Phosphorylation of the MAPKKK Regulator Ste50p in Saccharomyces cerevisiae: a Casein Kinase I Phosphorylation Site Is Required for Proper Mating Function

The Ste50 protein of Saccharomyces cerevisiae is a regulatorof the Ste11p protein kinase. Ste11p is a member of the MAP3K(or MEKK) family, which is conserved from yeast to mammals.Ste50p is involved in all the signaling pathways that requireSte11p function, yet little is known about the regulation ofSte50p itself. Here, we show that Ste50p is phosphorylated onmultiple serine/threonine residues in vivo. Threonine 42 (T42)is phosphorylated both in vivo and in vitro, and the proteinkinase responsible has been identified as casein kinase I. Replacementof T42 with alanine (T42A) compromises Ste50p function. Thismutation abolishes the ability of overexpressed Ste50p to suppresseither the mating defect of a ste20 ste50 deletion mutant orthe mating defect of a strain with a Ste11p deleted from itssterile-alpha motif domain. Replacement of T42 with a phosphorylation-mimeticaspartic acid residue (T42D) permits wild-type function in allassays of Ste50p function. These results suggest that phosphorylationof T42 of Ste50p is required for proper signaling in the matingresponse. However, this phosphorylation does not seem to havea detectable role in modulating the high-osmolarity glycerolsynthesis pathway.

INTRODUCTION

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Introduction

All eukaryotic cells use a highly conserved mitogen-activatedprotein kinase (MAPK) module as the central core of a varietyof complex signal transduction pathways. These pathways respondto many external stimuli and regulate numerous cellular processes.Each MAPK cascade is typically comprised of three protein kinases:a MAP3K, or MEKK; a MAP2K, or MEK; and a MAPK. These kinasesare activated by sequential phosphorylation (2, 39). Eukaryoticcells typically contain multiple MAPK modules containing uniqueor shared protein kinases that provide the bases for signaltransduction specificity and cross talk between signaling pathways.This regulation in turn may control the pattern of signaling(i.e., transient versus sustained) and/or coordinate multiplebiological processes in response to a variety of environmentalcues (for reviews, see references 6, 9, 14, 27, 29, 42, and48).

The yeast Saccharomyces cerevisiae uses five MAPK cascades torespond to different physiological stimuli. One cascade is requiredfor a/ ${alpha}$ diploid cells undergoing meiosis, and two cascades controlthe developmental processes of mating and filamentation, whiletwo other cascades control the response to environmental osmostress—thehigh-osmolarity glycerol synthesis (HOG) pathway regulates responseto high-osmolarity stress, and the MPK pathway modulates responseto low osmolarity and challenges to cell wall integrity (forreviews, see references 9, 15, 20, 23, 25, 29, and 43). Componentsof these MAPK cascades are shared among different modules, includingthose controlling mating, filamentation, and the HOG pathway(7, 17, 26, 28, 34, 35, 49). Although the extent of sharingof these components varies among different pathways, the commonmodule among the mating, filamentation, and HOG pathways comprisesat least Ste11p (MAP3K) and its two regulators—Ste20pand Ste50p.

Ste20p is the founding member of the PAK/Ste20p kinase family.The activities of these kinases are modulated by small GTPasesof the Rho superfamily. Ste20p is required for the activationof Ste11p and has been shown to phosphorylate Ste11p both invitro and in vivo (8, 18, 51). Ste50p is also implicated inthe regulation of Ste11p activity. Ste50p lacks any currentlyidentified enzymatic function but is involved in all the signalingpathways that require the function of Ste11p. The involvementof Ste50p in the modulation of Ste11p function is dependenton physical interaction of the two proteins through their respectivesterile-alpha motif (SAM) domains (17, 35, 49). This interactionappears to be constitutive; however, modulation of the interactionthrough mutations has been shown to differentially influenceSte11p activity in the different pathways (17). The C-terminalpart of Ste50p is also required for its function, but this activityrequires the presence of an intact SAM domain (49). In contrastto its clear involvement in Ste11p regulation, little is knownabout the regulation of Ste50p itself.

Here, we show that Ste50p is a phosphoprotein that is phosphorylatedat multiple serine/threonine sites in intact cells. We haveidentified one of these sites as amino acid residue threonine42. Casein kinase I (CKI) is capable of phosphorylating thisresidue in vitro. Preventing phosphorylation of threonine 42by its replacement at this site with alanine results in vivoin decreased signaling during the mating response but has nodetectable effect on signaling in the HOG pathway. Replacementof threonine 42 with the phosphomimetic residue aspartic acidpermits the wild-type function of Ste50p in both the matingand HOG pathways. It appears that phosphorylation of Ste50pby casein kinase activity in yeast modulates the function ofSte50p, and this modulation may have different effects in thedifferent pathways that share the Ste11p-Ste50p complex.

MATERIALS AND METHODS

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Materials and Methods

Materials. Restriction endonucleases and DNA-modifying enzymes were obtainedfrom New England Biolabs and Amersham Biosciences. High-fidelityTaq thermostable DNA polymerase and tablet protease inhibitorswere purchased from Roche Molecular Biochemicals. Acid-washedglass beads (450 to 600 µm in diameter), synthetic ${alpha}$ matingfactor, protease inhibitors, and bovine serum albumin were purchasedfrom Sigma. ${alpha}$ mating factor was dissolved in 90% methanol ata concentration of 1.0 mg/ml and stored at -20°C. PlasmidspGEX-4T-3 and pGEX-2TK, glutathione-Sepharose beads, glutathione,and protein A/G-Sepharose beads were obtained from AmershamBiosciences. The antibody against glutathione S-transferase(GST) was described previously (50). The anti-Ste50p antibodieswere raised in rabbits against bacterially expressed, purifiedGST-Ste50p. GST-Ste50 protein fusions were detected using rabbitpolyclonal anti-GST antibodies (49). Rabbit polyclonal antibodiesdirected against Ste5p were described previously (22). Anti-Fus3goat polyclonal antibodies were from Santa Cruz Biotechnology.Nitrocellulose membranes were from Bio-Rad. Horseradish peroxidase-conjugatedsecondary antibodies were from Santa Cruz Biotechnology. Theenhanced chemiluminescence assay system was purchased from AmershamBiosciences.

Yeast strains and manipulations. Yeast media, culture conditions, and manipulations of yeaststrains were as described previoulsy (40). Yeast transformationswith circular or linearized plasmid DNA were carried out aftertreatment of yeast cells with lithium acetate (40). The yeaststrains used in this study are listed in Table 1.

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TABLE 1. Yeast strains used in this study

Plasmid constructions. Yeast expression constructs carrying different fragments ofSTE50 were generated by PCR (41) using appropriate primers andcloned into pYEX-4T2. The starting plasmid for constructingthe STE50 mutants was pVL57 (49). To make Ste50p (1-67), pVL57was digested with EcoRI and BglII, blunt ended with T4 DNA polymerase,and religated to create pCW250. To make Ste50p(99-346), thefragment of STE50 was PCR amplified with primers OCW78 (5'-CGGGATCCATGAGAGACAGCAAGTTG-3'[BamHI site is underlined]) and OCW18 (5'-GGGAATTCTTAGAGTCTTCCACCGGG-3'[EcoRI site is underlined]), digested with BamHI and EcoRI,and cloned into pYEX-4T2 to give rise to pCW206. To make theserine/threonine (S/T)-to-alanine (A) mutations in Ste50p, site-directedmutagenesis by PCR was used with specific mutagenic primer pairsand flanking primers of OCW18 and OCW104: 5'-CGGAATTCATGTCCCCTATACTAGG-3',which annealed to the GST sequence within pVL57. The PCR productswere digested and cloned as BamHI-EcoRI fragments into pYEX-4T2,and mutations were confirmed by DNA sequencing. pCW259 containsthe serine 12-to-alanine mutation (S12A), pCW260 contains S16A,pCW261 contains T24A, pCW262 contains S33A, pCW263 containsS36A, pCW264 contains T42A, pCW265 contains S46A/T47A, and pCW266contains T53A. To make centromere-containing plasmid versionsof the STE50 constructs that express STE50 under its own promoter,the 5'-flanking sequences of STE50 were amplified by PCR fromgenomic DNA with primers OCW87 (5'-TCCCCGCGGGTCCGGTGAAAAGTAT-3'[SpeI site is underlined]) and OCW88 (5'-CGGGATCCTGATTTGCTATCTCTGCTAG-3'[EcoRI site is underlined]). These PCR products were digestedwith BamHI and SpeI and cloned along with the BamHI-EcoRI fragmentof STE50 from pVL57 into the SpeI and EcoRI sites of pRS316.The resulting construct, pCW267, contained an 800-bp 5' flankingsequence of STE50 with an added BamHI site upstream of the STE50coding sequence. The mutant alleles of STE50 were then clonedby exchanging the BamHI-EcoRI fragments from pCW259, pCW260,pCW261, pCW262, pCW263, pCW264, pCW265, and pCW266 with thatof pCW267 to generate pCW276, pCW277, pCW278, pCW279, pCW280,pCW281, pCW282, and pCW283. Plasmid pCW379 expressing Ste50pwith a substitution of aspartic acid for T42 was created ina similar manner. Multiple S/T-to-A mutations were created bymultiple-round site-directed PCR mutagenesis. Several yeastconstructs expressing Ste50p bearing multiple S/T-to-A substitutionsas GST fusions were created: pCW372, with the N-terminal six-S/Tsubstitution by A (6A); pCW373, with the N-terminal eight-S/Tsubstitution by A, except T42 (7A/T42); and pCW401, with theN-terminal eight-S/T substitution by A (8A).

For bacterial expression constructs, pVL56 expressing the full-lengthSte50p in pGEX-2TK was used as the starting construct. PlasmidpCW249 was created to express the N-terminal amino acids (aa)1 to 67 of Ste50p by digesting pVL56 with EcoRI and BglII, bluntending it with T4 DNA polymerase, and religation. Plasmids similarto pCW249, expressing the N-terminal 67 aa of Ste50p, were createdfor all the multiple S/T-to-A mutants. Plasmid pCW360 had thesubstitution of alanine for threonine 42 (T42A), pCW358 hadthe N-terminal five S/T residues replaced with alanine (5A),pCW380 had the N-terminal six S/T residues replaced with alanine(6A), pCW359 had the N-terminal eight S/T residues replacedwith alanine (8A), and pCW381 had the N-terminal eight S/T residuesreplaced with alanine, except T42 (7A/T42).

Preparation of GST fusion proteins from Escherichia coli and yeast. The GST fusion proteins were expressed in E. coli strain UT5600(New England Biolabs), extracted, bound to glutathione-Sepharosebeads, and eluted with glutathione as previously described (51).The eluted proteins were then concentrated and washed with storagebuffer (50 mM Tris-HCl, pH 7.5, 200 mM KCl, 1 mM dithiothreitol,and 10% glycerol) by centrifugation using the Centricon-30 system(Amicon Inc.) and stored at -80°C. For yeast GST fusionexpression constructs, including the yeast ORF protein kinaselibrary, cells were induced with galactose for 5 h with GALpromoter-driven GST fusion vectors (55) or with the additionof 0.5 mM CuSO₄ for 2 h with CUP1 promoter-driven GST fusionvectors. Total cell extracts were prepared as described previously(49). Purification of yeast GST fusion proteins were performedwith yeast extracts and glutathione-Sepharose beads accordingto the procedure described previously for purification of E.coli GST fusion proteins (51). The eluted proteins were washedwith storage buffer, concentrated with the Centricon 30 system,and stored at -80°C.

Protein kinase assays,³²P metabolic labeling, and phosphopeptide mapping. In vitro kinase assays were performed essentially as describedpreviously (51). The reactions were carried out in 30 µlof kinase buffer containing 2 µM [ ${gamma}$ -³²P]ATP ( $~$ 2 x 10⁴ Ci/mol),and the reaction mixtures were incubated at 30°C for 30min. The reaction mixture was resolved by sodium dodecyl sulfate-polyacrylamidegel electrophoresis (SDS-PAGE), and the labeled products werevisualized by either autoradiography or phosphorimaging (MolecularDynamics).

The in vivo metabolic labeling with [³²P]orthophosphate wasperformed with yeast cells (ssk2 ssk22 ${Delta}$ ste50) carrying differentalleles of the STE50 gene as GST fusions under the control ofthe CUP1 promoter. Exponentially growing cells from selectivemedium were inoculated into phosphate-free YPD medium (54) atan optical density at 600 nm (OD₆₀₀) of $~$ 0.2 for 3 h, and coppersulfate was then added to the medium to a final concentrationof 0.5 mM and incubated for 2 h. Approximately 10 OD₆₀₀ unitsof cells were then harvested, resuspended in 5 ml of fresh phosphate-freeYPD medium containing 1.5 mCi of [³²P]orthophosphate (AmershamBiosciences), and incubated for 1 h at 30°C. Yeast totalcell extracts were prepared, and labeled Ste50p was purifiedwith glutathione-Sepharose beads as described for the purificationof GST fusion protein from yeast. Two-dimensional (2-D) trypticphosphopeptide mapping analysis was performed essentially asdescribed previously (3, 12).

Subcellular fractionation of Ste50p-containing protein complexes. Cells expressing GST-Ste50p or GST-Ste50-T42Ap were grown inliquid Ura-dropout medium to late exponential phase. The cultureswere divided into two aliquots, and one aliquot of each wastreated with ${alpha}$ -factor at a final concentration of 3 µMfor 90 min at 30°C. Equivalents of 250 OD₆₀₀ units of cellswere harvested by centrifugation; washed with ice-cold extractionbuffer containing 50 mM HEPES (pH 7.5), 150 mM NaCl, 10% glycerol,1 mM dithiothreitol, 2 mM EDTA, 50 mM NaF, 1 mM phenylmethylsulfonylfluoride, and 1 mM Na₃VO₄ and supplemented with protease inhibitorcocktail tablets (Roche Molecular Biochemicals); and disruptedusing a French press. The homogenates were centrifuged at 6,000x g for 5 min at 4°C to remove cell debris. The supernatantaliquots, corresponding to $~$ 50 OD₂₈₀ units, were loaded on aneight-step (20 to 65% [wt/wt]) sucrose gradient over a 65% (wt/wt)2-ml sucrose pad with each step prepared in 50 mM HEPES, pH7.5, 150 mM NaCl, and 2 mM EDTA. The gradients were centrifugedat 38,000 rpm in an SW41 swinging-bucket rotor (Beckman) at4°C for 12 h. Fractions ( $~$ 0.85 ml) were collected from thetop of the gradient. Proteins from each fraction were precipitatedwith 10% trichloroacetic acid, and the protein pellets werewashed with ice-cold acetone, resuspended in SDS sample buffer,and subjected to immunoblotting analyses.

Yeast mating and other assays. Plate mating tests were carried out as described previously(19). Quantitative mating assays were carried out by a filterassay as described previously (21). ß-Galactosidaseactivities were measured as described previously (19), withMiller units defined as follows: (OD₄₂₀ x 1,000)/(OD₆₀₀ x tx V), where t is the time in minutes and V is the volume inmilliliters. Halo assays to test cell growth inhibition in responseto ${alpha}$ mating factor were performed as described previously (21).

Photomicroscopy. Cells were grown to mid-log phase and fixed with formaldehydeat a final concentration of 3.7% with 150 mM NaCl. The cellswere viewed with a microscope equipped with Nomarski optics,and microscopic photographs were acquired with a 100x objectiveusing a Micro Max camera (Princeton Instruments Inc.) with NorthernEclipse imaging software (Empix Imaging Inc.) and processedusing Adobe Photoshop for Macintosh.

RESULTS

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Results

Ste50p is a phosphoprotein in vivo and is phosphorylated on multiple serine/threonine residues. The functions of many signaling components are regulated throughphosphorylation. Ste50p has been shown to be one of the regulatorsof the MAPKKK Ste11p and is involved in all the signal transductionpathways that need the function of Ste11p (17, 28, 35, 36, 49).To examine if Ste50p is phosphorylated in vivo, yeast cellsexpressing Ste50p as a GST fusion were metabolically labeledwith [³²P]orthophosphate. GST-Ste50p was then purified and analyzedby SDS-PAGE and autoradiography. As shown in Fig. 1, Ste50pwas phosphorylated in vivo. The extent of phosphorylation ofSte50p was not significantly affected by treatment with pheromoneat 5 µM. Tryptic phosphopeptide mapping revealed severallabeled spots, indicating that Ste50p is phosphorylated on multiplesites in vivo, as the GST protein alone is not labeled (8, 33).Phosphoamino acid analysis indicated that the phosphorylationoccurred exclusively on serine/threonine residues (data notshown). Fragmentation of Ste50p showed that both the N terminus(aa 1 to 67) and the C terminus (aa 99 to 346) were labeledin vivo (Fig. 1C). The N terminus of Ste50p contains all nineserine/threonine residues within the core SAM domain (32, 44),and they are located in a single 53-residue tryptic peptide(see Fig. 5C).

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FIG. 1. Ste50p is phosphorylated in vivo. (A) GST-Ste50p was expressed in a ${Delta}$ ste50 strain, metabolically labeled with [³²P]orthophosphate in the presence (+) or absence (-) of 5 µM ${alpha}$ mating factor for 1 h, purified with glutathione-Sepharose, and resolved by SDS-PAGE. (B) Labeled GST-Ste50p from the gel in panel A was digested with trypsin and subjected to 2-D phosphopeptide mapping analysis. TLC, thin-layer chromatography; TLE, thin-layer electrophoresis. (C) Both the N- and C-terminal fragments are phosphorylated in vivo. Constructs expressing the N-terminal (aa 1 to 67) and C-terminal (aa 99 to 346) portions of Ste50p were expressed as GST fusions and analyzed as described for panel A.

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FIG. 5. Protein kinases Yck1p, Gin4p, and Rim11p phosphorylate GST-Ste50p in vitro, and threonine 42 of Ste50p is phosphorylated in vitro by Yck1p. (A) Protein kinases Yck1p, Gin4p, and Rim11p isolated from yeast as GST fusions were tested for the ability to phosphorylate purified GST-Ste50p in vitro. The positions of phosphorylated GST-Ste50p and GST are indicated. +, present. (B) The N-terminal fragment of Ste50p is phosphorylated by Yck1p. The N-terminal and C-terminal fragments of Ste50p were expressed and purified from bacteria and used as substrates in vitro for the protein kinases indicated. The positions of the N-terminal and C-terminal fragments of Ste50p as GST fusions are indicated. (C) Amino acid sequence of the N-terminal fragment of Ste50p. The alanine substitutions are indicated, and the names of the corresponding mutants are indicated on the right. wt, wild type. (D) The N-terminal fragment (aa 1 to 67) of Ste50p with various alanine substitutions was purified from bacteria and used as a substrate in the in vitro kinase assay with Yck1p. The ³²P-labeled GST-Ste50p(1-67) is shown in the autoradiogram above, and the amounts of protein used in the kinase assay are shown as Coomassie staining below. (E) Threonine 42 of Ste50p is not phosphorylated either by Gin4p or Rim11p. GST-Ste50p(1-67)7A/T42 was used as a substrate in the in vitro kinase assays with Yck1p, Gin4p, and Rim11p under the same conditions as for panel D. The autoradiogram (top) and the input protein indicated by Coomassie staining (bottom) are shown.

Threonine 42 is important for Ste50p function in the pheromone response pathway. Given the functional importance (17, 35, 49) of the SAM domain(amino acid residues 32 to 100) and the fact that this regionof Ste50p is phosphorylated in vivo, site-directed mutagenesiswas performed to change all of the S/T residues in the SAM domainto A. To assess the role of the potential phosphorylation site(s),the single S/T-to-A mutants, expressed as GST fusions underthe control of the CUP1 promoter on a 2µm plasmid, werefirst tested for the ability to suppress the mating defect ofa ${Delta}$ ste20 ${Delta}$ ste50 strain.

Both Ste20p and Ste50p are regulators of Ste11p MAPKKK. Deletionof STE50 results in reduced mating, but the cells are far fromsterile, whereas ${Delta}$ ste20 ${Delta}$ ste50 strains are completely sterile.However, overexpression of Ste50p has been shown to partiallysuppress the mating defect of ${Delta}$ ste20 mutants (52), and thus,the ${Delta}$ ste20 ${Delta}$ ste50 strain provides a sensitive assay for Ste50pfunction. We analyzed the S/T-to-A mutants of Ste50p for theability to permit mating in the ${Delta}$ ste20 ${Delta}$ ste50 (YCW350) geneticbackground, since the mating response in this strain dependssolely on the function of Ste50p. As shown in Fig. 2A, the yeaststrain YCW350 ( ${Delta}$ ste20 ${Delta}$ ste50) transformed with only the vectorplasmid showed no detectable mating, whereas overexpressionof wild-type Ste50p, as expected, increases the mating to areadily detectable level. All but one of the S/T-to-A mutantsshowed no significant difference in the ability to confer matingcompetence compared to the level of mating generated by wild-typeSte50p. However, the T42A mutant was significantly impairedin its ability to permit mating in the ${Delta}$ ste20 ${Delta}$ ste50 strain. Incontrast, the T42D mutant allowed mating at a level comparableto that permitted by wild-type Ste50p. The phenotype observedwas not due to different protein concentrations, because thesteady-state levels of both mutant and wild-type Ste50p werevery similar, as judged by Western blot analysis (Fig. 2B).Quantitative mating analysis revealed that the Ste50-T42Ap mutantcaused a >30-fold decrease, compared to wild-type Ste50p,in suppression of the mating defect of the ${Delta}$ ste20 ${Delta}$ ste50 strain(Table 2), while the T42D mutant functioned essentially likewild-type Ste50p. These observations suggest that T42 may needto be phosphorylated for Ste50p to perform its function in themating pathway.

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FIG. 2. Replacement of threonine 42 of Ste50p with alanine abolishes its ability to suppress the ${Delta}$ ste20 defect in mating. (A) Yeast strain YCW350 (MATa ${Delta}$ ste20 ${Delta}$ ste50) was transformed with the various STE50 alleles indicated as GST fusion constructs under the control of the CUP1 promoter and tested for both growth (left) and ability to mate with tester strain DC17 (MAT ${alpha}$ his1) by plate mating assay. The mating was performed for 8 h at 30°C, and diploids were then selected on minimal medium (right). (B) Western blot analysis of the expression of the various Ste50p constructs. Yeast cell extracts from strains used in panel A were prepared, resolved on SDS-PAGE, and probed with an anti-GST antibody ( ${propto}$ GST).

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TABLE 2. Influence of Thr42 of Ste50p on the mating response of yeast with ${Delta}$ ste20 or STE11 ${Delta}$ SAM

Phosphorylation of threonine 42 is required to suppress the mating defect of Ste11 ${Delta}$ SAMp. The SAM domain of Ste11p is required for its proper function,as removal of this motif results in complete loss of Ste11pactivity in the HOG pathway branch and greatly reduces the matingresponse (17, 35, 49). Intriguingly, the mating defect of Ste11 ${Delta}$ SAMpstrains was sensitive to the expression level of Ste11p: thechromosomal-level expression of an integrated allele generatedan extremely low mating level that was close to sterile, whileoverexpression led to an almost complete suppression of themating defect (17, 49). We constructed a strain with an integratedallele of STE11 containing a deletion of aa 26 to 130 withinthe SAM domain (STE11 ${Delta}$ SAM). This strain had a very low levelof mating response and behaved essentially as if it was sterilein plate mating assays. We found that overexpression of Ste50pfrom the CUP1 promoter as a GST fusion protein could partiallysuppress the mating defect of the STE11 ${Delta}$ SAM strain (Fig. 3, secondpanel from left), even though the Ste11 ${Delta}$ SAMp protein has no detectableinteraction with Ste50p (17, 49). This suppression of the matingresponse requires the activity of Ste11 ${Delta}$ SAMp, since overexpressionof Ste50p did not improve the mating of ${Delta}$ ste11 cells (data notshown). However, overexpression of Ste50p was unable to makethe osmosensitive ssk2 ssk22 STE11 ${Delta}$ SAM strain capable of growthon high-osmolarity medium (Fig. 3, third panel from left). Althoughoverexpression of Ste50p resulted in partial suppression ofthe STE11 ${Delta}$ SAM mating defect, it did not allow a detectable pheromone-inducedcell cycle arrest as measured by halo assay or permit eithersignificant induction of a FUS1::LacZ reporter or typical pheromone-inducedmorphogenesis (data not shown).

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FIG. 3. Replacement of threonine 42 of Ste50p with alanine abolishes its ability to suppress the STE11 ${Delta}$ SAM defect in mating. Yeast strain YCW466 (MATa STE11 ${Delta}$ SAM ${Delta}$ ssk2 ${Delta}$ ssk22) was transformed with the STE50 alleles indicated and tested for growth (left), for the ability to mate with tester strain DC17 (MAT ${alpha}$ his1) by selecting for diploids on minimal medium (second panel from left), and for the ability to grow on high-osmolarity medium containing 1.25 M sorbitol (third panel from left). Both the T42A and T42D alleles of Ste50p complement wild-type (WT) Ste50p function to allow strain YCW365 ( ${Delta}$ ste50 ${Delta}$ ssk2 ${Delta}$ ssk22) to grow on high-osmolarity medium containing 1.25 M sorbitol (right). Vec, control vector.

The mechanism of suppression of the Ste11 ${Delta}$ SAMp signaling defectby overexpression of Ste50p is unclear. However, due to itssensitivity, this system was also used to assay the Ste50p mutantsfor the ability to suppress the signaling defect of Ste11 ${Delta}$ SAMp.All the S/T-to-A mutations except T42A were able to suppressthe mating defect of Ste11 ${Delta}$ SAMp to a level identical to thatgenerated by the wild-type Ste50p. However, the T42A mutationalmost completely blocked the ability of Ste50p overproductionto suppress the mating defect of Ste11 ${Delta}$ SAMp (Fig. 3, second panelfrom left; Table 2). In contrast to the T42A substitution, theT42D mutation was able to suppress the Ste11 ${Delta}$ SAMp mating defectjust like the wild-type Ste50p, suggesting that phosphorylationof Ste50p on T42 is required for the suppression function. Likethe wild-type Ste50p, none of the Ste50p S/T-to-A mutants orthe T42D mutant was able to suppress the Ste11 ${Delta}$ SAMp signalingdefect in the HOG pathway, although they all complemented Ste50pfunction in the ssk2 ssk22 ${Delta}$ ste50 strain and permitted growthon high-osmolarity media (Fig. 3, right panel). This is consistentwith previous observations that the interaction between Ste11pand Ste50p through their respective SAM domains is absolutelyrequired for HOG pathway function (17, 35, 49).

Threonine 42 preferentially regulates the function of Ste50p in the pheromone response pathway. We next assessed the role of the potential regulatory phosphorylationsite threonine 42 in functional-complementation assays. Forthese experiments, the T42A, T42D, and wild-type versions ofSte50p were expressed under the control of the STE50 promoteron a centromere (CEN) plasmid and tested for the ability tocomplement ${Delta}$ ste50 in both the pheromone response and the HOGpathways. We found that the T42A mutant showed a defect in pheromoneresponse as measured by FUS1::LacZ induction. Figure 4B showsthat the Ste50-T42Ap mutant was less responsive than the wild-typeprotein, as indicated by the dose-response curve for FUS1::LacZinduction. In addition, the mating efficiency decreased $~$ 10-foldcompared to the wild type. (Mating efficiencies were as follows:STE50, 13.8 ± 1.05; STE50-T42A, 1.70 ± 0.20; STE50-T42D,18.0 ± 0.34; vector, <0.1 ± 0.05. The strainused was YCW315 [MAT a ${Delta}$ ste50::TRP1] transformed with the STE50alleles mentioned above. All STE50 alleles were carried on theCEN plasmid and expressed under the control of its own promoter.The mating efficiency is the number of diploids formed withthe MAT ${alpha}$ tester strain DC17 cells divided by the number of plasmid-containingMATa cells in the mating mixture at the beginning of the experimentmultiplied by 100. The data given are expressed as the averagesof three repetitions ± standard deviations.) However,replacement of Thr42 with the phosphomimetic aspartic acid residuecreated no discernible phenotype, suggesting that phosphorylationof Thr42 is involved in the proper functioning of Ste50p. Thephenotypes observed were not due to differences in protein concentrations,because the steady-state levels of both mutant and wild-typeSte50p proteins were very similar, as judged by Western blotanalysis (Fig. 4C).

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FIG. 4. Phosphorylation of threonine 42 of Ste50p is required for the proper pheromone response. Yeast strain YCW393 (MATa ${Delta}$ ste50::TRP1 FUS1::LacZ::LEU2 sst1::hisG) was transformed with STE50 alleles expressed from its own promoter on a CEN plasmid or with a control vector. Exponentially growing cells were treated with the indicated concentrations of ${alpha}$ mating factor ( ${alpha}$ F) for 4 h. (A and B) Cell morphology was monitored by microscopy (A), and mating-specific transcriptional activation was measured by ß-galactosidase assays (B) as described in Materials and Methods. Each data point represents the average of triplicates ± standard deviation. (C) The steady-state level of Ste50p protein before induction was analyzed by Western blotting with an anti-Ste50p ( ${propto}$ Ste50p) polyclonal antibody. The arrowheads indicate Ste50p; the lower band is likely to be a degradation product.

Threonine 42 is phosphorylated by CKI in vitro. To identify the kinase that is responsible for the phosphorylationof Thr42 of Ste50p, we first identified the protein kinase(s)that could phosphorylate Ste50p in vitro. Ste50p was expressedand purified as a GST fusion protein from E. coli and used asa substrate in a kinase assay screen with a yeast kinase library(see Materials and Methods). The protein kinases from the librarywere purified from yeast as pools of eight kinases. The positivepools were then deconvoluted to identify candidate kinases.This in vitro kinase screening identified Yck1p, Gin4p, andRim11p as kinases capable of phosphorylating Ste50p in vitro(Fig. 5A). Further analysis showed that Yck1p phosphorylatedboth the N-terminal portion (aa 1 to 67) and the C-terminalportion (aa 99 to 346) of Ste50p, whereas Gin4p phosphorylatedonly the C-terminal portion. Rim11p phosphorylated both theN- and C-terminal fragments of Ste50p but gave a relativelyweak signal on the N terminus of the protein (Fig. 5B). Theseresults identified Yck1p and/or Rim11p as a candidate kinasefor the phosphorylation of Thr42 of Ste50p. Sequence analysisindicated that Thr42 matches well with the canonical consensussequence (D/E)_n-X-X-S/T (where D/E is aspartic acid or glutamicacid, S/T is serine or threonine, X is any amino acid residue,and n = 1 to 3) for CKI phosphorylation (reference 45 and referencestherein). To determine if Thr42 of Ste50p is phosphorylatedby Yck1p in vitro, the aa 1 to 67 fragment of Ste50p, whichcontains all the S/T residues in the SAM domain (Fig. 5C), wassubcloned from the various mutants. These fragments were expressed,purified from E. coli, and used as substrates in the in vitrokinase assays with Yck1p. The results of the kinase assays aresummarized in Fig. 5D. The fragment aa 1 to 67 of wild-typeSte50p was phosphorylated extensively by Yck1p, indicating thatit is a good in vitro substrate for the kinase. In contrast,the phosphorylation was totally abolished when the first eightS/T residues in this fragment were mutated to alanine residues(8A), indicating that the Yck1p phosphorylation site(s) is amongthe first eight S/T residues. The 8A construct also served asa negative control for the kinase assay to show that Yck1p doesnot phosphorylate the GST part of the fusion protein. In contrast,the Ste50p fragment with all of the first eight S/T residuesexcept Thr42 mutated to alanine residues (7A/T42) was a goodsubstrate for Yck1p, indicating that the Thr42 residue of Ste50prepresents a good Yck1p phosphorylation site in vitro. To checkif Thr42 was the sole Yck1p phosphorylation site, the Ste50pfragment (aa 1 to 67) with only the T42A mutation was used inthe kinase assay. The Ste50(1-67)T42Ap fragment was efficientlyphosphorylated by Yck1p, indicating that Thr42 is not the soleYck1p phosphorylation site in this region of Ste50p. Other Yck1pin vitro phosphorylation sites are limited to the first fiveS/T residues, since the Ste50(1-67)p fragment with the firstsix S/T residues (including Thr42) mutated to alanine was notphosphorylated by Yck1p. Neither Gin4p nor Rim11p phosphorylatedthe T42 site of Ste50 in vitro using Ste50(1-67)7A/T42p as asubstrate (Fig. 5E), indicating that T42 is phosphorylated specificallyby Yck1p in vitro, although there is still the possibility thatRim11p phosphorylates other S/T sites within the first 67 aaof Ste50p.

Although the screen identified only Yck1p as a Ste50p in vitrokinase, three other casein kinase isomers (Yck2p, Yck3p, andHrr25p) exist in S. cerevisiae. We asked whether these othercasein kinase isomers could also phosphorylate Ste50p in vitro.Yck2p and Hrr25 (Yck3p was found not to be expressed in thelibrary) were individually purified from the yeast expressionlibrary and used in the kinase assay and were found to effectivelyphosphorylate both the full-length GST-Ste50p and the N-terminalregion (aa 1 to 67) of Ste50p in vitro. These kinases also phosphorylatedGST-Ste50(1-67)7A/T42p, but not GST-Ste50(1-67)8Ap, in vitro(data not shown).

Ste50p is phosphorylated on threonine 42 in vivo. To confirm that Thr42 was phosphorylated in vivo, the 8A and7A/T42 mutants, as well as the wild-type Ste50p, were expressedas GST fusion proteins in a yeast strain with STE50 deletedand then subjected to [³²P]orthophosphate metabolic labeling.The labeled Ste50p was purified, resolved by SDS-PAGE (Fig.6A), and analyzed by tryptic phosphopeptide mapping. As shownin Fig. 6B, a single phosphopeptide that was observed on themaps of both the wild-type and the 7A/T42 mutant was absentfrom the map of the 8A mutant. Since the only difference betweenthe 8A and 7A/T42 mutants was that Thr42 in the 7A/T42 mutantwas replaced by a nonphosphorylatable alanine in the 8A mutant,Thr42 of Ste50p was the only residue responsible for the appearanceof the phosphopeptide that was absent in the map obtained fromthe 8A mutant. This result strongly suggests that Thr42 of Ste50pwas phosphorylated in vivo, most likely by a CKI isomer.

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FIG. 6. Ste50p is phosphorylated on threonine 42 in vivo. Ste50p wild type (WT) and the 7A/T42 and 8A mutants were expressed as GST fusion proteins and metabolically labeled with [³²P]orthophosphate and purified with glutathione-Sepharose beads. (A) The labeled Ste50p was resolved on SDS-PAGE; the arrowheads indicate GST-Ste50p. (B) The bands corresponding to Ste50p in panel A were excised, digested with trypsin, and subjected to 2-D phosphopeptide mapping. The arrows indicate the positions of a phosphopeptide which is present in the maps of both wild-type Ste50p and the 7A/T42 mutant but absent from the map of the 8A mutant.

T42D does not bypass the requirement for CKI activity for efficient mating. The above-mentioned data show that Thr42 is phosphorylated byCKI and that the Ste50p T42A mutant is unable to suppress themating defect of strains with STE11 ${Delta}$ SAM, suggesting that phosphorylationof Ste50p on Thr42 is required for the suppression effect. Todetermine if the phosphomimetic mutant (T42D) of Ste50p is ableto bypass the requirement for yeast CKI activity in this process,we constructed a yeast strain with the genotype STE11 ${Delta}$ SAM ssk1 ${Delta}$ yck1 ${Delta}$ yck2^ts. This strain (YCW1151) was temperature sensitivefor growth at 37°C and had a nearly sterile phenotype atroom temperature, as judged by plate mating assays; SSK1 wasalso deleted to make the strain hyperosmotically sensitive,which can be useful for other assays. This strain was transformedwith the overexpression constructs STE50, STE50-T42A, and STE50-T42D,as well as a control vector, and the transformants were testedfor their mating responses. As expected, both wild-type Ste50pand T42D suppressed the mating defect of the strain at 25°C,whereas the T42A mutant, like the control vector, failed todo so. At the nonpermissive temperature (37°C), the T42Dmutant should be able to mate if phosphorylation of Ste50p Thr42by YCK activity was the only requirement for the suppressionof the mating defect of STE11 ${Delta}$ SAM. However, we found that Ste50-T42Dpwas unable to give rise to a detectable level of mating, asjudged by the plate mating assay (Fig. 7). This result is consistentwith the observation that CKI activities are involved in multiplephysiological processes, including mating (5, 16), some of whichare collectively essential in S. cerevisiae (38, 47).

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FIG. 7. Replacement of T42 of Ste50p with aspartic acid does not bypass the requirement for Yck1p and/or Yck2p to suppress the mating defect of STE11 ${Delta}$ SAM. Yeast YCW1151 (MATa ura3 leu2 his3 ${Delta}$ ssk1::KanR yck1 yck2 [supi]ts STE11 ${Delta}$ SAM) was transformed with various STE50 alleles (described in Fig. 3) and control plasmid (Vec) as indicated. The cells were tested for the ability to mate both at 25 (room temperature [RT]) and 37°C with the tester strain DC16 (MATa his1). For mating at 37°C, both the tester and the strain to be tested were preincubated for 2 h before the two strains were mixed to start the mating process at the same temperature for five more hours and then selected for diploids on a minimal medium plate. For mating at 25°C, the mating was allowed to proceed for 5 h at 25°C, and diploids were then selected at 37°C. WT, wild type.

The T42A mutation alters the subcellular fractionation profile of Ste50p. Since T42 is located within the N-terminal SAM domain core,we used a GST resin pull-down assay to examine whether the observeddefect in the mating response was due to altered interactionof Ste50-T42Ap with Ste11p. To this end, the wild-type, T42A,and T42D versions of Ste50p expressed as GST fusion proteins,together with a control vector, were cotransformed with Myc-taggedSte11p (49). The GST fusion proteins were purified on glutathione-Sepharosebeads, and the presence of Ste11p was analyzed by Western blottingusing an anti-Myc antibody (9E10). As shown in Fig. 8A, therewas no significant difference in the amount of Myc-tagged Ste11pbrought down by the wild type or the Thr42 mutants (either T42Aor T42D) of Ste50p. This suggests that phosphorylation of Thr42does not play a major role in modulating the interaction ofSte50p with Ste11p.

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FIG. 8. The T42A mutation retained the ability to interact with Ste11p but altered the subcellular fractionation profile of Ste50p. (A) T42A of Ste50p does not alter the association between Ste50p and Ste11p. Yeast strain YCW315 (MATa ${Delta}$ ste50::TRP1) was cotransformed with pCW199 (Myc-tagged Ste11p) (49) and various STE50 alleles as GST fusions as indicated. Total cell extracts were prepared from $~$ 10⁹ exponentially growing cells and incubated with glutathione-Sepharose beads (GSB). The beads were washed, and bound proteins were analyzed by immunoblotting them with an anti-Myc ( ${propto}$ Myc) (9E10) monoclonal antibody for the presence of Ste11p (top) and an anti-GST ( ${propto}$ GST) antibody for GST-Ste50p (middle). The presence of Myc-Ste11p in all the samples at similar levels before GSB pull-down is shown in the bottom blot, which represents $~$ 1/10 of the cell extract used in the pull-down experiment. (B to D) Total cell extracts from YCW315 expressing ether GST-Ste50p or GST-Ste50-T42Ap were fractionated on sucrose gradients. Proteins from each fraction were subjected to immunoblot analyses with the indicated antibodies.

However, signaling protein complexes usually involve multipleinteractions among their components, so we asked whether themutation had any influence on the formation of Ste50p-containingprotein complexes in vivo. We fractionated cell extracts usingsucrose velocity gradients and analyzed the protein distributionsby immunoblotting. Comparative analysis of the fractionationprofiles showed that the distribution of GST-Ste50-T42Ap wassignificantly different from that of the GST-Ste50 protein.Fractionation of the cell extracts prepared from asynchronouslygrowing cells revealed that both GST-Ste50p and GST-Ste50-T42Apwere found in the light pool near the top of the gradient butthat only the wild-type protein was found with heavy proteincomplexes at the bottom of the gradient (Fig. 8B). These differencesbecame even more apparent when we analyzed the distributionof the GST-Ste50p-containing protein complexes prepared frompheromone-treated cells. Pheromone treatment resulted in moreof the wild-type Ste50p pool shifting to the bottom of the densitygradient. In contrast, pheromone treatment did not efficientlyrecruit the mutant Ste50-T42Ap to these heavy protein complexes;the majority of the T42A substituted protein remained at thetop of the gradient (Fig. 8C). We also examined the distributionsof both Ste5p and Fus3p from pheromone-treated cell extractsin the density gradient. As shown in Fig. 8D, this heavy fractionincludes much of the Fus3p and essentially all of the Ste5p.These changes in the cosedimentation profiles suggest that themutant Ste50p may be ineffectively associated with pheromonesignaling complexes.

DISCUSSION

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Discussion

MAP3K nodes are important for the regulation of MAPK modules.One of the best-studied MAP3K proteins is Ste11p, which is sharedby several signaling pathways in the yeast S. cerevisiae (24,28, 34). Ste50p is an important regulator of Ste11p function(17, 35, 36, 49). Despite this regulatory role played by Ste50pin the MAPK cascades that share Ste11p, little is known aboutthe regulation of Ste50p itself. In an attempt to gain someinsight into the role that phosphorylation may play in modulatingthe function of Ste50p, we established by 2-D tryptic phosphopeptidemapping analysis that Ste50p is phosphorylated on multiple serine/threonineresidues in vivo. One of these sites of phosphorylation is atarget for CKI activity, and this site plays a role in the regulationof Ste50p function.

Using a yeast protein kinase library (55), we identified severalprotein kinases, including Yck1p, that can phosphorylate GST-Ste50pin vitro. It is evident that our screen may not have identifiedall possible protein kinases that could phosphorylate GST-Ste50pin vitro for two reasons: first, not all the protein kinasesare present or expressed in the library; second, expressionof multiple kinase clones as a pool may lead to the loss orunderrepresentation of those clones that grow slowly. For example,Yck3p was not found in the library, and while Yck2p and Hrr25pwere present in the library and were active as individual proteins,they were not picked up in the first round of the in vitro kinasescreen using the pools of eight kinases. Nevertheless, thisgenomewide screen provides an approach to identify candidatekinases for a specific substrate in the absence of genetic orbiological information.

We focused our study on the N-terminal portion of Ste50p, sinceit contains the functionally important and relatively well-studiedSAM domain (17, 32, 35, 36, 49). The in vitro kinase assay establishedthat Thr42 of Ste50p was phosphorylated by CKI. Although initiallyonly Yck1p was identified as a relevant kinase, further analysisusing other purified CKI isomers (Yck2p and Hrr25p) indicatedthat all yeast CKI isomers tested were able to phosphorylateGST-Ste50p in vitro. It is not surprising that CKI isomers lackspecificity in the in vitro assay. It is believed that regulationof the specificity of this family of kinases is controlled inpart by their spatial localization and proximity to substrates(13). Thus, more detailed in vivo studies in which both spatialorganization and temporal regulation of CKI activity is maintainedwill be necessary to address the question of which YckI isomer(s)is responsible for the phosphorylation of T42 of Ste50p in vivo.However, it is perhaps significant that Yck1p and/or Yck2p islocalized to the plasma membrane, where the mating responsesignals are initiated.

The CKI family of protein kinases is a group of highly related,ubiquitously expressed serine/threonine kinases found in alleukaryotic organisms from protozoa to mammals. With a wide subcellulardistribution that includes the plasma-organelle membranes, thecytoplasm, and the nucleus, CKI family members have been implicatedin diverse roles that control critical physiological processes,such as Wnt signaling, circadian rhythms, DNA repair, and nuclearimport (31, 45, 56). There are at least seven CKI isomers thathave been characterized in mammals (13, 45). Recently, it hasbeen elegantly shown that CKI ${alpha}$ , in concert with the glycogensynthase kinase-3 protein kinase, is responsible for the hyperphosphorylationof ß-catenin, which is required to target ß-cateninfor degradation in the Wnt signaling pathway. CKI is requiredfor the "priming" phosphorylation event (1, 53). CKI has alsobeen shown to phosphorylate the NF-AT4 transcription factorto mask its nuclear import signal and thus regulate its subcellularlocalization (56).

The yeast S. cerevisiae has four CKI gene homologues: HRR25and YCK3 are an essential pair that are involved in processessuch as DNA repair and protein vesicle transport (47), whereasthe YCK1 and YCK2 genes, which provide all the plasma membraneCKI activity, comprise another pair encoding an essential function(38). Yck1p and Yck2p have been shown to associate with theplasma membrane, to localize to sites of polarized growth, andto act in morphogenesis and septin organization (37, 38). Ithas been shown that yeast Yck1p and Yck2p are responsible forthe phosphorylation of plasma membrane-localized proteins, includingthe H⁺-ATPase (10) and the ${alpha}$ -factor receptor, Ste2p (16). Thephosphorylation of Ste2p provides the signal for ubiquitinationand internalization of the receptor (16). Yeast cells containingSte2p variants that have C-terminal phosphorylation sites mutatedshow mating response defects, such as increased sensitivityto ${alpha}$ -factor and moderately decreased mating efficiency (5). Similarly,the signal for ubiquitination and subsequent internalizationof Ste3p, the a-factor receptor, is also mediated by Yck1p/Yck2pphosphorylation within the PEST-like sequence of the receptor.In this case, however, the phosphorylation is constitutive andindependent of ligand binding (11, 30). Overexpression of Yck1phas also been reported to interfere with pheromone-induced cellcycle arrest in wild-type yeast cells (4).

It appears that residue Thr42 of Ste50p needs to be phosphorylatedfor a proper mating response, since the T42A mutation causesa defect in mating. The defect is not likely due merely to astructural change, since T42D-containing proteins behave indistinguishablyfrom wild-type proteins. Furthermore, in yeast strain YCW365( ${Delta}$ ssk2 ${Delta}$ ssk22 ${Delta}$ ste50), both the T42A and T42D alleles complementSte50p function in the HOG pathway in a manner indistinguishablefrom that of the wild type, suggesting that the interactionbetween Ste11p and Ste50p is not affected. This notion is supportedby the fact that both the T42A and T42D versions of Ste50p canpull down Ste11p as well as the wild-type protein does. Theresidue Thr42 of Ste50p is located in the first helix of theSAM domain in the alignment with the structure of the Eph receptorSAM domain (43). Although the residue at this position is nothighly conserved at the primary sequence level, many SAM domainsfrom a variety of organisms have an acidic glutamic or asparticacid residue at the Thr42-equivalent position (44). Interestingly,T42A, but not T42D, is severely defective in its ability tosuppress the mating defect of Ste11 ${Delta}$ SAMp, which has no detectableinteraction with Ste50p (17, 35, 49), suggesting that phosphorylationof Ste50p at T42 may be required to maintain or amplify a weakmating signal generated from the crippled Ste11p kinase. Thereis no suppression observed with a ste11 null mutation throughoverexpression of Ste50p, suggesting that the suppression isnot taking place at a step downstream of Ste11p.

Our subcellular-fractionation results suggest that Ste50-T42Aphas an altered ability to form heavy protein complexes comparedto the wild-type protein (Fig. 8). Such alteration may resultin less Ste50-T42Ap localizing to the pheromone signaling proteincore complex and thus lead to inefficient signaling. Overall,it appears that phosphorylation of residue Thr42 is importantfor the function of Ste50p in the mating response pathway, butintriguingly, the role of Ste50p in the HOG pathway does notappear to be influenced by the phosphorylation state of T42.This suggests that although the role of Ste50p is to serve asa coactivator of Ste11p in both pathways, posttranslationalmodifications of the protein can alter its relative effectivenessin one pathway or the other. Although our metabolic-labelingresult indicated that the general phosphorylation of Ste50pdid not seem to be affected by pheromone treatment and appearedto be constitutive, we cannot rule out the possibility thatsome phosphorylation site(s) may be dynamically regulated. Becausethe Yck1 and Yck2 proteins exhibit localization to sites ofpolarized growth that overlap with the observed localizationof proteins like Ste20p, it is possible that the modulationof Ste50p function through casein kinase phosphorylation ofThr42 acts to fine tune the activation of Ste11p in the matingpathway. Yck1p and Yck2p also phosphorylate pheromone receptorsand signal their internalization, which is necessary for propermating functions, such as orientation or reorientation of matingprojections (16, 46). Although the low level of expression ofendogenous Ste50p and Ste11p has precluded their direct cellularlocalization, they function as parts of complexes that are localizedto mating projections.

Sharing components among different MAPK cascades is a commonphenomenon in eukaryotes. Although our understanding of whythis architecture has evolved and how these shared componentsare differentially regulated is far from clear, it is generallyaccepted that cells use the sharing of MAPK cascade componentsto coordinate physiological processes among different pathways.It is conceivable that fine tuning of the signal distributionof the shared components is required for the differential regulationof specific pathways. In this case, the Ste50p function in themating pathway may be fine tuned by yeast CKI-directed phosphorylation.

ACKNOWLEDGMENTS

We thank H. Zhu and M. Snyder for the yeast kinase library andL. Robinson for strains.

G.J. was the recipient of a Deutsche Forschungsgemeinschaftpostdoctoral fellowship and an NRC/NSERC postdoctoral fellowship.M.Z. was the recipient of an NRC/NSERC postdoctoral fellowship.This work was supported by the NRC/GHI and by grants from theCancer Research Society to S.M. and MOP 85769 to D.Y.T. andM.W.

FOOTNOTES

* Corresponding author. Mailing address: Genetics Group, Biotechnology Research Institute, National Research Council of Canada, 6100 Royalmount Ave., Montreal, Quebec, Canada H4P 2R2. Phone: (514) 496-6202. Fax: (514) 496-6213. E-mail: cunle.wu{at}cnrc-nrc.gc.ca.

¹ This is publication number 46158 of the National Research Councilof Canada.

Present address: CuraGen Corporation, 20 Commercial St., Branford,CT 06405.

REFERENCES

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