Rho2 Is a Target of the Farnesyltransferase Cpp1 and Acts Upstream of Pmk1 Mitogen-activated Protein Kinase Signaling in Fission Yeast

Yan Ma^*, Takayoshi Kuno^*, Ayako Kita, Yuta Asayama, and Reiko Sugiura^*^,

*Division of Molecular Pharmacology and Pharmacogenomics, Department of Genome Sciences, Kobe University Graduate School of Medicine, Kobe 650-0017, Japan; and Laboratory of Molecular Pharmacogenomics, School of Pharmaceutical Sciences, Kinki University, Higashi-Osaka 577-8502, Japan

Submitted August 8, 2006; Revised September 14, 2006; Accepted September 18, 2006
Monitoring Editor: Charles Boone

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

We have previously demonstrated that knockout of the calcineuringene or inhibition of calcineurin activity by immunosuppressantsresulted in hypersensitivity to Cl^– in fission yeast.We also demonstrated that knockout of the components of thePmk1 mitogen-activated protein kinase (MAPK) pathway, such asPmk1 or Pek1 complemented the hypersensitivity to Cl^–.Using this interaction between calcineurin and Pmk1 MAPK, herewe developed a genetic screen that aims to identify new regulatorsof the Pmk1 signaling and isolated vic (viable in the presenceof immunosuppressant and chloride ion) mutants. One of the mutants,vic1-1, carried a missense mutation in the cpp1⁺ gene encodinga $beta$ subunit of the protein farnesyltransferase, which causedan amino acid substitution of aspartate 155 of Cpp1 to asparagine(Cpp1^D155N). Analysis of the mutant strain revealed that Rho2is a novel target of Cpp1. Moreover, Cpp1 and Rho2 act upstreamof Pck2–Pmk1 MAPK signaling pathway, thereby resultingin the vic phenotype upon their mutations. Interestingly, comparedwith other substrates of Cpp1, defects of Rho2 function weremore phenotypically manifested by the Cpp1^D155N mutation. Together,our results demonstrate that Cpp1 is a key component of thePck2–Pmk1 signaling through the spatial control of thesmall GTPase Rho2.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The mitogen-activated protein kinase (MAPK) pathway is one ofthe most important intracellular signaling that plays a crucialrole in cell proliferation, cell differentiation, and cell cycleregulation (Nishida and Gotoh, 1993; Marshall, 1994; Herskowitz,1995; Levin and Errede, 1995). The Pmk1 MAPK, a homologue ofthe mammalian extracellular signal-regulated kinase (ERK)/MAPK,regulates cell morphology and cell integrity in fission yeastSchizosaccharomyces pombe (Toda et al., 1996; Zaitsevskaya-Carterand Cooper, 1997). A functional connection between the Pmk1pathway and the protein kinase C homologues Pck1 and Pck2 hasbeen suggested, and differential roles of Pck1 and Pck2 in theregulation of cell integrity also have been suggested; however,it is unclear whether these protein kinase C homologues actupstream of the Pmk1 pathway or synergistically regulate independentaspects of cell integrity (Toda et al., 1996;Sengar et al.,1997; Arellano et al., 1999; Calonge et al., 2000).

We have previously demonstrated that knockout of the fissionyeast calcineurin gene ppb1⁺ or inhibition of calcineurin activityby immunosuppressants results in hypersensitivity to Cl^–,and that calcineurin and Pmk1 MAPK play antagonistic roles inCl^– homeostasis (Sugiura et al., 1998). Based on thisgenetic interaction between calcineurin and Pmk1 MAPK, we screenedfor multicopy suppressors of the Cl^–-hypersensitive phenotypeof the calcineurin knockout and identified genes encoding anMAPK phosphatase Pmp1 (Sugiura et al., 1998); MAPK kinase (MAPKK)Pek1 (Sugiura et al., 1999), and a novel KH-type RNA-bindingprotein Rnc1 that binds and stabilizes Pmp1 mRNA (Sugiura etal., 2003).

We also demonstrated that knockout of the components of thePmk1 MAPK pathway, such as Pmk1 or Pek1 complemented the Cl^–-hypersensitivephenotype of calcineurin knockout. Notably, these knockout strainsare viable in the presence of immunosuppressant FK506 and highconcentrations of MgCl₂, whereas the wild-type cells are inviablein the same condition (Sugiura et al., 1998, 1999). These resultsprompted us to perform a novel genetic screen to isolate vic(viable in the presence of immunosuppressant and chloride ion)mutants, aiming to identify novel components of the Pmk1 MAPKpathway.

We have identified a vic1-1/cpp1-v1 mutant, in addition to themutation allele in the known components of the Pmk1 MAPK pathway,including pmk1⁺ (MAPK), pek1⁺ (MAPKK), mkh1⁺ (MAPKK kinase,MAPKKK) as well as pck2⁺ (protein kinase C). The cpp1⁺ geneencodes a $beta$ subunit of the farnesyltransferase (FTase) that ishighly conserved through evolution.

In mammals, many proteins, including Ras family small GTPases,nuclear lamins A and B, transducin, rhodopsin kinase, and aperoxisomal protein termed PxF, have been reported as substratesfor FTase (Glomset and Farnsworth, 1994; Zhang and Casey, 1996;Casey and Seabra, 1996; Gelb, 1997; Mumby, 1997). There is widespreadinterest in FTase because Ras proteins are modified by FTaseand such a modification is critical for the oncogenic transformation(Hancock et al., 1989; Jackson et al., 1990; Kato et al., 1992).Several FTase inhibitors (FTIs) have been in clinical trialsfor the treatment of cancer (Johnston, 2001; Ayral-Kaloustianand Salaski, 2002). Also, recent studies have reported thatabnormal persistence of the farnesyl modifications on the nuclearprelamin A has been implicated in the pathogenesis of Hutchinson–Gilfordprogeria syndrome, a devastating premature aging disease (Pollexand Hegele, 2004). Thus, FTIs represent a possible therapeuticoption for cancer as well as for individuals with Hutchinson–Gilfordprogeria syndrome.

In budding yeast Saccharomyces cerevisiae, ${alpha}$ -factor mating pheromoneand Ras2 involved in the cAMP pathway have been identified assubstrates of FTase (Goodman et al., 1990; He et al., 1991).In fission yeast Schizosaccharomyces pombe, FTase Cpp1 has beenreported to play a critical role in sexual differentiation andmorphogenesis through Ras1 (Yang et al., 2000) and also hasbeen reported to play a role in cell cycle progression throughRheb (Yang et al., 2001).

Here, we show that the small GTPase Rho2 is a novel target ofCpp1 and that Cpp1 and Rho2 act upstream of Pck2-Pmk1 MAPK cellintegrity signaling pathway.

MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Strains, Media, and Genetic and Molecular Biology Methods
The S. pombe strains used in this study are listed in Table 1.The complete medium yeast extract-peptone-dextrose (YPD) andthe minimal medium Edinburgh minimal medium (EMM) have beendescribed previously (Toda et al., 1996). Standard genetic andrecombinant DNA methods (Moreno et al., 1991) were used exceptwhere noted. FK506 was provided by Fujisawa Pharmaceutical Co.(Osaka, Japan).

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Table 1. S. pombe strains used in this study

Isolation of vic1-1/cpp1-v1 Mutant
The vic1-1/cpp1-v1 mutant was isolated in a screen of cellsthat had been mutagenized with nitrosoguanidine as describedpreviously (Zhang et al., 2000

). Mutants were spread on YPDplates to give $~$ 1000 cells/plate, and the plates were incubatedat 27°C for 4 d. The plates were then replica-plated at27°C onto plates containing 0.5 µg/ml FK506 and 0.2M MgCl₂. Mutants that grew in the plates were selected and designatedas vic mutants. The original mutants isolated were backcrossedthree times to wild-type strains HM123 and HM528.

Cloning and Knockout of the cpp1⁺ Gene
To clone the vic1⁺ gene, the temperature sensitivity of vic1-1mutants (KP754) was used. The vic1-1 mutants were grown at 27°Cand transformed with an S. pombe genomic DNA library constructedin the vector pDB248 (Beach et al., 1982). Leu⁺ transformantswere replica-plated onto YPD plates at 36°C, and the plasmidDNA was recovered from transformants that showed plasmid-dependentrescue. These plasmids complemented both the temperature sensitivityand vic phenotype of the vic1-1 mutant. By DNA sequencing, thesuppressing plasmids were identified to contain the cpp1⁺ gene(SPAC17G6.04c). To investigate the relationship between thecloned cpp1⁺ gene and vic1-1 mutant, linkage analysis was performedas follows. The entire cpp1⁺ gene was subcloned into the pUC-derivedplasmid containing S. cerevisiae LEU2 gene and integrated byhomologous recombination into the genome of the wild-type strainHM123. The integrant was mated with the vic1-1 mutant. The resultingdiploid was sporulated, and tetrads were dissected. In total,30 tetrads were dissected. In all cases, only parental ditypetetrads were found, indicating allelism between the cpp1⁺ geneand the vic1-1 mutation (our unpublished data).

To knockout cpp1⁺ gene, a one-step gene disruption by homologousrecombination was performed as described previously (Rothstein,1983). The cpp1::ura4⁺ disruption was constructed as follows.The BamHI fragment containing the cpp1⁺ gene was subcloned intothe BamHI site of BlueScriptSK(+) (Stratagene, La Jolla, CA).Then, a PstI/SmaI fragment containing the ura4⁺ gene was insertedinto the NsiI/EcoRV site of the previous construct. The fragmentcontaining the disrupted cpp1⁺ gene was transformed into haploidcells. Stable integrants were selected on medium lacking uracil,and knockout of the gene was checked by genomic Southern hybridizationand tetrad analysis (our unpublished data).

Cloning and Tagging of the rho1⁺, rho2⁺, rho3⁺, and ras1⁺ Genes
The rho1⁺, rho2⁺, rho3⁺, and ras1⁺ genes were amplified by PCRwith the genomic DNA of wild-type cells as a template. The primersused were summarized in Table 2. The amplified products containingtheses genes were digested with BamHI, and the resulting fragmentswere subcloned into BlueScriptSK(+).

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Table 2. S. pombe primers used in this study

For ectopic expression of proteins, we used the thiamine-repressiblenmt1 promoter (Maundrell, 1993

). Expression was repressed bythe addition of 4 µM thiamine to EMM and was induced bywashing and then incubating the cells in EMM lacking thiamine.To express green fluorescent protein (GFP)-Rho1, Rho2, Rho3,or Ras1, these genes were tagged at its N terminus with GFPcarrying the S65T mutation. Rho2CIIL and Rho2SIIS were madein the same way except that the antisense primers were specificallydesigned for amplifying Rho2CIIL and Rho2SIIS. Similarly, Rho2,Ras1, or Rho3 was tagged at its N terminus with FLAG. Theseconstructs were confirmed to be fully functional as their expressioncomplemented the phenotypes associated with ${Delta}$ ras1, ${Delta}$ rho2, and ${Delta}$ rho3, respectively (our unpublished data).

Microscopy and Miscellaneous Methods
Methods in light microscopy, such as fluorescence microscopyand differential interference contrast microscopy, were performedas described previously (Kita et al., 2004). Cell extract preparationand immunoblot analysis were performed as described previously(Sio et al., 2005).

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Isolation of vic Mutants
To identify new components of the protein kinase C-Pmk1 MAPKsignaling pathway, we performed a genetic screen in S. pombebased on the functional interaction that calcineurin and Pmk1MAPK play antagonistic roles in Cl^– homeostasis (Sugiuraet al., 1998). On inhibition of the Pmk1 MAPK signaling, theCl^–-hypersensitive phenotype of calcineurin knockout wascomplemented, i.e., the knockout of pmk1⁺, pek1⁺, mkh1⁺, orpck2⁺ all complemented the Cl^–-hypersensitive phenotypeof calcineurin knockout (Figure 1A, +0.2 M MgCl₂). The inhibitionof calcineurin signaling is also achieved by the immunosuppressantFK506, a specific inhibitor of calcineurin, because wild-typecells failed to grow in the presence of FK506 and 0.2 M MgCl₂(Figure 1A, wt, +FK506 + 0.2 M MgCl₂). Consistently, knockoutof the components of protein kinase C-MAPK signaling makes cellsgrow in the presence of FK506 and MgCl₂ (Figure 1A, +FK506 +0.2 M MgCl₂). We therefore hypothesized that if we isolate mutantsthat can grow in the presence of FK506 and 0.2 M MgCl₂, thegenes responsible for the mutation are expected to functionin the protein kinase C–Pmk1 MAPK signaling. These mayinclude mutations in the unknown factor downstream of Pmk1 orin novel factors required for the activation or function ofPmk1 MAPK. We then performed the isolation of the mutants thatare viable in the presence of immunosuppressant and chlorideion; hence, we named these as vic mutants. By this genetic approach,we isolated several novel mutants, in addition to mkh1, pek1,pmk1, and pck2 mutants (our unpublished data). Here, we focuson the characterization of the vic1-1 mutant.

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Figure 1. A mutation in the vic1⁺/cpp1⁺ gene causes vic and temperature-sensitive phenotypes. (A) Knockout of the components of the Pmk1 MAPK pathway ( ${Delta}$ mkh1, ${Delta}$ pek1, or ${Delta}$ pmk1) or the protein kinase C ( ${Delta}$ pck2) suppressed the Cl^– hypersensitivity caused by calcineurin knockout ( ${Delta}$ ppb1). The cells as shown were streaked onto the plates as indicated, then incubated for 4 d at 27°C. (B) The vic and temperature-sensitive phenotypes of vic1-1/cpp1-v1 mutant cells. Cells transformed with the multicopy vector pDB248 or the vector containing the cpp1⁺ gene were streaked onto the plates as indicated and then incubated for 4 d at 27°C or 3 d at 36°C, respectively. (C) Partial alignment of protein sequences of S. pombe Cpp1 with related proteins from S. cerevisiae (Dpr1p), human (hFT $beta$ ), and tomato (tFT $beta$ ). Sequence alignment was performed using the ClustalW program. Asterisks indicate identical amino acids, and colons indicate similar amino acids. Arrow indicates the mutation site in the aspartic acid 155 of Cpp1, which when mutated to asparagine resulted in vic and temperature-sensitive phenotypes in Cpp1. (D) The phenotypes of cpp1-v1 and ${Delta}$ cpp1. Wild-type cells, cpp1-v1 mutant, and ${Delta}$ cpp1 cells were dropped onto the plates as indicated and then incubated for 4 d at 27°C or 3 d at 33 and 36°C, respectively.

As shown in Figure 1B, the vic1-1 mutants grew well in the presenceof FK506 and 0.2 M MgCl₂ at 27°C wherein wild-type cellsfailed to grow (Figure 1B, + FK506 + 0.2 M MgCl₂). However,vic1-1 mutant cells could not grow at 36°C whereas wild-typecells grew normally (Figure 1B, EMM 36°C). As predicted,the vic1-1 ${Delta}$ ppb1 double mutant cells were able to grow in thepresence of 0.2 M MgCl₂ (our unpublished data), indicating thatthe vic1-1 mutation suppresses the Cl^– sensitivity ofcalcineurin knockout and suggesting that the gene product isinvolved in the regulation of the Pmk1 MAPK pathway.

The vic1-1/cpp1-v1 Is an Allele of the cpp1⁺ Gene That Encodes a $beta$ Subunit of Protein FTase
The vic1⁺ gene was cloned by complementation of the temperature-sensitivegrowth defect of vic1-1 mutant cells (Figure 1B, EMM 36°C,+cpp1⁺). The vic1⁺ gene also complemented the vic phenotypeof vic1-1 mutant cells, because these cells failed to grow inthe presence of FK506 and 0.2 M MgCl₂ at 27°C when the vic1⁺gene was introduced (Figure 1B, + FK506 + 0.2 M MgCl₂, + cpp1⁺).Nucleotide sequencing of the cloned DNA fragment revealed thatthe vic1⁺ gene is identical to the cpp1⁺ gene (SPAC17G6.04c),which encodes the $beta$ subunit of the protein FTase of 382 aminoacids that is highly similar to the human hFT $beta$ and S. cerevisiaeDpr1p. Linkage analysis was performed (see Materials and Methods),and results indicated the allelism between the cpp1⁺ gene andthe vic1-1 mutation. We therefore renamed vic1-1 as cpp1-v1.

To identify the mutation site in the cpp1-v1 allele, the genomicDNA from cpp1-v1 mutant cells was isolated, and the full-lengthcoding region of the cpp1-v1 gene was sequenced. The G-to-Anucleotide substitution caused a highly conserved aspartic acidto be altered to an asparagine residue at the amino acid position155 (Figure 1C, black arrow). We therefore refer to the proteinproduct of the cpp1-v1 gene as Cpp1^D155N.

We constructed Cpp1 knockout (see Materials and Methods), and ${Delta}$ cpp1 cells displayed a slow growth rate even at the permissivetemperature of 27°C as reported by Yang et al. (2000). Incontrast, cpp1-v1 mutant cells grew normally at the permissivetemperature of 27°C (Figure 1D, YPD 27°C). The ${Delta}$ cpp1cells also grew in the presence of FK506 and 0.2 M MgCl₂; however,the growth rate was significantly slower compared with thatof the cpp1-v1 mutant cells (Figure 1D, + FK506 + 0.2 M MgCl₂).Thus, in contrast to the cpp1-v1 mutant cells, the ${Delta}$ cpp1 cellsdid not display a markedly clear vic phenotype. Notably, thedegree of the temperature-sensitive growth defect was more severein ${Delta}$ cpp1 cells, because ${Delta}$ cpp1 cells failed to grow even at 33°C,whereas cpp1-v1 mutant cells grew well (Figure 1D, YPD 33°C).Thus, the cpp1-v1 mutant and ${Delta}$ cpp1 cells displayed similar butdistinct phenotypes, suggesting that FTase activity is partiallydeficient in cpp1-v1 mutant cells. Consistently, overexpressionof Cpp1^D155N suppressed the temperature-sensitive phenotypeof ${Delta}$ cpp1 cells (our unpublished data).

Rho2 Is the Target of Cpp1 Responsible for vic Phenotype
FTase catalyzes the posttranslational modification of Ras andother Ras family proteins. The target proteins have a consensusCAAX motif (where C represents cysteine, A represents aliphaticamino acid, and X preferentially represents methionine, cysteine,serine, alanine, or glutamine) at the C terminus (Maltese, 1990;Cox and Der, 1992; Magee et al., 1992).

In fission yeast, Ras1 (a known target of Cpp1), Rho2, and Rho3small GTPases contain CAAX motif modified by FTase (Figure 2A,FTase), and Rho1 small GTPase contains CAAL motif modified bygeranylgeranyltransferase I (Figure 2A, GGTase I). We examinedthe intracellular localization of Ras1, Rho2, Rho3, and Rho1in wild-type, cpp1-v1 mutant, or ${Delta}$ cpp1 cells, based on the assumptionthat a mutation in the cpp1⁺ gene should cause a defect in thefarnesylation of the target small GTPases, thereby leading toa defect in their intracellular localization.

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Figure 2. Rho2 is the target of Cpp1 responsible for vic phenotype. (A) The C-terminal sequence of Ras1, Rho2, Rho3, and Rho1 in fission yeast. Ras1, Rho2, and Rho3 contain CAAX motif modified by FTase, and Rho1 contains CAAL motif modified by GGTase I. (B) Intracellular localization of various small GTPases in wild-type, cpp1-v1 mutant, and ${Delta}$ cpp1 cells. The GFP-fused Ras1, Rho2, Rho3, or Rho1 was transformed into wild-type, cpp1-v1 mutant, or ${Delta}$ cpp1 cells. The transformants were grown to early log phase in EMM containing 4 µM thiamine and were examined under the fluorescence microscope. Bar, 10 µm. (C) Defective modification of Rho2, Ras1, and Rho3 in cpp1-v1 mutant and ${Delta}$ cpp1 cells. The FLAG-fused Rho2, Ras1, or Rho3 was transformed into wild-type or cpp1-v1 mutant cells. The transformants were grown in EMM in the absence of thiamine at 27°C for 20 h, and then the cells were collected and lysed. Cell extracts were subjected to 15% polyacrylamide gel and immunoblotted using anti-FLAG antibody. Prenylated and unmodified forms of Rho2, Ras1, or Rho3 are indicated. (D) ${Delta}$ rho2 cells showed vic phenotype. The cells as shown were dropped onto the plates as indicated and then incubated for 4 d at 27°C. (E) Morphology of ${Delta}$ rho2, ${Delta}$ ras1, and ${Delta}$ rho3 cells. Cells were grown to mid-log phase in YPD at 27°C and were observed under the differential interference contrast microscopy. Bar, 10 µm.

As shown in Figure 2B, in wild-type cells all these small GTPasespredominantly localized to the plasma membrane. However, incpp1-v1 mutant cells and ${Delta}$ cpp1 cells, the plasma membrane localizationof Ras1 or Rho2 was not clearly observed. In contrast, in cpp1-v1mutant cells the plasma membrane localization of Rho3 was clearlyobserved, and in ${Delta}$ cpp1 cells it was abolished. Note that thelocalization of CAAL-ending GTPase Rho1 was not affected ineither cpp1-v1 mutant or ${Delta}$ cpp1 cells. ${Delta}$ cpp1 cells displayed theround cell shape as reported previously owing to the defectivefarnesylation of Ras1 (Yang et al., 2000

, 2001

) (Figure 2B, ${Delta}$ cpp1). In clear contrast, the cpp1-v1 mutant cells displayedcylindrical cell shape (Figure 2B, cpp1-v1), suggesting thatfarnesylation of Ras1 in cpp1-v1 mutant cells is not considerablydefective so as to affect the cell shape. These results suggestthat CAAX-ending Ras1, Rho2, and Rho3 are targets of Cpp1 infission yeast. More importantly, the partial loss of the farnesyltransfereaseactivity caused by the cpp1-v1 mutation differentially impactsthe function of these small GTPases.

To investigate whether there is a defect in the farnesylationof these three substrates in cpp1-v1 mutant cells, we constructedFLAG-tagged Rho2, Ras1, and Rho3, and we expressed these inwild-type, cpp1-v1 mutant, and ${Delta}$ cpp1 cells. As shown in Figure 2C,Rho2, Ras1, and Rho3 extracted from ${Delta}$ cpp1 cells migrated slower(unmodified), compared with those from wild-type cells (prenylated).Rho2, Ras1, and Rho3 extracted from the cpp1-v1 mutant cellsexhibited significantly different patterns of migration fromthe wild-type or ${Delta}$ cpp1 cells (Figure 2C). Notably, in cpp1-v1mutant cells, prenylation of Ras1 and Rho2 was severely impaired,whereas that of Rho3 was modestly impaired (Figure 2C).

Because our intention is to identify components of the proteinkinase C–Pmk1 MAPK signaling by isolating vic mutants,we next investigated whether the knockout cells of the threetargets exhibit vic phenotype similar to that of cpp1-v1/vic1-1cells. Results clearly showed that ${Delta}$ rho2 cells, but not ${Delta}$ ras1or ${Delta}$ rho3 cells, were able to grow in the presence of FK506 and0.2M MgCl₂ (Figure 2D). These results raise the possibilitythat Cpp1-Rho2 is involved in the protein kinase C-Pmk1 MAPKsignaling. We also examined the morphology of ${Delta}$ rho2, ${Delta}$ ras1, and ${Delta}$ rho3 cells to understand the differential roles of differentsmall GTPases in cellular morphogenesis. ${Delta}$ ras1 cells displayedthe round cell shape similar to that of ${Delta}$ cpp1 cells, whereasneither ${Delta}$ rho2 nor ${Delta}$ rho3 cells showed obvious defect in morphology(Figure 2E).

Farnesylation by Cpp1 Is Essential for the Membrane Localization and Function of Rho2
To examine whether the membrane localization of Rho2 is criticalfor its function, we created various mutant versions of Rho2at its C terminus. As shown in Figure 2B and here, wild-typeRho2 (Rho2CIIS) localized to the plasma membrane in wild-typecells, but not in cpp1-v1 mutant or ${Delta}$ cpp1 cells (Figure 3A, GFP-Rho2CIIS).In contrast, the geranylgeranylated mutant form of Rho2 (Rho2CIIL),which bypasses the farnesylation requirement, localized to theplasma membrane both in wild-type cells and in cpp1 mutant cells,indicating that geranylgeranylation allows Rho2 to associatewith the membrane even in the absence of farnesylation (Figure 3A,GFP-Rho2CIIL). However, the prenylation-defective Rho2 (Rho2SIIS),wherein the cysteine in the CAAX-motif was replaced with serine,failed to localize to the plasma membrane even in wild-typecells (Figure 3A, GFP-Rho2SIIS).

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Figure 3. Farnesylation by Cpp1 is essential for the proper membrane localization and function of Rho2. (A) Intracellular localization of GFP-fused wild-type Rho2 (Rho2CIIS), the geranylgeranylated mutant version of Rho2 (Rho2CIIL), or the prenylation-defective mutant version of Rho2 (Rho2SIIS) in wild-type, cpp1-v1 mutant or ${Delta}$ cpp1 cells. The GFP-Rho2CIIS, GFP-Rho2CIIL, or GFP-Rho2SIIS was transformed into wild-type, cpp1-v1 mutant, or ${Delta}$ cpp1 cells. The transformants were cultured and examined as in Figure 2B. (B) The plasma membrane localization is essential for Rho2 function. Wild-type Rho2 (Rho2CIIS) and the geranylgeranylated mutant version of Rho2 (Rho2CIIL), but not the prenylation-defective mutant version of Rho2 (Rho2SIIS), suppressed the phenotypes. The ${Delta}$ rho2 cells harboring the control vector, Rho2CIIS, Rho2CIIL, or Rho2SIIS were streaked onto the plates as indicated and then incubated for 4 d at 27°C or 3 d at 37°C, respectively. (C) Geranylgeranylated mutant version of Rho2 (Rho2CIIL) suppressed the vic phenotype of cpp1-v1 mutant cells. The cpp1-v1 mutant cells harboring the control vector, Rho2CIIS, Rho2CIIL, or Rho2SIIS were dropped onto the plates as indicated and then incubated for 4 d at 27°C.

Notably, Rho2CIIL, which localized to the plasma membrane, fullysuppressed the temperature-sensitive and vic phenotypes of ${Delta}$ rho2cells, suggesting that geranylgeranylated Rho2, which bypassesfarnesylation, can function as well as farnesylated Rho2 (Figure 3B,+Rho2CIIL). On the other hand, Rho2SIIS, which failed to localizeto the plasma membrane, could not suppress the phenotypes (Figure 3B,+Rho2CIIS), suggesting that the plasma membrane localizationof Rho2 is critical for its function.

To address whether the vic phenotype of cpp1-v1 mutant cellsis because of the defective farnesylation of Rho2, we overexpressedthese mutant forms of Rho2 in cpp1-v1 mutant cells. As expected,only Rho2CIIL, which can localize to the plasma membrane evenin cpp1-v1 mutant cells, reversed the vic phenotype of cpp1-v1mutant cells, whereas Rho2CIIS and Rho2SIIS could not (Figure 3C).Thus, Rho2 is the target of Cpp1, that is responsible for thevic phenotype of cpp1-v1 mutant cells, strongly suggesting thatCpp1 functions in Pmk1 MAPK signaling through Rho2 regulation.

Cpp1 and Rho2 Act Upstream of the Pck2–Pmk1 MAPK Pathway
As a first step to examine the functional relationship betweenCpp1-Rho2 and Pmk1 signaling, we examined whether the vic phenotypeis a specific indication for Pmk1 MAPK signaling, or whetherit is shared by other MAPK pathways in fission yeast. For this,null cells of sty1⁺ encoding a stress-activated MAPK or spk1⁺encoding a MAPK involved in meiosis was compared with rho2 nullcells, cpp1 mutant cells, together with null cells of the componentsof the Pmk1 MAPK pathway. Results clearly showed that ${Delta}$ rho2,cpp1 mutant cells, as well as ${Delta}$ pmk1, ${Delta}$ pek1, ${Delta}$ mkh1, or ${Delta}$ pck2 grewin the presence of FK506 and 0.15M MgCl₂, but ${Delta}$ sty1 or ${Delta}$ spk1 couldnot grow (Figure 4A, +FK506 + 0.15M MgCl₂), indicating thatthe vic phenotype is specifically shared by the mutations inthe components of the protein kinase C–Pmk1 MAPK signalingpathway.

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Figure 4. Rho2 functions upstream of the Pck2–Pmk1 MAPK pathway. (A) Knockout of the rho2⁺, pck2⁺, and the component of the Pmk1 MAPK pathway exhibited vic phenotype and micafungin sensitivity. The cells as indicated were streaked onto the indicated plates and then incubated for 4 d at 27°C. (B) Overexpression of Rho2 showed toxicity to wild-type cells, but not to ${Delta}$ pck2, ${Delta}$ mkh1, ${Delta}$ pek1, or ${Delta}$ pmk1 cells. The cells as indicated transformed with pREP1-GFP-Rho2 were dropped onto EMM plate with or without 4 µM thiamine and then incubated for 4 d at 27°C. (C) Overexpression of Pck2 showed toxicity to wild-type cells but not to ${Delta}$ mkh1, ${Delta}$ pek1, or ${Delta}$ pmk1 cells. The cells as shown harboring pREP1-GFP-Pck2 were dropped onto the plate as indicated and then incubated as in Figure 4B. (D) Rho2 stimulates the phosphorylation of Pmk1 in vivo. Wild-type cells containing pREP42-GST-Pmk1 and either pREP1-vector (+vector), pREP1-pek1^DD (+Pek1^DD), pREP1-Pck2 (+Pck2), pREP1-Rho2 (+Rho2), pREP1-Pck1 (+Pck1), pREP1-Ras1 (+Ras1), or pREP1-Rho3 (+Rho3) were grown in EMM. Immunoblotting using anti-phospho Pmk1 (top) and anti-GST (bottom) antibodies showed that overproduction of Pek1^DD, Pck2 as well as Rho2 but not that of Pck1 increased the levels of phosphorylation of Pmk1. (E) ${Delta}$ rho2 ${Delta}$ mkh1, ${Delta}$ rho2 ${Delta}$ pek1, ${Delta}$ rho2 ${Delta}$ pmk1, or ${Delta}$ rho2 ${Delta}$ pck2 double mutants did not show synergism in the sensitivity to micafungin. The cells as indicated were dropped onto the plate as indicated and then incubated as in Figure 4B. (F) Pck2 associates with Mkh1. Cells integrated with GFP-Pck2 were transformed with the control GST vector or pREP1—GST–Mkh1 and then grown in EMM medium in the absence of thiamine for 20 h. GST-Mkh1 and GST were precipitated by glutathione beads, washed extensively, and subjected to SDS-PAGE and immunoblotted using anti-GFP or anti-GST antibodies.

Because mutations that perturb the signaling through the proteinkinase C–Pmk1 MAPK pathway are known to result in defectivecell integrity (Toda et al., 1996

), we examined whether knockoutof the components of the protein kinase C–Pmk1 MAPK signalingpathway display hypersensitivity to the cell wall-damaging agentmicafungin, an inhibitor of (1,3)- $beta$ -D-glucan synthase (Carver,2004

). The ${Delta}$ rho2, ${Delta}$ cpp1 as well as ${Delta}$ pck2 or knockout of the componentsof Pmk1 MAPK pathway were hypersensitive to micafungin, whereasthe growth of ${Delta}$ sty1 or ${Delta}$ spk1 cells was not inhibited in the presenceof 1.2 µg/ml micafungin (Figure 4A, top, + 1.2 µg/mlmicafungin). Thus, the vic phenotype and the sensitivity tomicafungin are specific indications of defective protein kinaseC–Pmk1 MAPK signaling. Interestingly, ${Delta}$ rho3 cells, butnot ${Delta}$ ras1 cells, displayed hypersensitivity to micafungin (Figure 4A,bottom), whereas neither of them showed the vic phenotype (Figure 2D).

We next examined whether Rho2 acts upstream of the protein kinaseC–Pmk1 MAPK signaling. As reported by Calonge et al. (2000)and as shown here (Figure 4B), overexpression of Rho2 is toxicto wild-type cells, but not to ${Delta}$ pck2 cells. If the toxicity ofRho2 overexpression is caused by the hyperactivation of Pmk1MAPK pathway, it would be expected that this toxicity couldbe complemented by knockout of the components of Pmk1 signalingpathway. As expected, the overexpression of Rho2 was not toxicto ${Delta}$ mkh1, ${Delta}$ pek1, and ${Delta}$ pmk1 cells (Figure 4B), indicating that thetoxicity of Rho2 overexpression is mediated by Pck2 and Mkh1–Pek1–Pmk1signaling pathway. Similarly, overexpression of Pck2 causedthe lethality in wild-type cells, but not in ${Delta}$ mkh1, ${Delta}$ pek1 and ${Delta}$ pmk1 cells (Figure 4C), indicating that the lethality causedby Pck2 overexpression is mediated by Mkh1–Pek1–Pmk1signaling. Together, these genetic analyses strongly suggestthat Rho2 functions upstream of Pck2–Mkh1–Pek1–Pmk1signaling.

To further confirm that Rho2–Pck2 activates and transmitssignaling to Pmk1, we examined the effects of Rho2, Pck2, orPck1 overexpression on the phosphorylation levels of Pmk1 MAPKby using anti-phospho Pmk1 antibodies (Sugiura et al., 1999).As shown in Figure 4D, overexpression of Rho2 and Pck2 dramaticallyincreased the phosphorylation levels of Pmk1 similar to thatobtained from the overexpression of Pek1^DD, a constitutivelyactive MAPKK for Pmk1 (Figure 4D). In clear contrast, overexpressionof Pck1 did not increase the phosphorylation level of Pmk1 (Figure 4D).Thus, Rho2–Pck2 acts upstream of the Pmk1 MAPK pathwayand stimulates the Pmk1 signaling in vivo. In addition, overexpressionof Ras1 or Rho3 did not increase the phosphorylation level ofPmk1 (Figure 4D). Together with the results of Figures 2D and4A, this suggests that Rho3 is involved in the regulation ofcell wall integrity but independently of the Pmk1 signalingpathway.

Next, we constructed a series of double mutants between ${Delta}$ rho2and knockout of the components of the protein kinase C–Pmk1MAPK signaling and compared the sensitivity to micafungin witheach single mutant. The ${Delta}$ rho2 cells showed a relatively weaksensitivity to micafungin, because ${Delta}$ rho2 cells grew in the presenceof 0.6 µg/ml micafungin, wherein ${Delta}$ mkh1, ${Delta}$ pek1, ${Delta}$ pmk1, or ${Delta}$ pck2 mutants failed to grow. However, ${Delta}$ rho2 ${Delta}$ mkh1, ${Delta}$ rho2 ${Delta}$ pek1, ${Delta}$ rho2 ${Delta}$ pmk1or ${Delta}$ rho2 ${Delta}$ pck2 double knockout mutant cells failed to grow in thepresence of 0.4 µg/ml micafungin and do not show synergismin the sensitivity to micafungin compared with the parentalsingle knockout (Figure 4E).

The above-mentioned results strongly suggest that Pck2 functionsupstream of Pmk1. We thus examined whether Pck2 associates withthe MAPKKK Mkh1. For this, we expressed glutathione S-transferase(GST)-fused Mkh1 in strains where GFP-Pck2 is chromosomallyintegrated. In the GST pull-down assay, GFP–Pck2 associateswith GST–Mkh1 but not with control GST vector alone (Figure 4F),indicating a protein–protein interaction between Pck2and Mkh1.

Pck1 Is Involved in Cell Integrity Signaling and Acts Independently of the Pmk1 MAPK Pathway
In the study by Toda et al. (1993), Pck1 and Pck2 have beenreported to share an overlapping function for cell viabilityand to partially complement each other. We then examined whetherPck2 and Pck1 share an overlapping function in cell integrityand chloride ion homeostasis.

For this, we first compared ${Delta}$ pck1 and ${Delta}$ pck2 cells regarding vicphenotype. Results clearly showed that ${Delta}$ pck2, but not ${Delta}$ pck1, grewin the presence of FK506 and 0.2 M MgCl₂ (Figure 5A), suggestingthat Pck1 is not involved in Cl^– homeostasis. We alsocompared ${Delta}$ pck1 and ${Delta}$ pck2 cells regarding the cell integrity defect.As shown in Figure 5B, at a higher concentration of micafungin(0.6 µg/ml), the growth of ${Delta}$ pck1 and ${Delta}$ pck2 cells were significantlyinhibited, but at a lower concentration of micafungin (0.4 µg/ml),the growth of ${Delta}$ pck2 cells was markedly inhibited compared withthat of ${Delta}$ pck1 cells. These results indicate that although ${Delta}$ pck1and ${Delta}$ pck2 cells are both sensitive to micafungin, ${Delta}$ pck1 cellsdisplayed a weaker sensitivity to micafungin compared with ${Delta}$ pck2cells.

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Figure 5. Pck1 is involved in cell integrity signaling and acts independently of the Pmk1 MAPK pathway. (A) The phenotypes of ${Delta}$ pck2 and ${Delta}$ pck1. Wild-type, ${Delta}$ pck2, or ${Delta}$ pck1 cells were dropped onto the plates as indicated and then incubated for 4 d at 27°C. (B) ${Delta}$ rho2 ${Delta}$ pck1 double mutants showed synergism in the sensitivity to micafungin. Wild-type, ${Delta}$ pck1, ${Delta}$ rho2, or ${Delta}$ rho2 ${Delta}$ pck1 cells were dropped onto the plates as indicated and then incubated for 4 d at 27°C. (C) pck1⁺, but not pck2⁺, partially suppressed the micafungin sensitivity of ${Delta}$ mkh1 and ${Delta}$ pmk1 cells. The ${Delta}$ mkh1 or ${Delta}$ pmk1 cells were transformed with the control vector, pck1⁺ or pck2⁺ gene. The transformants were dropped onto the plates as indicated and then incubated for 4 d at 27°C. (D) Pck1 does not associate with Mkh1. GFP-Pck1 integrated cells were transformed with the control GST vector or pREP1-GST-Mkh1 and then grown in EMM medium in the absence of thiamine for 20 h. Pull-down assay was performed as described in Figure 4E.

As shown in Figure 4D, ${Delta}$ rho2 ${Delta}$ pck2 double mutants showed micafunginsensitivity to the same extent as that of ${Delta}$ pck2 mutants. Here,we constructed ${Delta}$ rho2 ${Delta}$ pck1 double mutants and investigated themicafungin sensitivity. Although both ${Delta}$ pck1 cells and ${Delta}$ rho2 cellscan grow in the presence of 0.4 µg/ml micafungin, ${Delta}$ rho2 ${Delta}$ pck1double mutants failed to grow in the presence of 0.4 µg/mlmicafungin, indicating a synergism in the sensitivity to micafungincompared with that of the parental single knockout (Figure 5B).Thus, Pck1 seems to play a role in cell integrity in parallelto the Rho2–Pck2–Mkh1–Pek1–Pmk1 signalingpathway. Consistently, our recent study showed that Pmk1 isrequired for the stimulation of calcineurin via Yam8/Cch1-mediatedCa²⁺ influx and that knockout of pck2⁺, but not pck1⁺ gene,markedly diminished the Yam8/Cch1-dependent stimulation of calcineurinactivity, suggesting that Pck2 acts upstream of the Pmk1 inthis signaling pathway (Deng et al., 2006).

Furthermore, overexpression of pck1⁺, but not pck2⁺, partiallysuppressed the micafungin sensitivity of ${Delta}$ mkh1 and ${Delta}$ pmk1 cells(Figure 5C). Overexpression of pck1⁺ also partially suppressedthe micafungin sensitivity of ${Delta}$ pek1 cells (our unpublished data).These results indicate that Pck1 stimulates the cell integritysignaling independently of the Pmk1 MAPK pathway, whereas Pck2exerts its function on cell integrity through the MAPK pathway.In addition, a pull-down experiment demonstrated that Pck1 doesnot associate with Mkh1 (Figure 5D), in clear contrast to theassociation observed between Pck2 and Mkh1 (Figure 4F). Theseresults are in good agreement with the findings obtained withphosphorylation experiments.

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In the present study, we performed a novel genetic screen thataims to identify new regulators of the Pmk1 signaling, and weidentified a missense mutation of the cpp1⁺ gene encoding FTase.Substitution of a highly conserved aspartic acid to an asparagineresidue at the amino acid position 155 resulted in the partialbut severe impairment of the FTase activity in cpp1-v1 mutantcells.

Interestingly, the cpp1-v1 mutation caused the differentialeffects on the function of its substrates. That is, the membranedistribution of Ras1 and Rho2 was apparently abolished but thatof Rho3 was still maintained in cpp1-v1 mutant cells, indicatingthat Rho3 farnesylation is not completely abolished in cpp1-v1mutant cells. This is in good correlation with the moderatedefect of prenylation as shown in Figure 2C. Furthermore, althoughRas1 prenylation was severely impaired in cpp1-v1 mutant cells(Figure 2C), the function of Ras1 seemed to be maintained inthe cpp1-v1 mutant cells because their cell shape was not somuch affected compared with that of ${Delta}$ cpp1 cells. In clear contrast,the function of Rho2 seemed to be severely impaired in the cpp1-v1mutant cells, because the mutant cells showed a clear vic phenotypesimilar to that of the ${Delta}$ rho2 cells. These results suggest thatRho2 function is preferentially sensitive to defect of FTaseactivity in the cpp1-v1 mutant cells.

Although a numbers of studies showed that functions of Ras proteinsdepend on its farnesylation, the identities of the relevantfarnesylated proteins in human oncogenesis are not fully resolved.FTIs clearly have the potential to inhibit oncogenic Ras signaling,but FTIs are also effective on tumor cell lines that do notcontain mutant Ras (Sepp-Lorenzino et al., 1995; End et al.,2001), suggesting that the pharmacological effects extend outsideof the Ras protein (Tamanoi et al., 2001). RhoB, a small GTPaseof the mammalian Rho family has been suggested as a potentialrelevant FTI target (Prendergast, 2001; Cox and Der, 2002).RhoB exists as both farnesylated and geranylgeranylated forms,whereas the highly homologous RhoA and RhoC isoforms are solelygeranylgeranylated (Adamson et al., 1992). Treatment of cellswith FTIs causes a loss of farnesylated RhoB and a consequentincrease in geranylgeranylated RhoB (Lebowitz et al., 1997),and these changes in prenylation have been implicated in theantineoplastic responses to FTIs (Liu et al., 2000).

Given the high degree of conservation of FTase, Ras and Rhoproteins as well as its involvement in human oncogenesis, thecpp1-v1 mutant may be a useful model for studying the conservedmolecular mechanism of protein farnesylation and the differentialeffects of FTase inhibition on the various substrates.

In conclusion, the identification and analyses of cpp1-v1 mutantcells have demonstrated for the first time the functional importanceof the posttranslational modification of Rho GTPase proteinin the activation of cell integrity signaling through proteinkinase C–MAPK pathway. Because of the high similaritybetween the fission yeast and mammalian MAPK pathway, the screenof vic mutants would further provide an excellent opportunityto identify novel components of MAPK cascade and analyze regulatorymechanisms of MAPK signaling in higher eucaryotes.

ACKNOWLEDGMENTS

We thank Drs. Takashi Toda, Mitsuhiro Yanagida, and MasayukiYamamoto for providing strains and plasmids; Susie O. Sio forcritical reading of the manuscript; and Fujisawa PharmaceuticalCo. for the gift of FK506. This work was supported by the 21stCentury Centers of Excellence Program, the Asahi Glass Foundation,the Uehara Memorial Foundation, and research grants from theMinistry of Education, Culture, Sports, Science, and Technologyof Japan.

Footnotes

This was published online ahead of print in MBC in Press(http://www.molbiolcell.org/cgi/doi/10.1091/mbc.E06-08-0688)on September 27, 2006.

Address correspondence to: Reiko Sugiura (sugiurar{at}phar.kindai.ac.jp)

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