Cyclin-dependent kinase–mediated phosphorylation of the exocyst subunit Exo84 in late G1 phase suppresses exocytic secretion and cell growth in yeast

In eukaryotic cells, the growth rate is strictly regulated for proper progression of the cell cycle. In the budding yeast Saccharomyces cerevisiae, it was previously shown that cell growth dramatically slows down when the cells start budding at the G1/S transition. However, the molecular mechanism for this G1/S-associated growth arrest is unclear. In this study, using exocytic secretion, cyclin-dependent kinase (CDK) assay, immunoprecipitation, and microscopy, we demonstrate that the exocyst subunit Exo84, which is known to be phosphorylated in mitosis, can also be phosphorylated directly by Cdk1 in the late G1 phase. Of note, we found that the Cdk1-mediated Exo84 phosphorylation impairs exocytic secretion in the late G1 phase. Using conditional cdc mutants and phosphodeficient and phosphomimetic exo84 mutants, we further observed that Cdk1-phosphoryated Exo84 inhibits the exocyst complex assembly, exocytic secretion, and cell growth, which may be important for proper execution of the G1/S-phase transition before commitment to a complete cell cycle. Our results suggest that the direct Cdk1-mediated regulation of the exocyst complex critically contributes to the coordination of cell growth and cell cycle progression.

The growth rate of eukaryotic cells is tightly controlled at each stage of the cell cycle for accurate reproduction and size homeostasis (1)(2)(3)(4). A reduction of growth speed at the late G 1 phase was seen in mammalian cells (5), which is thought to help cells adapt to the increased energy demands for subsequent cell cycle processes (6). Similarly, cell growth of fission yeast also decreases during late G 1 (7)(8)(9). In budding yeast, cell polarity is established by G 1 cyclin/cyclin-dependent kinase (CDK) 3 complexes, and the cell growth rate is drastically reduced at late G 1 phase (10 -13).
It was reported that exocytosis is involved in cell growth during cell cycle progression (14,15), and cell surface expansion is completed through polarized exocytosis in which post-Golgi secretory vesicles carrying proteins and membranes are docked to the growth site of plasma membrane and then fused with each other (16). The exocyst complex, consisting of Sec3, Sec5, Sec6, Sec8, Sec10, Sec15, Exo70, and Exo84, is essential for polarized exocytic secretion and cell surface expansion in eukaryotic cells (17)(18)(19)(20)(21)(22). The dynamic assembly and disassembly of the octameric protein complex link the post-Golgi secretory vesicles to the plasma membrane in a process called "tethering" in the late stage of the exocytosis process (17,21,(23)(24)(25)(26)(27). The exocyst subunits have been shown to be direct targets of small GTPases and protein kinases that spatially or temporally regulate exocytosis for many physiological processes such as polarized cell growth, epithelium formation, neuronal branching, and cell migration (17, 18, 20, 28 -31). However, little is known about how exocytosis is coordinated with cell growth arrest during cell cycle progression.
The CDKs are master regulators of the cell cycle and play central roles in growth control during cell cycle progression (2,6,32). Goranov et al. (11) showed that cells arrested at the time of late G 1 phase or in metaphase exhibited lower growth rates, and Cdk1 activity negatively regulated cell growth. We have shown that Exo84 is phosphorylated by Clb2-Cdk1, which disrupts exocyst assembly, inhibits exocytic secretion, and arrests cell growth at metaphase (33). However, whether Exo84 is also phosphorylated by Cdk1 in late G 1 and contributes to cell growth arrest is unknown. In this study, we demonstrate that Cdk1 is a regulator of exocytosis at late G 1 phase during cell cycle progression in the budding yeast Saccharomyces cerevisiae. When bound to the late G 1 cyclin Cln2, Cdk1 inhibits exocytosis before the G 1 /S transition by direct phosphorylation of the exocyst component Exo84. Cdk1-mediated phosphorylation of Exo84 disrupts the assembly of the exocyst complex in late G 1 phase, thereby blocking exocytosis. Our study provides a molecular mechanism by which exocytosis and cell growth are controlled during cell cycle progression.

Exocytic secretion is inhibited at late G 1 phase
We have reported that cell growth and exocytic secretion are reduced at metaphase (33). To examine whether exocytosis is also regulated in late G 1 phase, we monitored the secretion of an endo-␤-1,3-glucanase, Bgl2, a cell wall-remodeling enzyme and a commonly used exocytosis marker, in cdc34-2 and cdc53-1 mutants. Cdc34 and Cdc53 are two catalytic subunits of Skp1/Cul1/F-box (SCF) ubiquitin-protein ligase complex that regulates cell cycle progression by targeting key substrates for degradation and is required for the G 1 /S transition (34). When transferred to restrictive temperature (37°C), cdc34-2 and cdc53-1 cells arrest in late G 1 phase with high Cln1/2-Cdk1 activity (35)(36)(37). As shown in Fig. 1, A and B, the internal Bgl2 levels were elevated in cdc34-2 and cdc53-1 mutant cells but not in WT cells, indicating that Bgl2 secretion was inhibited in these two mutants. This result is consistent with the observation that cell growth is largely reduced in late G 1 phase (11). In addition to the Bgl2 secretion assay, we also examined the secretion of the cdc mutants using invertase, which marks a smaller branch of the exocytic routes (38). As expected, neither cdc34-2 nor cdc53-1 mutant cells had invertase secretion block (Fig. 1C). This result is consistent with previous observation that exocytic secretion of invertase is not compromised during cell cycle progression (33,39).
Because Cdk1 plays a central role in cell cycle progression, we speculated that Cdk1 may regulate the reduction of exocytic secretion in late G 1 cells. To test this prediction, we assayed Bgl2 secretion in cdc34-2 cells that contain an analog-sensitive cdk1 allele (cdk1-as1), which encodes a mutant kinase that is specifically inhibited by 1NM-PP1 (40). We arrested cdc34-2 cdk1-as1 double-mutant cells in late G 1 phase by shifting to 37°C for 90 min and then added 1NM-PP1 to inhibit Cdk1. Within 15 min of 1NM-PP1 addition, the intracellular fraction of Bgl2 decreased significantly compared with DMSO-treated cells (Fig. 1, D and E). These data suggest that Cdk1 activity is critical for blocking exocytosis at late G 1 phase. Alternatively, it is possible that Cdk1 inhibition alleviates the secretion defect by allowing late G 1 -arrested cdc34-2 cells to enter S phase.
Secretory vesicles often accumulate in cells defective in exocytic secretion. Thus, we examined cdc34-2 cells via thin-section electron microscopy (EM) for secretory vesicle accumula-  A, conditional cdc34-2 mutants exhibit Bgl2 secretion defects at the restrictive temperature. Internal ("In") and external ("Ex") pools of Bgl2 in WT, cdc34-2 (late G 1 phase), and cdc53-1 (late G 1 phase) cells were examined by Western blot analysis. Cells were grown at 25°C or shifted to 37°C for 2 h. Alcohol dehydrogenase (Adh1) levels were probed as a protein loading control. The conditional mutants and cell cycle arrest points are listed to the right. B, quantification of Bgl2 accumulation in A. n ϭ 3. *, p Ͻ 0.01. C, Cdk1 is required for the reduction in Bgl2 secretion in metaphase-arrested cdc34-2 cells. cdc34-2 and cdc34-2 cdk1-as1 cells were grown to early log phase at 25°C and shifted to 37°C for 1.5 h. Cells were then treated with DMSO (mock) or 15 M 1NM-PP1 for 30 min. Internal and external pools of Bgl2 in cdc34-2 and cdc34-2 cdk1-as1 cells were examined by Western blotting. Corresponding immunoblots of alcohol dehydrogenase serve as a protein loading control. D, quantification of Bgl2 accumulation in C. n ϭ 3; *, p Ͻ 0.01. E, invertase secretion was not changed in cdc34-2 and cdc28-4 mutants. Cells were grown at 25°C or shifted to 37°C for 1.5 h, and secretion of invertase was examined. The percentage of external invertase (secreted) versus total invertase was measured. Error bars represent S.D. (n ϭ 3). AU, arbitrary unit.

Exo84 suppresses exocytic secretion in late G 1 phase
tion. Cells were grown at 25°C to early log phase and then shifted to 37°C for 90 min. Secretory vesicles were barely detectable in WT cells (Fig. 2, A and B). In contrast, there was clear accumulation of vesicles (179 Ϯ 28 vesicles per section) in late G 1 -arrested cdc34-2 cells. The size of the accumulated vesicles (80 -100 nm in diameter) was characteristic of post-Golgi secretory vesicles (41). These data suggest that exocytosis is blocked in late G 1 -arrested cells and are consistent with previous findings that yeast cell growth is inhibited when cells start to bud (11).

Exo84 is phosphorylated directly by Cdk1 in late G 1 phase
It has been shown that the exocyst subunit Exo84 can be phosphorylated by Clb2-Cdk1 at mitosis during cell cycle progression (33). However, previous data also indicate that Exo84 may also be a direct substrate of Cln2-Cdk1 in late G 1 (33,42). To confirm this result in vivo, we immunoprecipitated Exo84 from yeast and probed for Cdk1 phosphorylation using an antibody specific for Cdk1-phosphorylated peptides (Cell Signaling Technology, catalog number 2325) in cdc34-2 mutant arrested at late G 1 phase at 37°C. As shown in Fig. 3, A and B, phosphorylation of Exo84 in cdc34-2 mutant was similar to that in WT cells at 25°C. At 37°C, however, phosphorylation of Exo84 in cdc34-2 mutant was about 3 times more than that in WT cells. To confirm that Exo84 is a direct substrate of Cdk1 in late G 1 phase, GST-tagged Exo84 was expressed and purified from Escherichia coli and incubated with Cln2-Cdk1 or Clb5-Cdk1 in the presence of [␥-32 P]ATP. As shown in Fig. 3C, purified GST was not phosphorylated by any Cdk1 complexes, whereas GST-Exo84 was phosphorylated by Cln2-Cdk1 but not Clb5-Cdk1. This is consistent with previous reports (33,42).
To confirm that in vitro phosphorylation occurs on Cdk1 consensus sites, we mutated the five confirmed phosphorylation sites of Exo84 (Thr 28 , Ser 31 , Ser 291 , Ser 482 , and Ser 716 ) to nonphosphorylatable alanine residues and used the resultant "Exo84-A" protein as substrate for in vitro Cdk1 kinase assays. Exo84 Thr 28 , Ser 31 , Ser 291 , Ser 482 , and Ser 716 were selected because previous MS analysis established that those residues were phosphorylated in vivo (43)(44)(45). As expected, Cln2-Cdk phosphorylation of Exo84-A was greatly diminished compared with unmutated Exo84 (Fig. 3D). Collectively, these data indicate that Exo84 is a substrate of Cln-Cdk1 and are consistent

Exo84 suppresses exocytic secretion in late G 1 phase
with the emerging model that Cdk1 inhibits exocytosis in late G 1 phase.

Exocyst assembly is inhibited in late G 1 phase
Cdk1 activity has been reported to inhibit exocyst assembly, leading to reduction of exocytic secretion (15,33). To determine whether the assembly of the exocyst complex is inhibited in late G 1 phase, in which the Cdk1-Cln2 is most active, we immunoprecipitated Exo84 from WT cells and cdc34-2 mutant cells arrested in late G 1 phase at 37°C and probed for associated exocyst components by Western blotting. As shown in Fig. 4, A and B, Exo84 bound less to Sec6, Sec10, and Sec15 in late G 1 phase-arrested cells than those in WT cells, suggesting that exocyst assembly is blocked in late G 1 phase. Our previous data also showed that the treatment of the cdk1-as cells with 1NM-PP1 led to an increase of Exo84 binding to other exocyst subunits (33). Taken together, these data suggest that Cdk1 activity in late G 1 phase blocks exocyst assembly.

Exo84 phosphorylation is required for secretion reduction in cdc34-2 mutant cells
To more closely examine the effect of nonphosphorylatable Exo84 (Exo84-A) on exocytic secretion, we generated strains in which the Exo84 phosphomutant was expressed in the cdc34-2 mutant background. As shown in Fig. 5, A and B, the Bgl2 secretion defect was significantly reduced in cdc34-2 exo84-A double-mutant cells compared with the cdc34-2 single mutant, indicating that phosphorylation-deficient Exo84-A expression partially rescues the cdc34-2 secretion defect. These results suggest that Exo84 phosphorylation by Cdk1 is required for secretion reduction in late G 1 phase.

Exo84 phosphorylation inhibits cell growth and polarization of Sec4 in sec3 mutant cells
Exocytic secretion defects often lead to inhibition of cell growth. However, our previous data showed that the growth of exo84-A and exo84-E mutant cells were only slightly changed compared with WT cells (33). To determine whether phosphorylation of Exo84 by Cdk1 affects cell growth, we examined the growth rate of the sec3⌬ strain carrying either exo84-A or exo84-E mutant. Sec3 is the only nonessential gene among exocyst subunits, and it was reported that the sec3⌬ strain is deficient in apical growth at the beginning of the cell cycle and is unable to generate pointed projections when cells were arrested in late G 1 phase (46). To explore the role of Exo84 phosphorylation in cell growth and cell cycle progression, the original copy of Exo84 in sec3⌬ strain was replaced with a plasmid carrying either exo84-A or exo84-E mutant gene, and the cell growth of these mutant cells was examined using serial dilution experiments. As shown in Fig. 6A, exo84-A can rescue the growth of sec3⌬ mutant at 25°C, whereas exo84-E was synthetically lethal with sec3⌬ mutant. A similar result was also observed for the sec3-2 temperature-sensitive mutant strain at restrictive temperature. We found that exo84-A can rescue the growth of sec3-2 at 37°C, whereas exo84-E was synthetically lethal with sec3-2 (Fig. 6B). These results indicate that phosphorylation of Exo84 inhibits cell growth.
Sec4 is a marker protein of post-Golgi secretory vesicles (26,46). Using Sec4 as a marker, we next examined whether phosphorylation of Exo84 regulates targeting of secretory vesicles to the bud tip in cells lacking SEC3. Sec4 is normally concentrated in a small spot at the bud tip (46, 47). As shown in Fig. 7, sec3⌬

Exo84 suppresses exocytic secretion in late G 1 phase
cells showed a much broader distribution of Sec4 than WT cells as expected (46), whereas the distribution area of Sec4 in sec3⌬ was reduced by exo84-A. Our finding demonstrates that phosphorylation of Exo84 negatively regulates the spatial regulation of secretion in sec3⌬ strains. Considering that Sec3 is required for apical growth at the beginning of the cell cycle (46), these data suggest that phosphorylation of Exo84 by Cdk1 plays an important role in G 1 /S transition during cell cycle progression.

Discussion
Membrane growth and surface expansion of eukaryotic cells are tightly controlled during cell cycle progression and mainly rely on the tight regulation of polarized exocytic secretion, by which proteins and lipids from post-Golgi are incorporated into the plasma membrane. Although several aspects of the cell cycle such as DNA replication and chromosomal segregation have been intensively studied, the molecular mechanisms controlling cell membrane growth are still unclear (3,6). An important feature of late G 1 phase before the G 1 /S transition of budding yeast cells is growth reduction, which is critical to control the cell size and to help dividing cells adapt to the energy demands required for cell cycle progression (6, 7, 9, 11, 16, 48 -53).
Cell growth and morphogenesis have been carefully investigated in budding yeast for each stage of the cell cycle, providing solid evidence for the coordination of the cell cycle and membrane growth mechanisms by Cdk1 (11, 54). It has been shown that budding yeast cells arrested in early G 1 phase grow faster than those in other stages, whereas cells arrested in late G 1 phase right before G 1 /S transition and metaphase grow slower than those in other stages (11, 55). Although we have shown that phosphorylation of Exo84 by Cdk1 is required for growth reduction and secretion at metaphase (33), whether it is involved in the growth inhibition in late G 1 phase is unknown. In this study, we confirmed that Exo84 is a direct substrate of Cln-Cdk1 in late G 1 phase, and phosphorylation of Exo84 inhibits exocyst assembly and exocytic secretion, which may contribute to G 1 /S transition during cell cycle progression.
It has been reported that cell membrane growth depends on exocytic secretion (11, 55). But how exocytic secretion is coordinated with cell cycle progression is unclear. We have found that the exocyst complex subunit Exo84 is a direct substrate of Clb2-Cdk1 in mitosis stage (33). Phosphorylation of Exo84 disrupts exocyst assembly, which leads to a secretion defect and cell growth arrest at metaphase. Previous data suggest that Exo84 can be phosphorylated by Cln2-Cdk1 and Clb2-Cdk1 in vitro at late G 1 phase and mitosis phase, respectively (33,42), which coincides with the cell growth reduction when cells start budding or entering mitosis stage. Because phosphorylation of

Exo84 suppresses exocytic secretion in late G 1 phase
Exo84 plays a critical role in cell growth arrest at metaphase, we hypothesized that it may also be involved in cell growth reduction when cells start to bud, that is the late G 1 phase before G 1 /S transition. We showed that Cln-Cdk1 phosphorylates Exo84 in vivo and in vitro, and phosphorylation site-mutated exo84 mutant cannot be phosphorylated by Cln2-Cdk1 in vitro, confirming the prediction that Exo84 is a direct substrate of Cdk1 in late G 1 phase. It would be very interesting to determine which CDK consensus site(s) play a critical role for Exo84 phosphorylation. However, we found that mutation of any one of these five sites (T 28 P, S 31 PAK, S 291 P, S 482 PNK, and S 716 P) did not affect the phosphorylation of Exo84 in vitro (Fig. S1). In our study, we tested five consensus Cdk1 sites in Exo84, but it also contains three additional putative full-consensus Cdk1 sites (T 22 PAK, T 474 PGR, and T 496 PGR), although these sites were not confirmed by MS. These three putative full-consensus sites may compensate the phosphorylation of Exo84 when one of the five sites tested in this study is mutated. In addition, previous studies have shown that CDKs can phosphorylate proteins at sites lacking the proline ϩ1 of consensus CDK target sites (56 -58), and mutating all or most of the consensus CDK phosphorylation sites on a single substrate such as Swe1 (58), Slk19 (59), Cdc24 (12), Boi1 (54), and Rga2 (60) had no significant consequences. Taken together, it seems that other consensus Cdk1 sites or nonconsensus Cdk1 sites can compensate the Exo84 phosphorylation by Cdk1 when one Cdk1 site is mutated.
Similar to the phosphorylation at metaphase, phosphorylation of Exo84 in late G 1 phase disrupts exocyst assembly (Fig. 4), which further leads to the reduction of exocytic secretion and cell growth (Figs. 5-7). To investigate whether phosphorylation of Exo84 is involved in cell growth arrest in late G 1 phase and affects G 1 /S transition, we compared the distribution of Sec4, the exocytic vesicle marker protein, in the bud tip of WT, sec3⌬, and sec3⌬ exo84-A cells arrested at late G 1 and found that distribution area of Sec4 in sec3⌬ bud tip was reduced by exo84-A (Fig. 7), indicating that phosphorylation of Exo84 negatively regulates the spatial secretion in the sec3⌬ strain.
At present, Exo84 is the only protein in the exocytic secretory pathway found to be regulated directly by Cdk1. Although Sec3 was able to be phosphorylated by Cdk1 in vitro (61), we found

Exo84 suppresses exocytic secretion in late G 1 phase
that Sec3 cannot be phosphorylated by Cdk1 in vivo. 4 The result that Exo84 phosphorylation by Cdk1 in late G 1 and metaphase negatively regulates exocytic secretion correlates with the fact that cell growth are arrested in these two stages (6). These data support a model in which phosphorylation of Exo84 by Cdk1 negatively regulates cell membrane growth in late G 1 and early mitosis during cell cycle progression in budding yeast. As the exocyst complex is evolutionarily conserved in eukaryotic cells, we speculate that this mechanism also operates in other eukaryotes, and it would be interesting to investigate whether Exo84 is phosphorylated in mammalian cells arrested in late G 1 and metaphase and whether Exo84 dephosphorylation and subsequent exocyst assembly/activation contribute to the plasma membrane expansion that has been observed during cell cycle progression (9,16). Our study demonstrates how cell cycle progression and membrane trafficking are coordinated and provides a molecular mechanism for cell growth inhibition in late G 1 phase.

Yeast strains, plasmids, and procedures
Standard methods were used for yeast growth and genetic manipulations as described previously (62). All strains used in this study are listed in Tables S1. Yeast transformation was performed based on the lithium acetate method (63).
Yeast strains containing mutations of the CDK consensus sites (as described in Table S1) were constructed as follows. The balancer plasmid pG279, which contains Exo84 ORF in p416TEF (URA3, CEN) plasmid (64), was transformed into the parental yeast strain, and chromosomal Exo84 was then replaced by KanMX6 according to the procedure described previously (65) and confirmed by PCR. The CEN plasmid containing WT EXO84, exo84-A, or exo84-E under control of the endogenous EXO84 promoter and terminator was transformed into this strain. The yeast transformants were counterselected for pG279 in medium containing 1 mg/ml 5-fluoroorotic acid. All plasmids used in this study are listed in Tables S2. The CDK sites in Exo84 were mutated using a multimutagenesis kit (Stratagene).

Whole-cell extract preparation
Yeast extracts were prepared by using glass beads and vortexing as described previously (66). The hot-SDS protein extraction protocol was used with slight modification (67). 50 A 600 units of yeast cells were collected by centrifugation, washed once with water, and then suspended in 1000 l of cold distilled water followed by the addition of 1000 l of 0.2 M NaOH. Samples were mixed and incubated for 5 min at room temperature. Cells were collected by centrifugation, resuspended in 1000 l of SDS sample buffer (0.06 M Tris-HCl, pH 8.6, 5% glycerol, 1% SDS, and 10 mM ␤-mercaptoethanol), and boiled for 5 min. Samples were centrifuged, and protein concentrations were determined using the DC protein assay kit (Bio-Rad).

Exo84 suppresses exocytic secretion in late G 1 phase Secretion assays
Analyses of the secretion of Bgl2 and invertase were carried out as described previously (68). 20 ml of yeast cells were grown to early log phase (A 600 of 0.6 -1.0) at 25°C. NaN 3 and NaF were added directly to the culture at a final concentration of 10 mM each. 10 A 600 units of cells were collected and washed with cell wash buffer (20 mM Tris-HCl, pH 7.5, 10 mM NaN 3 , and 10 mM NaF). The cells were resuspended in 300 l of spheroplast solution buffer (50 mM Tris-HCl, pH 7.5, 1.4 M sorbitol, 10 mM NaN 3 , 10 mM NaF, 30 mM 2-mercaptoethanol, and 0.2 mg/ml Zymolyase) and incubated at 37°C in a water bath for 30 min. The spheroplasts were pelleted gently by centrifugation at 2000 rpm for 5 min at 4°C. 100 l of supernatant were carefully transferred to a new tube and mixed with 20 l of 6ϫ SDS loading buffer (300 mM Tris-HCl, pH 6.8, 600 mM DTT, 12% SDS, 0.6% bromphenol blue, and 60% glycerol). This is the external pool. The remaining supernatant was removed, and the pellet (spheroplasts) was washed once with 1 ml of spheroplast wash buffer (50 mM Tris-HCl, pH 7.5, 1.4 M sorbitol, 10 mM NaN 3 , and 10 mM NaF) to remove residue external pool. The spheroplasts were dissolved in 300 l of lysate buffer (20 mM Tris-HCl, pH 7.5, 100 mM NaCl, 2 mM MgCl 2 , 0.5% Triton X-100, and 1ϫ protease inhibitor mixture (Roche Applied Science)) by leaving on ice for 10 min. The cell debris was removed after the sample was centrifuged at 13,000 rpm for 5 min at 4°C. 100 l of supernatant (lysates) were transferred to a new tube and mixed with 20 l of 6ϫ SDS loading buffer. This is the internal pool. The internal pool and external pool samples were boiled at 95°C for 5 min and loaded for 12% SDS-PAGE. Bgl2 was detected by Western blotting with an anti-Bgl2 rabbit polyclonal antibody (1:2000). For temperature-sensitive mutants, the cells were grown at 25°C or shifted to 37°C for 90 min before being processed for the Bgl2 assay.
Invertase secretion was examined as described previously (41). 20 ml of yeast cells were grown to early log phase (A 600 of 0.6 -1.0) at 25°C. 1 A 600 unit if cells was transferred to a new tube and washed with 1 ml of ice-cold 1 mM NaN 3 . The cells were then resuspended in 1 ml of YP plus glucose medium (1% Bacto yeast extract, 2% Bacto peptone, and 0.1% glucose) and incubated at 25°C for 1 h to induce invertase expression. After 1 h of incubation, the cells were collected and washed once with 1 ml of 10 mM NaN 3 . The cells were resuspended in 1 ml of 10 mM NaN 3 and kept on ice. The external invertase was measured directly on the whole intact cells, whereas the internal invertase was measured after preparation of lysates. 0.5 ml of cells was removed and mixed with 0.5 ml of 2ϫ spheroplast mixture (2.8 M sorbitol, 0.1 M Tris-HCl, pH 7.5, 10 mM NaN 3 , 0.4% 2-mercaptoethanol, and 10 g/ml Zymolyase-100T). The cells were incubated in a water bath at 37°C for 45 min. The spheroplasts were collected, and the supernatant was removed carefully without disturbing the pellet. The spheroplasts were dissolved at 4°C in 0.5 ml of 0.5% Triton X-100. The invertase assay was performed in 13 ϫ 100-mm test tubes. 20 l of sample were placed in the tube, and 80 l of 50 mM sodium acetate, pH 5.1, were added. Then 25 l of 0.5 M sucrose were added, and the tube was incubated at 37°C for 30 min. 150 l of 0.2 M K 2 HPO 4 were added, and the tube was placed on ice to stop the reaction.
The sample was boiled for 3 min and put on ice. 1 ml of assay mixture was added (0.1 M KP i buffer, pH 7.0, 10 units/ml glucose oxidase, 2.5 g/ml peroxidase, 150 g/ml o-dianisidine, and 20 M N-ethylmaleimide), and the sample was incubated at 37°C for 30 min. 1 ml of 6 N HCl was added into the tube, and the value of A 540 was measured by a spectrophotometer (Smart-Spec 3000, Bio-Rad). For temperature-sensitive mutants, the cells were grown at 25°C or shifted to 37°C for 90 min and then grown in low-glucose medium (0.1% glucose) at the same temperature for 1 h.

Immunoprecipitation and detection of Exo84 phosphorylation
For immunoprecipitation of Exo84-myc and Exo84, total proteins were extracted by using a glass-bead method (66). A mouse anti-myc antibody (9E10) or rabbit anti-Exo84 antibody was used for immunoprecipitation as described below. Typically, 50 A 600 units of a mid-log-phase yeast culture were harvested, and total protein was extracted using the NaOH-SDS method (67). Cell lysates were used for immunoprecipitation using protein G beads and anti-myc antibody (9E10) in immunoprecipitation buffer (50 mM Tris-HCl, pH 7.5, 150 mM NaCl, 1 mM EDTA, 1 mM EGTA, 10% glycerol, 1ϫ protease inhibitor (Roche Applied Science), and 1ϫ phosphatase inhibitor I (Roche Applied Science)) at 4°C for 4 h with rotation. Beads were washed with washing buffer (50 mM Tris-HCl, pH 7.5, 150 mM NaCl, 1 mM EDTA, 1 mM EGTA, and 10% glycerol) three times. The beads were mixed with 30 l of 1ϫ SDS loading buffer and incubated at 95°C for 5 min. Protein samples were then cooled on ice for several minutes and separated by 10% SDS-PAGE. Western blotting was performed using the phospho-CDK substrate antibody (catalog number 2325, Cell Signaling Technology) and anti-Exo84 antibody as described previously (33).

In vitro Cdk1 kinase assays
50-l reactions were prepared in kinase assay buffer (50 mM HEPES, pH 7.5, 2 mM MgCl 2 , 0.05% Tween 20, 2.5% glycerol, 1 mM DTT, and 1 mM ATP) containing 7 nM Cln2-Cdk1 or Clb5-Cdk1, 1 g of GST or 2 g of GST-Exo84 fusion protein, and 10 Ci of [␥-32 P]ATP. Reactions were incubated at room temperature for 60 min and terminated by the addition of 10 l of 6ϫ sample buffer. Samples were boiled for 5 min and resolved by 10% SDS-PAGE. The gel was stained with Coomassie Blue and dried on a filter paper, and 32 P radioactive signal was analyzed by a phosphorimaging system (Storm 860 molecular imager).

Microscopy
Fluorescence microscopy was conducted with a Leica CTR6000 fluorescence microscope equipped with a Plan Apo 100ϫ, 1.40 oil immersion objective. Images were taken using LAS AF 1.5.1 acquisition software. For EM, cells were collected by vacuum filtration using a 0.45-m nitrocellulose membrane and fixed for 1 h at room temperature in 0.1 M cacodylate, pH 7.4, 3% formaldehyde, 1 mM MgCl 2 , and 1 mM CaCl 2 . The cells were spheroplasted and fixed with 1% glutaraldehyde (in PBS, pH 7.4) at 4°C overnight. The spheroplasts were washed in 0.1 M cacodylate buffer and postfixed twice with ice-cold 0.5%

Exo84 suppresses exocytic secretion in late G 1 phase
OsO 4 and 0.8% potassium for 10 min each. After dehydration and embedding in Spurr's epoxy resin (Polysciences, Inc.), thin sections were cut and transferred onto 600 mesh uncoated copper grids (Ernest F. Fullam, Inc.) and poststained with uranyl acetate and lead citrate. Cells were observed on a transmission electron microscope (Model 1010, JEOL) at 100,000ϫ magnification.