Rho GTPase regulation of exocytosis in yeast is independent of GTP hydrolysis and polarization of the exocyst complex

doi:10.1083/jcb.200504108

Published 15 August 2005. doi:10.1083/jcb.200504108
The Rockefeller University Press, 0021-9525 $8.00
JCB, Volume 170, Number 4, 583-594

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Article

Rho GTPase regulation of exocytosis in yeast is independent of GTP hydrolysis and polarization of the exocyst complex

Olivier Roumanie¹, Hao Wu¹, Jeffrey N. Molk², Guendalina Rossi¹, Kerry Bloom², and Patrick Brennwald¹

¹ Department of Cell and Developmental Biology, University of North Carolina at Chapel Hill, Chapel Hill, NC 27599
² Department of Biology, University of North Carolina at Chapel Hill, Chapel Hill, NC 27599

Correspondence to Patrick Brennwald: pjbrennw{at}med.unc.edu

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Abstract
Introduction
Results
Discussion
Materials and methods
References

Rho GTPases are important regulators of polarity in eukaryoticcells. In yeast they are involved in regulating the dockingand fusion of secretory vesicles with the cell surface. Ouranalysis of a Rho3 mutant that is unable to interact with theExo70 subunit of the exocyst reveals a normal polarization ofthe exocyst complex as well as other polarity markers. We alsofind that there is no redundancy between the Rho3–Exo70and Rho1–Sec3 pathways in the localization of the exocyst.This suggests that Rho3 and Cdc42 act to polarize exocytosisby activating the exocytic machinery at the membrane withoutthe need to first recruit it to sites of polarized growth. Consistentwith this model, we find that the ability of Rho3 and Cdc42to hydrolyze GTP is not required for their role in secretion.Moreover, our analysis of the Sec3 subunit of the exocyst suggeststhat polarization of the exocyst may be a consequence ratherthan a cause of polarized exocytosis.

O. Roumanie's present address is Laboratoire de Biologie Moléculaireet Séquençage, Institut de Biochimie et GenetiqueCellulaires, 33077 Bordeaux, France.

Abbreviations used in this paper: DIC, differential interferencecontrast; RBD, Rho-binding domain.

Introduction

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Abstract
Introduction
Results
Discussion
Materials and methods
References

In eukaryotic cells, exocytosis is the major route by whichnewly synthesized proteins and lipids are delivered to the cellsurface. This process involves the directed transport, docking,and fusion of Golgi-derived secretory vesicles with the plasmamembrane. In Saccharomyces cerevisiae, polarization of exocytosisis tightly coordinated with the overall polarity of the cell.Much of the protein machinery responsible for cell polarityand exocytosis is itself concentrated at sites of polarizedgrowth (Pruyne and Bretscher, 2000).

In yeast, the polarized delivery of vesicles along actin cablesis thought to be performed by a type V myosin Myo2 and the RabGTPase Sec4 (Goud et al., 1988; Pruyne et al., 1998). Elegantgenetic and biochemical analyses have shown that a multisubunitcomplex known as the exocyst complex or Sec6–Sec8 complexis required for the docking and fusion of secretory vesiclesat the plasma membrane (Terbush et al., 1996; Guo et al., 1999).The secretory machinery, including Myo2, Sec4, and the exocystcomplex, is concentrated at sites of active growth to enablethe polarized fusion of secretory vesicles with the plasma membrane.The final step of the exocytic process requires the formationof complexes between the v-SNAREs Snc1/2, located on the secretoryvesicles, and the plasma membrane t-SNAREs Sec9 and Sso1/2,distributed around the periphery of the cell (Brennwald et al., 1994).

Recent studies from our laboratory have implicated Rho GTPasesin the regulation of exocytosis (Adamo et al., 1999, 2001).In addition, physical interactions between specific Rho proteinsand two subunits of the exocyst complex have been reported.Rho1 and Cdc42 have been shown to bind to the NH₂-terminal domainof Sec3 to promote its polarization, and Rho3 interacts withExo70, another subunit of the exocyst (Robinson et al., 1999;Guo et al., 2001; Zhang et al., 2001). We have shown that Rho3and Cdc42 have specific and direct roles in post-Golgi secretion,which are independent of their roles in other aspects of polarityand morphogenesis (Adamo et al., 1999, 2001). However, the precisemechanism by which Rho3 and Cdc42 regulate exocytosis is presentlyunclear.

Here, we report that, like cdc42-6, the cold-sensitive rho3-V51allele has a secretion defect that does not involve detectableeffects on the polarized localization of the exocytic machinery.Moreover, GTP hydrolysis by Rho3 and Cdc42 was found to be dispensablefor their function in secretion. This suggests that these GTPasesact in vesicle docking and fusion at the plasma membrane throughallosteric regulation of the exocytic machinery. We proposethat the observed polarization of the exocytic apparatus, includingthe exocyst complex, may be a result of, rather than a causeof, polarized exocytosis. This suggests a model in which theunpolarized exocytic machinery present on the plasma membranecan respond directly to a polarization signal initiated by thepresence of a patch of activated Rho GTPase. This mechanismdoes not require the direct recruitment of factors by the RhoGTPase to the site of polarized growth. Recent evidence hasshown that much of the exocytic machinery is associated withtransport carriers destined for the plasma membrane (Boyd et al., 2004).Thus, the direct asymmetric regulation of exocytosisby activated Rho proteins would reinforce the delivery of secretoryvesicles at the site of active growth and lead indirectly tothe appearance of a polarized secretion machinery.

Results

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Abstract
Introduction
Results
Discussion
Materials and methods
References

The rho3-V51 secretory defective mutant does not affect the cellular localization of essential secretion and polarity markers
To determine the function of Rho3 in the cell, we previouslyidentified four mutants in the effector domain of Rho3 thatresult in conditional growth defects. Of these, rho3-V51 wasthe only allele that exhibited a well polarized actin cytoskeleton,but showed a severe defect in secretion after a shift to therestrictive temperature (Adamo et al., 1999). This was the firstdemonstration that Rho GTPases could function in exocytic transportindependent of their effects on actin.

To determine how Rho3 regulates exocytosis, we first examinedthe effect of the rho3-V51 mutation on the localization of markersof polarized exocytosis. Our initial analysis included Cdc42,Myo2, and Sec4. Cdc42 is an essential Rho GTPase involved inpolarized assembly of the cytoskeleton and in regulation ofthe late secretory pathway and is known to polarize independentlyof polymerized actin to sites of active growth (Ayscough et al., 1997).Sec4 is a member of the Rab GTPase family that actsbetween the Golgi apparatus and the plasma membrane (Goud et al., 1988).Myo2 is an unconventional type V myosin implicatedin targeting post-Golgi vesicles to the bud tip (Pruyne et al., 1998).Sec4 and Myo2 localize to the presumptive bud site andthe tip of small budded cells through a mechanism that is sensitiveto both the integrity of actin cables and on-going secretion.The localization of these three markers was analyzed in therho3-V51 mutant and wild-type cells using affinity-purifiedantibodies against endogenous proteins. Temperature shifts of5 h at 14°C were used, as these were previously shown toresult in a severe post-Golgi secretory defect (Adamo et al., 1999).We observed that Cdc42 gave a similar polarized stainingpattern in the rho3-V51 mutant and wild-type cells before andafter a shift to 14°C (Fig. 1 A). Quantitation of the number(i.e., penetrance) of cells exhibiting a polarized Cdc42 stainingpattern was found to be virtually identical between the rho3-V51mutant and wild-type cells at both 25 and 14°C (Fig. 1 B).Furthermore, quantitation of the average intensity (i.e., magnitude)of Cdc42 patch staining in each condition varied by <5% betweenthe wild-type and the rho3-V51 mutant. We observed that, asin wild-type cells, Sec4 and Myo2 were polarized in rho3-V51cells after a 5-h shift to the restrictive temperature (Fig. 1A). Both wild-type and mutant cells showed a similar efficiencyof polarization for either Sec4 or Myo2 at 25 and 14°C (Fig. 1B), and there was no significant effect on the staining intensity.Thus, Myo2 and Sec4 are properly localized in the rho3-V51 mutant,consistent with the fact that the actin cytoskeleton organizationin this mutant is largely unaffected at the restrictive or permissivetemperature (Adamo et al., 1999; unpublished data). These resultsdemonstrate that rho3-V51 cells are fully competent in localizingcritical factors involved in post-Golgi transport.

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Figure 1. Distribution of the polarity and secretion markers Cdc42, Myo2, and Sec4 is normal in the rho3-V51 secretory mutant at both permissive and nonpermissive temperatures. (A) Wild-type (WT) and mutant (rho3-V51) cells were grown at 25°C or shifted to 14°C for 5 h before fixation and then processed for fluorescence microscopy. Visualization of the polarity establishment protein Cdc42, the Rab GTPase Sec4, and the vesicle-transport motor Myo2 was performed using specific purified antibodies. Bar, 2 µm. (B) Quantitation of polarized markers in wild-type and rho3-V51 cells. Cells were processed as described in A and scored for the polarized localization of Cdc42, Sec4, and Myo2 at the emerging bud sites, bud tips, or mother-daughter neck regions. A minimum of 200 cells were counted for each experiment.

Post-Golgi vesicle tethering and docking to the plasma membraneis dependent on a multisubunit protein complex known as theexocyst complex. Although the aforementioned results suggestthat vesicles are properly delivered to sites of polarized growthin rho3-V51 cells, it is possible that the accumulation of post-Golgivesicles observed in this mutant could result from a failurein vesicle docking due to the absence of the exocyst complexat sites of polarized growth. To determine if rho3-V51 cellsare defective in polarization of the exocyst complex, we followedthe fluorescence associated with three GFP-tagged exocyst subunitsSec3, Sec8, and Exo70. Sec8 and Exo70 are two of the seven essentialsubunits of the exocyst, and Exo70 has been shown to interactwith Rho3 in a GTP-dependent manner (Robinson et al., 1999).Sec3 is the only nonessential subunit of the complex, and ithas been proposed to act as a spatial landmark for secretion(Finger et al., 1998). We found that these exocyst componentswere polarized in rho3-V51 cells at the restrictive temperature(Fig. 2 A). Furthermore, the percentage of mutant cells displayingpolarized subunits was comparable to that observed in wild-typecells (Fig. 2 B). To confirm that the rho3-V51 strains containingthe GFP-tagged exocyst subunits showed secretory defects similarto those described for the parental rho3-V51 strains, we examinedtheir capacity for secretion of the periplasmic enzymes invertaseand Bgl2 after a shift to the restrictive temperature. As canbe seen in Fig. 2 C we find that, like the parental rho3-V51strain, the GFP-tagged derivatives show a pronounced secretorydefect for both enzymes. As previously observed for rho3-V51,these strains show a partial secretory defect for both enzymesat the permissive temperature, which correlates with post-Golgivesicle accumulation by electron microscopy (Fig. 2 C; Adamo et al., 1999).The invertase secretion defect is significantlyexacerbated after the shift to 14°C, which also correlateswith an increase in vesicle accumulation by EM (Fig. 2 C; Adamo et al., 1999).Also, as previously observed, Bgl2 secretionwas similarly defective at both temperatures (Fig. 2 C; Adamo et al., 1999).Thus, we conclude that the secretory defectspresent in the rho3-V51 mutant is not due to an inability toproperly localize the exocyst complex to sites of polarizedgrowth.

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Figure 2. Exocyst subunits Sec3, Sec8, and Exo70 are polarized in the rho3-V51 secretory mutant at permissive and nonpermissive temperatures. (A) Plasmids containing functional, COOH-terminal–tagged GFP versions of Sec3, Sec8, or Exo70 were introduced into wild-type and rho3-V51 strains. Transformed cells were grown at 25°C or shifted to 14°C for 5 h and immediately fixed and processed for fluorescence microscopy. DIC images of the same cells are shown. Bar, 2 µm. (B) Quantitation of Sec3-GFP, Sec8-GFP, and Exo70-GFP polarized localization in wild-type and rho3-V51 cells. Cells processed as described in A were scored for the presence of the exocyst components at the emerging bud sites, bud tips, or bud necks. Approximately 50 cells were analyzed under each condition. (C) Invertase and Bgl2 secretion assays on GFP-tagged wild-type and rho3-V51 strains processed as described in A were performed as described previously (Adamo et al., 1999). The secretion defect associated with each strain is expressed as the percentage of total (internal + external) invertase or Bgl2 found internally. Results shown represent the average of three experiments. Error bars represent SD.

Testing the functional redundancy between the Rho–Sec3 and Rho–Exo70 pathways
Studies on the yeast exocyst complex have revealed interactionsof two subunits, Sec3 and Exo70, with Rho GTPases (Fig. 3 A;Robinson et al., 1999; Guo et al., 2001; Zhang et al., 2001).Exo70 interacts specifically with Rho3 (Robinson et al., 1999),and introduction of the V51 mutation in the effector domainof Rho3 leads to a loss of this interaction (Adamo et al., 1999)without affecting the localization of Exo70 or other exocystcomponents as described in the preceding section. The Sec3 proteinhas been shown to interact with both Rho1 and Cdc42 throughan NH₂-terminal Rho-binding domain (RBD; Guo et al., 2001; Zhang et al., 2001).Surprisingly, although the RBD regulates thepolarized localization of Sec3 to sites of polarized growth,its deletion has no effect on the polarized localization ofthe rest of the exocyst complex. Guo et al. (2001) and Boyd et al. (2004)have suggested that a parallel pathway involvingExo70 may localize the exocyst complex to sites of polarizedgrowth in the absence of the Rho–Sec3 pathway. This suggestedthat the lack of an effect of the rho3-V51 mutant on exocystlocalization might be due to redundancy with the Rho–Sec3pathway in localizing the exocyst complex to sites of polarizedgrowth (Fig. 3 A). If such redundancy exists between these pathways,then the combination of mutations impairing both the Rho3–Exo70and Rho–Sec3 pathways would be expected to be detrimentalto the cell. Therefore, we used a mutant sec3- ${Delta}$ N allele lackingthe NH₂-terminal RBD of SEC3 to replace the genomic wild-typeSEC3 locus. The sec3- ${Delta}$ N was expressed behind the GPD promoteras in previous studies involving sec3- ${Delta}$ RBD mutants (Guo et al., 2001;Wiederkehr et al., 2003). To detect both wild-type andSec3- ${Delta}$ N proteins, we raised and affinity purified antibodiesto a hydrophilic region in the central portion of the Sec3 protein(Fig. 3 B). We observed that cells expressing sec3- ${Delta}$ N as thesole copy grew as well as wild-type cells at all temperaturesexamined. Cellular localization of the endogenous Sec3 by immunofluorescencerevealed a characteristic polarized staining at sites of activeexocytosis, whereas the sec3- ${Delta}$ N mutant appeared as a diffusebright staining all over the cell (Fig. 3 C). Under our experimentalconditions, no detectable portion of Sec3- ${Delta}$ N was found to betargeted correctly to sites of cellular growth. Nevertheless,staining of polarity and secretion markers confirmed that, aspreviously reported (Guo et al., 2001), the exocytic machinerywas properly localized in the sec3- ${Delta}$ N strain (Fig. 3, C and D).In addition, the average signal intensity of these markers didnot display any decrease in the mutant compared with wild type(Fig. 3 E), demonstrating that the proteins were fully competentfor targeting to sites of polarized secretion.

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Figure 3. Testing the redundancy model for Rho function in the polarization of secretory and polarity markers. (A) Redundancy model for Rho3 and Rho1/Cdc42 pathways in polarizing the exocyst. The Exo70 and Sec3 exocyst subunits interact with distinct Rho GTPases, and these interactions have been proposed to localize the exocyst complex to help promote secretion and polarity. (B) A sec3 mutant strain lacking the NH₂-terminal RBD (aa 3–320) of Sec3 was placed as the only copy of Sec3 in the cell on high copy expression (see Materials and methods). Correct integration of the construct was checked by Western blot analysis of whole cell lysates from wild-type and sec3- ${Delta}$ N strains using anti-Sec3 antibodies directed against the middle region of the protein. Blotting with anti-Exo70 antibodies was used as loading control. (C) Polarization of distinct secretion markers in the sec3- ${Delta}$ N mutant. Wild-type and sec3- ${Delta}$ N cells were grown at 25°C, fixed, and processed for immunofluorescence. Specific purified antibodies directed against the Sec3 and Sec15 exocyst subunits, the polarity protein Cdc42, or the secretion regulator Sec4 were used. Bar, 2 µm. (D) Quantitation of Cdc42, Sec4, and Sec15 polarization in the sec3- ${Delta}$ N mutant at 25°C. The polarized distribution of the three proteins was scored as described in Fig. 1. (E) Measurement of the relative fluorescence associated with the Cdc42, Sec4, and Sec15 markers in small budded cells at 25°C. Proteins were detected by immunofluorescence microscopy in wild-type and sec3- ${Delta}$ N cells, and the fluorescence intensity of the polarized spots was measured in small budded cells using Metamorph software. Results for each marker are reported as an intensity of fluorescence relative to the fluorescence observed in the wild-type strain for the same marker. Error bars represent SD.

Analysis of rho3-V51,sec3- ${Delta}$ N double mutants reveals no synthetic effects on growth or polarity
To assay for redundancy between the Rho3–Exo70 and theRho–Sec3 pathways, we crossed strains containing the sec3- ${Delta}$ Nand rho3-V51 alleles to evaluate the phenotype of cells containingboth mutations as the only source of Sec3 and Rho3 in the cell.No synthetic effects on growth were observed, as growth of therho3-V51,sec3- ${Delta}$ N double mutant is identical to that of the rho3-V51mutant at both permissive (25°C) and nonpermissive (14°C)conditions (Fig. 4 A). None of the double mutants showed sensitivityto growth at high temperature (37°C), and both rho3-V51,sec3- ${Delta}$ Nand rho3-V51 grew slightly slower than wild-type or sec3- ${Delta}$ N strainsat 25°C. To determine the extent to which secretion wasblocked in the rho3-V51,sec3- ${Delta}$ N mutant cells, the export of theBgl2 exoglucanase was monitored at both 25 and 14°C (Fig. 4B). Wild-type and sec3- ${Delta}$ N cells displayed similar small amountsof internal pools of the enzyme, indicating that deletion ofthe Sec3 RBD motif did not impair secretion. The rho3-V51,sec3- ${Delta}$ Nstrain was found to have a defect in secretion comparable torho3-V51. As expected, a large amount of Bgl2 accumulated inthe rho3-V51 cells and a comparable fraction of enzyme was detectedwithin the rho3-V51,sec3- ${Delta}$ N double mutant at both temperatures.Therefore, the growth and secretion defects displayed by rho3-V51cells were not amplified in combination with the sec3- ${Delta}$ N mutation.

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Figure 4. rho3-V51 and sec3- ${Delta}$ N mutations do not demonstrate any synthetic effects on growth and secretion. (A) Analysis of the growth phenotypes of the rho3-V51,sec3- ${Delta}$ N double mutant. The sec3-2 and sec4-P48 strains were used as growth controls. Plates at 37 and 25°C were incubated for 2–3 d or at 14°C for 6 d. (B) Analysis of Bgl2 protein secretion in wild-type, sec3- ${Delta}$ N, rho3-V51, and rho3-V51,sec3- ${Delta}$ N strains. Cells were grown at 25°C or shifted to 14°C for 5 h before analyzing the distribution of the secreted protein Bgl2 as described previously (Adamo et al.,1999). Quantitation of the bands was performed using ImageQuant software. The percentage of the total Bgl2 that is found internally in different strains is depicted. The data represent the average of three independent experiments. Error bars represent SD.

Next, we determined whether the loss of Sec3's ability to interactwith Rho proteins had any effect on the localization of componentsof the exocytic machinery in rho3-V51 cells. Immunofluorescencestudies on the rho3-V51,sec3- ${Delta}$ N double mutants demonstrated thatCdc42, Sec4, and Myo2 were polarized normally after a shiftto the nonpermissive temperature of 14°C (Fig. 5 A). Inaddition, the ability of mutant cells to maintain the localizationof these markers was normal (Fig. 5, B and C). The exocyst complexpolarization was then investigated using GFP-tagged Sec8 andExo70 subunits and antibodies directed against Sec15. No defectin the localization of these exocyst components was observedat the restrictive temperature (Fig. 5, A and D), showing thatthe exocyst was polarized in rho3-V51,sec3- ${Delta}$ N cells at 14°C.The amount of cells showing polarized exocyst subunits was determinedto be similar in wild-type and mutant strains (Fig. 5 E). Also,examination of the rho3-V51,sec3- ${Delta}$ N mutant actin cytoskeletonrevealed that both patches and cables were polarized at 25 and14°C (unpublished data).

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Figure 5. rho3-V51,sec3- ${Delta}$ N cells show no defect in the polarization of polarity or secretory markers. (A) The rho3-V51,sec3- ${Delta}$ N cells were grown at 25°C and shifted to 14°C for 5 h before being analyzed by fluorescence microscopy. Purified antibodies were used to visualize polarity/secretion markers (Cdc42, Sec4, and Myo2) and exocyst subunits (Sec3 and Sec15). Bar, 2 µm. (B) Quantitation of polarized markers at 14°C in the indicated wild-type or mutant strains. Cells were scored for the polarized localization of Cdc42, Sec4, Myo2, and Sec15 as described in Fig. 1. (C) Measurement of relative fluorescence associated with the polarity/secretion markers in small budded cells at 14°C. Polarized staining was analyzed as described in Fig. 3. Error bars represent SD. (D) The plasmids carrying the GFP-tagged exocyst subunits Sec8 or Exo70 were transformed into the rho3-V51,sec3- ${Delta}$ N double mutant strain. The cells were grown at 25°C, shifted to 14°C for 5 h, fixed, and observed by fluorescence and DIC microscopy. Bar, 2 µm. (E) Quantitation of Sec8-GFP and Exo70-GFP polarized localization in wild-type and mutant strains at 14°C. Under each condition, $~$ 50 cells were analyzed and scored for the presence of the exocyst components at the emerging bud sites, bud tips or bud neck.

To determine if there was an effect of RHO3 mutants on the dynamicsof exocyst polarization, photobleaching was performed on Sec8-GFP–expressingcells and FRAP was analyzed. Wild-type strains expressing Sec8-GFPfrom a CEN plasmid were photobleached at the bud tip of smallor medium budded cells (Fig. 6 A). Sec8-GFP had a half-recoverytime of $~$ 17 s that was fit by a single exponential curve (Fig. 6B and Table S1, available at http://www.jcb.org/cgi/content/full/jcb.200504108/DC1),similar to previous FRAP measurements (Boyd et al., 2004). Thecorrected fluorescence recovery was measured as $~$ 82% of the prebleachfluorescence intensity (Table S1). Photobleaching and FRAP measurementsof Sec8-GFP in rho3-V51 mutants demonstrated that both the t_1/2and fluorescence recovery values were not significantly differentfrom wild-type cells (Fig. 6, C and D). Likewise, expressionof the GTP-locked CEN-RHO3^Q74L as the only source of Rho3 inthe cell did not significantly alter Sec8-GFP recovery rates.Nor did we detect any significant differences in the Sec8-GFPrecovery rates in the sec3- ${Delta}$ N single mutant or rho3-V51,sec3- ${Delta}$ Ndouble mutants from that seen in wild-type cells (Fig. 6, C and D).Therefore, the analysis of exocyst dynamics using FRAPstrongly supports our observations that polarization of thiscomplex is unperturbed in the rho3-V51 mutants or in the rho3-V51,sec3- ${Delta}$ Ndouble mutants. Thus, the Rho1–Sec3 and Rho3–Exo70pathways do not appear to act redundantly to determine the localizationor dynamics of the exocyst complex at sites of polarized growth.Interestingly, we also find kinetics similar to wild-type cellswith the RHO3^Q74L GTP-locked mutant, suggesting that activationof Rho3 function has no dramatic effect on the overall dynamicsof exocyst polarization. Rho3, therefore, does not appear todirectly regulate exocyst polarization. Moreover, we also findthat Rho1–Sec3 and Rho3–Exo70 pathways do not actredundantly to determine the localization or dynamics of theexocyst complex at sites of polarized growth.

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Figure 6. Sec8-GFP photobleaching and FRAP measurements in rho3-V51,sec3- ${Delta}$ N cells show wild-type recovery times. (A) Representative example of Sec8-GFP photobleaching experiment. Arrow denotes photobleached area. Prebleach, t = –3 s; photobleaching, t = 0 s; maximum recovery, t = 105 s. Bar, 2 µm. (B) Measured fluorescence recovery of Sec8-GFP (black squares) compared with single exponential fit of recovery (gray triangles). Fluorescence intensity is recorded in arbitrary units (A.U.). See Materials and methods for details of analysis. (C) Average half-recovery times measured for Sec8-GFP. (D) Average percent recovery values for Sec8-GFP. Error bars represent SD.

To determine if the loss of the RBD has any effect on Sec3 functionin combination with other late secretory mutants, we introduceda sec3- ${Delta}$ N or a control SEC3 construct into cdc42-6 and severallate sec mutants (Table S1). As with the rho3-V51 mutant, wefound no obvious synthetic effect of the sec3- ${Delta}$ N allele on growthof sec9-4 cells. However, synthetic effects at semipermissivetemperatures were apparent in sec1-1, sec8-9, and, most severely,sec15-1 mutant cells. Strikingly, we were unable to obtain transformantsof the sec3- ${Delta}$ N construct in cdc42-6 cells, which we confirmedby meiotic analysis was due to the synthetic lethality of thisallele with cdc42-6. Therefore, when secretory function is compromisedin certain ways, a positive role for the function of the Rhobinding domain of Sec3 is apparent. The synthetic lethalitywith cdc42-6 may indicate that this function is especially importantin the highly polarized membrane growth during bud emergence,when the secretory defect of cdc42-6 is manifested (Adamo et al., 2001).

Sec3 polarization is sensitive to the same perturbations as other exocyst subunits and other polarity markers
A previous study using GFP-tagged Sec3 suggested that the polarizationof this subunit of the exocyst was uniquely and remarkably insensitiveto perturbations in vesicle transport and actomyosin polarity.These observations led to the suggestion that this subunit mayact as a spatial landmark for localization of the exocyst complexand consequently polarization of membrane transport (Finger et al., 1998).In light of our previous results, we reexaminedthe polarization of the native Sec3 protein by using purifiedantibodies raised against recombinant Sec3 (see Materials andmethods). To determine if the localization of Sec3, like otherexocyst components, is sensitive to ongoing secretion, we examinedSec3 immunostaining in mutants defective for ER to Golgi transport(sec21-1 and sec22-3) or for post-Golgi trafficking (sec1-1,sec6-4, sec9-4, and myo2-66). We also examined the localizationof Sec4, Myo2, and Sec15 markers in these strains. As previouslyreported (Walch-Solimena et al., 1997), Sec4 was found to beredistributed in myo2-66 and ER-to-Golgi mutants and to be polarizedin post-Golgi sec mutants after a shift to the restrictive temperature(Fig. 7 and not depicted). Myo2 and Sec15 concentration in thebud was lost in early or late secretion mutants after a 1-hshift to the restrictive temperature (Fig. 6), suggesting thatMyo2 and Sec15 polarized localization is dependent on an activesecretory pathway. These results are consistent with observationsthat suggest that both proteins are associated with post-Golgivesicles (Pruyne et al., 1998; Guo et al., 1999), and thereforetheir polarized localization on the plasma membrane would beexpected to depend on ongoing secretion. In contrast to previousstudies using GFP-Sec3, we find that whereas immunostained,native Sec3 was well polarized in wild-type cells, a completeloss of polarized staining was observed in both early and latesecretion mutants at the restrictive temperature (Fig. 7). Thesedata strongly suggest that, like the other subunits of the exocyst,ongoing secretion is required for the polarization of Sec3.

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Figure 7. A functional secretory pathway is required to polarize the exocyst subunits Sec3 and Sec15 and the myosin Myo2. Sec1-1, sec6-4, and myo2-66 mutants, which are blocked at a late stage in transport, and the early secretion mutant sec22-3 and wild-type cells were grown at 25°C and shifted to 37°C for 1 h, fixed, and processed for fluorescence microscopy. Purified antibodies directed against the Rab protein Sec4, the type V myosin Myo2, and the Sec3 and Sec15 exocyst subunits were used for immunostaining. Bar, 2 µm.

To determine the dependence of native Sec3 polarization on actomyosinfunction, we made use of a temperature-sensitive tropomyosinmutant strain, tpm1-2 (in a tpm2 ${Delta}$ background), which rapidlyloses polarized actin cables after a temperature shift to 34°C.Previous studies have demonstrated that both Sec4 and the exocystsubunit Sec8 rapidly depolarize upon loss of actin cables (Pruyne et al., 1998).In contrast, GFP-tagged Sec3 has recently beenshown to be resistant to the tpm1-2–induced depolarization(Zajac et al., 2005). To determine if native Sec3 behaves similarlyto the Sec3-GFP, we followed its polarization in this strainby immunofluorescence staining at different times after thetemperature shift. We also examined the effects of this mutanton Sec4 and Sec15 polarization. As expected, Sec4 and Sec15were found to rapidly depolarize in the tpm1-2 strain with kineticssimilar to that seen previously by Pruyne et al. (1998) forSec4 and Sec8 in this mutant. However, in contrast to the resultsof Zajac et al. (2005), we find that untagged native Sec3 rapidlydepolarizes in this strain with kinetics that closely matchthat found for Sec15. As expected, all three markers remainedpolarized in the control tpm2 ${Delta}$ strain (Fig. 8). Together withthe aforementioned results, we conclude that the behavior ofnative Sec3 in these experiments is distinct from that of Sec3-GFP,as its polarization appears to require ongoing polarized exocytosisand polarized actin cables as found for the other exocyst subunitsexamined.

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Figure 8. The polarized localization of Sec3, Sec15, and Sec4 is dependent on actin cables. (A) Polarization of Sec3 and Sec4 in tpm1-2, tpm2 ${Delta}$ homozygous diploids and control tpm2 ${Delta}$ diploid cells (with functional TPM1; both gifts of A. Bretscher, Cornell University, Ithaca, NY) was examined by double-label immunofluorescence after temperature shifts to 34°C for the indicated times. Bar, 1 µm. (B) Shift to the restrictive temperature rapidly disrupts the polarization of Sec3, Sec15, and Sec4 in tropomyosin mutant strains. Cells were shifted for the indicated times and immediately fixed. Small budded cells were scored for the polarization of Sec3, Sec15, and Sec4 after immunofluorescent staining. Small budded cells were defined as cells whose buds were less than half the size of the mother cell. 200–300 cells were scored per data point.

The functions of Rho3 and Cdc42 in secretion do not require GTP hydrolysis
The ability of Cdc42 to hydrolyze GTP has been shown to be essentialfor its ability to promote septin ring assembly and polarityestablishment (Gladfelter et al., 2002; Irazoqui et al., 2003).Local cycles of GTP loading and hydrolysis by Cdc42 have beenproposed to be critical for the proper assembly of multisubunitcomplexes and in producing an initial asymmetric patch of Cdc42.Our analysis of the cdc42-6 allele revealed a role for Cdc42in docking and fusion of secretory vesicles that was independentof its other major functions in cell polarity, including polarizationof actin cytoskeleton, septin ring assembly, and polarizationof Cdc42 itself (Adamo et al., 2001). Similar to what we observedpreviously for the rho3-V51 mutant, cdc42-6 cells have a severeexocytic defect but show normal localization of all the markersfor polarized exocytosis. This suggests that the mode of actionfor both Rho GTPases is not in the recruitment of the exocyticmachinery but rather by direct allosteric activation of thismachinery at sites of growth. One prediction of this allostericmechanism is that it would not be expected to require GTP hydrolysisto regulate exocytosis.

We investigated whether the specific roles of Rho3 and Cdc42in exocytosis required cycling between GTP and GDP bound formsusing mutations analogous to the RAS^Q61L allele, which blockthe ability of Rho GTPases to hydrolyze GTP, as well as themutants analogous to RAS^S17N, resulting in a GDP-locked formof the GTPase. We first examined whether a single-copy (CEN)plasmid containing RHO3^Q74L could suppress several secretion-deficientstrains. Although the cold-sensitive Rab GTPase mutant sec4-P48was weakly suppressed by CEN-RHO3, CEN-RHO3^Q74L strongly rescuedgrowth at the restrictive temperature, whereas the RHO3^T30NGDP-locked mutant failed to suppress (Fig. 9 A, i). These resultsare similar to those obtained previously using a different activatingmutation in RHO3 (Adamo et al., 1999). In complementation tests,wild-type and GTP-locked RHO3 alleles were able to equally restoregrowth of rho3-V51 cells at 14°C (Fig. 9 A, ii). CEN-RHO3^Q74Lwas found to be a strong suppressor of the growth defect associatedwith the cdc42-6 mutation at 32°C, and the level of suppressionwas significantly better than CEN-RHO3 (Fig. 9 A, iii). At 37°C,cdc42-6 cells have been shown to be altered for both the actincytoskeleton and secretion (Adamo et al., 2001). We observedthat constitutively activated RHO3 was not able to restore growthof cdc42-6 at 37°C (Fig. 9 A, iii), suggesting a secretion-basedspecificity in suppression. These results show that GTP hydrolysisby Rho3 is not required for its secretory function. RHO3 isknown to have multiple genetic interactions with the exocyticapparatus. Indeed, wild-type RHO3 has the ability to suppressdifferent late-acting sec mutants, and, importantly, the rho3null allele is suppressed by components of the secretion pathwaysuch as SEC4, SRO7, and SEC9 (Adamo et al., 1999). We examinedthe ability of various nucleotide forms of Rho3 to functionas the only source of Rho3 in the cell using a plasmid shuffleassay. Complementation of a rho3 deletion was observed by followinggrowth on 5-FOA–containing media, which selects againsta plasmid containing the wild-type RHO3 gene, leaving the indicatedRHO3 allele as the sole source of Rho3 in the cell. Althoughempty vector shows no growth at 30°C, introduction of CEN-RHO3(Fig. 9 A, iv, middle) or activated CEN-RHO3^Q74L (Fig. 9 A,iv, bottom) fully complemented the growth defect associatedwith loss of chromosomal rho3. Moreover, complementation byRHO3^Q74L was indistinguishable from RHO3 at high (37°C)or low (14°C) temperatures (unpublished data). In contrast,the GDP-locked mutant RHO3^T30N failed to show any complementationactivity. These results demonstrate that all the essential functionsof Rho3 in yeast, including regulation of polarized exocytosis,are fulfilled by a GTPase inactive allele. These data suggestthat GTP hydrolysis and cycling are not critical to the regulatoryfunctions of Rho3, which further supports the notion that Rho3functions primarily through allosteric regulation of its effectors.

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Figure 9. GTP hydrolysis by Rho3 and Cdc42 is not essential for their secretory function. (A, i) sec4-P48 cs phenotype is efficiently suppressed by the activated RHO3^Q74L allele. Wild-type and mutant sec4-P48 strains were transformed with single-copy (CEN) plasmids with the indicated gene, picked into microtiter wells, and transferred onto SC-ura plates at 25 and 14°C. Similar results were obtained on YPD medium. (ii) GTP hydrolysis by Rho3 is not necessary for its function in secretion. Centromeric plasmids containing the wild-type or activated alleles of RHO3 were introduced into the secretion-defective mutant rho3-V51 and wild-type strain. Suppression of cs phenotype was assayed as described for A (i). (iii) Constitutively activated Rho3 is a strong suppressor of the cdc42-6 secretion mutant. RHO3 and RHO3^Q74L centromeric plasmids were transformed into wild-type and cdc42-6 cells. Suppression of the growth defect was tested on YPD media at the restrictive temperatures of 32 and 37°C. (iv) Complementation of the rho3 deletion by activated RHO3^Q74L. A rho3 ${Delta}$ strain containing CEN/URA3/RHO3 plasmid was used in a plasmid shuffle complementation assay. This strain was transformed with an empty CEN/HIS3 plasmid or an identical plasmid containing wild-type RHO3, activated RHO3^Q74L, or the GDP-blocked mutant RHO3^T30N. Transformants were tested for growth on control (SD) plates or 5-FOA plates, which select against the CEN/URA3/RHO3 plasmid, to monitor growth of each strain with the CEN/HIS3 plasmid as the sole source of RHO3 in the cell. Plates were grown for 3 d at 30°C. (B) GTP hydrolysis by Cdc42 is not necessary for suppression of the cdc42-6 secretion defect. GAL1^EG43 plasmid carrying the wild-type or activated (Q61L) allele of CDC42 was integrated into the URA3 locus of the wild-type, cdc42-6, cdc42-17, and cdc42-27 strains. Empty GAL1^EG43 vector was used as a growth control. Colonies from each transformation were picked into microtiter wells and transferred onto YP plates containing either 2% glucose or 2% galactose to repress or induce the EG43 crippled GAL1 promoter, respectively. The cells were then incubated at the permissive temperature (25°C) or at the nonpermissive temperatures (32°C and 37°C) for 2–3 d.

In contrast to Rho3, many of the functions of Cdc42 are knownto require GTP hydrolysis (Irazoqui et al., 2003). To determineif the specific role of Cdc42 in exocytosis requires GTP hydrolysis,we examined the ability of a GTPase-deficient allele to complementgrowth defects associated with various temperature-sensitivemutations in Cdc42. Because high levels of Cdc42^Q61L proteinare known to be lethal to yeast, we made use of a constructthat allows production of sublethal amounts of activated CDC42^Q61Lfrom a crippled version of the GAL1 promoter (Gladfelter et al., 2002).The thermosensitive mutants of cdc42 were transformedwith this construct and then scored for growth under a varietyof conditions. We have shown previously that the cdc42-6 mutantshows a highly allele-specific defect in exocytosis after shiftsto 32°C, but demonstrates pleiotropic polarity defects whenshifted to 37°C (Adamo et al., 2001). We observed that cdc42-6growth and secretion defects at 32°C were rescued when expressionof wild-type CDC42 or CDC42^Q61L was induced on galactose medium(Fig. 9 B; unpublished data). As expected, only wild-type CDC42was able to complement cdc42-6 growth defects at 37°C becausethe phenotype of this mutant at high temperature resembles thatof the pleiotropically defective cdc42-1 allele. Consistentwith a previous paper (Irazoqui et al., 2003), we found thatat the restrictive temperatures GTP-locked Cdc42 was unableto rescue defects in cdc42-17 and cdc42-27 (Fig. 9 B, bottom)or cdc42-1 (not depicted), all of which show general defectsin Cdc42-mediated polarity. Together, these results show thatGTP-locked Cdc42 specifically rescues the highly allele-specificsecretory defect associated with cdc42-6. Hence, both Rho3 andCdc42 do not require GDP/GTP cycles to regulate exocytosis,which is consistent with the allosteric mechanism suggestedby our phenotypic analysis of rho3-V51 and cdc42-6.

Discussion

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Abstract
Introduction
Results
Discussion
Materials and methods
References

We have previously characterized a mutant in the Cdc42 GTPase,which is specifically defective in post-Golgi vesicle dockingand fusion with the plasma membrane but exhibits no detectabledefect in the polarized localization of the exocytic machinery.Based on these results, we suggested that Cdc42 acts as a positiveallosteric regulator of the late secretory apparatus at sitesof polarized growth. Here, we show that another Rho GTPase inyeast, Rho3, acts in a similar manner to positively regulateexocytosis independent of any effect in the polarization ofthe exocytic machinery. Together, these findings suggest a novelmechanism for the action of Rho GTPases in polarized secretion.This new model, depicted in Fig. 10, is distinct from previousmodels in which Rho proteins were thought to act in polarizationof exocytosis by sequestering components of the secretion machineryat a specific site on the plasma membrane (Fig. 10, A and B,top; Guo et al., 2001; Symons and Rusk, 2003). In this model,a polarized patch of activated Rho GTPase would act directlyon the initially unpolarized late secretory machinery (Fig. 10, A and B,bottom). This localized signal would increase theactivity of the machinery and hence the likelihood of a productivesecretory vesicle fusion event at a precise site on the membrane.Because many components of the docking and fusion machinery—includingthe exocyst complex (Guo et al., 1999; Folsch et al., 2003;Vik-Mo et al., 2003), Cdc42, and Rho1 (Abe et al., 2003; Wedlich-Soldner et al., 2003)—havebeen found to associate with secretoryvesicles and other transport intermediates, ongoing allostericregulation would be expected to lead to the polarization ofthe secretion apparatus and to a further increase in allostericactivation. According to this view, the polarization of thesecretory machinery would then be a consequence, rather thana cause, of ongoing polarized delivery of vesicles to the plasmamembrane. Based on this model, the activated Rho GTPases, ratherthan their effectors, would serve as the major spatial landmarksfor polarized secretion.

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Figure 10. Models for the spatial regulation of exocytosis by Rho GTPases. (A) Recruitment model for regulation of exocytosis. A polarized patch of GTP-bound Rho protein would recruit specific components of the exocytic machinery, including the exocyst complex, to a specific site on the plasma membrane. Once polarized, the exocyst complex would act as a spatial landmark for exocytosis, restricting the docking and fusion of post-Golgi vesicles at this site. (B) Allostery model for regulation of exocytosis. A polarized patch of activated Rho GTPase would act directly as a spatial landmark for exocytosis by locally activating the late secretory machinery, including the exocyst complex. This locally activated machinery would increase the likelihood of productive docking and fusion at this site. Many components of the exocytic machinery, including Rho GTPases and exocyst subunits, have been shown to be associated with secretory vesicles. Therefore, increased exocytosis at sites of allosteric activation would lead to both reinforcement of the activation signal as well as polarization of the exocytic machinery.

Previous work on the Sec3 component of the exocyst complex hasled to the hypothesis that the localization of this proteinmight serve as a spatial landmark for polarization of vesicledocking and fusion events on the plasma membrane (Finger et al., 1998).However, in the current study, we found that polarizationof Sec3, through its NH₂-terminal RBD, is dispensable for itsoverall function in the cell, although a positive role for thisdomain was detected in combination with certain other secretorydefective mutants. Indeed, although the NH₂-terminal RBD domainis essential for the polarization of Sec3, localization andfunction of the exocytic machinery is not dependent on Sec3polarization. Our analyses of Sec3 localization using antibodiesto examine the localization of native Sec3 suggest that itspolarization is determined in the same way as the rest of theexocyst complex. This is in strong agreement with our modelfor Rho-dependent polarization of exocytosis. It is not presentlyclear why we see such distinct differences in the polarizationof Sec3 to those seen in the previous studies done primarilywith GFP-tagged forms of the protein. It is possible that eitherthe presence of the GFP tag itself influences the localizationof Sec3 or that our Sec3 antibodies recognize an epitope whoseaccessibility is sensitive to a conformational change in theprotein.

Guo et al. (2001) has suggested that, in the absence of polarizedSec3, the rest of the exocyst complex may be polarized througha parallel pathway involving Exo70. Because Exo70 binds to Rho3,this interaction could represent a redundant pathway for exocystlocalization. We tested this hypothesis directly using an alleleof Rho3 that has been shown to be specifically defective ininteracting with Exo70. We find no evidence for redundancy betweenthe Rho3–Exo70 and Rho1–Sec3 pathways. To excludean indirect effect due to sec3- ${Delta}$ N overexpression, we performedsimilar experiments using a strain producing a wild-type levelof Sec3- ${Delta}$ N protein as the only source of Sec3. Again, no redundancybetween the two pathways was observed (unpublished data). Thus,we find no evidence to suggest that either Sec3 alone or theexocyst as a whole act as spatial landmarks for exocytosis.Rather, we propose that the exocyst polarization is a consequenceof ongoing polarized exocytosis (Fig. 10, A and B, bottom).Sec3 is the only component of the exocyst whose localizationhas been reported to be independent of the secretory pathwayand the actin cytoskeleton (Finger et al., 1998). In yeast,the Sec8 and Sec15 subunits are delivered to the plasma membranethrough the secretory pathway, and the other exocyst subunits,with the exception of Sec3, act similarly (Finger et al., 1998;Guo et al., 1999, Boyd et al., 2004). However, we report herethat the mechanism by which Sec3 becomes polarized appears tobe similar to that of the other exocyst subunits and involvespolarized delivery of vesicles to the plasma membrane. Thus,it is unlikely that additional interactions between Rho GTPasesand the exocyst would be involved in the initial polarizationof this complex, but these signals would serve to regulate theassembled complex at sites of growth.

A prediction of the allostery model is that the function ofRho GTPases in exocytosis would not require GTP hydrolysis,as allosteric regulation is expected to be maximal in the GTP-boundstate (Buck et al., 2004; Peterson et al., 2004). In supportof this model, we found that Rho3 efficiently fulfills its functionin exocytosis when locked in a GTP-bound form, as measured bysuppression of specific late secretory mutants. In fact, theGTPase-deficient mutant can fulfill all the functions of Rho3in the cell because it completely rescues a deletion in thegene in a manner that is genetically and morphologically indistinguishablefrom the wild-type RHO3 gene. In contrast, Cdc42 is known torequire GTP hydrolysis for many of its functions in the cell,including septin ring assembly and early polarization (Gladfelter et al., 2002;Irazoqui et al., 2003). Consistent with this,we and others have found that most cdc42 mutant alleles failto be rescued by a mutant form of Cdc42 unable to hydrolyzeGTP. In contrast, we found that the cdc42-6 allele, which hasa very specific defect in exocytosis, is well complemented bya GTPase-deficient form of Cdc42. These results provide furthersupport for the fact that Rho3 and Cdc42 function in a similarallosteric fashion in the spatial regulation of exocytosis.

Overall, our analysis of the rho3-V51 and cdc42-6 mutants showthat these Rho GTPases regulate secretion independent of theirability to polarize the exocytic machinery and to hydrolyzeGTP. These observations lead us to propose a model in whichRho proteins work as allosteric regulators of the unpolarizedsecretion machinery by activating the fusion of vesicles withthe plasma membrane. As a consequence of this activation, componentsof the secretion machinery, carried on post-Golgi vesicles,would themselves become polarized (Boyd et al., 2004). Thiswould be expected to result in the reinforcement of the polarizationof this process by a positive feedback mechanism. Importantly,this model is applicable to polarization events observed inmammalian cells. In particular, the basolateral membrane recruitmentof the Sec6/8 complex in epithelial cells is known to be a consequenceof cell–cell adhesion. The polarized localization of theSec6/8 complex correlates with, but does not precede, the developmentof polarized transport to the basolateral membrane (Grindstaff et al., 1998).In the developing neuron, the polarized patchesof Sec6/8 observed in the synaptic region disappear upon maturationof the synapse (Hazuka et al., 1999). This phenomenon may simplyreflect a decrease in the delivery of the exocyst componentsto the membrane, as trafficking strongly decreases after maturationof the synapse.

Determining the precise nature of allosteric regulation by Rho3and Cdc42 on the exocytic machinery and the exocyst will becritical to understanding the molecular mechanism by which Rhoproteins regulate polarized secretion. A likely mechanism forallosteric regulation would involve relief of an autoinhibitoryinteraction similar to that found for the effect of Rho GTPasesin regulating the activity of members of the formin family (Zigmond, 2004).By analogy, binding of the Rho3 GTPase to the RBD ofExo70 (for example) would relieve an inhibitory interactionwithin Exo70 or perhaps between Exo70 and another exocyst subunit.The conformational change created by the binding of Rho3 wouldthen promote the ability of this complex to drive downstreamevents through direct effects on SNAREs (Sivaram et al., 2005)or through an intermediary (Lehman et al., 1999). In eithercase, the result would be a direct increase in the rate of vesicledocking and fusion at sites populated by the activated Rho GTPase.

Materials and methods

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Results
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Materials and methods
References

Genetic techniques and yeast strains construction
Standard yeast genetic manipulations were performed as describedby Guthrie and Fink (1991). Cells were grown in complete YPmedia (1% Bacto yeast extract and 2% Bacto peptone containing2% glucose or galactose) or in minimal media (0.67% yeast nitrogenbase without amino acids and 2% glucose) supplemented with appropriatemetabolites. For all assays performed, 25°C was the permissivetemperature, whereas the restrictive temperature of 14 or 32°Cwas used to visualize rho3-V51 and cdc42-6 growth defects, respectively.

To construct the sec3- ${Delta}$ N strain, a region encoding amino acids321–653 of Sec3 was PCR amplified from yeast genomic DNAand cloned into the BamHI and SalI sites of the integrative,HIS3, pRS303 plasmid (Sikorski and Hieter, 1989). A 0.7-kb PCRfragment containing the glyceraldehyde-3-phosphate hehydrogenase3 promoter (GPDp) sequence fused to the first two Sec3 codonswas ligated into the BamHI and NotI sites. Digestion of theresulting plasmid at the unique PmlI site was used to targetintegration into the SEC3 gene, and thus create a modified locusexpressing truncated sec3- ${Delta}$ 3-320 under the dependence of GPDp.The PmlI-linearized plasmid was transformed into a diploid wild-typeyeast strain (a/ ${alpha}$ , ura3-52/ura3-52, leu2-3, 112/leu2-3, 112,his3 ${Delta}$ 200/his3 ${Delta}$ 200), and his⁺ transformants were sporulated. Thetetrads were dissected on complete media, and the haploid progenywere analyzed by replica plating for the presence of wild-type(scored as his^–) or modified (scored as his⁺) SEC3 locus.Correct replacement of wild-type SEC3 locus by GPDp-sec3- ${Delta}$ 3-320was further confirmed by immunoblot analysis using anti-Sec3antibodies directed against the middle region of the protein(aa 279–474).

To assay for the genetic interaction between rho3-V51 and sec3- ${Delta}$ N,an integrative plasmid containing the rho3-V51 allele (Adamo et al., 1999)was first linearized with PstI and integratedinto the URA3 locus of a haploid sec3- ${Delta}$ N strain (a, sec3::HIS3::GPDp-sec3- ${Delta}$ N,ura3-52, leu2-3, 112, his3 ${Delta}$ 200). The resulting strain was thencrossed to rho3-V51 ( ${alpha}$ , ura3::rho3-V51, rho3 ${Delta}$ ::LEU2, leu2-3, 112,his3 ${Delta}$ 200), and the diploid cells were sporulated and dissectedon complete media. Progeny were analyzed for the presence ofGPDp-sec3- ${Delta}$ N (scored as his⁺) and RHO3 deletion (scored as leu⁺)by replica plating and were analyzed for a growth defect at14°C by dilution assays. Sec3 and Sec3- ${Delta}$ N proteins productionwas monitored by immunoblot analysis using anti-Sec3 antibodies.

Wild-type and activated forms of CDC42 expressed from a crippledversion of the GAL1 (EG43) promoter (a gift of J. Irazoqui andD. Lew, Duke University, Durham, NC) were integrated into theURA3 locus of temperature-sensitive cdc42 mutants as previouslydescribed (Gladfelter et al., 2002). Expression was inducedin the presence of galactose and repressed in the presence ofglucose in the medium.

Immunoblot analysis
Western blot analyses were performed on either yeast whole-celllysates, to detect Sec3 and Exo70 proteins, or on internal/externalcellular fractions, to analyze Bgl2 secretion. Blots were probedwith polyclonal ${alpha}$ -Sec3 or ${alpha}$ -Exo70 antibodies at 1:1,000 dilutionor affinity-purified ${alpha}$ -Bgl2 antibody diluted 1:100, dependingon the experiment. Primary antibodies were detected with radiolabeled¹²⁵I-protein A at 1:660 dilution. Quantitation of bands wasdone on a STORM phosphoimager using ImageQuant software (MolecularDynamics).

Invertase and Bgl2 secretion assays
Invertase assays were performed as described previously (Adamo et al., 1999).Exoglucanase Bgl2 secretion was tested essentiallyas described previously (Adamo et al., 1999). In brief, yeaststrains were grown overnight to midlog phase at 25°C inYPD and then either shifted to 14°C for 5 h or kept at 25°C.NaF and NaN₃ were added to a final concentration of 20 mM. 25ODs of cells were washed in Tris/NaF/NaN3 and spheroplasted,and the internal and external fractions were separated and boiledin 2x or 6x sample buffers, respectively. Samples were subjectedto SDS-PAGE, transferred to nitrocellulose, and probed withaffinity-purified ${alpha}$ -Bgl2 antibody.

Immunofluorescence microscopy
Cells were grown overnight to mid-log phase and then eitherfixed immediately with 3.7% formaldehyde or shifted to the restrictivetemperature. Fixed cells were spheroplasted, permeabilized with0.5% SDS, and affixed to the slides as described previously(Brennwald and Novick, 1993). The following primary antibodieswere incubated for 1 h at RT: Sec4 mAb (1:100 dilution), affinity-purifiedpolyclonal Cdc42 (1:75 dilution), Myo2 (1:100 dilution), Sec3(1:50 dilution), or Sec15 (1:100 dilution). The secondary antibodiesused were FITC-conjugated goat anti–mouse at 1:50 dilutionfor detection of Sec4, and rhodamine-conjugated goat anti–rabbitat 1:50 dilution for detection of Cdc42, Myo2, and Sec3 or at1:100 dilution for detection of Sec15 (secondary antibodieswere obtained from Jackson ImmunoResearch Laboratories). Aftera 1-h incubation at RT, the slides were washed extensively andmounting media (90% glycerol with 4', 6-diamidino-2-phenylindoleto visualize DNA and o-phenylenediamine to retard photobleaching)was added. Stained cells were viewed on a microscope (modelE600; Nikon) equipped with a 512 x 512 back illuminated frame-transfercharge coupled device camera (Princeton Instruments) and Metamorphsoftware (Universal Imaging Corp.) to capture images. Pictureswere processed for presentation using Adobe Photoshop.

Intensity of fluorescence associated with polarized immunostainedproteins was measured in small budded cells using Metamorphsoftware. A minimum of 25 distinct spots from wild-type andmutant cells were measured for each experimental condition,and the average and SD values were determined. Result for eachmarker was then expressed as a fluorescence intensity in mutantcells relative to the fluorescence observed in wild type.

Visualization of GFP-tagged exocyst components
GFP experiments were performed on wild-type or mutant cellstransformed with a plasmid containing Sec3, Sec8, or Exo70 fusedto a single GFP molecule at the COOH-terminal extremity (Adamo et al., 2001).Yeast strains were grown overnight in selectivemedia to an early log phase and then either shifted to 14°Cfor 5 h or kept at 25°C. Cells were fixed by a 10-min treatmentin –20°C methanol, washed with acetone at –20°C,and rehydrated by three washes with ice-cold PBS before beingobserved by a fluorescence microscope.

Photobleaching experiments and FRAP analysis
Mid-logarithmic Sec8-GFP cells grown at 32°C in selectivemedia were placed on a slab of selective media supplementedwith 25% gelatin and imaged at RT ( $~$ 22°C). Photobleachingof Sec8-GFP was performed on an inverted microscope (EclipseTE2000-U; Nikon) equipped with a 1.4 NA 100x differential interferencecontrast (DIC) objective. Single focal plane images were capturedby a digital camera (Orca ER; Hamamatsu) using a 400-ms (ms)epifluorescence exposure time (binned 2 x 2) and a 200-ms DICexposure time. Cells were photobleached using the 488-nm linefrom a 100-mW argon laser (Spectra-Physics) controlled by asliding filter cube set (Conix Research). The bud tip signalwas photobleached to $~$ 25% of the prebleach fluorescence intensity.The photobleaching exposure time was 50–175 ms. Duringimage acquisition, one prebleach data point was recorded, followedby eight data points acquired every 5 s, and then five datapoints every 20 s. The total imaging time was $~$ 140 s. AperiodicDIC images were also acquired. FRAP measurements were performedas previously described (Molk et al., 2004).

Online supplemental material
Table S1 details the data obtained from the FRAP analysis withSec8-GFP. Table S2 shows the synthetic genetic effects of combiningthe sec3- ${Delta}$ N mutant with various rho3, cdc42, and late sec mutants.Online supplemental material is available at http://www.jcb.org/cgi/content/full/jcb.200504108/DC1.

Acknowledgments

The authors are grateful to Anthony Bretscher, Javier Irazoqui,and Daniel Lew for the gift of plasmids and yeast strains, ChadPearson for construction of the photobleaching microscope, E.D.Salmon for support, Akanksha Gangar and Anne Andreeva for discussionsand critical reading of the manuscript, and Robert Hales andWill Smith for technical assistance. We also thank members ofthe Pringle and Lew laboratories for stimulating discussions.

This work was supported by National Institutes of Health grantsGM 54712 (P. Brennwald) and GM 32238 (K. Bloom).

Submitted: 19 April 2005

Accepted: 12 July 2005

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Introduction
Results
Discussion
Materials and methods
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