Sac3 Is an mRNA Export Factor That Localizes to Cytoplasmic Fibrils of Nuclear Pore Complex

doi:10.1091/mbc.E02-08-0520

QUICK SEARCH:

[advanced]

	Author:		Keyword(s):
Year:		Vol:		Page:

Originally published as MBC in Press, 10.1091/mbc.E02-08-0520 on November 18, 2002

This Article

	Abstract
	Full Text (PDF)
	All Versions of this Article: E02-08-0520v1 14/3/836 most recent
	Alert me when this article is cited
	Alert me if a correction is posted

Services

	Similar articles in this journal
	Similar articles in PubMed
	Alert me to new issues of the journal
	Download to citation manager


Citing Articles

	Citing Articles via HighWire
	Citing Articles via Google Scholar

Google Scholar

	Articles by Lei, E. P.
	Articles by Silver, P. A.
	Search for Related Content

PubMed

	PubMed Citation
	Articles by Lei, E. P.
	Articles by Silver, P. A.

Vol. 14, Issue 3, 836-847, March 2003

Sac3 Is an mRNA Export Factor That Localizes to Cytoplasmic Fibrils of Nuclear Pore Complex

Elissa P. Lei,^* Charlene A. Stern,^* Birthe Fahrenkrog, Heike Krebber,^* Terence I. Moy,^*^§ Ueli Aebi, and Pamela A. Silver^*

^*Department of Biological Chemistry and Molecular Pharmacology, Harvard Medical School and Dana Farber Cancer Institute, Boston, Massachusetts 02115; and M.E. Müller Institute for Structural Biology, Biozentrum, University of Basel, 4056 Basel, Switzerland

Submitted August 19, 2002; Revised October 23, 2002; Accepted October 31, 2002
Monitoring Editor: Joseph Gall

	ABSTRACT

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

In eukaryotes, mRNAs are transcribed in the nucleus and exported to the cytoplasm for translation to occur. Messenger RNAscomplexed with proteins referred to as ribonucleoparticles arerecognized for nuclear export in part by association with Mex67,a key Saccharomyces cerevisiae mRNA export factor and homologof human TAP/NXF1. Mex67, along with its cofactor Mtr2, is thoughtto promote ribonucleoparticle translocation by interacting directlywith components of the nuclear pore complex (NPC). Herein, weshow that the nuclear pore-associated protein Sac3 functions inmRNA export. Using a mutant allele of MTR2 as a starting point,we have identified a mutation in SAC3 in a screen for syntheticlethal interactors. Loss of function of SAC3 causes a strong nuclearaccumulation of mRNA and synthetic lethality with a number ofmRNA export mutants. Furthermore, Sac3 can be coimmunoprecipitatedwith Mex67, Mtr2, and other factors involved in mRNA export. Immunoelectronmicroscopy analysis shows that Sac3 localizes exclusively to cytoplasmicfibrils of the NPC. Finally, Mex67 accumulates at the nuclearrim when SAC3 is mutated, suggesting that Sac3 functions in Mex67translocation through theNPC.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Nuclear export of mRNA in eukaryotes is an obligatory feature of normal gene expression. This process can be divided intotwo basic steps: formation of the export competent ribonucleoparticle(RNP) and translocation of the RNP through the nuclear pore complex(NPC). Beginning at transcription, mRNAs are bound and packagedby RNA binding proteins to form RNPs (reviewed in Lei and Silver,2002). Once properly formed, the RNP is actively exported acrossthe nuclear envelope via large aqueous channels formed by theproteinaceousNPC.

Structural integrity of the RNP is an important factor in obtaining export competence. Central to this process is the heterogeneousnuclear (hn)RNP protein Npl3, which is a highly abundant poly(A)⁺ RNA binding protein in Saccharomyces cerevisiae (Wilson et al.,1994). Npl3 shuttles between the nucleus and cytoplasm and isrequired for nuclear export of mRNA (Flach et al., 1994; Singletonet al., 1995; Lee et al., 1996). The nuclear export of Npl3 isclosely tied to that of mRNA, making its localization a usefulreporter for mRNA export (Krebber et al., 1999).

The overall structure of the NPC is a central framework with eightfold symmetry embedded in the membrane of the nuclear envelope.In addition, the NPC includes a nuclear-oriented basket of filamentsflanked by nuclear and terminal rings as well as fibrils extendinginto the cytoplasm (reviewed in Stoffler et al., 1999). The NPCis composed of proteins called nucleoporins, many of which arecharacterized by stretches of FG (Phe-Gly) dipeptide repeats.These FG repeats are thought to serve as binding sites for solubletransport receptors during translocation (Iovine et al., 1995;Radu et al., 1995).

Translocation of RNPs through the NPC is thought to be mediated by the mRNA export factor Mex67 in S. cerevisiae or TAP/NXF1in humans. Together as a heterodimer with its counterpart yeastMtr2 or metazoan p15, Mex67/TAP is essential for the export ofall mRNAs tested in S. cerevisiae and Drosophila (Hurt et al.,2000; Herold et al., 2001). Mex67/TAP is thought to be recruitedto RNPs via interaction with the conserved mRNA export factoryeast Yra1 or human Aly/REF (Strä $beta$ er and Hurt, 2000; Stutz etal., 2000; Zenklusen et al., 2001). Once bound, Mex67/TAP maypromote translocation through the NPC through serial interactionswith the FG repeats of nucleoporins (Bachi et al., 2000; Strä $beta$ eret al., 2000; Strawn et al., 2001).

Mtr2 is required for proper nuclear pore targeting of Mex67. Mutation of MTR2 causes mislocalization of Mex67 from the nuclearrim to the cytoplasm, and Mtr2 itself interacts with the nucleoporinNup85 (Santos-Rosa et al., 1998). However, there is disagreementas to whether Mtr2 promotes Mex67 interaction with nucleoporins(Strä $beta$ er et al., 2000; Strawn et al., 2001). In higher eukaryotes,the TAP cofactor p15 seems to be important for NPC targeting ofTAP (Fribourg et al., 2001; Levesque et al., 2001; Wiegand etal., 2002). The function of these mRNA export receptor heterodimersis conserved because MEX67/MTR2 can be replaced by introductionof both TAP and p15 in S. cerevisiae, although Mtr2 and p15 shareno sequence homology (Katahira et al., 1999). Additionally, Mtr2has been implicated in the export of the large ribosomal subunit(Stage-Zimmermann et al., 2000; Ba $beta$ ler et al., 2001). Moreover,Ba $beta$ ler et al. (2001) described a mutant allele of MTR2 that displaysa defect in ribosome but not mRNA export, suggesting that thefunctions of Mtr2 in both processes are distinct andseparable.

An additional requirement for mRNA export is the integrity of the NPC. Three nucleoporin subcomplexes seem to be specificallyrequired for mRNA export, the Nup84-Nup85-Nup120-Nup145-Seh1-secs13complex, the Nsp1-Nup82-Nup159 complex, and the Nup116-Gle2 complex(Wente and Blobel, 1993; Murphy et al., 1996; Siniossoglou etal., 1996; Teixeira et al., 1997; Bailer et al., 1998; Belgarehet al., 1998; Hurwitz et al., 1998). These nucleoporins may providedocking sites for Mex67 during RNP translocation. In fact, Nup116can be coimmunoprecipitated with Mex67 from cell lysates (Strawnet al., 2001), and Mex67 is able to bind to fragments containingthe FG repeats of Nsp1, Nup116, Nup159, and Rip1 in vitro (Strä $beta$ eret al., 2000; Strawn et al., 2001). These interactions are likelyto be important for Mex67-mediated RNP translocation through theNPC.

On the cytoplasmic face of the NPC exists a putative complex of proteins that is proposed to serve as the terminal dockingsite for RNPs. This complex consists of Nup159/Rat7, Gle1, Rip1,and Dbp5/Rat8. Nup159 localizes exclusively to the cytoplasmicfibrils of the NPC, whereas Gle1, Rip1, and Dbp5 display a widerspatial distribution, including the cytoplasmic fibrils (Kraemeret al., 1995; Schmitt et al., 1999; Strahm et al., 1999). Dbp5is an RNA helicase that has been postulated to remodel the RNPas it is transported or to promote release of RNA binding proteinsfrom the mRNA in the final steps of mRNA export (Snay-Hodge etal., 1998; Tseng et al., 1998). It has been suggested that a functionof these nucleoporins is to position Dbp5 at the NPC (Hodge etal., 1999; Strahm et al., 1999). Alternately, these proteins mayact as docking sites for RNPs as they translocate through theNPC.

The NPC-associated protein Sac3 has been implicated previously in nuclear transport. SAC3 was originally identified in a screenfor suppressors of actin mutations (Novick et al., 1989) and hasbeen subsequently shown to be required for normal mitotic progressionand spindle morphology (Bauer and Kölling, 1996b). Localizingto the NPC, Sac3 associates physically with the nucleoporin Nsp1(Jones et al., 2000). Finally, Sac3 has been ascribed a role innuclear transport that may be related to its function in the cellcycle (Jones et al., 2000).

In this study, we have characterized the role of Sac3 in mRNA export. Mutation of SAC3 causes synthetic lethality with mutationof MEX67, MTR2, and several genes that encode cytoplasmic fibril-associatedmRNA export factors. In addition, Sac3 is associated physicallywith Mex67, Mtr2, and other factors involved in mRNA export. Byimmunoelectron microscopy, Sac3 localizes exclusively to the cytoplasmicfibrils of the NPC. Finally, Mex67 accumulates at the nuclearrim in sac3 mutants, suggesting that Sac3 functions in the terminal stepof Mex67 translocation through theNPC.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Indirect Immunofluorescence and In Situ Hybridization

These procedures were performed as described previously (Krebber et al., 1999). $alpha$ -Nsp1 (gift of M. Stewart; MRC LMB, Cambridge,United Kingdom) was used at a 1:1000 dilution and detected withTexas Red-conjugated donkey $alpha$ -rabbit (1.5 mg/ml; Jackson ImmunoresearchLaboratories, West Grove, PA) at a 1:1000 dilution. For sac3 $Delta$ 139and $Delta$ sac3-rg, in situ hybridization was performed with a Cy3-labeledoligo dT₅₀ probe at 50 nM, and all steps between probe hybridizationand the first 2× SSC wash wereeliminated.

Synthetic Lethal Screen

mtr2-142 cells (PSY1720) carrying a plasmid encoding pJT10-MTR2-URA3-ADE8 (pPS1852) were subjected to ethyl methanesulfonatemutagenesis to a rate of 50% killing. We screened 15,000 coloniesby the colony sectoring assay for loss of sectoring (Elledge andDavis, 1988). Candidates were selected that meet the criteriafor synthetic lethality as described previously (Henry and Silver,1996) and backcrossed to parental mtr2-142 cells (PSY1719) threetimes. Linkage to SAC3 was determined by crossing this strainto ACY276, which is marked with HIS3 at the SAC3 locus. A sporefrom this cross was further outcrossed into the S288C backgroundby crossing twice to FY23. The resulting strain was marked withthe HIS3MX6 marker downstream of sac3 $Delta$ 139 by a method describedpreviously (Longtine et al., 1998) to createPSY2555.

Immunoprecipitation

Cells (50 ml) were grown in YPD at 25-30°C to ~2 × 10⁷ cells/ml. All subsequent steps were performed at 4°C. Pellets were lysedin 50-100 µl of ice-cold PBSMT (2.5 mM MgCl₂, 3 mM KCl, 0.5% TritonX-100 in phosphate-buffered saline) plus protease inhibitors (1mM phenylmethylsulfonyl fluoride and 2 ng/ml each of pepstatinA, leupeptin, aprotinin, antipain, benzamidine, and chymostatin)by using glass beads in a FastPrep bead beater (6.5 m/s; SavantInstruments, Holbrook, NY). After lysis, an additional 1 ml ofPBSMT was added, and lysates were clarified by centrifugationat 14,000 rpm for 10 min. Protein A-Sepharose (40 µl) was washedthree times in PBSMT and added to 1 mg of lysate in a total of1 ml of PBSMT. Then 1.5 µl of affinity-purified rabbit polyclonal $alpha$ -green fluorescent protein (GFP) (0.9 mg/ml) was added and incubatedovernight with agitation. Beads were washed three times with 750µl of PBSMT and once with 750 µl of Tris-EDTA, pH 8.0. Samplebuffer (20 µl) was added to samples and boiled for 5 min. Immunoprecipitates(IPs) and total lysate were resolved by 7% SDS-PAGE and transferredto nitrocellulose in 10 mM CAPS (3-[cyclohexylamino]-1 propanesulfonic acid), pH 11, 1% methanol. Blots were probed with $alpha$ -GFPat 1:10,000 and $alpha$ -myc (9E10, 200 µg/ml; Santa Cruz Biotechnology,Santa Cruz, CA) at 1:1000.

Immunoelectron Microscopy

Spheroplasted, Triton X-100 extracted ECFP-Sac3 cells were incubated with $alpha$ -GFP antibody directly conjugated to 8-nm colloidalgold and processed for preembedding labeling as described previously(Fahrenkrog et al., 1998).

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Sac3 Functions in mRNA Export

In an effort to identify genes involved in mRNA export in S. cerevisiae, we performed a screen for mutants that disrupt theexport of the hnRNP protein Npl3 (Lei et al., 2001). This screenrelies on a mutant form of Npl3, Npl3-27, that is slowed for nuclearimport and localizes at steady state throughout the nucleus andcytoplasm of cells as determined by indirect immunofluorescence(Figure 1A, a-c) (Krebber et al., 1999). We found that mutationof the mRNA export factor MTR2 causes nuclear accumulation ofNpl3-27 (Figure 1A, d-f). In addition, this mutant is temperaturesensitive for growth (our unpublished data). The lesion in MTR2maps to a single nucleotide mutation changing Gly142 to Asp, andthis mutant is thus designated mtr2-142.

View larger version (56K):
[in this window]
[in a new window]

Figure 1. Characterization of the mtr2-142 mutant. (A) mtr2-142 causes nuclear accumulation of Npl3-27. Localization of Npl3-27 in npl3-27 (PSY1031, a-c) and npl3-27 mtr2-142 (PSY1717, d-f) cells. Cells were shifted to 37°C for 30 min. Indirect immunofluorescence with polyclonal antibodies to Npl3 (left), DAPI (middle), and Nomarski images (right) are shown. (B) mtr2-142 cells display an mRNA export defect. Localization of poly (A)⁺ RNA in mtr2-142 cells (PSY1719) grown at 25°C (a-c) or shifted to 37°C for 10 min (d-f). In situ hybridization with an oligo (dT)₅₀ probe (left), DAPI (middle), and Nomarski images (right) are shown. (C) mtr2-142 cells mislocalize Mex67 to the cytoplasm. Localization of Mex67-GFP in mtr2-142 cells (PSY2857) grown at 25°C (a and b) or shifted to 37°C for 15 min (c and d). GFP fluorescence (left) and Nomarski images (right) are shown. (D) mtr2-142 cells display a large ribosome export defect. Localization of Nmd3-GFP in wild-type (FY23, a and b) and mtr2-142 cells (PSY1719, c and d). Localization of Rpl11b-GFP in wild-type (e and f) and mtr2-142 cells (g and h). Cells were grown at 25°C.

We further characterized the mtr2-142 mutation in isolation from npl3-27 to determine its effects on nuclear export. MTR2has been implicated in the export of mRNA as a cofactor for theexport receptor Mex67 (Santos-Rosa et al., 1998). We examinedthe localization of mRNA in mtr2-142 cells by in situ hybridizationwith an oligo dT₅₀ probe. In cells grown at permissive growthtemperature, poly (A)⁺ RNA localizes throughout the nucleus and cytoplasm similar towild-type (Figure 1B, a-c) but accumulates in the nuclei of cellsshifted to the nonpermissive temperature for 10 min (Figure 1B,d-f). In addition, we examined the localization of Mex67-GFP inmtr2-142 cells. At permissive growth temperature, Mex67-GFP localizesto the nuclear rim as in wild type (Figure 1C, a and b). However,in cells shifted to the nonpermissive growth temperature for 15min, Mex67-GFP mislocalizes to the cytoplasm in a punctate pattern(Figure 1C, c and d). On longer shifts to 37°C, mtr2-142 cellsundergo considerable lysis (our unpublished data). The extentof Mex67 mislocalization in the mtr2-142 mutant is apparentlyless severe than previously published mutant alleles of mtr2 (Santos-Rosaet al., 1998). Furthermore, mtr2-142 is unable to support growthin combination with the mex67-5 mutation, indicating a syntheticlethal relationship (our unpublished data). Therefore, mtr2-142results in a rapid accumulation of mRNA in the nucleus and mislocalizationof Mex67 to thecytoplasm.

Because Mtr2 also functions in the nuclear export of large ribosomal subunits, we examined the localization of large ribosomalsubunits in mtr2-142. The mtr2-33 mutant causes nuclear accumulationof the large ribosomal subunit but not of mRNA, suggesting thatMtr2 functions in discrete export pathways (Ba $beta$ ler et al., 2001).Export of the large ribosomal subunit can be monitored by localizationof the 60S export adapter Nmd3 (Ho et al., 2000) or a large ribosomalprotein such as Rpl11b (Hurt et al., 1999; Stage-Zimmermann etal., 2000). In wild-type cells, Nmd3-GFP and Rpl11b-GFP localizethroughout the nucleus and cytoplasm (Figure 1D, a and b and eand f), whereas both Nmd3-GFP and Rpl11b are concentrated in thenucleus in nearly one 100% of mtr2-142 cells. These defects areapparent at the permissive growth temperature, indicating a stronginhibition of 60Sexport.

To determine what export factors interact genetically with Mtr2, we performed a synthetic lethal screen by the colony sectoringassay by using the mtr2-142 mutant (our unpublished data). Weobtained three mutants that are likely to be complete loss offunction mutations in MTR2. A fourth mutant was determined toharbor a mutation in SAC3, which encodes a nuclear pore-associatedprotein (Jones et al., 2000). Mapping of the genetic lesion bygap repair and sequencing revealed a mutation of a single nucleotideto cause a nonsense mutation of Trp139 to Stop thus truncatingSac3 from its wild-type length of 1301 aa. This mutant is herebyreferred to as sac3 $Delta$ 139.

Given its interaction with mtr2-142, we examined sac3 $Delta$ 139 cells for a defect in mRNA export. sac3 $Delta$ 139 cells have a decreasedrate of growth at all temperatures tested (our unpublished data).In wild-type cells, poly (A)⁺ RNA localizes throughout the nucleus and cytoplasm as monitoredby in situ hybridization (Figure 2A, a-c). In sac3 $Delta$ 139 cells,mRNA accumulates in the nucleus (Figure 2A, d-f). Similarly, thedeletion mutant $Delta$ sac3-rg obtained from the Saccharomyces GeneDeletion Project (Winzeler et al., 1999) displays a nuclear accumulationof mRNA (Figure 2A, j-l). In the corresponding wild-type strainfor $Delta$ sac3-rg mutant, poly (A)⁺ RNA localizes throughout the nucleus and cytoplasm (Figure 2A,g-i). The mRNA export defect of sac3 $Delta$ 139 cells can be rescuedby introduction of a wild-type SAC3 plasmid (our unpublished data).Furthermore, heterozygous sac3 $Delta$ 139 diploid cells display a wild-typelocalization of mRNA, whereas diploids homozygous for sac3 $Delta$ 139accumulate mRNA in the nucleus (our unpublished data). Therefore,sac3 $Delta$ 139 is a recessive loss of function mutation.

View larger version (33K):
[in this window]
[in a new window]

Figure 2. Sac3 functions primarily in mRNA export. A. sac3 mutant cells display an mRNA export defect. Localization of poly (A)⁺ RNA in wild-type (FY23, a-c), sac3 $Delta$ 139 cells (PSY2555, d-f), wild-type (PSY1930, g-i), and $Delta$ sac3-rg cells (PSY2844, j-l) grown at 30°C. In situ hybridization with an oligo (dT)₅₀ probe (left), DAPI (middle), and Nomarski images (right) are shown. (B) sac3 $Delta$ 139 cells do not display a large ribosome export defect. Localization of Rpl11b-GFP in wild-type (FY23, a-d) and sac3 $Delta$ 139 cells (PSY2555, e-h) grown at 25°C (a, b, e, and f) or shifted to 37°C for 1 h and back to 25°C for 1 h (c, d, g, and h). (C) sac3 $Delta$ 139 cells do not have an NES-protein export defect. Localization of NLS-NES-GFP in wild-type (FY23) and sac3 $Delta$ 139 cells (PSY2555) grown at 25°C.

Because mtr2-142 cells display several defects in nuclear export, we examined sac3 $Delta$ 139 cells for various nuclear export phenotypes.In wild-type cells expressing Rpl11b-GFP, the reporter localizesthroughout the nucleus and cytoplasm (Figure 2B, a-b). Examinationof cells after a temperature shift to 37°C to reduce the poolof ribosomes and shift back to 25°C to resume synthesis is a highlysensitive assay for large ribosome export (Hurt et al., 1999;Stage-Zimmermann et al., 2000). On a shift to 37°C and shift backto 25°C, the localization of Rpl11b-GFP is unchanged in wild-typecells (Figure 2B, c and d). In sac3 $Delta$ 139 cells grown at 25°C, Rpl11b-GFPlocalizes throughout cells similar to wild type (Figure 2B, eand f). On a shift to high temperature and shift back, <10% ofcells display a mild nuclear accumulation of the reporter (Figure2B, g and h). This slight effect is milder than that of bona fide60S export mutants as well as some mRNA export mutants (Stage-Zimmermannet al., 2000). Furthermore, the localization of Nmd3-GFP is unaffectedin sac3 $Delta$ 139 mutants (our unpublished data). The export of smallribosomal subunits is also unaffected (our unpublished data) (Moyand Silver, 1999). Finally, the ability to export an artificialreporter containing the simian virus 40 nuclear localization sequence(NLS) and the protein kinase inhibitor (PKI) nuclear export sequence(NES) fused to two GFP moieties was examined in sac3 $Delta$ 139 cells.The NLS-NES-GFP reporter localizes throughout the nucleus andcytoplasm in wild-type cells (Figure 2C, a and b). In sac3 $Delta$ 139cells grown at 25°C, the NLS-NES-GFP reporter localizes throughoutthe nucleus and cytoplasm in most cells (Figure 2C, c and d) althoughin ~15% of cells, a slight nuclear accumulation is seen (Figure2C, e and f). When sac3 $Delta$ 139 cells are grown at 30°C or shiftedto 37°C for 2 h, ~30% of cells show a slight nuclear accumulationof the NLS-NES-GFP reporter, and the same results were obtainedwith the $Delta$ sac3-rg strain (our unpublished data). Intense nuclearaccumulation of the NLS-NES-GFP reporter in the NES-protein exportreceptor mutant xpo1-1 is seen in ~100% of cells when shiftedto 37°C for 15 min similar to previously reported results (ourunpublished data) (Stade et al., 1997). Therefore, failure toexport mRNA is the principal defect of sac3 $Delta$ 139cells.

Sac3 Interacts with mRNA Export Factors

To further test the hypothesis that Sac3 is involved in mRNA export, we tested for synthetic lethality of sac3 $Delta$ 139 and variousnuclear export factor mutants. This form of genetic interactioncan indicate that two genes function in the same pathway or inparallel pathways. The results of these experiments are summarizedin Table 1. We found that sac3 $Delta$ 139 is not synthetically lethalwith deletion of the NES export factor $Delta$ yrb2 or factors localizedto the nuclear basket, $Delta$ mlp1 and $Delta$ mlp2. Furthermore, we foundthat sac3 $Delta$ 139 displays synthetic lethality with a number of mRNAexport factor mutants such as mex67-5, rat8-2/dbp5, rat7-1/nup159,and results in synthetic sickness with nup82- $Delta$ 108. Interestingly,all of these factors localize predominantly to the cytoplasmicfibrils of the NPC, although Mex67 and Mtr2 localize to both thenuclear and cytoplasmic faces of the pore (Kraemer et al., 1995;Hurwitz et al., 1998; Santos-Rosa et al., 1998; Strahm et al.,1999). Two mRNA export factor mutants that sac3 $Delta$ 139 is not syntheticallylethal with are $Delta$ nup116-5 and gle1-L356A. These results show thatSAC3 interacts genetically with specific mRNA export factor genes.

View this table:
[in this window]
[in a new window]

Table 1. Mutations tested for synthetic lethality with sac3 $Delta$ 139

View this table:
[in this window]
[in a new window]

Table 2. S. cerevisiae strains used in this study

To assess whether Sac3 associates physically with mRNA export factors, we tested whether Sac3 could be coimmunoprecipitatedfrom cell lysates with several export factors. Lysates were preparedfrom three different strains bearing a myc epitope-tagged Sac3,an EYFP-tagged Mtr2, or both tagged proteins. Western blottingwith $alpha$ -GFP to detect EYFP-Mtr2 shows expression only in the EYFP-Mtr2and the double-tagged strains (Figure 3A, lanes 7-9). By using $alpha$ -myc antibody, Sac3-myc is detectable only in the Sac3-myc anddouble-tagged strains (Figure 3A, lanes 1-3). Lysates from eachstrain were immunoprecipitated with $alpha$ -GFP antibody against EYFP-Mtr2.Equal amounts of EYFP-Mtr2, which migrates just below the heavychain of the $alpha$ -GFP antibody, are immunoprecipitated from the EYFP-Mtr2and double-tagged strains (Figure 3A, lanes 10-12). In the double-taggedstrain but not single tagged strains, Sac3-myc is detectable inthe immunoprecipitate (Figure 3A, lanes 4-6), indicating thatSac3 interacts physically with Mtr2. In the same manner, we examinedwhether Sac3 associates physically with Mex67, which interactsstably with Mtr2 (Santos-Rosa et al., 1998). Western blottingof lysates from Sac3-myc, Mex67-GFP, and double-tagged strainsby using $alpha$ -myc and $alpha$ -GFP antibodies show even levels of expressionof Sac3-myc and Mex67-GFP, respectively, only in strains withthe appropriate epitope tag (Figure 3B, lanes 1-3, 7-9). Whenlysates from Sac3-myc, Mex67-GFP, and double-tagged strains areimmunoprecipitated using $alpha$ -GFP antibody, which recognizes Mex67-GFP,Mex67-GFP is efficiently immunoprecipitated in the Mex67-GFP anddouble-tagged strains (Figure 3B, lanes 10-12). Sac3-myc is detectablein the immunoprecipitate of the double-tagged strain only, indicatingthat Sac3 and Mex67 can be coimmunoprecipitated (Figure 3B, lanes4-6). Therefore, Sac3 interacts physically with the mRNA exportfactors Mtr2 and Mex67.

View larger version (25K):
[in this window]
[in a new window]

Figure 3. Sac3 associates physically with mRNA export factors and nuclear pore associated proteins. (A) Sac3 coimmunoprecipitates with Mtr2. Lysates (left) and $alpha$ -GFP immunoprecipitates (right) from Sac3-myc (PSY2451, lanes 1, 4, 7, and 10), EYFP-Mtr2 (PSY2729, lanes 2, 5, 8 and 11), and double tagged Sac3-myc EYFPMtr2 (PSY2729, lanes 2, 5, 8 and 11), and double tagged Sac3-myc EYFP-Mtr2 (PSY2747, lanes 3, 6, 9 and 12) strains. The asterisk denotes the heavy chain of the $alpha$ -GFP antibody. Arrows point to EYFP-Mtr2. Lanes 7-9 were exposed ten times longer than lanes 10-12. B. Sac3 coimmunoprecipitates with Mex67. Lysates (left) and $alpha$ -GFP immunoprecipitates (right) from Sac3-myc (PSY2451, lanes 1, 4, 7 and 10), Mex67-GFP (lanes 2, 5, 8 and 11), and double tagged Sac3-myc Mex67-GFP (PSY2691, lanes 3, 6, 9 and 12) strains. C. Sac3 coimmunoprecipitates with Mlp1. Lysates (left) and $alpha$ -GFP immunoprecipitates (right) from Sac3-myc (PSY2451, lanes 1, 4, 7, and 10), Mlp1-EYFP (PSY2751, lanes 2, 5, 8, and 11), and double-tagged Sac3-myc Mlp1-EYFP (PSY2752, lanes 3, 6, 9, and 12) strains. (D) Sac3 coimmunoprecipitates with Nup116. Lysates (left) and $alpha$ -GFP immunoprecipitates (right) from Sac3-myc (PSY2451, lanes 1, 4, 7, and 10), Nup116-EYFP (PSY1832, lanes 2, 5, 8, and 11), and double-tagged Sac3-myc Nup116-EYFP (PSY2856, lanes 3, 6, 9, and 12) strains. (E) Sac3 coimmunoprecipitates with Dbp5. Lysates (left) and $alpha$ -GFP immunoprecipitates (right) from Sac3-myc (PSY2451, lanes 1, 4, 7, and 10), ECFP-Dbp5 (PSY2726, lanes 2, 5, 8, and 11), and double-tagged Sac3-myc ECFP-Dbp5 (PSY2755, lanes 3, 6, 9, and 12) strains. (F) Sac3 does not coimmunoprecipitate with NLS-NES-GFP. Lysates (left) and $alpha$ -GFP immunoprecipitates (right) from a Sac3-myc strain containing empty vector (PSY2451 transformed with pPS703; lanes 1, 4, 7, and 10), a wild-type strain expressing NLS-NES-GFP (FY23 transformed with pPS1372; lanes 2, 5, 8, and 11), and a Sac3-myc strain expressing NLS-NES-GFP (PSY2451 transformed with pPS1372; lanes 3, 6, 9, and 12). The asterisk denotes the heavy chain of the $alpha$ -GFP antibody. Arrows point to two bands corresponding to NLS-NES-GFP. Samples were run on an SDS-PAGE gel. Lysate (10 µg) and 1/20th of the IP (from a total of 1 mg of lysate) were blotted with $alpha$ -GFP (lanes 7-12) and 10 µg of lysate and the remainder of the IP were blotted with $alpha$ -myc (9E10, lanes 1-6).

We next tested whether Sac3 interacts physically with NPC-associated proteins. It has been shown previously that Sac3 canbe copurified with the nucleoporin Nsp1 from cell lysates, indicatingthat Sac3 associates physically with the NPC (Jones et al., 2000).We examined whether Sac3 could be coimmunoprecipiatated with theyeast homologue of mammalian Tpr, Mlp1, which has been shown tolocalize to the nuclear basket of the NPC (Strambio-de-Castilliaet al., 1999; Kosova et al., 2000). When lysates from Sac3-myc,Mlp1-EYFP, and double-tagged strains are subjected to immunoprecipitationwith $alpha$ -GFP antibody against Mlp1-EYFP, Sac3-myc is visible inthe immunoprecipitate of the double-tagged strain only, indicatingthat both proteins exist in a complex (Figure 3C). Interestingly,it has been stated as unpublished data that Mlp2, which is redundantwith Mlp1, can be copurified with Mex67 and Mtr2 (Kosova et al.,2000). Furthermore, overexpression of Mlp1 causes nuclear accumulationof poly (A)⁺ RNA, possibly implicating Mlp1 in the mRNA export process (Kosovaet al., 2000). We also examined whether Sac3 can be coimmunoprecipitatedwith the nucleoporin Nup116, which is essential for proper mRNAexport (Wente and Blobel, 1993). In the same manner, we testedwhether $alpha$ -GFP immunoprecipitation against Nup116-EYFP in Sac3-myc,Nup116-EYFP, and double-tagged strains results in copurificationof Sac3-myc. Western blotting shows that Sac3-myc is detectablein the immunoprecipitation from the double-tagged strain only(Figure 3D), indicating that Sac3 associates physically withNup116.

Finally, we tested whether Sac3 could be coimmunoprecipitated with the RNA helicase Dbp5. Dbp5 is an mRNA export factor thatlocalizes to the cytoplasmic fibrils of the NPC (Schmitt et al.,1999; Strahm et al., 1999). Sac3-myc is detectable in the $alpha$ -GFPimmunoprecipitate of the double-tagged but not single-tagged Sac3-mycor ECFP-Dbp5 strains (Figure 3E). To ensure that Sac3 does notsimply associate with the GFP moiety of GFP-tagged proteins, wealso examined whether Sac3 interacts physically with the plasmidborne NLS-NES-GFP reporter, which continuously shuttles betweenthe nucleus and the cytoplasm through the NPC. Western blottingof lysates from Sac3-myc cells transformed with vector, wild-typecells expressing NLS-NES-GFP, and Sac3-myc cells expressing NLS-NES-GFPshows Sac3-myc expression only in Sac3-myc cells transformed witheither plasmid (Figure 3F, lanes 1-3). NLS-NES-GFP expressionis visible as a doublet in wild-type and Sac3-myc cells transformedwith NLS-NES-GFP plasmid (Figure 3F, lanes 7-9). In cells transformedwith NLS-NES-GFP, $alpha$ -GFP can immunoprecipitate NLS-NES-GFP, whichmigrates closely to the heavy chain of the $alpha$ -GFP antibody (Figure3F, lanes 10-12). Sac3-myc is not present in the immunoprecipitatesfrom any of the three strains (Figure 3F, lanes 4-6), indicatingthat Sac3-myc does not associate with all GFP-tagged proteins.In addition, we were able to detect consistently ECFP-Dbp5, EYFP-Mtr2,and Mex67-GFP in $alpha$ -myc immunoprecipitations directed against Sac3-mycin the reverse experiment (our unpublished data). These resultsindicate that Sac3 interacts physically with the mRNA export factorsMtr2, Mex67, and Dbp5 as well as the NPC-associated proteins Mlp1andNup116.

Sac3 Localizes to Cytoplasmic Fibrils of NPC

To determine the precise localization of Sac3 within the NPC, we performed immunoelectron microscopy by using epitope-taggedSac3. Previously, it has been shown that Sac3 localizes exclusivelyto the nuclear rim by using a GFP-fusion (Jones et al., 2000).To localize Sac3, preembedding labeling immunoelectron microscopyby using a yeast strain expressing ECFP-Sac3 was carried out.An $alpha$ -GFP antibody conjugated directly to 8-nm colloidal gold labeledonly the cytoplasmic face of the NPC (Figure 4A). Quantitationof the gold particle distribution associated with the NPC withrespect to the central plane of the nuclear envelope revealedthat 95% of the gold particles were detected at distances from20-60 nm (average distance 36.9 ± 10.5 nm) from the central plane(Figure 4B). With respect to the eightfold symmetry axis of theNPC, 95% of the gold particles were distributed over a broad rangeat distances from 0 to 50 nm (average distance 20.2 ± 15.3 nm)from this plane. From these results, we concluded that ECFP-Sac3is associated exclusively with the cytoplasmic filaments of theNPC. We obtained similar results with C-terminal myc and GFP epitopetags on Sac3 (our unpublished data).

View larger version (63K):
[in this window]
[in a new window]

Figure 4. Immunogold-localization of Sac3 in ECFP-Sac3 cells. (A) Triton X-100-extracted spheroplasts from ECFP-Sac3 cells were preimmunolabeled with a polyclonal anti-GFP antibody directly conjugated to 8-nm colloidal gold. Shown is a view along a cross-sectioned nuclear envelope stretch with labeled NPCs (arrows, top), and a gallery of selected samples of gold-labeled NPC cross sections (bottom). The anti-GFP antibody labeled exclusively the cytoplasmic periphery of the NPC. c, cytoplasm; n, nucleus. Bars, 100 nm. (B) Quantitative analysis of the gold particles associated with the NPC. Fifty-two gold particles were scored.

We also tested whether Sac3 localization is dependent on other transport factors. Dbp5 localizes to the nuclear rim and thecytoplasm in wild-type cells, but in xpo1-1 cells, Dbp5 accumulatesin the nucleus, suggesting that Dbp5 shuttles through the nucleus(Hodge et al., 1999). We localized ECFP-Sac3 in xpo1-1 cells byfluorescence microscopy and found its localization to be unaffectedcompared with wild type (our unpublished data), indicating thatit does not shuttle in a XPO1/CRM1-dependent manner. Similarly,Sac3 localization is also unaffected in the mtr2-142 mutant (ourunpublisheddata).

Sac3 Is Required for Proper Localization of Mex67

To determine whether Sac3 may function in the translocation of Mex67 through the NPC, we examined the localization of Mex67and Mtr2 in the sac3 $Delta$ 139 mutant. In wild-type cells, Mex67-GFPlocalizes to the nuclear rim (Figure 5A, a and b). In sac3 $Delta$ 139cells, Mex67-GFP is localized to the entire nuclear rim as inwild type; however, a single strong focus several times the intensityof the rest of the nuclear rim is visible (Figure 5A, c and d).Western blotting was performed to verify that Mex67-GFP levelsare similar in wild-type and sac3 $Delta$ 139 cells (our unpublished data).A similar and more profound defect of Mex67-GFP mislocalizationwas visible in SAC3 $Delta$ cells (ACY159) (our unpublished data). Incontrast, Mtr2-GFP was unaltered in sac3 cells compared with wild type, suggesting that the defect ofMex67 localization in sac3 cells is not a result of Mtr2 mislocalization (our unpublisheddata). We conclude that SAC3 is required for proper localizationof Mex67.

View larger version (34K):
[in this window]
[in a new window]

Figure 5. Mex67 mislocalizes in sac3 $Delta$ 139 cells. (A) Localization of Mex67-GFP in wild-type (MEX67-GFP, a and b) and sac3 $Delta$ 139 cells (c and d, PSY2843, top and PSY2842, bottom) grown at 30°C. GFP fluorescence (left) and Nomarski images (right) are shown. Arrows point to intense foci at the nuclear rim. (B) Localization of Nsp1 in wild-type (FY23, a and b), rat2-1 (Dat4-2, c and d), and sac3 $Delta$ 139 cells (e and f) grown at 25°C. Indirect immunofluorescence with polyclonal antibodies to Nsp1 (left) and 4,6-diamidino-2-phenylindole (right) are shown.

The mislocalization of Mex67 in sac3 $Delta$ 139 cells is not due to pore clustering, a phenotype of some nucleoporin mutants. Toexamine the distribution of nuclear pores, we localized the nucleoporinNsp1 in the sac3 $Delta$ 139 mutant. By indirect immunofluorescence, Nsp1is visible as a punctate signal at the nuclear rim in wild-typecells grown at 25°C (Figure 5B, a and b). In a pore clusteringmutant rat2-1, NPCs are clustered on one side of the nucleus (Heathet al., 1995), and Nsp1 signal concentrates in a crescent shapeadjacent to the DAPI signal (Figure 5B, c and d). In sac3 $Delta$ 139cells, Nsp1 localizes to the entire nuclear rim similar to wildtype (Figure 5B, e and f), indicating that NPCs do not clusterin sac3 $Delta$ 139 cells. The same results are obtained when cells aregrown at 30°C or shifted to 37°C for 3 h (our unpublished data).Furthermore, Dbp5, which clusters in a pore clustering mutant(Snay-Hodge et al., 1998), is not mislocalized in sac3 $Delta$ 139 cells(our unpublished data). Therefore, the mislocalization of Mex67in sac3 $Delta$ 139 cells is not a result of poreclustering.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Using a combination of genetic screens to identify genes involved in mRNA export, we have identified the nuclear pore-associatedprotein Sac3. Mutation of SAC3 causes a robust accumulation ofmRNA in the nucleus but only mildly affects other nuclear exportpathways. Furthermore, Sac3 interacts physically with severalproteins involved in mRNA export and localizes exclusively tothe cytoplasmic fibrils of the NPC. Finally, mutation of SAC3causes mislocalization of Mex67 to a strong focus at the nuclearrim. Taken together, these results show that Sac3 is involvedin mRNA export and implicate Sac3 at the step of RNP translocationthrough theNPC.

Earlier studies have implicated Sac3 in actin function and mitotic progression. Mutations in SAC3 were found to suppress thetemperature sensitivity of the act1-1 mutant (Novick et al., 1989).A potential explanation for the suppression of act1-1 by sac3 mutants is that diminished export of the defective actin transcriptdecreases the deleterious effects of this actin mutation. However,this possibility is unlikely because the suppression is allelespecific (Bauer and Kölling, 1996a; Novick et al., 1989), suggestingthat loss of SAC3 function does not bypass the act1-1 mutation.In addition, a later study found that mutation of SAC3 causesaberrant mitosis and spindle morphology (Bauer and Kölling, 1996b).A direct role for the actin cytoskeleton has not been establishedin nuclear transport, but there is speculation that RNPs may travelalong cellular microfilament tracks to reach their destinations.In fact, it has been suggested that Tpr and its homologues Mlp1and 2 may form intranuclear filaments that can serve as tracksconnecting the chromatin and the NPC on which RNPs travel (Cordeset al., 1997; Strambio-de-Castillia et al., 1999). It is alsopossible that the actin cytoskeleton may be physically attachedto the cytoplasmic filaments of the NPC and necessary for properorientation of the NPC and/or the mitotic spindle. A screen fornuclear import mutants revealed that mutation of ARP2/ACT2, anactin-related gene, causes a defect in NPC morphology (Yan etal., 1997). Currently, it is unclear as to how the nuclear transportfunction of Sac3 is related to its function with respect toactin.

Previously, Sac3 was ascribed a role in nuclear transport. Examination of Sac3 showed that it localizes to the nuclear rimand interacts with nucleoporins (Jones et al., 2000). Specifically,Sac3 was copurified with Nsp1 from yeast lysate and was shownto interact with Nup1 and Nup159 by yeast two hybrid. Interestingly,Nsp1 and Nup159 together with Nup82 form a nucleoporin subcomplexthat functions primarily in mRNA export (Belgareh et al., 1998).Analysis of a SAC3 deletion (SAC3 $Delta$ ) strain showed synthetic lethalinteractions with several NES-protein export mutants and a defectin NES-protein export (Jones et al., 2000). We found that thesac3 $Delta$ 139 mutant as well an independent deletion strain ( $Delta$ sac3-rg)display a strong nuclear accumulation of mRNA. Consistent withour results, overexpression of SAC3 by using a galactose-induciblepromoter causes an mRNA export defect (Corbett, personal communication).In addition, in sac3 $Delta$ 139 cells no synthetic lethality with $Delta$ yrb2is observed and only a mild NES-protein export defect is detectedusing the same reporter used in the previous study. In SAC3 $Delta$ cells,the NLS-NES-GFP reporter localizes exclusively to the nucleusin ~30% of cells grown at 25°C and ~50% of cells shifted to 37°Cfor 2 h (Corbett, personal communication). These results contrastwith the mild nuclear accumulation visible in a low percentageof sac3 $Delta$ 139 and $Delta$ sac3-rg cells (Figure 2C; our unpublished data).In our hands, the SAC3 $Delta$ strain seemed to revert to faster growingcells at a high rate, especially upon plasmid transformation (ourunpublished data). Therefore, we speculate that a second mutationmay be present in the SAC3 $Delta$ strain. Alternately, contrasting degreesof effects on NES-export in these sac3 mutants may be due to differences in strain background. SAC3as well as a number of other genes involved in mRNA export arenot essential for viability. Deletion of any of several genessuch as NUP116, GLE2, and NUP133 causes profound defects in mRNAexport but allows growth, although at significantly reduced rates(Wente and Blobel, 1993; Li et al., 1995; Murphy et al., 1996).Apparently, cells are able to compensate for lack of these genesbecause of the functional redundancy of various exportfactors.

Several findings support the notion that Sac3 functions at the translocation step of mRNA export. First, the sac3 $Delta$ 139 mutationresults in synthetic lethality when combined with mex67-5 andmtr2-142, both of which cause Mex67 to mislocalize to the cytoplasmupon a shift to nonpermissive temperature (Figure 1C; Segref etal., 1997). The sac3 $Delta$ 139 mutant also mislocalizes Mex67; therefore,these combined mutations could further disrupt Mex67 localizationand function and cause lethality. Additionally, Sac3 can be coimmunoprecipitatedwith Mex67, Mtr2, and Nup116 suggestive of interactions that maybe required for RNP translocation through the NPC. To addresswhether SAC3 may affect the interaction of Mex67 with FG-repeat-containingnucleoporins, we performed coimmunoprecipitations of Mex67 andNup116 as described previously (Strawn et al., 2001) in wild-typecompared with sac3 $Delta$ 139 cells but found the interaction to be unaffected(our unpublished data). Nevertheless, Mex67 interacts with multipleFG-repeat containing nucleoporins (Strä $beta$ er et al., 2000; Strawnet al., 2001), and Sac3 could affect any number of these or otherinteractions.

More specifically, Sac3 may be involved in the terminal step of export. As determined by immunoelectron microscopy, Sac3 localizesexclusively to the cytoplasmic fibrils of the NPC, suggestingthat it acts at a late stage of mRNA export. Sac3 may be a staticNPC-associated protein because Sac3 localizes exclusively to thenuclear rim and remains properly localized in the xpo1-1 mutant(Jones et al., 2000; our unpublished data). However, we also foundthat Sac3 coimmunoprecipitates with Mlp1, which localizes to thenuclear basket by immunoelectron microscopy (Strambio-de-Castilliaet al., 1999; Kosova et al., 2000). It is possible that eitherMlp1 or Sac3 or both proteins are mobile factors despite beingpreferentially localized to opposite sides of the pore at steadystate. Interestingly, Sac3 was not identified in a large-scaleanalysis of NPC proteins despite that it meets the criteria definedin this study (Rout et al., 2000). The absence of Sac3 in thisNPC purification may be a result of its sensitivity to proteolysisduring the preparation or its transient interaction with the NPC.Our genetic analysis revealed specificity of interactions betweensac3 $Delta$ 139 and mutations in genes encoding transport factors, perhapsproviding a better indication of Sac3 function than our coimmunoprecipitationexperiments. All of the synthetic lethal interactors identifiedin our analysis correspond to mRNA export factors that localizeat least partially to the cytoplasmic fibrils of theNPC.

Understanding of the release of proteins from the mRNA remains elusive. A candidate for the mediator of this process is theRNA helicase Dbp5, which localizes to the cytoplasmic fibrilsand the cytoplasm (Snay-Hodge et al., 1998; Tseng et al., 1998;Strahm et al., 1999). Dbp5 can be coimmunoprecipitated with Sac3from cell lysates. Furthermore, sac3 $Delta$ 139 is synthetically lethalwith a mutant of DBP5, rat8-2, and with a mutant allele of NUP159,which is required for Dbp5 localization to the nuclear rim (Hodgeet al., 1999; Schmitt et al., 1999). In addition, sac3 $Delta$ 139 combinedwith a mutant allele of NUP82 results in synthetic sickness. Aphenotype of nup82- $Delta$ 108 cells is that Nup159 localization to thenuclear pore is disrupted (Hurwitz et al., 1998). Each of theseproteins seems to be important for proper localization of othercytoplasmic fibril-associated proteins involved in mRNA exportand may function as terminal docking sites for RNPs during NPCtranslocation. Further studies should elucidate the mechanismof this complexprocess.

	ACKNOWLEDGMENTS

We thank G. Blobel, D. Botstein, C. Cole, A. Corbett, E. Hurt, M. Rout, and S. Wente for sharing strains and plasmids. Weare grateful to M. Stewart for $alpha$ -Nsp1 antibodies. We thank A.Corbett for communicating unpublished data, M. Damelin for criticalcomments on the manuscript, and members of the Silver laboratoryfor thoughtful discussions. E.P.L. and T.M. were supported bygrants from the Ryan Foundation and the National Cancer Institute.C.S. was supported by grants from the National Institutes of Healthand American Cancer Society. B.F. was supported by a grant fromthe M.E. Müller Foundation. H.K. was supported by a grant fromthe Deutsche Forschungsgemeinshaft. This work was supported bygrants from the National Institutes of Health and Human FrontiersScience Project (to P.A.S. and U.A.).

	FOOTNOTES

Present addresses: Philipps-University Marburg, Institute for Molecular Biology and Tumor Research, Emil-Mannkopff-Stra $beta$ e 2, 35033 Marburg, Germany; ^§Department of Genetics, Harvard Medical School and Massachusetts General Hospital, Boston, MA02114.

Corresponding author. E-mail address: pamela_silver{at}dfci.harvard.edu.

Article published online ahead of print. Mol. Biol. Cell 10.1091/mbc.E02-08-0520. Article and publication date are at www.molbiolcell.org/cgi/doi/10.1091/mbc.E02-08-0520.

REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Bachi, A., et al. (2000). The C-terminal domain of TAP interacts with the nuclear pore complex and promotes export of specific CTE-bearing RNA substrates. RNA 6, 136-158[Abstract].
Bailer, S.M., Siniossoglou, S., Podtelejnikov, A., Hellwig, A., Mann, M., and Hurt, E. (1998). Nup116p and nup100p are interchangeable through a conserved motif which constitutes a docking site for the mRNA transport factor gle2p. EMBO J. 17, 1107-1119[CrossRef][Medline].
Ba $beta$ ler, J., Grandi, P., Gadal, O., Lessmann, T., Petfalski, E., Tollervey, D., Lechner, J., and Hurt, E. (2001). Identification of a 60S preribosomal particle that is closely linked to nuclear export. Mol. Cell 8, 517-529[CrossRef][Medline].
Bauer, A., and Kölling, R. (1996a). Characterization of the SAC3 gene of Saccharomyces cerevisiae. Yeast 12, 965-975[CrossRef][Medline].
Bauer, A., and Kölling, R. (1996b). The SAC3 gene encodes a nuclear protein required for normal progression of mitosis. J. Cell Sci. 109, 1575-1583[Abstract].
Belgareh, N., Snay-Hodge, C., Pasteau, F., Dagher, S., Cole, C.N., and Doye, V. (1998). Functional characterization of a Nup159p-containing nuclear pore subcomplex. Mol. Biol. Cell 9, 3475-3492[Abstract/Free Full Text].
Cordes, V.C., Reidenbach, S., Rackwitz, H.R., and Franke, W.W. (1997). Identification of protein p270/Tpr as a constitutive component of the nuclear pore complex-attached intranuclear filaments. J. Cell Biol. 136, 515-529[Abstract/Free Full Text].
Damelin, M., and Silver, P.A. (2000). Mapping interactions between nuclear transport factors in living cells reveals pathways through the nuclear pore complex. Mol. Cell 5, 133-140[CrossRef][Medline].
Damelin, M., and Silver, P.A. (2002). In situ analysis of spatial relationships between proteins of the nuclear pore complex. Biophys. J. 83, 3626-3636[Abstract/Free Full Text].
Elledge, S.J., and Davis, R.W. (1988). A family of versatile centromeric vectors designed for use in the sectoring-shuffle mutagenesis assay in Saccharomyces cerevisiae. Gene 70, 303-312[CrossRef][Medline].
Fahrenkrog, B., Hurt, E.C., Aebi, U., and Pante, N. (1998). Molecular architecture of the yeast nuclear pore complex: localization of Nsp1p subcomplexes. J. Cell Biol. 143, 577-588[Abstract/Free Full Text].
Flach, J., Bossie, M., Vogel, J., Corbett, A., Jinks, T., Willins, D.A., and Silver, P.A. (1994). A yeast RNA-binding protein shuttles between the nucleus and the cytoplasm. Mol. Cell. Biol. 14, 8399-8407[Abstract/Free Full Text].
Fribourg, S., Braun, I.C., Izaurralde, E., and Conti, E. (2001). Structural basis for the recognition of a nucleoporin FG repeat by the NTF2-like domain of the TAP/p15 mRNA nuclear export factor. Mol. Cell 8, 645-656[CrossRef][Medline].
Gorsch, L.C., Dockendorff, T.C., and Cole, C.N. (1995). A conditional allele of the novel repeat-containing yeast nucleoporin RAT7/NUP159 causes both rapid cessation of mRNA export and reversible clustering of nuclear pore complexes. J. Cell Biol. 129, 939-955[Abstract/Free Full Text].
Heath, C.V., Copeland, C.S., Amberg, D.C., Del Priore, V., Snyder, M., and Cole, C.N. (1995). Nuclear pore complex clustering and nuclear accumulation of poly(A)+ RNA associated with mutation of the Saccharomyces cerevisiae RAT2/NUP120 gene. J. Cell Biol. 131, 1677-1697[Abstract/Free Full Text].
Henry, M.F., and Silver, P.A. (1996). A novel methyltransferase (Hmt1p) modifies poly(A)+-RNA-binding proteins. Mol. Cell. Biol. 16, 3668-3678[Abstract].
Herold, A., Klymenko, T., and Izaurralde, E. (2001). NXF1/p15 heterodimers are essential for mRNA nuclear export in Drosophila. RNA 7, 1768-1780[Abstract].
Ho, J.H., Kallstrom, G., and Johnson, A.W. (2000). Nmd3p is a Crm1p-dependent adapter protein for nuclear export of the large ribosomal subunit. J. Cell Biol. 151, 1057-1066[Abstract/Free Full Text].
Hodge, C.A., Colot, H.V., Stafford, P., and Cole, C.N. (1999). Rat8p/Dbp5p is a shuttling transport factor that interacts with Rat7p/Nup159p and Gle1p and suppresses the mRNA export defect of xpo1-1 cells. EMBO J. 18, 5778-5788[CrossRef][Medline].
Hurt, E., Hannus, S., Schmelzl, B., Lau, D., Tollervey, D., and Simos, G. (1999). A novel in vivo assay reveals inhibition of ribosomal nuclear export in ran-cycle and nucleoporin mutants. J. Cell Biol. 144, 389-401[Abstract/Free Full Text].
Hurt, E., Strä $beta$ er, K., Segref, A., Bailer, S., Schlaich, N., Presutti, C., Tollervey, D., and Jansen, R. (2000). Mex67p mediates nuclear export of a variety of RNA polymerase II transcripts. J. Biol. Chem. 275, 8361-8368[Abstract/Free Full Text].
Hurwitz, M.E., and Blobel, G. (1995). NUP82 is an essential yeast nucleoporin required for poly(A)+ RNA export. J. Cell Biol. 130, 1275-1281[Abstract/Free Full Text].
Hurwitz, M.E., Strambio-de-Castillia, C., and Blobel, G. (1998). Two yeast nuclear pore complex proteins involved in mRNA export form a cytoplasmically oriented subcomplex. Proc. Natl. Acad. Sci. USA 95, 11241-11245[Abstract/Free Full Text].
Iovine, M.K., Watkins, J.L., and Wente, S.R. (1995). The GLFG repetitive region of the nucleoporin Nup116p interacts with Kap95p, an essential yeast nuclear import factor. J. Cell Biol. 131, 1699-1713[Abstract/Free Full Text].
Jones, A.L., Quimby, B.B., Hood, J.K., Ferrigno, P., Keshava, P.H., Silver, P.A., and Corbett, A.H. (2000). SAC3 may link nuclear protein export to cell cycle progression. Proc. Natl. Acad. Sci. USA 97, 3224-3229[Abstract/Free Full Text].
Katahira, J., Strä $beta$ er, K., Podtelejnikov, A., Mann, M., Jung, J.U., and Hurt, E. (1999). The Mex67p-mediated nuclear mRNA export pathway is conserved from yeast to human. EMBO J. 18, 2593-2609[CrossRef][Medline].
Kölling, R., Nguyen, T., Chen, E.Y., and Botstein, D. (1993). A new yeast gene with a myosin-like heptad repeat structure. Mol. Gen. Genet. 237, 359-369[Medline].
Kosova, B., Panté, N., Rollenhagen, C., Podtelejnikov, A., Mann, M., Aebi, U., and Hurt, E. (2000). Mlp2p, a component of nuclear pore attached intranuclear filaments, associates with Nic96p. J. Biol. Chem. 275, 343-350[Abstract/Free Full Text].
Kraemer, D.M., Strambio-de-Castillia, C., Blobel, G., and Rout, M.P. (1995). The essential yeast nucleoporin NUP159 is located on the cytoplasmic side of the nuclear pore complex and serves in karyopherin-mediated binding of transport substrate. J. Biol. Chem. 270, 19017-19021[Abstract/Free Full Text].
Krebber, H., Taura, T., Lee, M.S., and Silver, P.A. (1999). Uncoupling of the hnRNP Npl3p from mRNAs during the stress-induced block in mRNA export. Genes Dev. 13, 1994-2004[Abstract/Free Full Text].
Lee, M.S., Henry, M., and Silver, P.A. (1996). A protein that shuttles between the nucleus and the cytoplasm is an important mediator of RNA export. Genes Dev. 10, 1233-1246[Abstract/Free Full Text].
Lei, E.P., Krebber, H., and Silver, P.A. (2001). Messenger RNAs are recruited for nuclear export during transcription. Genes Dev. 15, 1771-1782[Abstract/Free Full Text].
Lei, E.P., and Silver, P.A. (2002). Protein, and RNA export from the nucleus. Dev. Cell. 2, 261-272[CrossRef][Medline].
Levesque, L., Guzik, B., Guan, T., Coyle, J., Black, B.E., Rekosh, D., Hammarskjold, M.L., and Paschal, B.M. (2001). RNA export mediated by tap Involves NXT1-dependent interactions with the nuclear pore complex. J. Biol. Chem. 28, 28.
Li, O., Heath, C.V., Amberg, D.C., Dockendorff, T.C., Copeland, C.S., Snyder, M., and Cole, C.N. (1995). Mutation or deletion of the Saccharomyces cerevisiae RAT3/NUP133 gene causes temperature-dependent nuclear accumulation of poly(A)+ RNA and constitutive clustering of nuclear pore complexes. Mol. Biol. Cell 6, 401-417[Abstract].
Longtine, M.S., McKenzie, A., 3rd, Demarini, D.J., Shah, N.G., Wach, A., Brachat, A., Philippsen, P., and Pringle, J.R. (1998). Additional modules for versatile and economical PCR-based gene deletion and modification in Saccharomyces cerevisiae. Yeast 14, 953-961[CrossRef][Medline].
Moy, T.I., and Silver, P.A. (1999). Nuclear export of the small ribosomal subunit requires the ran-GTPase cycle and certain nucleoporins. Genes Dev. 13, 2118-2133[Abstract/Free Full Text].
Murphy, R., Watkins, J.L., and Wente, S.R. (1996). GLE2, a Saccharomyces cerevisiae homologue of the Schizosaccharomyces pombe export factor RAE1, is required for nuclear pore complex structure and function. Mol. Biol. Cell 7, 1921-1937[Abstract].
Murphy, R., and Wente, S.R. (1996). An RNA-export mediator with an essential nuclear export signal. Nature 383, 357-360[CrossRef][Medline].
Novick, P., Osmond, B.C., and Botstein, D. (1989). Suppressors of yeast actin mutations. Genetics 121, 659-674[Abstract/Free Full Text].
Radu, A., Moore, M.S., and Blobel, G. (1995). The peptide repeat domain of nucleoporin Nup98 functions as a docking site in transport across the nuclear pore complex. Cell 81, 215-222[CrossRef][Medline].
Rout, M.P., Aitchison, J.D., Suprapto, A., Hjertaas, K., Zhao, Y., and Chait, B.T. (2000). The yeast nuclear pore complex: composition, architecture, and transport mechanism. J. Cell Biol. 148, 635-651[Abstract/Free Full Text].
Santos-Rosa, H., Moreno, H., Simos, G., Segref, A., Fahrenkrog, B., Panté, N., and Hurt, E. (1998). Nuclear mRNA export requires complex formation between Mex67p and Mtr2p at the nuclear pores. Mol. Cell. Biol. 18, 6826-6838[Abstract/Free Full Text].
Schmitt, C., et al. (1999). Dbp5, a DEAD-box protein required for mRNA export, is recruited to the cytoplasmic fibrils of nuclear pore complex via a conserved interaction with CAN/Nup159p. EMBO J. 18, 4332-4347[CrossRef][Medline].
Segref, A., Sharma, K., Doye, V., Hellwig, A., Huber, J., Luhrmann, R., and Hurt, E. (1997). Mex67p, a novel factor for nuclear mRNA export, binds to both poly(A)+ RNA and nuclear pores. EMBO J. 16, 3256-3271[CrossRef][Medline].
Singleton, D.R., Chen, S., Hitomi, M., Kumagai, C., and Tartakoff, A.M. (1995). A yeast protein that bidirectionally affects nucleocytoplasmic transport. J. Cell Sci. 108, 265-272[Abstract].
Siniossoglou, S., Wimmer, C., Rieger, M., Doye, V., Tekotte, H., Weise, C., Emig, S., Segref, A., and Hurt, E.C. (1996). A novel complex of nucleoporins, which includes Sec13p and a Sec13p homolog, is essential for normal nuclear pores. Cell 84, 265-275[CrossRef][Medline].
Snay-Hodge, C.A., Colot, H.V., Goldstein, A.L., and Cole, C.N. (1998). Dbp5p/Rat8p is a yeast nuclear pore-associated DEAD-box protein essential for RNA export. EMBO J. 17, 2663-2676[CrossRef][Medline].
Stade, K., Ford, C.S., Guthrie, C., and Weis, K. (1997). Exportin 1 (Crm1p) is an essential nuclear export factor. Cell 90, 1041-1050[CrossRef][Medline].
Stage-Zimmermann, T., Schmidt, U., and Silver, P.A. (2000). Factors affecting nuclear export of the 60S ribosomal subunit in vivo. Mol. Biol. Cell 11, 3777-3789[Abstract/Free Full Text].
Stoffler, D., Fahrenkrog, B., and Aebi, U. (1999). The nuclear pore complex: from molecular architecture to functional dynamics. Curr. Opin. Cell Biol. 11, 391-401[CrossRef][Medline].
Strä $beta$ er, K., Ba $beta$ ler, J., and Hurt, E. (2000). Binding of the Mex67p/Mtr2p heterodimer to FXFG, GLFG, and FG repeat nucleoporin