2059-2067[Abstract/Free Full Text]
49.	Lane, C. M., Cushman, I., and Moore, M. S. (2000) J. Cell Biol. 151, 321-332[Abstract/Free Full Text]
50.	Stoffler, D., Fahrenkrog, B., and Aebi, U. (1999) Curr. Opin. Cell Biol. 11, 391-401[CrossRef][Medline] [Order article via Infotrieve]
51.	Talcott, B., and Moore, M. S. (1999) Curr. Biol. 9, 312-318[CrossRef]
52.	Ben-Efraim, I., and Gerace, L. (2001) J. Cell Biol. 152, 411-417[Abstract/Free Full Text]
53.	Görlich, D., and Mattaj, I. W. (1996) Science 271, 1513-1518[Abstract]
54.	Davis, L. I., and Fink, G. R. (1990) Cell 61, 965-978[CrossRef][Medline] [Order article via Infotrieve]
55.	Wong, D. H., Corbett, A. H., Kent, H. M., Stewart, M., and Silver, P. A. (1997) Mol. Cell Biol. 17, 3755-3767[Abstract]
56.	Orr-Weaver, T. L., and Szostak, J. W. (1983) Proc. Natl. Acad. Sci. U. S. A. 80, 4417-4421[Abstract/Free Full Text]