Requirements of Fission Yeast Septins for Complex Formation, Localization, and Function

Hanbing An^*, Jennifer L. Morrell, Jennifer L. Jennings, Andrew J. Link, and Kathleen L. Gould^*

^* Howard Hughes Medical Institute, Nashville, TN 37232; Department of Cell and Developmental Biology, Vanderbilt University School of Medicine, Nashville, TN 37232; and Department of Microbiology and Immunology, Vanderbilt University School of Medicine, Nashville, TN 37232

Submitted July 28, 2004; Accepted September 9, 2004
Monitoring Editor: Trisha Davis

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

Septins are GTP binding proteins important for cytokinesis inmany eukaryotes. The Schizosaccaromyces pombe genome sequencepredicts orthologues of four of five Saccharomyces cerevisiaeseptins involved in cytokinesis and these are named Spns1-4p.That spns1-4 are not essential genes permitted the applicationof a combined genetic and proteomics approach to determine theirfunctional relationships. Our findings indicate that Spns1-4pare present throughout interphase as a diffusely localized $~$ 8.5Scomplex containing two copies of each septin linked togetheras a chain in the order Spn3p-Spn4p-Spn1p-Spn2p. Septin recruitmentto the medial region of the cell is genetically separable fromring formation, and whereas it is normally restricted to mitosis,it can be promoted without activation of the mitotic cell cyclemachinery. Coalescence into ring structures requires Spn1p andSpn4p associate with at least one other septin subunit and theexpression of Mid2p that is normally restricted to mitosis.This study establishes the functional requirements for septincomplex organization in vivo.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

Septins are a family of guanine nucleotide binding proteins.They were first identified in Saccharomyces cerevisiae for theirrole in cytokinesis (Hartwell, 1971). In the past 10 years,it has become evident that septins are highly conserved cytoskeletalelements found in most eukaryotes (Faty et al., 2002; Macaraet al., 2002). Although many septins have been implicated inthe process of cell division because of their localization tothe cell division site and/or because the disruption of theirfunction leads to cytokinesis defects, septins are likely involvedin additional biological processes because they are presentin nondividing cells such as neurons and in complexes with componentsof the secretory apparatus (reviewed in Field and Kellogg, 1999;Kartmann and Roth, 2001; Faty et al., 2002).

Septins typically exist in heterooligomeric complexes (Fieldet al., 1996; Frazier et al., 1998; Hsu et al., 1998; Sheffieldet al., 2003). In Drosophila, three septins form a stable complexthat likely consists of a linear array of each septin homodimer(Field et al., 1996). When expressed in Escherichia coli, threemammalian septins can form a complex of a size consistent witha hexamer, i.e., two of each subunit (Sheffield et al., 2003).In S. cerevisiae, four septins form a stable complex that hasbeen predicted to consist of two molecules each of Cdc3p, Cdc10p,and Cdc12p and 1 molecule of Cdc11p (Frazier et al., 1998).Although clearly existing in complexes, the organization ofseptins within these complexes has not been investigated previously.

In S. cerevisiae, Cdc3p, Cdc10p, Cdc11p, and Cdc12p togetherwith another septin, Shs1/Sep7, (Mino et al., 1998) assembleinto a patch at the incipient bud site during G1. As the cellcycle progresses, septins reorganize at the mother-bud neckinto an hourglass-shaped collar of cortical filaments (Frazieret al., 1998). Recombinant septins have the capacity to formfilaments in vitro in a GTP-dependent manner (Mendoza et al.,2002; Versele and Thorner, 2004). However, although GTP-bindingis important for in vitro filament assembly and ring formationin vivo (Versele and Thorner, 2004), nucleotide turnover onseptins in vivo is so slow that GTP hydrolysis is unlikely toplay a role in septin dynamics during the cell cycle (Vrabioiuet al., 2004). Rather, other events regulated by the GIN4 familyof kinases (Longtine et al., 1998; Mortensen et al., 2002; Dobbelaereet al., 2003) and/or Cla4p (Dobbelaere et al., 2003; Schmidtet al., 2003; Versele and Thorner, 2004) in S. cerevisiae havebeen shown to be important for assembly of functional septinrings in vivo. However, exactly how septin complexes are assembledinto higher order structures such as rings remains unknown.

Once organized into a ring structure in S. cerevisiae, septinsare thought to perform multiple functions at the mother-daughterbud neck. These include providing a boundary that restrictscertain determinants to particular cortical domains (reviewedby Faty et al., 2002) and acting as a bud neck scaffold necessaryfor the localization of many factors involved in polarity andcell division (reviewed by Gladfelter et al., 2001). Whetherseptins perform all of these roles in other organisms is yetto be established.

Septins have a conserved structure. They contain a central GTP-bindingdomain flanked by a basic region at the amino terminus, andmost septins contain a coiled-coil domain at the carboxy terminus.With the completion of the Schizosaccharomyces pombe genomesequence (Wood et al., 2002), homologues of the S. cerevisiaeseptins Cdc3p, Cdc10p, Cdc11p, and Cdc12p were identified andnamed Spn1p, Spn2p, Spn3p, and Spn4p, respectively. spn1-4 arenot essential, but the absence of any or all of them (Berlinet al., 2003; Tasto et al., 2003; our unpublished data) causesa delay in the completion of cell division, resulting in a chainedcell phenotype. Spn1p and Spn3p are known to organize at thesite of cell division late in mitosis where they form a ringthat splits as the septum forms, but this ring does not constrictwith actomyosin ring invagination; rather, the ring dissipatesafter cell cleavage (Berlin et al., 2003; Tasto et al., 2003).

Mid2p is a S. pombe protein related at its C-terminus to S.cerevisiae Bud4p, Candida albicans Int1p, and anillins presentin multicellular eukaryotes (Field and Alberts, 1995; Sandersand Herskowitz, 1996; Oegema et al., 2000; Gale et al., 2001).Anillin is able to direct septin filament assembly along actinbundles in an in vitro assay containing only purified components(Kinoshita et al., 2002). Mid2p lacks an obvious F-actin bindingdomain as is present in anillin, but Mid2p is similarly requiredfor the proper organization of septin rings at the site of celldivision (Berlin et al., 2003; Tasto et al., 2003). Like septins,mid2⁺ is not an essential gene, but its loss causes a chainedcell phenotype (Berlin et al., 2003; Tasto et al., 2003). Fluorescencerecovery after photobleaching (FRAP) analysis of Spn1p-GFP hasshown that septin rings are quite dynamic in mid2 ${Delta}$ cells, whereasin wild-type cells they are very stable (Berlin et al., 2003).Mid2p production is normally restricted to anaphase and overproductionof a stabilized truncation mutant of Mid2p leads to persistenceof septin rings through multiple cell divisions (Tasto et al.,2003). These observations suggest that Mid2p interacts eitherdirectly or indirectly with septins to promote their organizationinto stable ring structures in late mitosis.

To begin to address how Mid2p and its relatives affect septinring organization, we have investigated how Spns 1-4p are organizedin S. pombe cells using a combination of proteomic and geneticapproaches. Our data suggest that the building blocks of septinrings are $~$ 8.5S complexes containing two of each septin subunitlinked together in an almost linear array of specific order.These units are assembled into a functional ring structure inat least two steps. Recruitment to the medial region can occurif septation is forced during interphase but coalescence intoa ring structure requires Mid2p that is normally produced onlyin mitosis. Our data also indicate that each septin subunitcontributes uniquely to the formation of septin structures.

MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

Yeast Strains, Media, and Genetic Methods
S. pombe strains used in this study are listed in SupplementaryTable 1 and were grown in YE or minimal medium with the appropriatesupplements as described (Moreno et al., 1991). DNA transformationswere done by electroporation (Prentice, 1992) or lithium acetatetransformation (Keeney and Boeke, 1994). To arrest cells inS phase, cultures were grown in 12 mM hydroxyurea at 25°Cfor 4 h.

The spn1, spn2, spn3, and spn4 open reading frames (ORFs) wereeach tagged at their 3' ends with the HA3-Kan^R, myc13-Kan^R,2X CTAP-Kan^R, CFP-Kan^R, YFP-Kan^R, and EGFP-Kan^R cassette aspreviously described (Bahler et al., 1998). Kan^R transformantswere screened by whole cell PCR and then by immunoblotting toconfirm the accurate integration and expression of the fusionprotein.

The spn1 ORF was replaced with ura4⁺ by homologous recombinationin a diploid strain (Bahler et al., 1998). Ura⁺ transformantswere screened for the proper gene disruptant by whole-cell PCR.A heterozygous diploid strain was then sporulated at 25°Cfollowed by tetrad dissection to isolate the haploid spn1::ura4 strain.

Molecular Biology Techniques
PCR amplifications were carried out with TaqPlus Precision polymerase(Stratagene, La Jolla, CA) according to manufacturer's instructions.Oligonucleotides were synthesized by Integrated DNA Technologies,Inc. (Coralville, IA).

Purification and Analyses of Septin TAP Complexes
Eight-liter cultures of strains producing TAP-tagged proteinswere grown to log phase and the tagged proteins were isolatedas described (Tasto et al., 2001). For silver staining, onequarter of the eluate from the purification was precipitatedwith TCA, resuspended in LDS-PAGE buffer and resolved on a 4–12%NuPAGE using MOPS buffer (Novex, Encinitas, CA). Silver stainingwas carried out using the Plus One kit as recommended by themanufacturer (Amersham Pharmacia Biotech, Piscataway, NJ). TheTAP complexes were analyzed by DALPC-tandem mass spectrometryas described previously (Ohi et al., 2002; Sanders et al., 2002).

Immunoprecipitations, Sucrose Gradients, and Immunoblots
Whole cell lysates were prepared in NP-40 buffer followed byanti-HA or anti-Myc immunoprecipitations as previously described(McDonald et al., 1999). Denatured lysates were prepared asdescribed (Burns et al., 2002). For sucrose gradient analysis,a 200-µl volume of protein lysate was layered onto a 5-ml10–30% sucrose gradient prepared in NP-40 buffer. Gradientswere ultracentrifuged at 38,000 rpm for 18 h in a Beckman SW50.1rotor (Berkeley, CA). Sedimentation markers were fractionatedon gradients prepared and spun in parallel. Fractions were collectedfrom the bottom of the gradient and resolved on 4–12%NuPAGE gels in MOPS buffer and subsequently transferred by electroblottingto PVDF membrane (Immobilon P; Millipore, Bedford, MA). Immunoblottingwas done with anti-HA (12CA5; 2 µg/ml), anti-Myc (9E10;2 µg/ml), or anti-GFP (1:1000 dilution of serum) antibodies.Primary antibodies were detected with horseradish peroxidase–conjugatedgoat anti-mouse or goat anti-rabbit secondary antibodies (0.4mg/ml; Jackson ImmunoResearch Laboratories, West Grove, PA)at a dilution of 1:50,000 followed by ECL visualization usingSuperSignal (Pierce, Rockford, IL).

Yeast Two-hybrid Assays
The yeast two-hybrid system used in this study was describedpreviously (James et al., 1996). spn3 and spn1 cDNAs were clonedinto the bait plasmid pGBT9 (Clontech, Palo Alto, CA), spn1⁺,spn2⁺, spn3⁺, and spn4⁺ cDNAs were cloned into the prey plasmidpGAD424 (Clontech) and sequenced to ensure the absence of PCR-inducedmutations and that the correct reading frame had been retained.

To test for protein interactions, both bait and prey plasmidswere contransformed into S. cerevisiae strain PJ69-4A. ${beta}$ -galactosidasereporter enzyme activity in the two-hybrid strains was measuredusing the Galacto-StarTM chemiluminescent reporter assay systemaccording to the manufacturer's instructions (Tropix, Bedford,MA) with the exception that cells were lysed by glass bead disruption.Each sample was measured in triplicate. Reporter assays wererecorded either on the BMG luminometer (Bartlett-Williams Scientific,Chapel Hill, NC) or the Mediator Phl luminometer (Aureon Biosystems,Vienna, Austria).

Microscopy
Strains producing GFP-, YFP-, or CFP-tagged proteins were grownin YE medium and visualized in live cells or in cells fixedwith ethanol. Microscopy was performed at room temperature usinga spinning disk confocal microscope (Ultraview LCI; PerkinElmer,Norwalk, CT) and Ultraview LCI software (v5.2; PerkinElmer)for image acquisition. Images were processed using Velocitysoftware (v1.4.2; Improvision, Lexington, MA). Z-series opticalsections were taken at 0.5-µm spacing for 3D reconstructions.

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

The Four S. pombe Septins Form a Linear Complex
To define the building blocks of S. pombe septin rings, we analyzedhow S. pombe Spn1p, Spn2p, Spn3p, and Spn4p interacted. Forthese experiments, spn1-4 were tagged at their endogenous lociwith sequences encoding a variety of epitopes (TAP, HA, myc,GFP, CFP, and/or YFP) to create C-terminal–tagged variantsunder control of their own promoters. Unless otherwise noted,only strains that exhibited wild-type phenotypes were used forthese studies. spn1-4 were also deleted from the genome eitheralone or in combination. Although none of these S. pombe proteinsis essential, the absence of any or all of them causes a delayin the completion of cell division resulting in a chained cellphenotype, although the severity of this defect varies (Berlinet al., 2003; Tasto et al., 2003; see below and our unpublishedobservations).

First, we examined the composition of Spn3p-TAP, Spn4p-TAP,and Spn2p-TAP complexes purified from asynchronous populationsof cells. The spn1-TAP strain was not used because it displayeda loss of function phenotype (unpublished data). Spns 1-4p weredetected by silver staining and mass spectrometry in all threepurifications (Figure 1, A–C and Table 1). No additionalproteins were identified by mass spectrometry as specific componentsof these septin complexes. All other identified proteins weredetected in mock TAP eluates from strains lacking TAP-taggedproteins and/or from unrelated TAP complexes (unpublished data).

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Figure 1. Composition of S. pombe septin complexes. (A–H) Silver-stained gels of a portion of Spn-TAP complexes from the indicated strains. Spn proteins are indicated with arrows. Note that the calmodulin-binding portion of the TAP tag remains after the purification and changes the mass of the proteins. Other bands are nonspecific contaminants. (I) Protein lysates prepared in denaturing conditions from the indicated strains were resolved by SDS-PAGE and blotted with anti-GFP serum. (J) anti-myc (top panel) and anti-HA (bottom panel) immunoprecipitates from the indicated strains were blotted with anti-myc antibodies.

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Table 1. TAP/DALPC results

Next, the composition of septin TAP complexes purified fromstrains lacking one of the septin proteins was determined bysilver staining and mass spectrometry. In Spn3-TAP complexespurified from spn2 ${Delta}$ cells, Spn3p, Spn4p, and Spn1p were identified(Figure 1D and Table 1). In Spn3-TAP complexes purified fromspn1 ${Delta}$ cells, only Spn3p and Spn4p were present (Figure 1E andTable 1). Although Spn2p did not copurify with Spn3p from spn1 ${Delta}$ cells, Spn2p-GFP was readily detected in an spn1 ${Delta}$ strain suggestingthat it is not degraded in the absence of Spn1p (Figure 1I).Spn3p-TAP did not copurify with any other septin from an spn4 ${Delta}$ strain (Figure 1F and Table 1). These data suggested that septinsinteracted in a linear order of Spn3p-Spn4p-Spn1p-Spn2p (seeFigure 2A). To confirm this, we examined the composition ofthe Spn4p-TAP complexes from spn3 ${Delta}$ cells and Spn2p-TAP complexesfrom spn4 ${Delta}$ cells. As predicted, Spn4p, Spn1p, and Spn2p weredetected in Spn4p-TAP complexes from spn3 ${Delta}$ cells (Figure 1G andTable 1) and in the Spn2p-TAP complex isolated from spn4 ${Delta}$ cells,Spn1p and Spn2p but not Spn3p were detected (Figure 1H and Table 1).Spn3p was present, however, in cells lacking Spn4p, so degradationdid not explain the lack its association with other septins(Figure 1I). Finally, we examined whether Spn4p and Spn1p remainedassociated in the absence of both Spn2p and Spn3p. Consistentwith the proposed Spn3p-Spn4p-Spn1p-Spn2p arrangement, Spn1p-mycand Spn4p-HA coimmunoprecipitated from lysates prepared froma spn2 ${Delta}$ spn3 ${Delta}$ strain (Figure 1J). Based on the lower recoveryof coimmunoprecipitated proteins, this Spn1p-Spn4p complex appearsto be less stable than in the presence of Spn2p or Spn3p. Consistentwith the coimmunoprecipitation results, Spn4p-TAP complexespurified from spn2 ${Delta}$ spn3 ${Delta}$ cells contained Spn1p as determined bymass spectrometry as well as significantly more heat shock proteinsthan the TAP complexes described above (unpublished data). Weinterpret this as an indicator of complex instability and/oraggregation.

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Figure 2. Protein-protein interactions mapped between septin complex components. (A and H) Models of S. pombe septin interactions. (B) The PJ69-4A strain was transformed with pGBT9 or pGBT9spn3, and pGAD424 or pGAD424 carrying spn1, spn2, or spn4, which are shown schematically. (C) ${beta}$ -galactosidase activity (represented in relative light units) of the stains described in B. (D) The PJ69-4A stain was transformed with pGBT9 or pGBT9spn1 and pGAD424 or pGAD424 carrying spn2, spn3, or spn4, which are shown schematically. (E) ${beta}$ -galactosidase activity (represented in relative light units) of the stains described in D. (F) The PJ69-4A stain was transformed with pGBT9 or pGBT9spn2 and pGAD424 or pGAD424 carrying spn4, which are shown schematically. (G) ${beta}$ -galactosidase activity (represented in relative light units) of the stains described in D. Asterisk indicates positive interactions.

To examine the ability of septins to interact with each otherin a different manner, directed two-hybrid analysis was performed.As would be predicted by a linear model of interaction derivedfrom the TAP experiments (Figure 2A), Spn3p interacted robustlywith Spn4p, but not with Spn1p or Spn2p (Figure 2, B and C).Also, Spn1p interacted with both Spn2p and Spn4p, but not Spn3p(Figure 2, D and E). We next addressed the final possibilityof whether Spn2p could interact with Spn4p. Inconsistent withthe linear model of assembly derived from the TAP experiments(Figure 2A), significant interaction was observed between Spn2pand Spn4p (Figure 2, F and G). Although we considered the possibilitythat this interaction might be bridged by a S. cerevisiae septin,this seems unlikely because we did not detect any other bridginginteractions in our analysis (for example, spn2 with spn3, orspn3 with spn1). Therefore, we conclude that most likely 1)Spn2p can interact directly with Spn4p and 2) Spn1p is requiredto stabilize this association during a biochemical purificationof the complex. Thus, our model was refined by these experimentsto encompass the likelihood of a Spn2p-Spn4p interaction stabilizedby Spn2p-Spn1p and Spn4p-Spn1p associations (Figure 2H).

S. pombe Septin Complexes Contain at Least Two Copies of Each Subunit
We next asked whether each septin protein existed primarilyin a complex with other septins by sucrose gradient analysis.Each myc- or HA-epitope–tagged septin present in lysatesfrom asynchronously growing cells migrated with a single peakof 8.5S (Figure 3A), indicating that the majority of each septinexists primarily as a component of a larger septin complex.Because septin rings would be expected to sediment much fasterthan 8.5S, we reasoned that the 8.5S complex corresponds tothe septin ring organizational unit present throughout the remainderof the cell cycle and does not correspond to higher order ringstructures that must disassemble under our lysis conditions.Indeed, Spn4p-myc was found primarily in the 8.5S fraction inhydroxyurea-treated cells (Figure 3A) that are arrested in S-phase(unpublished data). We have so far been unable to purify a largercomplex containing septins (unpublished data). We also confirmedthat the 8.5S complex is what is purified by tandem affinitypurification because Spn1p-myc purified by tandem affinity purificationfrom a spn1-myc spn3-TAP strain cosedimented with unpurifiedSpn1p-myc from a protein lysate (Figure 3B).

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Figure 3. Characterization of S. pombe septin complexes. (A) Lysates prepared in NP-40 buffer from each myc-epitope– or HA-epitope–tagged septin protein from asynchronously growing cells or a hydroxyurea (HU)-arrested culture were resolved on sucrose gradients. Fractions were collected from the bottom of the gradient (1) and immunoblotted with 9E10 or 12CA5 to detect myc or HA-tagged proteins. The peaks of thyroglobulin (20S) and aldolase (8.5S) collected from gradients prepared and run in parallel are indicated. (B) A TAP and a lysate prepared in NP-40 buffer from spn1-myc spn3-TAP cells were resolved on sucrose gradients. Fractions were collected from the bottom of the gradient and immunoblotted with 9E10 to detect Spn1p-myc. The peaks of thyroglobulin (20S) and aldolase (8.5S) collected from gradients prepared and run in parallel are indicated. (C) anti-myc (left side of panels) and anti-GFP or anti-HA (right side of panels) immunoprecipitates from the indicated strains were blotted with anti-myc (top panels) and anti-GFP or anti-HA (bottom panels) antibodies.

The sedimentation value of the S. pombe septin complex at 8.5Sis similar to that reported for a S. cerevisiae septin complex(9S), which is predicted to contain two each of three subunitsand one of a fourth (Frazier et al., 1998). To determine ifS. pombe septins are organized similarly, diploid strains containingtwo different epitope-tagged alleles of each septin were constructed.These diploid strains were phenotypically wild-type (unpublisheddata) but the two epitope tags could introduce some instabilityto the complex. In the cases of spn2-HA/spn2-myc, spn3-HA/spn3-myc,and spn4-HA/spn4-myc strains, anti-HA immunoprecipitates containedthe myc-tagged septins in addition to the HA-tagged septins(Figure 3C). Coprecipitating proteins were not observed in thesingle HA-tagged strains (Figure 3C). Conversely, anti-myc immunoprecipitatesfrom the double-tagged strains but not the single myc–taggedstrains contained HA-tagged proteins in addition to myc-taggedproteins. In lysates prepared from spn1-CFP/spn1-myc diploidcells, antibodies to GFP precipitated both Spn1p-CFP and Spn1p-mycand conversely anti-myc immunoprecipitations contained bothSpn1p-myc and Spn1p-CFP. Coimmunoprecipitation was not observedin strains producing single epitope–tagged proteins (Figure 3C).From these data, we conclude that S. pombe septin complexescontain at least two copies of each subunit. Considering thesedimentation value of 8.5S, the proteomics data, and the similaritywith the S. cerevisiae septin complex (Frazier et al., 1998),it is probable that each S. pombe septin complex contains justtwo copies of each subunit, although this remains to be provenrigorously.

S. pombe Septins Associate in a Cooperative Manner
Thus far, our data supported a model in which two copies ofSpn3p-Spn4p-Spn1p-Spn2p are arrayed in an almost linear orderin which each S. pombe septin directly contacts its identicalpartner as well as one or two nonidentical subunits (Figure 4A,left panel). To determine whether there were cooperativeinteractions between septins to facilitate homotypic interactions,we examined which septins maintained homotypic interactionsin the absence of other components. Again, diploid strains producingtwo different epitope-tagged alleles of each septin in all combinationsof deletion strains were used in immunoprecipitation experiments.

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Figure 4 S. pombe septins interact in cooperative manner. (A) Possible models of S. pombe septin complex organization. (B–E) anti-myc (left side of panels) and anti-GFP or anti-HA (right side of panels) immunoprecipitates from the indicated strains were blotted with anti-myc (top panels) and anti-GFP or anti-HA (bottom panels) antibodies.

First, the role of Spn1p, Spn3p, and Spn4p in the Spn2p-Spn2pinteraction was examined. In the absence of spn1, spn3, or spn4,anti-HA immunoprecipitates from the double-tagged strains butnot the single-tagged strains contained Spn2p-myc in additionto Spn2p-HA (Figure 4B). Conversely, anti-myc immunoprecipitatesfrom the double-tagged strains but not the single-tagged strainscontained Spn2p-HA in addition to Spn2p-myc (Figure 4B). Therefore,we conclude that the Spn2p-Spn2p interaction is independentof the other three septins.

Next, we examined the Spn1p-Spn1p interaction in the absenceof spn2, spn3, or spn4. In lysates prepared from spn1-myc spn2::ura4/spn1-CFPspn2::ura4, spn1-myc spn3::ura4/spn1-CFP spn3::ura4, or spn1-mycspn4::ura4/spn1-CFP spn4::ura4 diploid cells, antibodies toGFP precipitated both Spn1p-CFP and Spn1p-myc, and converselyanti-myc immunoprecipitations contained both Spn1p-myc and Spn1p-CFP.Coprecipitating proteins that interacted specifically with theantibodies were not observed in strains producing single epitope–taggedproteins (Figure 4C). Therefore, the Spn1p-Spn1p interaction,like the Spn2p-Spn2p interaction, is independent of other septins.

In contrast, we found that the ability of Spn3p and Spn4p toself-associate depended on certain of the other septins. Inthe absence of spn1, anti-HA immunoprecipitates from the spn4-mycspn1::ura4/spn4-HA spn1::ura4 double-tagged strain did not containSpn4p-myc; the only protein detected in either the single- ordouble-tagged strains was Spn4p-HA (Figure 4D). Reciprocally,anti-myc immunoprecipitates from the spn4-myc spn1::ura4/spn4-HAspn1::ura4 double-tagged strain did not contain Spn4-HA either;the only protein detected in either the single- or double-taggedstrains was Spn4p-myc (Figure 4D). However, in lysates preparedfrom spn4-mycspn2::ura4/spn4-YFPspn2::ura4 or spn4-myc spn3::ura4/spn4-HAspn3::ura4 diploid cells, antibodies to GFP or HA did precipitateSpn4p-myc in addition to either Spn4p-YFP or Spn4p-HA, and converselyanti-myc immunoprecipitations contained both Spn4p-YFP or Spn4p-HAin addition to Spn4p-myc. Therefore, the Spn4p-Spn4p interactiondid require Spn1p but did not require Spn2p or Spn3p.

Lastly, the Spn3p-Spn3p interaction was found to be independentof spn2 but dependent on spn1 and spn4 (Figure 4E). Anti-HAimmunoprecipitates from the spn3-myc spn1::ura4/spn3-HA spn1::ura4or spn3-myc spn4::ura4/spn3-HA spn4::ura double-tagged straindid not pull down Spn3p-myc; the only protein detected in eitherthe single- or double-tagged strains was Spn3p-HA (Figure 4E).Reciprocally, anti-myc immunoprecipitates from the spn3-mycspn1::ura4/spn3-HA spn1::ura4 or spn3-myc spn4::ura4/spn3-HAspn4::ura double-tagged strain did not pull down Spn3-HA; theonly protein detected in either the single- or double-taggedstrains was Spn3p-myc (Figure 4E). In contrast, anti-HA immunoprecipitatesfrom the spn3-myc spn2::ura4/spn3-HA spn2::ura4 double-taggedstrain but not the single-tagged strain contained Spn3p-mycin addition to Spn3p-HA (Figure 4E). Conversely, anti-myc immunoprecipitatesfrom the spn3-myc spn2::ura4/spn3-HA spn2::ura4 double-taggedstrain but not the single-tagged strain contained Spn3p-HA inaddition to Spn3p-myc (Figure 4E).

In summary, the model consistent with all of our biochemicaldata is illustrated in Figure 4A, right panel, which indicatesa branch in the complex because we have gathered no evidencethat Spn3p and Spn4p are able to directly associate with themselves.However, the reduced recoveries of coprecipitating proteinsin some cases (Figure 4B, top panel, and D, middle panel) andthe absence of coprecipitating proteins in others indicate thatmost heterotypic septin interactions within the complex haveeither stabilizing effects or are absolutely required for homotypicseptin interactions. Considering this and the straight edgesof septin filaments observed by electron microscopy (Field etal., 1996; Frazier et al., 1998; Kinoshita et al., 2002; Mendozaet al., 2002; Versele and Thorner, 2004), we must also considerthe model illustrated in Figure 4A, left panel, for septin organizationand ultrastructural analysis will be required to distinguishbetween the two.

Interdependence of Septins for Ring Formation
Spn3p-GFP and Spn1p-GFP/CFP were shown previously to be localizeddiffusely during interphase and then organized into a ring structureat the end of anaphase (Berlin et al., 2003; Tasto et al., 2003).This ring splits as the septum forms but does not constrictwith actomyosin ring invagination; rather, the ring dissipatesafter cell cleavage (Berlin et al., 2003; Tasto et al., 2003).Spn4p-YFP and Spn2p-GFP localized identically to Spn1p and Spn3p(Figure 5, A and B). To determine which septin molecules orassemblies of molecules were critical for this localizationpattern, we used GFP/CFP/YFP-tagged strains in combination withdeletion alleles.

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Figure 5. Septin rings are absent in spn1 ${Delta}$ and spn4 ${Delta}$ cells. The (A) spn4-YFP (KGY496), (B) spn2-GFP (KGY4230), (C) spn4-YFP spn1 ${Delta}$ (KGY842), (D) spn1-CFP spn4 ${Delta}$ (KGY4417), (E) spn2-GFP spn1 ${Delta}$ (KGY4258), (F) spn2-GFP spn4 ${Delta}$ (KGY4259), (G) spn3-GFP spn1 ${Delta}$ (KGY4260), and (H) spn3-GFP spn4 ${Delta}$ (KGY2281) strains were grown in YE medium at 25°C, and GFP-tagged proteins were visualized in live cells. Scale bar, 5 µm.

In the absence of Spn1p, the remaining septins showed no specificlocalization (Figure 5, C, E, and G). Likewise, Spn1p, Spn2p,and Spn3p failed to concentrate at the medial cortex in spn4 ${Delta}$ cells (Figure 5, D, F, and H). When these observations are consideredin light of the model arising from our biochemical data (Figure 4A),we conclude that neither Spn3p or Spn2p alone, nor thesubcomplexes of Spn3p-Spn4p or Spn2p-Spn1p can be recruitedto the medial region of cells or form ring structures. It isnot surprising then that the cell separation defect of spn1 ${Delta}$ and spn4 ${Delta}$ cells is as severe as the loss of all spns (unpublisheddata).

In spn2 ${Delta}$ cells, we found that Spn1p, Spn4p, and Spn3p localizedto ring structures (Figure 6, A, D, and E). We infer that theserings are functional because most spn2 ${Delta}$ cells undergo normalcell separation (Figure 6, A, D, and E) in contrast to spn1 ${Delta}$ or spn4 ${Delta}$ cells (see Figure 5, C–H). Interestingly, Spn1p,Spn4p, and Spn3p were also detected in ectopic structures inthe cytoplasm of spn2 ${Delta}$ cells (Figure 6, A, D, and E). To determinewhether these structures contained more than one septin, weconstructed spn2 ${Delta}$ strains expressing Spn1p-CFP and Spn4p-YFPor, Spn1p-CFP and Spn3p-GFP. In both strains, the septins colocalizedin rings and ectopic structures (Figure 6, D and E), resultsconsistent with the biochemical analysis of septin complexesin spn2 ${Delta}$ cells presented above that indicated Spn1p, Spn3p, andSpn4p remained together in the absence of Spn2p. Similarly,Spn1p-CFP, Spn2p-GFP, and Spn4p-GFP localized to rings and ectopicstructures in spn3 ${Delta}$ cells and spn3 ${Delta}$ cells also displayed a mildercell separation phenotype (Figure 6, B, C, F, and G) than spn1 ${Delta}$ or spn4 ${Delta}$ cells (see Figure 5, C–H). Because we used mildfixation for one of our colocalization experiments (Figure 6D),we compared live and fixed cells directly (Figure 6, F and G,and unpublished data) and found no significant difference inseptin localization patterns. Septin localization patterns appearto resist ethanol fixation very well. Lastly, we examined thelocalizations of Spn1p-CFP or Spn4p-YFP in cells lacking bothSpn2p and Spn3p. In these strains, Spn1p-CFP and Spn4p-YFP didnot form rings (Figure 6F and unpublished data). Consistentwith this, the phenotype of spn2 ${Delta}$ spn3 ${Delta}$ cells is as severe asspn1 ${Delta}$ or spn4 ${Delta}$ cells (Figure 6F and unpublished data). Most cellscontained ectopic septin structures and in some cells, Spn1p-CFPand Spn4p-YFP formed a ring of medially placed "dots" (Figure 6Fand unpublished data). Combining this observation with ourbiochemical data, we conclude that a subcomplex of Spn1p-Spn4pis sufficient for formation of ectopic structures and localizingto the medial cortex, but at least one other septin is requiredfor assembly of a ring structure.

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Figure 6. Interdependence of septins for ring formation. (A) spn3-GFP spn2 ${Delta}$ (KGY3211), (B) spn1-CFP spn3 ${Delta}$ (KGY730), or (C) spn2-GFP spn3 ${Delta}$ (KGY3169) cells were grown at 25°C, and GFP-tagged proteins were visualized in live cells. (D) spn1-CFP spn4-YFP spn2 ${Delta}$ (KGY761) cells were fixed in ethanol and both Spn1p-CFP and Spn4p-YFP were photographed separately, and then the images merged. (E) spn1-CFP spn3-GFP spn2 ${Delta}$ (KGY887) cells were grown at 25°C, and Spn1p-CFP and Spn3p-GFP were photographed separately from live cells, and the images were merged. (F and G) spn4-GFP spn3 ${Delta}$ cells (KGY5000) were grown at 25°C, and either visualized live in (F) or fixed in ethanol before visualization (G). (H) Spn4p-YFP was visualized in live spn4-YFP spn2 ${Delta}$ spn3 ${Delta}$ cells (KGY1178). The inset shows the middle cell rotated on its Z-axis. Arrows point to the arrangement of Spn4p-YFP "dots" in the medial region of the cell. Gray lines represent the outlines of individual cells. Scale bar, 5 µm.

S. pombe Septin Ring Formation Requires Two Steps
The results presented above suggest that S. pombe septins 1-4are present in 8.5S complexes during all stages of the cellcycle except late mitosis when they are recruited to the medialcortex and organize into higher order oligomers that are visualizedas rings. To determine whether septin organization into higherorder structures requires entry into mitosis, we examined theability of synchronized cultures of cdc16-116 cells to formseptin rings when shifted to their nonpermissive temperature.Cdc16p is a component of the bipartite GAP for the small GTPase,Spg1p, whose activation triggers the septation initiation network(SIN; Schmidt et al., 1997; Furge et al., 1998). The SIN inducesactin ring constriction and septum formation normally as cellsexit mitosis (McCollum and Gould, 2001). When Cdc16p functionis abrogated during interphase, septation can occur before mitosis(Minet et al., 1979), and this allowed us to ask whether septinrings could form during interphase. cdc16-116 spn3-GFP cellssynchronized in early G2 phase were obtained by centrifugalelutriation and shifted to 36°C. Samples were collectedperiodically to examine nuclear division, septum formation,and formation of Spn3p-GFP rings (Figure 7A). At 60 min aftershift to 36°C, Spn3p-GFP had accumulated in the medial regionof cells and septa began to form in a population of interphasecells. However, close examination of these cells revealed thatSpn3p-GFP staining was more diffuse than in wild-type cellsand extended across the entire septum in a disk rather thanbeing restricted to the cortex (Figure 7C). It was never visualizedas a split ring in these cells (Figure 7C). In contrast, Spn3p-GFPrings were tight, focused, and cortically restricted in cellsthat had passed into and through mitosis before septum formation;in these cells split rings were easily detected (Figure 7D).We also examined the recruitment of Mid2p to the medial cortexin cdc16-116 cells at restrictive temperature. Consistent withthe cell cycle regulation of Mid2p abundance and localizationobserved previously (Tasto et al., 2003), Mid2p rings were detectedonly in cells that had passed through mitosis before septumformation (Figure 7, B and E). Further, the appearance of Mid2pat the cortex coincided with the assembly of organized septinrings (compare 150 min time points; Figure 7, D and E). Thesefindings indicate that ring formation and septation can driverecruitment of septin complexes to the medial region of thecell but another factor(s) available only in mitosis, such asMid2p, alone or in combination with other factors is requiredfor proper septin ring organization.

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Figure 7. Septin recruitment to the cortex, but not stable ring formation, can be induced during interphase. (A) spn3-GFP cdc16-116 (KGY738) and (B) mid2-GFP cdc16-116 (KGY741) cells were grown to midlog phase at 25°C, synchronized in early G2 phase by centrifugal elutriation, and then shifted to 36°C. Samples of cells were collected every 15 min. One portion of each sample was imaged immediately to determine the percentage of septated cells and the percentage of cells with Spn3p-GFP and Mid2p-GFP medial localization, respectively. Another portion was fixed with ethanol immediately and then stained with DAPI to determine the percentage of binucleate cells. (C and D) Spn3p-GFP localization in live cells from (C) 60 min or (D) 150 min time points (left panels of each). Images in the left panels were also rotated in the Z-axis to better reveal septin ring organization (right panels). Short arrows point to disorganized septin rings at 60 min. Longer arrows point to organized rings at 150 min. (E) Mid2p-GFP localization in live cells from 150 min time point. Cells are also rotated in the Z-axis to better show Mid2p ring organization. Arrows point to organized Mid2p rings. Scale bar, 5 µm.

To determine whether Mid2p is the sole additional factor requiredfor septin ring organization in interphase cdc16-116 cells,we mildly overproduced HA-Mid2p from the nmt41 promoter beforeselecting G2 phase cells by centrifugal elutriation. In thiscase, Spn3p-GFP was recruited to the medial region before mitosisas before (Figure 8A) and it was now assembled into highly organizedring structures that were easily visualized as split rings oncesepta had formed (Figure 8, B and C). Virtually no diffuse diskstructures were observed (Figure 8, B–D). We concludefrom this experiment that Mid2p is solely responsible directlyor indirectly for regulating septin ring coalesence in S. pombe.Another note-worthy consequence of mild Mid2p overexpressionwas the relative persistence of septin rings and the inhibitionof mitotic progression, as determined by monitoring the formationof binucleates (Figure 8A). This result is consistent with ourprevious results, indicating that prolonged expression of Mid2pstabilizes septin ring structures and influences cell cycleprogression (Tasto et al., 2003).

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Figure 8. Coalescence of septin rings can be induced during interphase by mid2⁺ expression. (A) spn3-GFP cdc16-116 (KGY738) cells were transformed with pREP41-HA-mid2⁺. Transformants obtained in the presence of thiamine in the medium were then grown to midlog phase in the absence of thiamine at 25°C for 15 h. They were then synchronized in early G2 phase by centrifugal elutriation and immediately shifted to 36°C. Samples of cells were collected every 15 min. One portion of each sample was imaged immediately to determine the percentage of septated cells and the percentage of cells with Spn3p-GFP medial localization. Another portion was fixed with ethanol and stained with DAPI to determine the percentage of binucleate cells. (B and C) Spn3p-GFP localization in live cells at the 75-min time point. In B, cells imaged with a single Z-series stack (0.49 µm) are shown to provide the best visualization of split septin rings as indicated by the arrow. In C, the image in the left panel represents a 3D reconstruction of Z-series stacks. This image was rotated in the Z-axis (right panel) to illustrate the cortical restriction of the septin rings. The arrows point to organized septin rings. (C) Quantitation of disorganized septin rings (disk) and organized septin rings (ring) in interphase cdc16-116 cells in the presence or absence of Mid2p. Percentages were determined by visual inspection of Z-series stacks of live cells that contained medially placed septin structures from the experiment described in Figure 7A, 75-min time point, 93 cells examined (-mid2) and from the experiment described in part A of this figure, 75-min time point, 88 cells examined (+mid2). Scale bar, 5 µm.

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

In this study, we have determined the basic organization ofS. pombe septin complexes that are used to build septin ringsduring cytokinesis and defined two discrete steps in septinring assembly. Because the four septins that participate inS. pombe cell division are not essential for viability, we wereable to assess the interdependence and function of each septinin the absence of any one or combination of the others. Themodel of septin complex organization arising from these studiesindicates that Spn1-4p form an almost linear array of a specificorder that is held together by a series of interdependent associations(Figure 4A). Further, different subunits within this complexare not equivalent in their functions. Our results have implicationsfor understanding the nature of septin complexes and their propertiesin other eukaryotes.

First, our data argue that each septin does not possess theintrinsic ability to localize to its site of action or to formring structures, a possibility raised by the finding that anindividual septin subunit (Xenopus laevis Sept2) can polymerizeinto filaments in vitro (Mendoza et al., 2002). Not only doour findings indicate that individual septin subunits do notnormally exist on their own in yeast (in S. pombe, the minimalunit comprises 8 polypeptides), our data also indicate thatring formation in S. pombe requires a minimum of three complexedseptins, either Spn3p-Spn4p-Spn1p or Spn4p-Spn1p-Spn2p. Thatthe complexes of three septins are sufficient to form ring structuresexplains why the absence of spn2⁺ or spn3⁺ generates a mildcell separation defect relative to the deletion of spn4⁺ orspn1⁺ or both spn2⁺ and spn3⁺.

Interestingly, our biochemical and cell biological analysesof various septin deletion strains indicate that the Spn4p-Spn1psubcomplex but not the Spn3p-Spn4p or Spn1p-Spn2p subcomplexesis able to accumulate as dot structures in the medial regionof cells. Although a conserved polybasic region within septinsbinds phosphatidyl inositol biphosphate in vitro and has beenimplicated in septin localization (Zhang et al., 1999; Casamayorand Snyder, 2003), our results suggest that the Spn1p-Spn4psubcomplex contains the targeting information for the complexand it will be interesting in the future to illuminate its nature.We also observed that subcomplexes of two (Spn4p-Spn1p) or three(Spn3p-Spn4p-Spn1p or Spn4p-Spn1p-Spn2p) septins formed ectopicstructures that were not observed in wild-type cells expressingthe full complement of the four cytokinetic septins. This raisesthe possibility that subunits on the end of the array (Spn2por Spn3p) might normally act in interphase to prevent spuriousassembly into aggregates or higher order structures. Purifiedseptins have been observed to polymerize into filaments in vitro(Field et al., 1996; Frazier et al., 1998; Kinoshita et al.,2002; Mendoza et al., 2002). If the ectopic structures observedin vivo are due to septin filament formation rather than aggregation,our observations may be relevant to the findings that individualseptins and complexes of septins display differential abilitiesto polymerize in vitro (reviewed in Mitchison and Field, 2002).Because ectopic structures were only observed with the particularsubcomplexes described above, the outcome of in vitro studiesmight depend on which septin or septin subcomplex is chosenfor examination. On that note, our model of septin organizationand function suggests that the integrity of the complex as awhole should be examined as part of any structure/function analysisperformed on individual subunits. For example, any mutationof either Spn2p (Cdc10p) or Spn3p (Cdc11p) that disturbs itsinteraction with Spn1p (Cdc3p) or Spn4p (Cdc12p), respectively,would be expected to negatively influence its ability to localizeappropriately but not necessarily because an intrinsic targetingdomain was disturbed.

Several observations suggest that the organization of septinswe have found in S. pombe will be relevant to other septin complexes,at least to those found in S. cerevisiae. First, S. cerevisiaecells lacking Cdc10p or Cdc11p (Spn2p and Spn3p homologues,respectively) contain complexes of the other three septins (Frazieret al., 1998). Second, such complexes retained some functionbecause the cells divided albeit with reduced efficiency (Frazieret al., 1998), a situation similar to what is observed in spn2 ${Delta}$ and spn3 ${Delta}$ cells. Third, subsets of S. cerevisiae proteins producedin E. coli comparable to those we have found associate withone another in S. pombe were able to complex with one anotherand form filamentous structures (Versele et al., 2004; Verseleand Thorner, 2004). Lastly, two-hybrid results testing S. cerevisiaeseptin interactions support our working models (Figure 4A),although they should be interpreted with caution because ofthe strong possibility of bridging interactions. These analysessuggest that Cdc11p (Spn3p homolog) interacts with Cdc12p (Spn4phomolog; Lee et al., 2002; Casamayor and Snyder, 2003), Cdc12pinteracts strongly with Cdc3p (Spn1p homolog) (Lee et al., 2002),and Cdc3p interacts with Cdc10p (Spn2p homolog; Lee et al.,2002), and there is an absence of strong interaction betweenCdc3p and Cdc11p (Lee et al., 2002; Casamayor and Snyder, 2003).

Precocious activation of the septation initiation network (SIN)induced septins to concentrate at the position of the actomyosinring in interphase cells. However these septin structures werenot organized properly. Indeed, they were very reminiscent ofseptin structures formed in cells lacking Mid2p (Berlin et al.,2003; Tasto et al., 2003) and in fact Mid2p-GFP was not visualizedat rings induced by activation of the SIN during interphase.Thus, we conclude that septin accumulation at the medial regionof the cell and coalescence into a ring structure are geneticallyseparable events. The first requires an event(s) that can beinitiated by actomyosin ring formation and SIN activity butis independent of mitotic entry. By supplying Mid2p artificiallyto interphase cdc16-116 cells, coalescence into ring structureswas induced. This result indicates that Mid2p, directly or indirectly,is solely responsible for septin ring coalescence. The two-stepassembly of S. pombe septin rings described here may be analogousto the situation in S. cerevisiae in which septin rings in unbuddedcells are relatively unstable and become stabilized as cellsproceed to bud (Caviston et al., 2003; Dobbelaere et al., 2003).Mid2p has a homolog in S. cerevisiae, Bud4p (Sanders and Herskowitz,1996), which is similarly cell cycle regulated, but it is notknown whether Bud4p participates in septin ring organization.

An established regulatory step for S. cerevisiae septin ringformation is septin phosphorylation, and several protein kinaseshave been implicated in septin ring dynamics including the GIN4family, Cdk1p, and Cla4p (Cvrckova et al., 1995; Longtine etal., 1998; Weiss et al., 2000; Mortensen et al., 2002; Tangand Reed, 2002; Dobbelaere et al., 2003; Schmidt et al., 2003;Versele and Thorner, 2004). Although the S. pombe homologuesof the GIN4 kinases, Cdr1p and Cdr2p, do not influence septinring organization (Morrell et al., 2004), it will be interestingto determine whether S. pombe septin ring assembly is regulatedby phosphorylation and whether Mid2p acts in concert with proteinkinases to control this process. Another factor implicated inthe organization of S. cerevisiae septin rings is a fifth septin,Shs1p/Sep7 (Mortensen et al., 2002; Dobbelaere et al., 2003).S. pombe does not have an ortholog of Shs1p/Sep7 and we didnot detect a fifth septin copurifying with Spn1-4p-TAP complexes.The S. pombe genome does encode an additional three septinsbut their expression is restricted to meiosis (Mata et al.,2002; Rustici et al., 2004). Thus, it is unclear whether therole of Shs1p/Sep7 in S. cerevisiae septin ring organizationwill extend to other organisms.

As both recombinant and purified septins can polymerize intofilaments in vitro (Field et al., 1996; Frazier et al., 1998;Kinoshita et al., 2002; Mendoza et al., 2002; Versele and Thorner,2004), it is interesting to consider how the complex describedhere is assembled into such higher order oligomers. It willbe informative in future studies to link the ability of particularseptin complexes to form filamentous structures in vitro withthe in vivo requirements of ring formation we have establishedhere.

ACKNOWLEDGMENTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

We thank Joseph Tasto for numerous strain constructions, JohnPringle for spn2 and spn3 deletion strains and for sharing unpublishedinformation, and Tony Hunter, Dan McCollum, and John Pringlefor stimulating discussions. J.L.J. was supported by NationalInstitutes of Health (NIH) grants GM64779 and HL68744. A.J.L.is supported by NIH grants GM64779, HL68744, NS43952, ES11993,and CA098131. Work in the Gould lab was supported by the HowardHughes Medical Institute, of which K.L.G. is an Investigator.

Footnotes

Article published online ahead of print. Mol. Biol. Cell 10.1091/mbc.E04–07–0640.Article and publication date are available at www.molbiolcell.org/cgi/doi/10.1091/mbc.E04–07–0640.

The online version of this article contains supplemental materialat MBC Online (http://www.molbiolcell.org).

Corresponding author. E-mail address: kathy.gould{at}vanderbilt.edu.

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