Yeast Mpk1 Mitogen-Activated Protein Kinase Activates Transcription through Swi4/Swi6 by a Noncatalytic Mechanism That Requires Upstream Signal

The cell wall integrity mitogen-activated protein kinase (MAPK)cascade of Saccharomyces cerevisiae drives changes in gene expressionin response to cell wall stress. We show that the MAPK of thispathway (Mpk1) and its pseudokinase paralog (Mlp1) use a noncatalyticmechanism to activate transcription of the FKS2 gene. Transcriptionalactivation of FKS2 was dependent on the Swi4/Swi6 (SBF) transcriptionfactor and on an activating signal to Mpk1 but not on proteinkinase activity. Activated (phosphorylated) Mpk1 and Mlp1 weredetected in a complex with Swi4 and Swi6 at the FKS2 promoter.Mpk1 association with Swi4 in vivo required phosphorylationof Mpk1. Promoter association of Mpk1 and the Swi4 DNA-bindingsubunit of SBF were codependent but did not require Swi6, indicatingthat the MAPK confers DNA-binding ability to Swi4. Based onthese data, we propose a model in which phosphorylated Mpk1or Mlp1 forms a dimeric complex with Swi4 that is competentto associate with the FKS2 promoter. This complex then recruitsSwi6 to activate transcription. Finally, we show that humanERK5, a functional ortholog of Mpk1, is similarly capable ofdriving FKS2 expression in the absence of protein kinase activity,suggesting that this mammalian MAPK may also have a noncatalyticfunction in vivo.

INTRODUCTION

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INTRODUCTION

The cell wall of the budding yeast Saccharomyces cerevisiaeis required to maintain cell shape and integrity (13, 41). Thecell must remodel this rigid structure during vegetative growthand during pheromone-induced morphogenesis. Wall remodelingis monitored and regulated by the cell wall integrity (CWI)signaling pathway controlled by the Rho1p GTPase (reviewed inreference 43). Two essential functions have been identifiedfor Rho1p. First, it serves as an integral regulatory subunitof the 1,3-β-glucan synthase (GS) complex stimulating GSactivity in a GTP-dependent manner. A second essential functionof Rho1 is to bind and activate protein kinase C, which is encodedby PKC1. Loss of Pkc1 function or of any of the components ofthe mitogen-activated protein kinase (MAPK) cascade under itscontrol results in a cell lysis defect that is attributableto a deficiency in cell wall construction. The MAPK cascadeis a linear pathway comprised of a MEKK (Bck1), a pair of redundantMEKs (Mkk1/2), and a MAPK (Mpk1/Slt2). Mpk1 is a functionalhomolog of human ERK5 (65), a MAPK that is activated in responseto growth factors as well as physical and chemical stresses(1, 68).

CWI signaling is induced in response to a variety of cell wallstressors. First, signaling is activated persistently in responseto growth at elevated temperatures (e.g., 37 to 39°C) (37),consistent with the finding that null mutants in many of thepathway components display cell lysis defects only when cultivatedat high temperatures. Second, hypo-osmotic shock induces a rapidbut transient activation of signaling (16, 37). Third, treatmentwith mating pheromone stimulates signaling at a time that iscoincident with the onset of morphogenesis (12). Finally, CWIsignaling is also stimulated by agents that interfere with cellwall biogenesis, such as the chitin antagonist calcofluor white(39), Congo red, caffeine, or zymolyase (18, 47).

One consequence of CWI signaling is activation of the Rlm1 transcriptionfactor (19, 67) through phosphorylation by Mpk1 (35). Rlm1 regulatesthe transcription of a wide array of cell wall metabolism genes(23, 36, 55). However, the FKS2 gene, which encodes one of twoalternative catalytic subunits of the GS complex, is an unusualtranscriptional target of CWI signaling because it is inducedindependently of Rlm1 (36, 70).

A second transcription factor that plays a poorly defined rolein CWI signaling is SBF (7, 44), a dimeric G₁ regulator comprisedof Swi4 and Swi6 (reviewed in reference 11). Swi4 is the sequence-specificDNA binding subunit (64), but Swi6 is required for DNA binding(4, 6, 58). SBF is essential to normal regulation of G₁-specifictranscription, but genetic and biochemical evidence suggeststhat SBF also participates in CWI signaling as a target of Mpk1.First, the cell lysis defect of an mpk1 ${Delta}$ mutant is suppressedby overexpression of Swi4 (44). Second, both swi4 ${Delta}$ and swi6 ${Delta}$ mutantsare hypersensitive to calcofluor white, supporting a role forSBF in cell wall biogenesis (33). Third, Mpk1 associates withSBF in vivo, as judged by coprecipitation experiments (44),and with Swi4 (but not Swi6) in vitro (7). Fourth, Swi6 is phosphorylatedin vivo and in vitro by Mpk1 in response to cell wall stress(44).

Here, we find that CWI signaling drives expression of the FKS2gene through SBF. Although Mpk1 must be in the active (phosphorylated)conformation to induce FKS2 expression, its protein kinase activityis not required. Indeed, the pseudokinase paralog of Mpk1, Mlp1(for Mpk-like protein), is also capable of inducing FKS2 expression.This novel noncatalytic function involves stable associationof Mpk1 or Mlp1 with SBF at the FKS2 promoter. Transcriptionalactivity of FKS2 has been conserved in mammalian ERK5, suggestingthat this MAPK may also have noncatalytic functions in metazoancells.

MATERIALS AND METHODS

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MATERIALS AND METHODS

Strains, growth conditions, and transformations. The S. cerevisiae strains used in this study are listed in Table1. Yeast cultures were grown in YEPD medium (1% Bacto yeastextract, 2% Bacto peptone, 2% glucose) with or without 10% sorbitol,or in SD medium (0.67% yeast nitrogen base, 2% glucose) supplementedwith the appropriate nutrients to select for plasmids and genereplacements. Escherichia coli DH5 ${alpha}$ was used to propagate allplasmids. E. coli cells were cultured in Luria broth medium(1% Bacto tryptone, 0.5% Bacto yeast extract, 1% NaCl) and transformedto carbenicillin resistance by standard methods. Two-hybridtests were conducted using yeast strain SFY526 (Clontech Laboratories)in cultures grown to mid-log phase. β-Galactosidase assaysfor promoter-lacZ fusion expression experiments and for two-hybridanalyses were conducted as described previously (70).

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TABLE 1. S. cerevisiae strains

Plasmids. Plasmids used in this study are listed in Table 2. A plasmidconsisting of FKS2 residues –540 to –375 [FSK2(–540to –375)]-CYC1-lacZ (plasmid p2052) was constructed byreplacing the 134-bp SmaI/XhoI fragment of the CYC1 promoterof pLG ${Delta}$ -312 (26) with a 165-bp PCR-amplified FKS2 fragment, resultingin fusion of the FKS2 promoter sequences to the CYC1 minimalpromoter. Three SBF-binding site mutant alleles of FKS2 wereconstructed by PCR overlap mutagenesis (32) of p2052: an A toT at residue –386 (plasmid p2053), a G to C at residue–388 (p2054), and a C to G at residue –389 (p2055).A plasmid consisting of FKS2(–706 to –360)-CYC1-lacZ(plasmid p1070), which bears a LEU2 marker, was created by replacementof the URA3 marker in plasmid p916 (70) by the method of Cross(15). A plasmid consisting of CLN2(–600 to –400)-CYC1-lacZ(plasmid p2066) was constructed by replacing the 134-bp SmaI/XhoIfragment of the CYC1 promoter of pLG ${Delta}$ -312 (26) with a 200-bpPCR-amplified CLN2 fragment, resulting in fusion of the CLN2promoter sequences containing multiple SBF-binding sites tothe CYC1 minimal promoter.

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TABLE 2. Plasmids

PCR overlap mutagenesis was used to construct point mutantsin MPK1-3xHA (where HA is hemagglutinin) and MLP1-3xHA. Thesealleles (mpk1-K54R-3xHA and mlp1-Y192F-3xHA), their wild-typecounterparts, and mpk1-T190A Y192F-3xHA (mpk1-TA/YF-3xHA) (37)were subcloned from a URA3-based multicopy plasmid (YEp352)(31) into LEU2-based multicopy (YEp351) (31) and centromeric(pRS315) (60) plasmids, using SalI/EcoRI for MPK1 alleles andXbaI/SacI for MLP1 alleles. Mutant alleles of MPK1 (mpk1-TA/YFand mpk1-K54R) were tagged with the FLAG epitope by subcloninga SacI/SacII fragment bearing the mutant regions from the appropriateYEp351 clones into YEp351(MPK1-FLAG) (40).

SWI4-6HIS was created by PCR amplification of the SWI4 codingregion using primers that include a SpeI site in the upstreamprimer and an Xhol site in the downstream primer. The downstreamprimer also included a six copies of the HIS tag adjacent tothe termination codon. This fragment was cloned into pUT36 (plasmidp2415) (49), creating pUT36(SWI4-6HIS) (p2418), which expressesSwi4-6HIS under the control of the MET25 promoter and is selectableby the URA3 marker.

ERK5-6HIS was subcloned from pUT36(ERK5-6HIS) (49) (gift ofP. Piper) using BamHl and Sall into vector pUT34 (plasmid p2348),creating pUT34(ERK5-6HIS) (p2349), which expresses ERK5-6HISunder the control of the MET25 promoter and is selectable bythe HIS3 marker. QuikChange site-directed mutagenesis (66) wasused to create pUT34(ERK5-T219A Y221F-6HIS) (p2350) and pUT34(ERK5-K84R-6HIS)(p2351).

A Gal4 activation domain (AD) fusion to Swi4 for two-hybridanalysis was constructed in pGAD424 (Clontech Technologies)(plasmid p1173) by PCR amplification of the coding region usingprimers that include an SalI site in the upstream primer anda BglII site in the downstream primer. The Gal4 DNA-bindingdomain (DBD) fusion to the catalytic domain of Mpk1 residues1 to 328 [pGBT9-Mpk1(1-328)]; plasmid (p2248) was the gift ofM. Molina. All PCR-amplified sequences were confirmed by DNAsequence analysis across the entire amplified region.

Genomic deletions of SWI4 and SWI6. To delete the genomic copy of SWI4, 595 bp of sequence 5' tothe SWI4 start codon and 614 bp of sequence 3' of the SWI4 stopcodon were amplified in separate PCRs from genomic DNA of yeaststrain 1788. The 5' fragment was amplified with primers thatplaced an NotI site at the end adjacent to the SWI4 coding sequenceand a PstI site at the opposite end. The 3' fragment was amplifiedwith primers that placed an SalI site adjacent to the SWI4 codingsequence and a PstI site at the opposite end. These fragmentswere ligated in a three-molecule reaction to the NotI and SalIsites of the integrative plasmid pRS304 (60) to create a uniquePstI site between the fragments. The resulting plasmid, pRS304(swi4 ${Delta}$ ::TRP1)(p2344), was linearized with PstI and used to transform yeaststrains to tryptophan prototrophy.

To delete the genomic copy of SWI6, 615 bp of sequence 5' tothe SWI6 start codon and 611 bp of sequence 3' of the SWI6 stopcodon were amplified in separate PCRs from genomic DNA of yeaststrain 1788. The 5' fragment was amplified with primers thatplaced an NotI site at the end adjacent to the SWI6 coding sequenceand a PstI site at the opposite end. The 3' fragment was amplifiedwith primers that placed an SalI site adjacent to the SWI6 codingsequence and a PstI site at the opposite end. These fragmentswere ligated in a three-molecule reaction to the NotI and SalIsites of the integrative plasmid pRS305 (60) to create a uniquePstI site between the fragments. The resulting plasmid, pRS305(swi6 ${Delta}$ ::LEU2)(p2345), was linearized with PstI and used to transform yeaststrains to leucine prototrophy.

ChIP. Chromatin immunoprecipitation (ChIP) assays were conducted asdescribed by Hecht and Grunstein (30), with the following modifications.Yeast cells expressing HA-tagged proteins of interest and multicopyplasmids containing various alleles of FKS2 were grown in YEPDmedium at room temperature or at 39°C to an A₆₀₀ of 1.5.DNA was cross-linked to proteins by the addition of formaldehydeto 1%, followed by incubation at 30°C for 1 h. Chromatinwas sheared using a Branson Sonifier 450 (output setting 5)in 10-s bursts for a total of 90 s so as to generate fragmentsof an approximately mean length of 500 bp. Mouse monoclonalantibody 12CA5 (BabCo) was used for immunoprecipitation of 500µg of protein. PCR (35 cycles) was used for detectionof coprecipitated DNA sequences. For FKS2-CYC1-lacZ promoterassociation, one primer of the pair was homologous to CYC1 sequenceto avoid interference from the endogenous FKS2 promoter. Thiswas critical for experiments testing Mpk1-HA and Mlp1-HA associationto the SBF-site mutant allele of the FKS2 promoter. A primerpair for amplification of part of the DYN1 gene was used asa negative control for genomic ChIP experiments. For primersequences, see Table S1 in the supplemental material.

Coimmunoprecipitation. Protein extractions and coimmunoprecipitation of yeast strainDL454 (mpk1 ${Delta}$ ) expressing Swi4-His₆ with Mpk1-FLAG (from 300 µgof protein) were conducted as described previously (37) usingmouse monoclonal anti-FLAG (M2) affinity beads (Sigma) or proteinA affinity beads (no antibody controls; Sigma). Sodium dodecylsulfate-polyacrylamide gel electrophoresis (on 7.5% gels) ofsamples representing 100 µg of initial protein was followedby immunoblotting to detect either Mpk1-FLAG (M2 anti-FLAG antibody;Sigma) or Swi4-His₆ (mouse monoclonal tetra-His antibody; Qiagen).Input controls represented 50 µg of initial protein.

RESULTS

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RESULTS

Cell wall stress induction of FKS2 requires SBF. Expression of the FKS2 gene is induced in response to a varietyof cell wall stressing agents including elevated growth temperature,Congo red, and calcofluor white (70; also K.-Y. Kim, unpublisheddata). A lacZ transcriptional reporter bearing the FKS2 promoterregion between residues –706 and –360 fused to thebasal CYC1 promoter (FKS2-lacZ) is responsive to thermal stress(70) and to expression of a constitutive form of the CWI MEK,Mkk1, but its induction is independent of the Rlm1 transcriptionfactor (36). A consensus SBF-binding site (SCB; CACGAAA) resideswithin the responsive region of the FKS2 promoter (–385to –391). To assess the contribution of this site to cellwall stress-induced activation of the FKS2 promoter, we mutatedthree residues predicted to abolish SBF binding (5). Mutantpromoters were tested in the context of a shorter FKS2-lacZreporter plasmid (with residues –540 to –375). Allthree mutations abolished induction of this reporter at increasedtemperatures or following Congo red treatment (Fig. 1A), indicatingthat the SCB is necessary for the response. Because elevatedgrowth temperature was the most effective of several cell wallstressors for induction of FKS2 expression, subsequent experimentswere conducted using that stress. Thermal induction of FKS2-lacZwas similarly abolished in swi4 ${Delta}$ and swi6 ${Delta}$ mutants (Fig. 1B),indicating the requirement for both subunits of SBF in thisresponse. Because the swi4 ${Delta}$ mutant has an osmotically remedialgrowth defect at elevated temperatures (44, 50), it was necessaryto conduct this experiment in the presence of sorbitol for osmoticsupport, which diminished somewhat the stress response in thewild-type strain. In contrast to these results, a reporter thatis activated by cell wall stress through the Rlm1 transcriptionfactor (PRM5-lacZ) was induced normally at an elevated temperaturein swi4 ${Delta}$ and swi6 ${Delta}$ mutants (Fig. 1C), indicating that Rlm1-mediatedtranscription is not dependent on these factors and that themutant strains are not generally impaired for transcriptionalinduction at high temperature.

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FIG. 1. Cell wall stress induction of FKS2 expression is dependent on an SBF-binding site and SBF. (A) The SBF-binding site in the FKS2 promoter is required for cell wall stress-induced activation. FKS2-lacZ reporter plasmids bearing point mutations in a predicted SBF-binding site (wild-type, p2052; –386T, p2053; –388C, p2054; and –389G, p2055) were transformed into wild-type yeast strain 1788. Transformants were grown to saturation at 23°C in SD-uracil medium. Cultures were diluted into 3 ml of YEPD medium so that subsequent incubation at 23°C, 39°C, or 23°C with 50 µg/ml Congo red for 15 h resulted in mid-log-phase cultures (A₆₀₀ of 1.0 to 1.5). β-Galactosidase (β-Gal) activity was measured in crude extracts. (B) Mutants in SWI4 and SWI6 are defective for thermal activation of FKS2 expression. An FKS2-lacZ reporter plasmid (p2052) was transformed into wild-type (1788), swi4 ${Delta}$ (DL3145), or swi6 ${Delta}$ (DL3148) strains. Transformants were treated as described in panel A, except that cultures were diluted into YEPD medium containing 10% sorbitol for osmotic support. (C) Mutants in SWI4 and SWI6 are competent for thermal activation of PRM5 expression. A PRM5-lacZ reporter plasmid (p1366) was transformed into wild-type (1788), swi4 ${Delta}$ (DL3145), or swi6 ${Delta}$ (DL3148) strains. Transformants were treated as described in panel A, except that cultures were diluted into YEPD medium containing 10% sorbitol for osmotic support. (D) A cell cycle-regulated SCB reporter is not induced in response to cell wall stress. A CLN2-lacZ reporter plasmid (p2066) and its parent vector (p904) were transformed into the wild-type strain (1788). Transformants were treated as described in panel A. Each value represents the mean and standard deviation from three independent transformants. Sp. Act., specific activity; U, unit.

It has been demonstrated previously that a pkc1 mutation doesnot affect expression of an SBF-driven cell cycle-regulatedpromoter (33). Consistent with this, we found that an SBF-drivenreporter that is regulated periodically through the cell cycle(CLN2-lacZ) showed no activation in response to cell wall stressinduced either by high temperatures or by Congo red (Fig. 1D),revealing that the SCB in FKS2 functions differently than theSCBs in cell cycle-regulated genes.

Thermal induction of FKS2 requires either the Mpk1 MAPK or its pseudokinase paralog, Mlp1. To determine which elements of the CWI signaling pathway arerequired for thermal induction of FKS2 through SBF, we examinedmutants in the MAPK (mpk1 ${Delta}$ ), the MEK (mkk1 ${Delta}$ /mkk2 ${Delta}$ ), and the MEKK(bck1 ${Delta}$ ) of this pathway. As above, these mutants were exposedto thermal stress in the presence of sorbitol for osmotic support.Although the bck1 ${Delta}$ and mkk1 ${Delta}$ /mkk2 ${Delta}$ mutants were defective for FKS2induction, we were surprised to find that the mpk1 ${Delta}$ mutant wasonly modestly impaired (Fig. 2A). This was unexpected becausethe MAPK branch of the CWI signaling pathway has been thoughtto be linear, with Mpk1 being the sole MAPK activated throughthis pathway (43).

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FIG. 2. CWI requirements for thermal induction of FKS2 and PRM5. (A) Induction of FKS2 expression is dependent on either Mpk1 or its pseudokinase paralog, Mlp1. An FKS2-lacZ reporter plasmid (p2052) was transformed into the wild-type (DL3193), bck1 ${Delta}$ (DL3529), mkk1 ${Delta}$ mkk2 ${Delta}$ (DL3541), mpk1 ${Delta}$ (DL3195), mlp1 ${Delta}$ (DL3194), or mpk1 ${Delta}$ mlp1 ${Delta}$ (DL3196) strain. Transformants were cultured as described in the legend of Fig. 1 in the presence of YEPD medium containing 10% sorbitol for osmotic support. β-Galactosidase (β-Gal) activity was measured in crude extracts. (B) Mpk1 does not require catalytic activity for thermal induction of FKS2, but Mpk1 and Mlp1 must be phosphorylated. An FKS2-lacZ reporter plasmid (p2052) was cotransformed with centromeric plasmids bearing MPK1 (p2188), mpk1-TA/YF (p2190), mpk1-K54R (p2193), MLP1 (p2346), mlp1-Y192F (p2347), or vector (pRS315) into an mpk1 ${Delta}$ mlp1 ${Delta}$ strain (DL3196). Transformants were treated as above. (C) Mpk1 catalytic activity is required for thermal induction of PRM5. A PRM5-lacZ reporter plasmid (p1366) was cotransformed with the indicated plasmids from panel B into an mpk1 ${Delta}$ mlp1 ${Delta}$ strain (DL3196). Transformants were treated as above, except that culture time was 5 h rather than 15 h. Each value represents the mean and standard deviation from three independent transformants. Sp. Act., specific activity; U, unit.

A paralog of Mpk1, encoded by the MLP1 gene (67), exists withinthe yeast genome as a consequence of an ancestral whole-genomeduplication (38). Mlp1 shares 53% amino acid sequence identitywith Mpk1. However, Mlp1 lacks two catalytic domain residuesrecognized to be critical for protein kinase activity. First,a universally conserved Lys residue within subdomain II of allprotein kinases, which is important for ATP positioning (28),is mutated to an Arg residue in Mlp1 (residue 54). This mutationis often engineered to create catalytically inactive forms ofprotein kinases. Second, a universally conserved Asp residuewithin the triplet DFG in subdomain VII is mutated to an Asnresidue in Mlp1 (residue 171). This residue normally coordinatesa magnesium ion that is also critical for ATP positioning (28),further suggesting that Mlp1 does not have the capability tobind ATP in a catalytically productive manner. Additionally,we have been unable to detect protein kinase activity associatedwith immunoprecipitated Mlp1 using in vitro substrates of Mpk1(unpublished results), supporting the conclusion that Mlp1 isa pseudokinase. In addition to the differences in the ATP-bindingsite, a conserved Thr residue within the dual phosphorylationsite of MAPK activation loops (TXY) is mutated to a Lys residuein Mlp1 (residue 190), further indicating that it is not a trueMAPK. However, because phosphorylation of the activation loopTyr residue by MEKs precedes that of the Thr residue (21, 29),it is possible that Mlp1 is phosphorylated on Tyr192 by Mkk1/2.

We tested an mlp1 ${Delta}$ mutation individually and in combination withmpk1 ${Delta}$ for thermal induction of FKS2 expression (Fig. 2A). Althoughthe mlp1 ${Delta}$ mutant was not compromised, the double mutant mlp1 ${Delta}$ mpk1 ${Delta}$ was incapable of inducing FKS2 expression, indicating thatthese proteins serve an overlapping function for activationof transcription through SBF. This surprising result also indicatedthat Mlp1 drives FKS2 expression through a noncatalytic mechanism.

Because protein kinase activity is not required for Mlp1 toinduce FKS2 expression, we asked if Mpk1 requires its proteinkinase activity for this function. To address this, two mutantforms of Mpk1 were constructed. The first was mpk1-K54R, a mutationwithin the ATP-binding site, which blocks catalytic activityby interfering with ATP positioning and is analogous to Arg54found naturally in MLP1. This allele fails to complement thecell lysis defect of an mpk1 ${Delta}$ mutant (46) and is devoid of detectableprotein kinase activity (44, 69). The second mutant form, mpk1-TA/YF,eliminates the two phosphorylation sites within the activationloop of Mpk1 that are normally phosphorylated by Mkk1/2. Thisallele similarly fails to complement the cell lysis defect ofan mpk1 ${Delta}$ mutant (42) and is devoid of detectable protein kinaseactivity (37). These forms were introduced into an mpk1 ${Delta}$ mlp1 ${Delta}$ double mutant on centromeric plasmids. Figure 2B shows thatalthough the mpk1-TA/YF mutant was blocked for thermal inductionof FKS2, the mpk1-K54R mutant was not, indicating that Mpk1must be in the active (phosphorylated) conformation to drivetranscription through SBF but need not be catalytically active.A mutant form of Mlp1 that eliminates its lone potential phosphorylationsite (Y192F) was similarly blocked for FKS2 induction (Fig.2B), suggesting that Mlp1 must also be in the active conformationto drive transcription. These results are in contrast to cellwall stress induction of PRM5 transcription, which requiresphosphorylation of the Rlm1 transcription factor by Mpk1 (35).Mutations in Mpk1 that either block its phosphorylation by Mkk1/2or interfere with its catalytic activity block thermal inductionof PRM5 (Fig. 2C). Additionally, although Mlp1 can associatewith Rlm1 (67), it cannot substitute for Mpk1 in the activationof this transcription factor (Fig. 2C).

Mpk1 and Mlp1 associate with the FKS2 promoter through Swi4. Because Mpk1 and Mlp1 must be in the active conformation butdo not require catalytic activity to drive FKS2 expression throughSBF, we considered a model in which these proteins act by stableassociation with SBF on the FKS2 promoter. We used ChIP analysisto test this model. Cells expressing epitope-tagged forms ofMpk1 were first exposed to mild heat stress to activate CWIsignaling (37). Proteins were then cross-linked to DNA withformaldehyde, followed by cell lysis and DNA fragmentation.Mpk1-HA was immunoprecipitated from extracts, and coprecipitatingFKS2 promoter sequence was detected by PCR. Wild-type Mpk1-HAwas detected in a complex with the FKS2 promoter only afterits activation by heat stress (Fig. 3A). The ATP-binding sitemutant form of Mpk1 (Mpk1-K54R-HA) was also detected in a promotercomplex. However, we failed to detect the phosphorylation sitemutant form of Mpk1 (Mpk1-TA/YF-HA) bound to the FKS2 promotereven though this mutant protein is maintained at normal levels(37). To determine if this association was dependent on theSBF-binding site, the plasmid bearing the wild-type FKS2 promoterwas replaced with one bearing the mutant SBF-binding site formdescribed above. Mpk1-HA was not detected in association withthis mutant promoter. Similarly to Mpk1-HA, wild-type Mlp1-HAwas detected in a complex with the FKS2 promoter, but the phosphorylationsite mutant of this protein (Mlp1-Y192F-HA) failed to bind thepromoter (Fig. 3B). These results are consistent with the transcriptionaldata presented above and indicate that phosphorylated Mpk1 andMlp1 drive transcription of FKS2 through association with theSCB at the promoter.

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FIG. 3. Phosphorylated Mpk1 and Mlp1 bind to the FKS2 promoter. (A) ChIP analysis of the FKS2 promoter with Mpk1-HA. A wild-type yeast strain (1788) was cotransformed with FKS2-lacZ reporter plasmids (p2052, wild-type; or p2053, SBF-site mutant –386T) and multicopy plasmids expressing the indicated HA-tagged MPK1 allele (wild-type, p777; mpk1-TA/YF, p778; mpk1-K54R, p2119; or vector, YEp351). Transformants were cultivated in YEPD medium at 23°C or subjected to thermal stress at 39°C for 15 h prior to ChIP analysis using primers designed to detect only the plasmid-borne FKS2 promoter. PCRs from whole-cell extracts (WCE) are also shown. (B) ChIP analysis of the FKS2 promoter with Mlp1-HA. Wild-type yeast strain 1788 was cotransformed with FKS2-lacZ reporter plasmids from panel A and multicopy plasmids expressing the indicated HA-tagged MLP1 allele (wild-type, p2022; mlp1-Y192F, p2024; or vector, YEp351). Transformants were cultivated and subjected to thermal stress prior to ChIP analysis, as above. WT, wild type; TAYF, T190A Y192F.

To determine the specific requirements for complex formationon the native FKS2 promoter, we conducted genomic ChIP analysisin swi4 ${Delta}$ , swi6 ${Delta}$ , and mpk1 ${Delta}$ /mlp1 ${Delta}$ mutants. As was observed usingthe plasmid-borne FKS2 promoter, wild-type Mpk1-HA and its ATP-bindingsite mutant form bound to the genomic FKS2 promoter in responseto activation by heat stress (Fig. 4A). By contrast, the phosphorylationsite mutant form of Mpk1-HA failed to bind FKS2. Mpk1-HA didnot associate with the FKS2 promoter in an swi4 ${Delta}$ mutant but wasstill capable of association in the swi6 ${Delta}$ mutant (Fig. 4A). Thelatter result was somewhat surprising because Swi4 requiresSwi6 to bind DNA at cell cycle-regulated promoters (4, 6, 58),and this suggests that Mpk1 can replace that function of Swi6in this context. Swi4-HA associated with the FKS2 promoter inan swi6 ${Delta}$ mutant but not in an mpk1 ${Delta}$ mlp1 ${Delta}$ mutant (Fig. 4B), supportingthe conclusion that Mpk1 (or Mlp1), but not Swi6, confers DNA-bindingability to Swi4 in this promoter context. Thus, Mpk1/Mlp1 andSwi4 promoter binding is codependent. Finally, because Swi6is required for thermal induction of FKS2 expression, we examinedthe requirements for Swi6-HA promoter binding. We found thatSwi6 association with the FKS2 promoter requires both Mpk1/Mlp1and Swi4 (Fig. 4C). Taken together, these results support amodel in which phosphorylated Mpk1 (or Mlp1) in stable complexwith Swi4 is competent to bind the FKS2 promoter at the SBFbinding site. However, transcriptional activation of FKS2 requiresthe further recruitment of Swi6 to the complex.

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FIG. 4. Interdependent recruitment of Mpk1 and Swi4 to the FKS2 promoter. (A) Genomic ChIP demonstrates that association of Mpk1-HA with the FKS2 promoter is dependent on Swi4 but not Swi6. Yeast strains (wild-type, DL3187; swi4 ${Delta}$ , DL3405; or swi6 ${Delta}$ , DL3233) were transformed with a multicopy plasmid bearing the indicated MPK1-HA allele and subjected to thermal stress prior to ChIP analysis as described in the legend of Fig. 3, except that strains were cultivated in the presence of 10% sorbitol. An additional primer pair for PCR amplification DYN1 sequence was included as a negative control. (B) Association of Swi4-HA with the FKS2 promoter is dependent on Mpk1/Mlp1 but not Swi6. Yeast strains (wild-type, DL3187; swi6 ${Delta}$ , DL3233; or mpk1 ${Delta}$ mlp1 ${Delta}$ , DL3183) were transformed with a multicopy plasmid bearing SWI4-HA (p2339) and treated as above. (C) Association of Swi6 with the FKS2 promoter is dependent on both Swi4 and Mpk1/Mlp1. Yeast strains (wild-type, DL3187; swi4 ${Delta}$ , DL3405; or mpk1 ${Delta}$ mlp1 ${Delta}$ , DL3183) were transformed with a multicopy plasmid bearing SWI6-HA (p2341) and treated as above. WCE, whole-cell extract; WT, wild type; ${alpha}$ , anti; TAYF, mpk1-T190A Y192F.

Association of Mpk1 with Swi4 is regulated by the phosphorylation state of Mpk1. Phosphorylation of Mpk1 might regulate its association withSwi4, indicating that formation of the heterodimeric complexis the key step controlling DNA binding. Alternatively, Mpk1might reside constitutively in complex with Swi4 and inducea conformational shift in response to activation that allowsDNA binding of the complex. Therefore, we examined the regulationof the interaction of these proteins by two-hybrid analysisand by coimmunoprecipitation. Because Mpk1 possesses a transcriptionalactivation region within its C-terminal domain (62) that wouldinterfere with two-hybrid analysis, we used a truncated form[Gal4DBD-Mpk1(1-328)] that possesses only the Mpk1 catalyticdomain. A full-length Swi4 fusion (Gal4AD-Swi4) displayed interactionwith Mpk1 but only in response to thermal stress (Fig. 5A),revealing that the interaction is regulated by the activationstate of Mpk1.

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FIG. 5. Physical association of activated Mpk1 with Swi4. (A) Two-hybrid association of Mpk1 with Swi4 is dependent on activation of Mpk1. A Gal4DBD fusion to the catalytic domain of Mpk1, Mpk1(1-328) (plasmid p2248), was tested for interaction with a Gal4AD fusion to Swi4 (p2352) in yeast two-hybrid strain SFY526. Transformants were cultivated in selective medium for 15 h either at 23°C or 39°C. Vector controls (Gal4DBD vector, p1172; Gal4AD vector, p1173) are included for each fusion. Each value represents the mean and standard deviation from three independent transformants. (B) Coimmunoprecipitation (IP) of Swi4 with Mpk1 requires phosphorylation of Mpk1 but not its protein kinase activity. Yeast strain DL454 (mpk1 ${Delta}$ ) was cotransformed with multicopy plasmids bearing the indicated FLAG-tagged MPK1 allele (wild-type, p2313; mpk1-TA/YF, p2316; mpk1-K54R, p2317) and His-tagged SWI4 allele (p2418). Transformants were cultivated to mid-log phase in selective medium lacking methionine (to induce expression of Swi4-His₆) and either subjected to heat stress for 1 h at 39°C or maintained at 25°C. Cell extracts (Input) and immunoprecipitates with anti-FLAG M2 affinity gel (Sigma) or protein A affinity gel (Sigma) or no-antibody controls were subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis and analyzed by immunoblotting with anti-FLAG or anti-His (Qiagen) antibodies. ${alpha}$ , anti; WT, wild type; β-Gal, β-galactosidase; Sp. Act., specific activity; U, unit; Ab, antibody.

We next tested for coimmunoprecipitation of Mpk1 and Swi4. Epitope-taggedforms of Mpk1 were immunoprecipitated from extracts of cellsthat had been either exposed to thermal stress or grown undernonstress conditions. Epitope-tagged Swi4 (Swi4-6His) coprecipitatedwith either wild-type Mpk1 (Mpk1-FLAG) or the ATP-binding sitemutant form of Mpk1 (Mpk1-K54R-FLAG) with an increased signalunder thermal stress conditions (Fig. 5B). However, Swi4 failedto associate with the phosphorylation site mutant form of Mpk1(Mpk1-TA/YF-FLAG) under either condition, confirming that Mpk1must be in the active (phosphorylated) state but does not requireprotein kinase activity to bind Swi4. Thus, we propose thatMpk1 (or Mlp1), activated by cell wall stress, associates withSwi4. This dimeric complex is competent to bind the SCB of theFKS2 promoter. Finally, Swi6 associates with this ternary complexto drive transcription initiation (Fig. 6).

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FIG. 6. Model for CWI-regulated induction of FKS2 expression. (A) Cell wall stress results in phosphorylation and activation of the Mpk1 MAPK and the Mlp1 pseudokinase. Activated Mpk1 or Mlp1 binds Swi4. (B) The dimeric complex binds to the SBF-binding site within the FKS2 promoter. (C) Swi6 engages the ternary complex to initiate transcription. (D) Model for activation of transcription by CWI signaling. Cell wall stress activates the Mpk1 MAPK and the Rlm1 transcription factor. MLP1 expression is under the transcriptional control of Rlm1. Stress-induced Mlp1 is phosphorylated by MEKs (Mkk1/2) and stimulates FKS2 transcription redundantly with Mpk1 by noncatalytic activation of SBF. P, phosphate.

Human ERK5 drives FKS2 expression through a noncatalytic mechanism. When expressed in yeast, the human ERK5 MAPK is activated inresponse to cell wall stress and suppresses the phenotypic defectsof an mpk1 ${Delta}$ mutant (65). Additionally, ERK5 is capable of activatingthe Rlm1 transcription factor. We therefore asked if the noncatalytictranscriptional activation of SBF by Mpk1 and Mlp1 is also conservedin ERK5. Human ERK5 variants were expressed in an mpk1 ${Delta}$ mlp1 ${Delta}$ mutant and tested for their ability to activate FKS2 transcriptionin response to thermal stress. Both the wild-type and ATP-bindingsite mutant (K84R) alleles of ERK5 were capable of activatingFKS2 reporter expression (Fig. 7). By contrast, a nonphosphorylatableform of ERK5 (T219A Y221F) failed to show an increase over thevector control. As was seen for Mpk1 and Mlp1, induction ofFKS2 by ERK5 was dependent on the SCB. We conclude that thenoncatalytic transcriptional function of Mpk1 and Mlp1 is conservedin ERK5.

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FIG. 7. The noncatalytic transcriptional function of Mpk1 and Mlp1 is conserved in human ERK5. FKS2-lacZ reporter plasmids (wild-type, p2052; SBF-binding site mutant, p2053) were cotransformed with ERK5 expression plasmids into an mpk1 ${Delta}$ mlp1 ${Delta}$ strain (DL3196). ERK5 plasmids were wild-type (ERK5; p2349), ERK5-T219A Y221F (TAYF; p2350), ERK5-K84R (p2351), or vector (pUT34; p2348). Transformants were cultured as described in the legend of Fig. 1 in the presence of YEPD medium containing 10% sorbitol for osmotic support. β-Galactosidase (β-Gal) activity was measured in crude extracts. Each value represents the mean and standard deviation from three independent transformants. Sp. Act., specific activity; U, unit.

DISCUSSION

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DISCUSSION

A common mechanism by which MAPKs regulate gene expression inresponse to environmental stresses is through phosphorylationof transcription factors. However, protein kinases can alsoregulate transcription through the formation of stable interactionson the DNA. For example, the yeast Kss1 and Fus3 MAPKs functionas repressors of transcription in the unphosphorylated statethrough association with the Ste12/Tec1 transcription factorcomplex (8, 14, 45). Inactive Kss1 binds directly to Ste12,recruiting the Dig1 and Dig2 transcriptional repressors to theDNA. Phosphorylation of Kss1 destabilizes this complex, causingderepression through a mechanism that does not require Kss1protein kinase activity. Additionally, recent reports have revealedthat some MAPKs can drive gene expression as integral componentsof transcription complexes (2, 3, 17, 51, 52, 53). This hasbeen studied most thoroughly in the yeast Hog1 stress-activatedprotein kinase, which is activated by osmotic stress and usesseveral distinct mechanisms for inducing gene expression includingrecruitment of transcription factors, chromatin remodelers,and RNA polymerase to responsive promoters (reviewed in reference20). All of these mechanisms require Hog1 protein kinase activity.In this study, we investigated the mechanism by which the yeastMpk1 MAPK and its pseudokinase paralog, Mlp1, regulate geneexpression.

Mpk1 and its pseudokinase paralog, Mlp1, function as transcriptional coactivators through a noncatalytic mechanism. The majority of transcriptional regulation through the CWI signalingpathway results from phosphorylation and activation of the Rlm1transcription factor by Mpk1 (23, 35, 36, 55). We demonstratedthat Mpk1 additionally uses a novel mechanism that does notrequire its protein kinase activity to drive expression of theFKS2 gene in response to cell wall stress. This mechanism, whichinvolves stable association with the FKS2 promoter, was revealedthrough the discovery that Mpk1 is redundant with its catalyticallyinactive paralog Mlp1 for this specific function. Mpk1 and Mlp1must nevertheless be activated through phosphorylation by theircognate MEKs (Mkk1/2).

In addition to phosphorylated Mpk1 or Mlp1, we found that FKS2transcription in response to wall stress requires the Swi4/Swi6(SBF) transcription factor. SBF regulates G₁ cyclin transcriptionin a cell cycle-periodic manner (11) but has been suggestedto serve another function in the response to cell wall stress(7, 44). We found that association of phosphorylated Mpk1 andMlp1 with the FKS2 promoter is dependent on an SBF-binding sitewithin the promoter. Moreover, promoter association of Mpk1and Swi4 was codependent but independent of Swi6. This is incontrast to the promoters of SBF-regulated cell cycle genes,in which association of Swi4 with Swi6 by their C termini rendersSwi4 competent to engage SBF-binding sites (4, 6, 58). Intramolecularassociation of the Swi4 C terminus with its DBD interferes withits ability to bind DNA, which is relieved by Swi6 association.Our results indicate that in the context of the FKS2 promoter,Mpk1 (or Mlp1) replaces the function of Swi6 in allowing Swi4to bind DNA. However, it is likely that Swi4 possesses separatebinding sites for Mpk1 and Swi6 because Mpk1 forms a ternarycomplex with SBF in vivo and in vitro (7, 44). The differencebetween the SBF-binding site in the FKS2 promoter, which isnot regulated periodically through the cell cycle (48, 63),and the sites found in promoters of genes subject to G₁-specifictranscriptional regulation must be defined outside of the coreSBF-binding site, which is identical in FKS2 and cell cycle-regulatedgenes. Perhaps the presence of a single SBF-binding site inFKS2, rather than the 2 to 10 sites found in cell cycle-regulatedgenes (5), contributes to this differential regulation.

Mpk1 has been shown previously to associate directly with Swi4in vitro but not with Swi6 (7). We found that Mpk1 must be inthe active conformation to associate with Swi4. MAPKs are activatedby dual phosphorylation of neighboring Thr and Tyr residuesin a TXY motif within their so-called activation loops, whichis thought to relieve steric inhibition of protein substratebinding (28). The requirement for Mpk1 phosphorylation to bindSwi4 therefore suggests that the kinase engages Swi4 as thoughit is a substrate. Nevertheless, catalytic activity is not requiredfor either DNA binding of the resulting complex or for transcriptionalactivation.

Although Swi6 is not required for Mpk1 or Swi4 to bind the FKS2promoter, we found that it is required for transcriptional activationand that Swi6 associates with the FKS2 promoter in an Mpk1-and Swi4-dependent manner. Mpk1 is known to phosphorylate Swi6in response to activation by cell wall stress (44). However,the consequence of phosphorylation has not been investigated.Our results demonstrate that this modification is not requiredfor the involvement of Swi6 in FKS2 induction. Indeed, lossof Mpk1 catalytic activity results in a small, but reproducibleenhancement in transcriptional activation of FKS2 (Fig. 2B).Mpk1 phosphorylation of Swi6 may be a negative regulatory modification,similar to phosphorylation of Swi6 by Cdc28, which results inits nuclear egress (25, 59). To our knowledge, this noncatalyticmode of transcriptional activation by a protein kinase (or apseudokinase) is unprecedented.

The Mlp1 pseudokinase. Mlp1 is a paralog of Mpk1 that arose as a consequence of anancestral whole-genome duplication (38). It was identified initiallyas a protein that interacts with the Rlm1 transcription factor(67). However, we demonstrated that Mlp1 neither contributesto Rlm1-driven transcription (Fig. 2C) nor interferes appreciably(K.-Y. Kim, unpublished). Although Mlp1 is not a catalyticallyactive protein kinase, it possesses a Tyr residue within itsactivation loop that, as in MAPKs, is predicted to be phosphorylatedin response to an activating signal. Mutation of this residueto Phe blocked the ability of Mlp1 to drive FKS2 transcriptionand to associate with the FKS2 promoter in response to cellwall stress. This result strongly suggests that tyrosine phosphorylationinduces a conformational change in Mlp1 that allows it to bindSwi4 in a manner similar to activated Mpk1. As noted above,MAPKs are dually phosphorylated on neighboring Thr and Tyr residues.However, the activation loop Thr is replaced by a Lys residuein Mlp1. The significance of this change is not clear, but itevidently allows Mlp1 to be activated through a single phosphorylationevent. This may alter its kinetics of activation by Mkk1/2 (34)or inactivation by the Msg5 and Sdp1 dual-specificity proteinphosphatases (22, 27).

It is interesting that the MLP1 gene is transcriptionally inducedin response to cell wall stress (35, 36). Its induction resultsfrom phosphorylation and activation of the Rlm1 transcriptionfactor by Mpk1. Thus, in the absence of Mpk1 or cell wall stress,very little Mlp1 is expressed (unpublished results). Nevertheless,it is evident that sufficient Mlp1 exists in the absence ofMpk1 to activate FKS2 transcription to nearly normal levels(Fig. 2A). Figure 6C depicts a revised model of the CWI MAPKcascade based on these results.

Other characterized pseudokinases fall into two categories.Some, including mammalian STRAD (10), the ErbB3 epidermal growthfactor receptor (9), and kinase suppressor of Ras (56), formcomplexes with active protein kinases (LKB1, ErbB, and Raf,respectively) and are critical to the regulation of their associatedkinases. Others exist as pseudokinase domains within activeprotein kinases, which also serve to regulate kinase activity.This group includes the yeast Gcn2 (54) and mammalian JAK kinases(57). Although we have not tested for a physical interactionbetween Mpk1 and Mlp1, our results clearly demonstrate thattheir functions are not interdependent.

What is the consequence of the absence of protein kinase activityin Mlp1? This is not yet clear, but it appears that mutationalloss of catalytic activity in Mpk1 paralogs has evolved independentlyat least twice. Saccharomyces castellii is a yeast species which,like S. cerevisiae, arose after an ancestral whole-genome duplicationevent that was followed by deletion of most of the paralogousgenes (38). Also like S. cerevisiae, S. castellii retained bothcopies of the MPK1 gene and appears to have allowed one proteinto evolve to a catalytically inactive state (Scas_678.13 [wolfe.gen.tcd.ie/browser])but through a different set of mutations than those that inactivatedS. cerevisiae Mlp1. This convergent evolution suggests thatloss of catalytic activity in Mpk1 paralogs was the productof selection.

The noncatalytic mechanism for activation of FKS2 expression is conserved in human ERK5. The human ERK5 MAPK complements loss of Mpk1 with respect toits cell lysis defect and transcriptional activation throughRlm1 (65). We found that this complementation extends to thenoncatalytic transcriptional activation of FKS2 through SBF.Although no Swi4 or Swi6 homologs are evident in metazoan genomes,our results raise the possibility that ERK5, or perhaps otherMAPKs, possess previously unappreciated noncatalytic functionsthat require a signal from upstream kinases.

ACKNOWLEDGMENTS

We thank Andrew Sobering and Un Sung Jung for early studieswith Mlp1; Brenda Andrews, Fred Cross, Val Culotta, Jean François,Joe Gray, Eric Grote, María Molina, and Peter Piper forstrains and plasmids; Alan Hinnebusch, Humberto Martín,and María Molina for valuable discussions; Eric Grotefor comments on the manuscript; and an anonymous reviewer forvaluable suggestions.

This work was supported by a grant from the NIH (GM48533) toD.E.L.

FOOTNOTES

* Corresponding author. Mailing address: Department of Biochemistry and Molecular Biology, Bloomberg School of Public Health, E8135, The Johns Hopkins University, Baltimore, MD 21205. Phone: (410) 955-9825. Fax: (410) 955-2926. E-mail: levin{at}jhmi.edu

Published ahead of print on 11 February 2008.

Supplemental material for this article may be found at http://mcb.asm.org/.

REFERENCES

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