The Rho3 and Rho4 small GTPases interact functionally with Wsc1p, a cell surface sensor of the protein kinase C cell-integrity pathway in Saccharomyces cerevisiae

doi:10.1099/mic.0.28231-0

HOME

HELP

FEEDBACK

SUBSCRIPTIONS

The Rho3 and Rho4 small GTPases interact functionally with Wsc1p, a cell surface sensor of the protein kinase C cell-integrity pathway in Saccharomyces cerevisiae

Helder Fernandes, Olivier Roumanie, Sandra Claret, Xavier Gatti, Didier Thoraval, François Doignon and Marc Crouzet

Laboratoire de Biologie Moléculaire et de Séquençage, Institut de Biochimie et Génétique Cellulaires, UMR Université Victor Segalen Bordeaux 2-CNRS 5095, box 64, 146 rue Léo Saignat, 33076 Bordeaux Cedex, France

Correspondence
François Doignon
doignon{at}u-bordeaux2.fr

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Rgd1, a GTPase-activating protein, is the only known negativeregulator of the Rho3 and Rho4 small GTPases in the yeast Saccharomycescerevisiae. Rho3p and Rho4p are involved in regulating cellpolarity by controlling polarized exocytosis. Co-inactivationof RGD1 and WSC1, which is a cell wall sensor-encoding gene,is lethal. Another plasma membrane sensor, Mid2p, is known torescue the rgd1 ${Delta}$ wsc1 ${Delta}$ synthetic lethality. It has been proposedthat Wsc1p and Mid2p act upstream of the protein kinase C (PKC)pathway to function as mechanosensors of cell wall stress. Analysisof the synthetic lethal phenomenon revealed that productionof activated Rho3p and Rho4p leads to lethality in wsc1 ${Delta}$ cells.Inactivation of RHO3 or RHO4 was able to rescue the rgd1 ${Delta}$ wsc1 ${Delta}$ synthetic lethality, supporting the idea that the accumulationof GTP-bound Rho proteins, following loss of Rgd1p, is detrimentalif the Wsc1 sensor is absent. In contrast, the genetic interactionbetween RGD1 and MID2 was not due to an accumulation of GTP-boundRho proteins. It was proposed that simultaneous inactivationof RGD1 and WSC1 constitutively activates the PKC–mitogen-activatedprotein kinase (MAP kinase) pathway. Moreover, it was shownthat the activity of this pathway was not involved in the syntheticlethal interaction, which suggests the existence of anothermechanism. Consistent with this idea, it was found that perturbationsin Rho3-mediated polarized exocytosis specifically impair theabundance and processing of Wsc1 and Mid2 proteins. Hence, itis proposed that Wsc1p participates in the regulation of a Rho3/4-dependentcellular mechanism, and that this is distinct from the roleof Wsc1p in the PKC–MAP kinase pathway.

Abbreviations: ASR, arrest of secretion response; 5-FOA, 5-fluoroorotic acid; GAP, GTPase-activating protein; HA, haemagglutinin; MAP kinase, mitogen-activated protein kinase; PKC, protein kinase C; WT, wild type

Supplementary Fig. S1, available with the online versionof this paper, shows the detection of phosphorylated and totalSlt2p in isogenic WT and rho3-V51 strains grown in syntheticmedium, the detection of phosphorylated and total Slt2p in aWT strain co-producing WT, GDP-blocked or GTP-blocked formsof Rho3 and Rho4 proteins from pCM185 and pCM189 plasmids, andthe detection of phosphorylated and total Slt2p in a WT strainproducing the GTP-blocked form of Rho3p or Rho4p from the pCM185plasmid.

${dagger}$ These authors contributed equally to this work.

${ddagger}$ Present address: Laboratoire de Génétique du Développementet Evolution, Institut Jacques Monod, 75251 Paris Cedex 05,France.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Monomeric GTPases of the Ras superfamily are key regulatorsof numerous physiological processes. They are classified intofive families: Ras, Rho/Rac/Cdc42, Rab, Sar1/Arf and Ran (VanAelst & D'Souza-Schorey, 1997; Etienne-Manneville &Hall, 2002). In the yeast Saccharomyces cerevisiae, six functionalRho proteins, namely Cdc42 and Rho1–Rho5, have been described(Garcia-Ranea & Valencia, 1998; Roumanie et al., 2001; Schmitzet al., 2002). Like most members of the Ras superfamily, RhoGTPases cycle between an active GTP-bound form and an inactiveGDP-bound form to control cell polarity by regulating secretion,actin cytoskeleton organization, and cell wall modelling (Johnson& Pringle, 1990; Matsui & Toh-e, 1992a; Robinson etal., 1999; Adamo et al., 2001; Roumanie et al., 2005). The balancebetween GDP- and GTP-bound forms is regulated by guanine nucleotideexchange factors, which promote GDP release and binding of GTP,and by GTPase-activating proteins (GAPs), which accelerate GTPhydrolysis by Rho proteins (Van Aelst and D'Souza-Schorey, 1997).

The yeast Rgd1 protein is known to possess GAP activity towardsboth Rho3 and Rho4 small G proteins (Doignon et al., 1999).By activating GTP hydrolysis, Rgd1p negatively regulates Rho3/4GTPases, and lack of Rgd1p leads to an accumulation of the GTP-boundforms of these two small G proteins in the cell (Roumanie etal., 2000). Inactivation of the RGD1 gene is not associatedwith a defect in cell polarity (de Bettignies et al., 1999);however, it results in an increase in cell mortality in thelate-exponential growth phase (Barthe et al., 1998). Rho3p andRho4p functions are partially redundant, and are involved incell polarity by regulating polarized exocytosis and actin cytoskeletonorganization (Matsui & Toh-e, 1992b; Roumanie et al., 2005).While no defect is associated with RHO4 deletion, inactivationof both RHO3 and RHO4 genes results in a severe growth phenotype,and lysis of cells with small buds. The Rho3 and Rho4 GTPaseshave been shown to bind the exocyst complex subunit Exo70, andto interact with formins to activate actin cable formation (Robinsonet al., 1999; Dong et al., 2003). Moreover, Rho3p has been shownto have a direct role in post-Golgi secretion by enabling polarizedfusion of secretory vesicles with the plasma membrane (Adamoet al., 1999). A recent study has demonstrated that regulationof cell polarity by Rho3p is independent of GTP hydrolysis (Roumanieet al., 2005), suggesting that, in yeast, Rgd1p GAP activityfunctions with other proteins to regulate Rho3p and Rho4p functionin cell growth.

Indeed, studies from our laboratory have implicated Rgd1p inthe regulation of cell polarity. We have reported the existenceof functional interactions between Rgd1p and the Arp2/3 complexactivators Vrp1p and Las17p (Roumanie et al., 2000). Geneticinteractions between RGD1 and WSC1 genes have also been demonstratedpreviously (de Bettignies et al., 1999). WSC1 encodes a highlyO-glycosylated integral membrane protein that acts as a parietalstress sensor once anchored to the plasma membrane (Verna etal., 1997). It has been found that although lack of Rgd1p orWsc1p under standard growth conditions does not have any effecton yeast, the combination of both rgd1 ${Delta}$ and wsc1 ${Delta}$ mutations leadsto cell mortality. At the same time, the Mid2p cell wall sensor,which has functions partially overlapping with those of Wsc1p(Ketela et al., 1999), was characterized as a suppressor ofthe rgd1 ${Delta}$ wsc1 ${Delta}$ synthetic lethality. Nevertheless, co-deletionof RGD1 and MID2 is not lethal under regular growth conditions,but leads to conditional lethality in the late-exponential growthphase (de Bettignies et al., 1999). At the plasma membrane,both the Wsc1 and Mid2 proteins monitor the integrity of yeastcell wall, and can activate the protein kinase C (PKC) pathway(Gray et al., 1997; Verna et al., 1997; Jacoby et al., 1998;Ketela et al., 1999; Rajavel et al., 1999; Martin et al., 2000).The PKC pathway is activated in response to various externalstresses, including high temperature, low osmolarity, cell wallperturbation, and mating (Heinisch et al., 1999). Pkc1 kinaseactivation is dependent on the interaction with stress-activatedRho1 GTPase (Nonaka et al., 1995; Kamada et al., 1996). ThePKC pathway is composed of a MAP kinase module involving theBck1, Mkk1/Mkk2 and Slt2 kinases (Gustin et al., 1998). It isknown that activated Wsc1p regulates both the PKC pathway and1,3- $beta$ -glucan synthesis, while Mid2p acts mainly on the PKC pathway(Sekiya-Kawasaki et al., 2002).

To gain insight into the cellular mechanism by which Rgd1p interactswith the cell wall sensor Wsc1, we investigated the role ofRho3 and Rho4 GTPases in the rgd1 ${Delta}$ wsc1 ${Delta}$ synthetic lethality. Inthis study, we report that the lethality involves an accumulationof activated Rho proteins, and that this is detrimental to thesurvival of wsc1 ${Delta}$ cells; however, the synthetic lethality isnot linked to a defect in the MAP kinase module of the PKC pathway.Moreover, functional interactions involving RGD1, and WSC1 orMID2, are distinct. Disturbance in the Golgi-to-plasma-membranesecretion leads to a specific defect in cell wall sensor abundance.Our results support the involvement of Wsc1 in a cellular pathwayconnected to Rho3p-regulated trafficking.

METHODS

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Yeast strains and genetic procedures.
The Saccharomyces cerevisiae strains used in this study, andtheir genetic backgrounds, are described in Table 1. Allthe strains, except rho3-V51, are isogenic to the S288C strain.Standard yeast genetic methods and media preparation were performedas described by Sherman et al. (1986). Unless otherwise indicated,yeast strains were grown at 30 °C. Yeast transformationwas performed according to Gietz et al. (1995). Dead cells werevisualized by Methylene Blue staining, and enumerated by microscopicexamination of at least 300 cells (Rose, 1975). The standarddeviation on determination of the percentage of lethality wascalculated to be 2·5 %.

View this table:
[in this window]
[in a new window]

Table 1. S. cerevisiae strains used in this study

Production of Rho3 and Rho4 GTPases.
Production of wild-type (WT), GDP- and GTP-blocked Rho3 andRho4 proteins was carried out using the pCM plasmid-based system,as described previously (Roumanie et al., 2000

). GDP-blockedmutant forms were obtained by substitution of threonine withasparagine at position 30 in Rho3p, and at position 86 in Rho4p.GTP-blocked mutants were obtained by replacing glutamines 74and 131 with leucine in Rho3 and Rho4, respectively. Repressionof protein production from the pCM system was obtained by adding1 µg doxycycline ml^–1 to the medium. Turn-onwas induced by putting cells in doxycycline-free medium. Completeactivation of production was obtained after about 8 h growth(Gari et al., 1997

; Roumanie et al., 2000

Heat-shock experiments.
The heat-shock experiments were performed essentially as describedby Martin et al. (2000). In brief, cells were grown overnightat 21 °C to mid-exponential phase (OD₆₀₀ 0·5), andthen either shifted to 39 °C, or kept at 21 °C. After2 h incubation, proteins were extracted, subjected to SDS-PAGE,transferred to nitrocellulose, and probed with ${alpha}$ -phospho-Slt2pantibodies to monitor PKC pathway activation.

Immunoblot analysis.
Protein extraction from yeast for Western blot analysis wasperformed according to Riezman et al. (1983). The YEp352-MID2^3HAand YEp352-WSC1^3HA plasmids were used to produce Mid2 and Wsc1proteins tagged at their C-terminals with a three-repeat haemagglutinin(HA), as described by Rajavel et al. (1999). Blots were probedfor phosphorylated Slt2p with ${alpha}$ -phospho-p44/42 MAP kinase (Thr202/Tyr204)antibody from Cell Signalling at 1 : 666 dilution. Total Slt2pwas detected with ${alpha}$ -GST-Slt2p antibodies, kindly provided byH. Martin and M. Molina (Universidad Complutense de Madrid,Madrid, Spain), at 1 : 2500 dilution. Fur4 and Ure2 proteinswere detected using specific polyclonal antibodies at 1 : 1000and 1 : 3000 dilutions, respectively (Silve et al., 1991; Fernandez-Bellotet al., 2002). Anti-HA 12CA5 monoclonal antibody was used at1 : 10 000 dilution. Primary antibodies were detected with ${alpha}$ -mouseor ${alpha}$ -rabbit antibodies coupled to horseradish peroxidase (Pierce)at 1 : 10 000 dilution. Protein–antibody complexes werevisualized with the Lumi-Light^PLUS system (Roche). Quantificationof bands was done using the ImageJ program (National Institutesof Health).

RESULTS

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Accumulation of activated Rho3p in WT cells leads to the rgd1 ${Delta}$ -like phenotype
In a previous study, we reported that about 20 % of rgd1 ${Delta}$ cellsdie at the end of the exponential growth phase, when grown inminimal medium (Barthe et al., 1998; de Bettignies et al., 1999).As the GAP domain of Rgd1p negatively regulates Rho3p and Rho4pGTPase activities (Doignon et al., 1999), we decided to explorethe involvement of these two small G proteins in the rgd1 ${Delta}$ phenotype.We hypothesized that, as a consequence of RGD1 inactivation,there was an accumulation of activated forms of Rho3p and Rho4p,and that this was detrimental to the survival of the yeast.Constitutively activated (GTP-blocked), inactivated (GDP-blocked)and WT forms of Rho3p and Rho4p were produced in the WT straingrown in YNB minimal medium, in order to examine the effectson cell morphology and lethality. We observed that the constitutivelyactive Rho3 led to a cell growth defect, as compared with cellscontaining endogenous Rho3p (control vector) only. Expressionof the other mutant forms did not show any detectable growthdefect (data not shown). Moreover, microscopic examination ofcells producing activated Rho3p or Rho4p revealed heterogeneousmorphological defects (Fig. 1A). The morphological alterationswere found to increase proportionally with an increase in cell-culturedensity. For example, at an OD₆₀₀ of 1·5, half of theyeast cells producing GTP-blocked Rho3p demonstrated abnormallyelongated cells, with 10 % of the cells also exhibiting an elongatedbud. These observations suggest that cells overproducing activatedRho3p have defects in polarized growth, in agreement with thatreported for the constitutively active rho3^Ala-131 allele; indeed,rho3^Ala-131 cells have been shown to become elongated and bent(Imai et al., 1996). Upon production of GTP-blocked Rho4p, weobserved that about 30 % of cells were larger and rounder, withan undefined bud neck. These results indicate impairment ofthe cytokinesis process.

View larger version (22K):
[in this window]
[in a new window]

Fig. 1. Morphological defects and lethality associated with production of activated Rho3 and Rho4 GTPases. (A) Micrographs of the representative morphology of WT yeast cells producing constitutively activated forms of Rho3p (Rho3-GTP) and Rho4p (Rho4-GTP) from the pCM189 plasmid. An empty plasmid was used as a control. Cells were grown to OD₆₀₀ 1·5 in minimal medium without doxycycline to induce production of Rho3 and Rho4 proteins, and photographs were taken using a phase-contrast microscope. (B) Growth and lethality observed for the rgd1 ${Delta}$ strain, and WT cells producing activated Rho3 and Rho4 GTPases, in minimal medium with 3x excess inositol. Growth of cells containing empty pCM189 vector ( ${triangleup}$ ), pCM189 producing Rho3-GTP ( ${blacktriangleup}$ ) and Rho4-GTP ( ${blacksquare}$ ), and rgd1 ${Delta}$ cells ( ${circ}$ ), was monitored by OD₆₀₀. Dead cells were counted as described in Methods.

Regarding the propensity of cells to die upon production ofactivated Rho proteins, we noted that the percentage lethalitywas relatively constant and low in the exponential growth phase,but slightly increased in the stationary phase. Importantly,production of GTP-blocked Rho3p led to an increase in cell mortalityin the late-exponential phase. The same phenomenon has beenobserved for the rgd1 ${Delta}$ mutant grown in minimal medium, at thesame stage of cell culture (Barthe et al., 1998

). Under ourexperimental conditions, accumulation of activated Rho3p ledto a reproducible 10 % increase in cell mortality when grownin YNB medium, in comparison with an increase of approximately20 % in cells inactivated for RGD1 (data not shown). We havepreviously reported that the rgd1 ${Delta}$ cell lethality is enhancedby increasing the inositol concentration in minimal medium (deBettignies et al., 2001

). Here, we observed that, in YNB mediumcontaining 3x excess inositol, cell lethality was increasedto 16 % upon production of GTP-blocked Rho3p (Fig. 1B

).These results suggest that inositol is detrimental to cell survivalwhen Rho3p activation is unbalanced in the cell. Cell mortalityobserved upon simultaneous production of activated Rho3 andRho4 GTPases was found to be similar to that observed in cellsproducing activated Rho3p only. We also observed that additionof 1 M sorbitol to the medium did not rescue the cell lethalitycaused by the production of activated Rho3p. We have previouslyreported that lethality of rgd1 ${Delta}$ cells cannot be suppressed bythe addition of an osmotic stabilizer (de Bettignies et al.,1999

). Taken together, these data suggest that the rgd1 ${Delta}$ lethalityin minimal medium is a consequence of an increase in the amountof activated Rho3p.

The Rho3 and Rho4 small GTPases functionally interact with Wsc1p
We have previously demonstrated the existence of a syntheticlethal interaction between the rgd1 ${Delta}$ and wsc1 ${Delta}$ mutations (de Bettignieset al., 1999). In the present study, we investigated the involvementof Rho3 and Rho4 GTPases in rgd1 ${Delta}$ wsc1 ${Delta}$ lethality. The differentforms of Rho3p and Rho4p were independently or simultaneouslyproduced in the wsc1 ${Delta}$ strain, or in the WT strain as a control,to examine the change in cell mortality as a function of growth.Based on the results presented above, and data published previously(de Bettignies et al., 1999), cells were grown in a syntheticcomplete medium, and not in minimal medium, to prevent an increasein cell mortality due to Rho3p accumulation in the late-exponentialphase. Production of the different forms of Rho3p or Rho4p inWT cells had no detectable effect on growth (data not shown).The percentage of cell mortality was found to be low and virtuallyidentical for all WT strains producing the different proteins(Fig. 2A, B). An increase in mortality was observed inlate-stationary phase upon co-production of Rho3p and Rho4p(Fig. 2C); we also observed the aforementioned morphologicaldefects that were associated with production of GTP-blockedRho3p and Rho4p. In contrast to the WT, differences in celllethality were observed in the wsc1 ${Delta}$ cells producing the differentforms of Rho proteins. We observed that the wsc1 ${Delta}$ cells containingthe control vector had an intrinsic lethality of about 10 %,as reported previously (de Bettignies et al., 1999). In additionto this, production of all the Rho3p forms resulted in an increasein cell lethality (Fig. 2D). After 40 h induction,production of the WT and GDP-blocked forms of Rho3p led to similarresponses, with around 40 % cell mortality. A pronounced effect,nearly 60 % mortality, was observed upon production of activatedRho3p. These data suggest a predominant role for GTP-bound Rho3pin the synthetic lethality observed in the rgd1 ${Delta}$ wsc1 ${Delta}$ strain.The results obtained using the different forms of Rho4p stronglysuggest that it also plays an important role in rgd1 ${Delta}$ wsc1 ${Delta}$ lethality(Fig. 2E). However, unlike the results obtained with Rho3p,production of GTP- and GDP-blocked forms of Rho4p led to similarincreases in cell mortality. In order to understand why theproduction of GTP- and GDP-blocked Rho4p led to the productionof similar phenotypes, we analysed the effect of different formsof the GTPase in the wsc1 ${Delta}$ strain inactivated for RHO4, thuseliminating the possibility that the concomitant synthesis ofWT Rho4 protein from the chromosomal RHO4 gene was affectingcell lethality. Thus, we followed the mortality of the wsc1 ${Delta}$ rho4 ${Delta}$ cells producing WT, GDP- and GTP-blocked Rho4p from the plasmid(Fig. 2G). We observed that in this genetic background,the production of GTP-blocked Rho4p significantly increasedcell mortality, which was approximately 50 % after 40 h.Contrary to that observed in the wsc1 ${Delta}$ background, productionof WT or GDP-blocked Rho4p in wsc1 ${Delta}$ rho4 ${Delta}$ cells did not lead toan increase in cell mortality, with regard to the control vector.Thus, simultaneous synthesis of activated Rho4p from the chromosomalRHO4, and mutant forms from the plasmid, has a notable effecton the growth of the wsc1 ${Delta}$ cells.

View larger version (24K):
[in this window]
[in a new window]

Fig. 2. Cell lethality results obtained from cultures of WT and wsc1 ${Delta}$ strains producing different forms of Rho3 and Rho4 GTPases. (A, B) WT cells containing empty pCM189 plasmid ( ${blacktriangleup}$ ), and WT cells producing WT Rho3p or Rho4p ( ${blacksquare}$ ), GDP-blocked Rho3p or Rho4p (x), and GTP-blocked Rho3p or Rho4p ( ${triangleup}$ ), from the pCM189 plasmid, were grown in synthetic medium without doxycycline to induce Rho production at t=0. Cell lethality was determined during growth, as described in Methods. (C) Lethality of WT cells co-producing WT ( ${blacksquare}$ ), GDP-blocked (x) and GTP-blocked ( ${triangleup}$ ) forms of Rho3 and Rho4 proteins from pCM185 and pCM189 plasmids. An empty vector was used as a control ( ${blacktriangleup}$ ). (D, E, F) Experiments similar to those shown in (A, B, C) were performed in the wsc1 ${Delta}$ genetic background. (G) Lethality of wsc1 ${Delta}$ rho4 ${Delta}$ cells producing WT, inactivated and activated forms of Rho4p; the symbols are the same as for (E).

We further analysed the effect of the co-production of activated,inactivated and WT forms of Rho3p and Rho4p in wsc1 ${Delta}$ cells (Fig. 2F

).Co-production of the GTP-active forms led to a significant increasein cell mortality, nearly 50 % after 40 h, which was almostcompletely rescued by addition of 1 M sorbitol to the medium(data not shown). Importantly, the synthetic lethality betweenthe wsc1 ${Delta}$ and rgd1 ${Delta}$ mutations is also known to be suppressed bythe addition of an osmotic stabilizer (de Bettignies et al.,1999

). The lethality observed with the wsc1 ${Delta}$ cells containingcontrol vectors, or co-producing the WT or GDP-blocked formsof Rho3p and Rho4p, was in the order of 20 % after 40 h.Thus, Rho3p and Rho4p in their GTP-bound forms have strong cumulativenegative effects on the survival of wsc1 ${Delta}$ cells. These resultsstrongly suggest that the accumulation of activated Rho3p andRho4p following inactivation of RGD1 is detrimental to the survivalof cells lacking the WSC1 gene. Notably, it has been shown previouslythat the synthetic lethality between the rgd1 and vrp1 mutationsis a consequence of an accumulation of GTP-bound Rho3 and Rho4GTPases (Roumanie et al., 2000

Inactivation of the RHO3 or RHO4 gene suppresses the rgd1 ${Delta}$ wsc1 ${Delta}$ synthetic lethality
We next investigated whether the rgd1 ${Delta}$ wsc1 ${Delta}$ synthetic lethalitycould be rescued by inactivating the RHO3 or RHO4 genes. Sinceactivated Rho3p and Rho4p are detrimental to the wsc1 ${Delta}$ cell survival,we hypothesized that reducing the amount of these GTPases wouldhelp to keep the cells alive. Accordingly, to assay for suppression,we crossed strains containing the wsc1 ${Delta}$ rho3 ${Delta}$ and rgd1 ${Delta}$ mutationsor the rgd1 ${Delta}$ rho4 ${Delta}$ and wsc1 ${Delta}$ mutations to evaluate the phenotypesof cells containing the three mutations. Crosses involving thewsc1 ${Delta}$ rho3 ${Delta}$ strain were performed in the presence of 1 M sorbitolto prevent cell lysis (Matsui & Toh-e, 1992b). In agreementwith the working hypothesis, the rgd1 ${Delta}$ wsc1 ${Delta}$ rho3 ${Delta}$ and rgd1 ${Delta}$ wsc1 ${Delta}$ rho4 ${Delta}$ triple mutants were found to be viable (Fig. 3A).

View larger version (41K):
[in this window]
[in a new window]

Fig. 3. Inactivation of RHO3 or RHO4 suppresses rgd1 ${Delta}$ wsc1 ${Delta}$ synthetic lethality. (A) Growth of mutant strains was tested by spotting tenfold serial dilutions of cells onto minimal medium, and the plates were incubated for 2·5 days at 30 °C. (B) WT ( $bullet$ ), rgd1 ${Delta}$ wsc1 ${Delta}$ rho3 ${Delta}$ ( ${blacktriangleup}$ ) and rgd1 ${Delta}$ wsc1 ${Delta}$ rho4 ${Delta}$ ( ${square}$ ) strains were grown in complete medium, and cell lethality was measured during growth, as described in Methods.

Next, we determined the cell mortality by growing the two triplemutant strains in complete medium. The analysis showed thatmortality associated with the rgd1 ${Delta}$ wsc1 ${Delta}$ mutations was stronglysuppressed by inactivation of RHO4 (Fig. 3B

). The rho4 ${Delta}$ mutation suppressed more than 85 % of cell lethality in theexponential growth phase. Levels of growth of the WT and rgd1 ${Delta}$ wsc1 ${Delta}$ rho4 ${Delta}$ strains were found to be similar (data not shown). Inactivationof the RHO3 gene also led to a suppressor effect on rgd1 ${Delta}$ wsc1 ${Delta}$ cell mortality. The strength of the suppression was not as greatas that for the rho4 ${Delta}$ mutation; about 30 % of the triple mutantrgd1 ${Delta}$ wsc1 ${Delta}$ rho3 ${Delta}$ cells still died in the early growth phase (Fig. 3B

).However, we observed that addition of 1 M sorbitol to themedium increased rho3 ${Delta}$ suppression to the level observed withthe rho4 ${Delta}$ mutation (data not shown). Taken together, these resultsshow that both rho3 and rho4 mutations rescue the growth andlethality defects associated with the rgd1 ${Delta}$ wsc1 ${Delta}$ mutations. Hence,reduced levels of activated Rho3 or Rho4 GTPases within thergd1 ${Delta}$ wsc1 ${Delta}$ cells suppress the synthetic lethal phenotype, whichis consistent with the mechanism suggested by our analysis ofinteractions between Wsc1p and the two GTPases.

The functional interaction between RGD1 and MID2 is not dependent on Rho3 and Rho4 GTPases
In a previous study, we reported that RGD1 interacts geneticallywith the cell wall sensor-encoding gene MID2, and it was observedthat inactivation of MID2 enhances the rgd1 ${Delta}$ phenotype, and thatthe double mutant strain has a higher number of dead cells inlate-exponential growth phase in minimal medium (de Bettignieset al., 1999). Based on the data presented above, we investigatedwhether activated Rho3 and Rho4 GTPases were involved in thergd1 ${Delta}$ mid2 ${Delta}$ genetic interaction. We produced the different formsof Rho3p and Rho4p in mid2 ${Delta}$ cells, and in WT cells as a control.Cells were grown in YNB minimal medium, and the lethality wasmonitored at different times. As expected, results obtainedwith WT control cells were similar to those described above.Production of WT, GDP- and GTP-blocked Rho GTPases in the mid2 ${Delta}$ cells did not lead to any increase in mortality, with respectto control cells (data not shown). In addition, the lethalityof the rgd1 ${Delta}$ mid2 ${Delta}$ mutant was not rescued by RHO3 or RHO4 inactivation(data not shown). These results indicate that the Rho3 and Rho4GTPases are not involved in the interaction between RGD1 andMID2.

The PKC pathway is constitutively active in the rgd1 ${Delta}$ wsc1 ${Delta}$ rho3 ${Delta}$ and rgd1 ${Delta}$ wsc1 ${Delta}$ rho4 ${Delta}$ triple mutants
The Wsc1 protein is a major sensor for cell wall integrity signallingthat acts upstream of Pkc1p and the Bck1/Mkk1,2/Slt2 MAP kinasecascade (Ketela et al., 1999; Philip & Levin, 2001). Wehave previously reported that inactivation of RGD1 reduces Rlm1ptranscriptional activity, as well as transcription of PST1,which is a target of the PKC pathway; moreover, it has beenshown that viability of the rgd1 ${Delta}$ cells in the late-exponentialphase is restored by overactivation of the PKC pathway (de Bettignieset al., 2001). Thus, one possibility is that in the rgd1 ${Delta}$ wsc1 ${Delta}$ cells, weakening of the cell wall, and a decrease in the activityof the PKC pathway, might be responsible for the synthetic lethality.Consistent with this hypothesis, and as known for mutants defectivein the PKC pathway, growth of the rgd1 ${Delta}$ wsc1 ${Delta}$ mutant is restoredby addition of an osmotic stabilizer to the medium (Cid et al.,1995; de Bettignies et al., 1999). We investigated the activityof the PKC pathway in the rgd1 ${Delta}$ wsc1 ${Delta}$ rho3 ${Delta}$ and rgd1 ${Delta}$ wsc1 ${Delta}$ rho4 ${Delta}$ triplemutants described above by monitoring phosphorylation of Slt2p.The Slt2 protein is specifically phosphorylated on residuesThr¹⁹⁰ and Tyr¹⁹² upon activation of the PKC pathway (Lee etal., 1993). As expected, we found that the control WT strain,as well as the rgd1 ${Delta}$ and wsc1 ${Delta}$ mutants, did not have a detectableamount of activated Slt2p. However, a significantly higher amountof phosphorylated Slt2p was observed in the rgd1 ${Delta}$ wsc1 ${Delta}$ rho3 ${Delta}$ andrgd1 ${Delta}$ wsc1 ${Delta}$ rho4 ${Delta}$ triple mutants grown in complete medium at a regulartemperature (30 °C) (Fig. 4A). Surprisingly, the abundanceof Slt2 protein was increased in the wsc1 ${Delta}$ strain only, eventhough activity of the PKC pathway was not stimulated (Fig. 4A).

View larger version (38K):
[in this window]
[in a new window]

Fig. 4. The PKC–MAP kinase pathway is constitutively activated in rho3 ${Delta}$ wsc1 ${Delta}$ rgd1 ${Delta}$ and rho4 ${Delta}$ wsc1 ${Delta}$ rgd1 ${Delta}$ mutants. (A)Detection of Slt2 MAP kinase phosphorylation in WT, rgd1 ${Delta}$ , wsc1 ${Delta}$ and two triple-mutant strains grown in complete medium at 30 °C. Slt2p activation was detected with ${alpha}$ -p44/42 antibodies. Total Slt2 protein was visualizedwith polyclonal ${alpha}$ -Slt2 antibodies. A cross-reacting protein was used as a loading control. Results similar to those in (A) were obtained with cells grown in minimal medium at30 °C. (B) Detection of Slt2p activation following heat shock in WT and mutant strains. The strains were grown in minimal medium at 21 °C to mid-exponential phase, and then half of the cells was quickly transferred to 39 °C for 2 h (with heat shock), and the other half was kept at 21 °C (without heat shock). Phosphorylated and total Slt2 proteins were detected as described for (A). The increase in phosphorylated and total Slt2p upon heat shock was quantified by band densitometry. The fold-increase results are presented as ratios ‘with heat shock’/‘without heat shock’.

It is known that Slt2p phosphorylation is stimulated upon heatshock of yeast cells (Kamada et al., 1995

). As inactivationof RHO4 strongly suppresses the rgd1 ${Delta}$ wsc1 ${Delta}$ synthetic lethalityin medium without an osmotic stabilizer (Fig. 3

), we nextdetermined the Slt2p phosphorylation state in the rgd1 ${Delta}$ wsc1 ${Delta}$ rho4 ${Delta}$ triple mutant, and in control strains, following heat shock.Although suppression of the synthetic lethality by inactivationof RHO3 is not as effective as with RHO4, the rho3 ${Delta}$ and rgd1 ${Delta}$ wsc1 ${Delta}$ rho3 ${Delta}$ strains were also included in the experiment to look for commonphysiological responses between the two triple mutants. Thedifferent strains were grown in minimal medium to mid-exponentialphase at 21 °C, and then half of the culture was transferredto 39 °C for 2 h, while the other half was kept at21 °C, and Slt2p phosphorylation was monitored at both temperatures(Fig. 4B

). As shown above, the two triple mutant strainsshowed a constitutive activation of Slt2p phosphorylation atthe regular temperature; none of the other strains showed adetectable amount of activated Slt2p at 21 °C. Temperatureshift to 39 °C resulted in an overall increase in Slt2 phosphorylationfor all the strains tested. However, quantification of the amountof activation showed that, although WT and rho4 ${Delta}$ cells were ableto significantly increase phosphorylation of Slt2p, other strainstested showed a partial decrease in the activation of Slt2pphosphorylation (Fig. 4B

). Importantly, the two triplemutants showed almost no increase in phosphorylation upon heatshock. Similar defects were observed when we measured the increasein the abundance of Slt2 protein after heat shock (Fig. 4B

).Thus, stressing cells inactivated for RGD1 and WSC1 did notinduce an additional increase in Slt2p phosphorylation. Altogether,our results suggest that the PKC pathway is constitutively activefollowing inactivation of both the RGD1 and WSC1 genes. Hence,it seems unlikely that the rgd1 ${Delta}$ wsc1 ${Delta}$ synthetic lethality couldbe a consequence of a defect in PKC pathway activity.

The PKC pathway is not involved in the rgd1 ${Delta}$ wsc1 ${Delta}$ synthetic lethality
The aforementioned observations led to the suggestion that thesynthetic lethality may not be linked to the PKC pathway. Toprecisely analyse the involvement of PKC pathway activity inthe rgd1 ${Delta}$ wsc1 ${Delta}$ interaction, we investigated the suppressor effectof genes encoding components of this pathway. We examined whethera single-copy plasmid containing a BCK1-20 activated allele,or multicopy plasmids containing RHO1 or MKK1 (de Bettignieset al., 2001), could suppress the synthetic lethality. The originalsynthetic lethal strain SLRGD1-1, which already contains a URA3centromeric plasmid with the RGD1 gene (de Bettignies et al.,1999), was transformed with the different plasmids. The transformantswere tested for growth on control and 5-fluoroorotic acid (5-FOA)plates to examine their ability to lose the URA3/RGD1 plasmid.An empty plasmid, and a high-copy plasmid containing RGD1 (deBettignies et al., 2001), were used as negative and positivecontrols, respectively. We observed that overexpression of RHO1,BCK1-20 or MKK1 genes did not rescue the growth defect associatedwith the synthetic lethality (Fig. 5A). This result indicatesthat overactivation of the PKC–MAP kinase cascade is notsufficient to suppress cellular defects following inactivationof RGD1 and WSC1 genes.

View larger version (40K):
[in this window]
[in a new window]

Fig. 5. The PKC–MAP kinase pathway is not involved in the rgd1 ${Delta}$ wsc1 ${Delta}$ synthetic lethality. (A) Tests of suppression of rgd1 ${Delta}$ wsc1 ${Delta}$ synthetic lethality by components of the PKC pathway. The rgd1 ${Delta}$ wsc1 ${Delta}$ synthetic lethal strain containing a low-copy (CEN) URA3/RGD1 vector was transformed with an empty control vector, a CEN/TRP1 vector containing the activated BCK1-20 allele, and a multicopy (2 µ) LEU2 vector containing RGD1, RHO1 or MKK1. Plasmid-shuffle complementation assays were then performed on control SD and selective 5-FOAplates. (B) Analysis of the growth phenotype of the rgd1 ${Delta}$ bck1 ${Delta}$ and rgd1 ${Delta}$ slt2 ${Delta}$ double mutants. rgd1 ${Delta}$ was crossed to the bck1 ${Delta}$ strain, and to the slt2 ${Delta}$ strain, and tetrads were dissected on complete medium containing 1 M sorbitol. The rgd1 ${Delta}$ and wsc1 ${Delta}$ mutations were also combined as a control. Growth of control and double-mutant strains was monitored on complete medium, either with or without 1 M sorbitol.

In order to gain additional evidence, we examined the interactionbetween the rgd1 ${Delta}$ mutation, and BCK1 and SLT2, which are twogenes encoding the first and last kinases of the PKC–MAPkinase module, respectively. To perform this analysis, rgd1 ${Delta}$ was crossed to a bck1 ${Delta}$ strain, and to a slt2 ${Delta}$ strain, the diploidcells were allowed to sporulate, and the tetrads were dissectedon complete medium containing 1 M sorbitol. As a control,the rgd1 ${Delta}$ and wsc1 ${Delta}$ strains were also crossed. Growth of double-mutantstrains was then analysed on complete medium, either with orwithout an osmotic stabilizer (Fig. 5B

). As expected, thergd1 ${Delta}$ wsc1 ${Delta}$ double-mutant strain was non-viable on medium lackingsorbitol. Importantly, we observed that the rgd1 ${Delta}$ bck1 ${Delta}$ and rgd1 ${Delta}$ slt2 ${Delta}$ double mutants did not exhibit any growth defect on medium lackingsorbitol, indicating the absence of synthetic lethality betweenRGD1 and BCK1, and between RGD1 and SLT2. Hence, these resultsare consistent with the idea that a defect in PKC pathway activityis not responsible for the rgd1 ${Delta}$ wsc1 ${Delta}$ synthetic lethal interaction.

Mutations in RHO3 specifically impair the abundance of Wsc1 and Mid2 proteins
The above results suggest that a cellular process distinct fromcell integrity signalling is perturbed when both Rgd1p and Wsc1pare absent. Rgd1p acts as a negative regulator of Rho3 and Rho4,which are GTPases that interact with the exocytic apparatusin yeast. It has been demonstrated that activated Rho3p interactswith the exocyst complex, and is important for regulating exocytosisat sites of polarized growth (Robinson et al., 1999; Roumanieet al., 2005). Wsc1 protein is known to be involved not onlyin sensing cell wall stress, and in activating the PKC pathway,but also in regulating cellular processes connected to secretion.In particular, it has been reported that WSC1 is a multicopysuppressor of the sly1 mutant defective for endoplasmic-reticulum–Golgitransport (Kosodo et al., 2001). Moreover, signals from thesecretory pathway caused by perturbation in intracellular traffickinghave been shown to be transduced by the WSC family of proteins.It has been observed that Wsc proteins need to be in intracellularcompartments along the secretory pathway to induce the arrestof secretion response (ASR) through activation of Pkc1p (Nanduri& Tartakoff, 2001). Interestingly, the Bck1/Mkk1,2/Slt2MAP kinase cascade activated by Pkc1p does not seem to be requiredfor the ASR, suggesting the existence of a new branch of Pkc1psignalling (Ng, 2001). We decided to explore whether alterationsin Rho3-dependent cellular trafficking induced defects in Wsc1protein abundance. We first made use of the rho3 ${Delta}$ mutant, inwhich regulation of polarized exocytosis by GTP-bound Rho3pis lost, and the actin cytoskeleton is depolarized (Roumanieet al., 2002, 2005). To perform this analysis, WT, rgd1 ${Delta}$ , rho4 ${Delta}$ and rho3 ${Delta}$ strains were transformed with a multicopy plasmid containingHA-tagged Wsc1p (Rajavel et al., 1999), and the protein abundancewas monitored. Although no defect was observed in the WT, orthe rgd1 ${Delta}$ and rho4 ${Delta}$ strains, the amount of Wsc1p was stronglyreduced in the rho3 ${Delta}$ mutant (Fig. 6A). Examination of thetranscription factor Ure2, and the plasma membrane protein Fur4,showed no defect in their abundance in the rho3 ${Delta}$ compared withthe other strains (Fig. 6A). Subsequently, we looked forthe abundance of another cell wall sensor, Mid2p, since WSC1and MID2 have been shown to functionally interact with eachother in yeast (de Bettignies et al., 1999). As shown in Fig. 6B,Mid2p was found to be present and highly O-glycosylated in allthe strains, except rho3 ${Delta}$ . Once again, no alteration in Ure2por Fur4p abundance was detected (Fig. 6B). These resultspoint towards a specific defect in the abundance of Wsc1 andMid2 proteins in the rho3 ${Delta}$ mutant. To investigate stress sensorfunctionality in the rho3 ${Delta}$ mutant, the effect of the cell wallinterfering compound Congo Red was tested on growth; we observedthat both the wsc1 ${Delta}$ and rho3 ${Delta}$ strains were unable to grow in thepresence of the compound (Fig. 6C). As previously reported,the mid2 ${Delta}$ mutant and, to a lower extent, the rgd1 ${Delta}$ mutant wereresistant, and grew better than the WT and rho4 ${Delta}$ strains on mediumcontaining Congo Red (de Bettignies et al., 1999). These datasuggest that the functionality of Wsc1p is impaired in rho3 ${Delta}$ .It has been reported that MID2 is a low-copy suppressor of thergd1 ${Delta}$ wsc1 ${Delta}$ synthetic lethal interaction, and that the mid2 ${Delta}$ wsc1 ${Delta}$ combination is lethal (de Bettignies et al., 1999). Since weobserved that the rgd1 ${Delta}$ mutation does not affect Mid2p abundance,our results lend support to the idea that rgd1 ${Delta}$ wsc1 ${Delta}$ co-lethalityis not a consequence of a decrease in the abundance of Mid2pfollowing inactivation of RGD1.

View larger version (39K):
[in this window]
[in a new window]

Fig. 6. Abundance of the Wsc1 and Mid2 proteins is strongly reduced in rho3 ${Delta}$ cells. (A) Analysis of Wsc1p abundance in WT, rgd1 ${Delta}$ , rho4 ${Delta}$ and rho3 ${Delta}$ mutant strains containing the YEp352-WSC1^3HA plasmid. An empty vector was used as a control. The strains were grown to early exponential phase in synthetic medium at 30 °C, and total proteins were extracted and subjected to SDS-PAGE, and Wsc1-3HA protein was detected by immunoblot analysis using 12CA5 antibodies. The control Ure2 and Fur4 proteins were detected using specific polyclonal antibodies. The positions of molecular mass markers (kDa) are indicated on the left. (B) Analysis of Mid2p abundance in WT, rgd1 ${Delta}$ , rho4 ${Delta}$ and rho3 ${Delta}$ mutant strains containing the YEp352-MID2^3HA plasmid. Experiments were performed as described for (A). (C) Analysis of the growth phenotype of the rho3 ${Delta}$ mutant in the presence of the cell-wall-interfering compound Congo Red. WT and mutant strains were grown in complete medium, and tenfold serial dilutions were spotted onto complete medium (YPD), and YPD containing 3 mg Congo Red ml^–1. Plates were incubated for 2–3 days at 30 °C.

Next, we looked at the behaviour of Wsc1 and Mid2 proteins inthe rho3-V51 mutant. The cold-sensitive rho3-V51 allele hasa specific secretion defect that does not involve, in contrastto the rho3 ${Delta}$ mutation, detectable effects on the polarized localizationof the exocytic machinery or the actin cytoskeleton (Roumanieet al., 2005

). Secretion of the periplasmic enzymes invertaseand Bgl2 has been shown to be perturbed at both permissive (25°C) and non-permissive (14 °C) temperatures, and therho3-V51 cells accumulate post-Golgi secretion vesicles in thecytosol (Adamo et al., 1999

). Thus, we conducted experimentsto follow HA-tagged Wsc1p and Mid2p in rho3-V51 cells and isogenicWT cells at 25 and 14 °C; as shown in Fig. 7(A)

, weobserved a decrease in the abundance of fully O-glycosylatedWsc1p at both temperatures in the rho3-V51 mutant compared withthe WT. Similar results were obtained with Mid2 protein (Fig. 7

B);the amount of the fully mature form of Mid2p was reduced, andwe observed the appearance of a 150 kDa form of the proteinin the rho3-V51 mutant at both 25 and 14 °C (Fig. 7B

).Thus, a specific block in trafficking between the Golgi apparatusand the plasma membrane led to a negative effect on both Wsc1and Mid2 proteins. We also examined growth of the rho3-V51 mutanton complete medium containing Congo Red. The rho3-V51 secretionmutant was found to be more sensitive to Congo Red when comparedwith the WT (Fig. 7C

). As the strain background used forstudying rho3-V51 has a higher sensitivity to Congo Red thanother strains used in this study, we also grew these strainson medium containing 1 M sorbitol as an osmotic stabilizer.Although the addition of sorbitol helped the growth of the WTstrain in the presence of Congo Red, rho3-V51 did not show acomparable increase under the same conditions (Fig. 7C

).Thus, like rho3 ${Delta}$ , rho3-V51 is hypersensitive to perturbationof the cell wall, suggesting that cell wall sensors, and inparticular Wsc1p, are not functional. Finally, these resultsdemonstrate that loss of active Rho3p affects Wsc1p and Mid2pbehaviour, strongly suggesting that perturbations in polarizedexocytosis influence the processing or synthesis of the twoproteins. Interestingly, similar experiments performed in cellsoverproducing constitutively active Rho3p showed no alterationin Wsc1 and Mid2 protein abundance (data not shown). This mightimply that only perturbation of polarized exocytosis due toloss of Rho3p, and not overactivation of exocytosis by Rho3p,has a negative effect on Wsc1 and Mid2 proteins in the cell.

View larger version (43K):
[in this window]
[in a new window]

Fig. 7. The Wsc1 and Mid2 proteins are specifically impaired in the rho3-V51 secretion mutant. (A) Analysis of Wsc1p abundance and maturation in isogenic WT and rho3-V51 strains containing the YEp352-WSC1^3HA plasmid, at 25 and 14 °C. Cells were grown to early exponential phase in synthetic medium, and either shifted to 14 °C for 5 h, or kept at 25 °C. Cells were then processed as described in Fig. 6(A)

to detect the Wsc1-3HA protein. An empty vector was used as a control. (B) Analysis of Mid2p abundance and maturation in WT and rho3-V51 strains containing the YEp352-MID2^3HA plasmid at 25 and 14 °C. Experiments were performed as described in (A). (C) Analysis of the growth phenotype of the rho3-V51 mutant in the presence of the cell-wall-interfering compound Congo Red. Isogenic WT and mutant strains were grown in complete medium at 25 °C, and tenfold serial dilutions were spotted onto YPD, and YPD containing 3 mg Congo Red ml^–1. Strains were also grown on control and selective media containing 1 M sorbitol. Plates were incubated for 2–3 days at 25 °C.

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

We have previously reported the existence of synthetic lethalitybetween the RGD1 and WSC1 genes in the yeast S. cerevisiae.Rgd1 protein is a GAP factor that negatively regulates Rho3pand Rho4p, which are two small GTPases dedicated to the maintenanceof cell polarity. Wsc1p and Mid2p are the two major cell surfacesensors that activate the PKC1–MPK1 cell integrity pathwayunder stress conditions. If one of the two cell surface proteinsis absent, the other becomes essential in the response to stress(de Bettignies et al., 1999

; Ketela et al., 1999

; Rajavel etal., 1999

). MID2 overexpression is known to suppress the rgd1 ${Delta}$ wsc1 ${Delta}$ synthetic lethality, and co-deletion of RGD1 and MID2 leadsto conditional lethality in the late-exponential growth phase(de Bettignies et al., 1999

). Upon analysing the interactionbetween RGD1 and WSC1, we found that unregulated accumulationof Rho3 and Rho4 proteins was lethal in wsc1 ${Delta}$ cells. However,accumulation of activated Rho3p and Rho4p had no effect in themid2 ${Delta}$ genetic background. Thus, Rho3 and Rho4 GTPases act differentlyon the partially redundant Wsc1 and Mid2 cell wall sensors.This is consistent with previous reports that, despite sharinga function in cell wall sensing, Wsc1p and Mid2p have distinctroles in yeast (Sekiya-Kawasaki et al., 2002

; Green et al.,2003

). The interaction between MID2 and RGD1 must involve anRgd1p function that is yet to be defined.

We also show that the PKC–MAP kinase pathway is not implicatedin the rgd1 ${Delta}$ wsc1 ${Delta}$ synthetic lethality, and hence the lethalitymust involve a function of Wsc1p that is different from itsrole as a cell wall stress sensor. Along the secretory route,distinct signalling pathways monitor ‘traffic jams' andmisfolding of proteins to slow down exocytosis and protein synthesis(Ng, 2001). In particular, it has been shown that the Wsc familyof proteins is involved in interorganellar signal transductionin response to perturbations in exocytosis. The ASR utilizesWsc proteins trapped along the secretory pathway to initiaterelocation of proteins, and then transcriptional changes (Nanduri& Tartakoff, 2001). The Bck1/Mkk1,2/Slt2 MAP kinase cascadeactivated by Pkc1p is not required for the ASR, suggesting theexistence of another branch of Pkc1p signalling (Ng, 2001).We report that disturbances in Rho3p-mediated polarized exocytosisspecifically decrease the abundance, and impair the processing,of Wsc1p and Mid2p, although other proteins, such as the plasmamembrane protein Fur4, were found to be unaltered. An importantdifference between these proteins is that Wsc1p and Mid2p arehighly glycosylated, whereas the Fur4 uracil permease is not(Silve et al., 1991; Lodder et al., 1999; Philip & Levin,2001). It has been proposed that O-mannosylation increases theactivity of Wsc1p and Mid2p by enhancing their stability (Lommelet al., 2004). Moreover, the defects observed for Wsc1 and Mid2proteins in the rho3 ${Delta}$ mutant are similar to those reported inthe protein O-mannosyltransferase pmt mutants (Lommel et al.,2004). Based on these results, it is likely that blocking theRho3-dependent polarized exocytosis impairs Wsc1p and Mid2pglycosylation, thus affecting their stability and function.As a consequence, the Wsc1 protein can no longer function insignal transduction in rho3 mutants. These data support theidea that Wsc1p, which is normally present on secretory vesicles,or in the plasma membrane, can no longer function when Rho3p-regulatedpolarized exocytosis is impaired. Together, our data show theexistence of a specific functional relationship between Wsc1pand Rho3/4 GTPases that could be linked to the regulation ofpolarized exocytosis.

Based on our results, the constitutive activation of the PKCpathway observed when both RGD1 and WSC1 are inactivated wouldbe an indirect effect of perturbations in Rho3/4p-regulatedpolarized exocytosis. In agreement with this analysis, we foundthat phosphorylated and total Slt2p were increased in the rho3-V51late-secretion mutant compared with WT cells (see SupplementaryFig. S1). Moreover, we observed that the PKC pathway wasspecifically activated upon production of GTP-bound Rho3p orRho4p in WT cells. A strong cumulative effect was obtained whenactivated Rho3 and Rho4 GTPases were co-produced. No activationwas observed when GDP-bound or WT forms of Rho3p and Rho4p wereused (see Supplementary Fig. S1). Thus, either blockingor overactivating Rho3p-regulated secretion leads to an increasein the PKC pathway activity. Results obtained from rho3 ${Delta}$ andrho4 ${Delta}$ showed that Slt2p was not phosphorylated in these mutants,strongly suggesting that the activation is dependent on thepresence of GTP-bound Rho3p and Rho4p in the cell. Interestingly,constitutive activation of the cell integrity pathway has alsobeen reported for the O-mannosyltransferase pmt2 ${Delta}$ pmt4 ${Delta}$ mutant,which is deficient in Wsc1p and Mid2p post-translational processing(Lommel et al., 2004). Taken together, these results demonstratethat the PKC pathway can be activated as a consequence of unbalancedpolarized exocytosis, possibly through a decrease in activeWsc1 along the secretory pathway.

Overall, our analyses show that the genetic interaction observedbetween RGD1 and WSC1 may be the consequence of cumulative defectson polarized secretion. One hypothesis is that both Rgd1p andWsc1p are involved in the pathway down-regulating polarizedexocytosis, which is dependent on Rho3 and Rho4 GTPases; theabsence of one of the two proteins is partly compensated bythe presence of the other under standard growth conditions.Nevertheless, when the mutant cells are subjected to additionalstresses, such as unbalanced exocytosis, diauxic shift or hightemperatures, down-regulation of polarized exocytosis is notsufficient, and the consequence is cell death. Future work willhelp to elucidate the precise mechanism involving both Rgd1pand Wsc1p in the regulation of Rho3/4p-dependent polarized secretion.

ACKNOWLEDGEMENTS

We thank A. Claveres and M. F. Peypouquet for technical assistance.We are grateful to Dr P. Brennwald, University of North Carolinaat Chapel Hill, USA, for providing the rho3-V51 and isogeniccontrol strains, Dr D. Levin, Johns Hopkins Bloomberg Schoolof Public Health, USA, for providing YEp352-Wsc1^3HA and YEp352-Mid2^3HAplasmids, and Dr A. Gangar for critical reading of the manuscript.The anti-GST-Slt2p antibodies were a kind gift from Drs H. Martinand M. Molina. The antibodies against Ure2p and Fur4p were providedby Dr C. Cullin, IBGC-Université Bordeaux 2, France,and Dr R. Haguenauer-Tsapis, Institut Jacques Monod, France,respectively. This work was supported by grants from the UniversitéVictor Segalen Bordeaux 2 and the CNRS.

REFERENCES

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Adamo, J. E., Rossi, G. & Brennwald, P. (1999). The Rho GTPase Rho3 has a direct role in exocytosis that is distinct from its role in actin polarity. Mol Biol Cell 10, 4121–4133.[Abstract/Free Full Text]

Adamo, J. E., Moskow, J. J., Gladfelter, A. S., Viterbo, D., Lew, D. J. & Brennwald, P. J. (2001). Yeast Cdc42 functions at a late step in exocytosis, specifically during polarized growth of the emerging bud. J Cell Biol 155, 581–592.[Abstract/Free Full Text]

Barthe, C., de Bettignies, G., Louvet, O., Peypouquet, M. F., Morel, C., Doignon, F. & Crouzet, M. (1998). First characterization of the gene RGD1 in the yeast Saccharomyces cerevisiae. C R Acad Sci III 321, 453–462.[Medline]

Cid, V. J., Duran, A., del Rey, F., Snyder, M. P., Nombela, C. & Sanchez, M. (1995). Molecular basis of cell integrity and morphogenesis in Saccharomyces cerevisiae. Microbiol Rev 59, 345–386.[Abstract/Free Full Text]

de Bettignies, G., Barthe, C., Morel, C., Peypouquet, M. F., Doignon, F. & Crouzet, M. (1999). RGD1 genetically interacts with MID2 and SLG1, encoding two putative sensors for cell integrity signalling in Saccharomyces cerevisiae. Yeast 15, 1719–1731.[CrossRef][Medline]

de Bettignies, G., Thoraval, D., Morel, C., Peypouquet, M. F. & Crouzet, M. (2001). Overactivation of the protein kinase C-signaling pathway suppresses the defects of cells lacking the Rho3/Rho4-GAP Rgd1p in Saccharomyces cerevisiae. Genetics 159, 1435–1448.[Abstract/Free Full Text]

Doignon, F., Weinachter, C., Roumanie, O. & Crouzet, M. (1999). The yeast Rgd1p is a GTPase activating protein of the Rho3 and Rho4 proteins. FEBS Lett 459, 458–462.[CrossRef][Medline]

Dong, Y., Pruyne, D. & Bretscher, A. (2003). Formin-dependent actin assembly is regulated by distinct modes of Rho signaling in yeast. J Cell Biol 161, 1081–1092.[Abstract/Free Full Text]

Etienne-Manneville, S. & Hall, A. (2002). Rho GTPases in cell biology. Nature 420, 629–635.[CrossRef][Medline]

Fernandez-Bellot, E., Guillemet, E., Ness, F., Baudin-Baillieu, A., Ripaud, L., Tuite, M. & Cullin, C. (2002). The [URE3] phenotype: evidence for a soluble prion in yeast. EMBO Rep 3, 76–81.[CrossRef][Medline]

Garcia-Ranea, J. A. & Valencia, A. (1998). Distribution and functional diversification of the ras superfamily in Saccharomyces cerevisiae. FEBS Lett 434, 219–225.[CrossRef][Medline]

Gari, E., Piedrafita, L., Aldea, M. & Herrero, E. (1997). A set of vectors with a tetracycline-regulatable promoter system for modulated gene expression in Saccharomyces cerevisiae. Yeast 13, 837–848.[CrossRef][Medline]

Gietz, R. D., Schiestl, R. H., Willems, A. R. & Woods, R. A. (1995). Studies on the transformation of intact yeast cells by the LiAc/SS-DNA/PEG procedure. Yeast 11, 355–360.[CrossRef][Medline]

Gray, J. V., Ogas, J. P., Kamada, Y., Stone, M., Levin, D. E. & Herskowitz, I. (1997). A role for the Pkc1 MAP kinase pathway of Saccharomyces cerevisiae in bud emergence and identification of a putative upstream regulator. EMBO J 16, 4924–4937.[CrossRef][Medline]

Green, R., Lesage, G., Sdicu, A. M., Menard, P. & Bussey, H. (2003). A synthetic analysis of the Saccharomyces cerevisiae stress sensor Mid2p, and identification of a Mid2p-interacting protein, Zeo1p, that modulates the PKC1–MPK1 cell integrity pathway. Microbiology 149, 2487–2499.[Abstract/Free Full Text]

Gustin, M. C., Albertyn, J., Alexander, M. & Davenport, K. (1998). MAP kinase pathways in the yeast Saccharomyces cerevisiae. Microbiol Mol Biol Rev 62, 1264–1300.[Abstract/Free Full Text]

Heinisch, J. J., Lorberg, A., Schmitz, H. P. & Jacoby, J. J. (1999). The protein kinase C-mediated MAP kinase pathway involved in the maintenance of cellular integrity in Saccharomyces cerevisiae. Mol Microbiol 32, 671–680.[CrossRef][Medline]

Imai, J., Toh-e, A. & Matsui, Y. (1996). Genetic analysis of the Saccharomyces cerevisiae RHO3 gene, encoding a rho-type small GTPase, provides evidence for a role in bud formation. Genetics 142, 359–369.[Abstract]

Jacoby, J. J., Nilius, S. M. & Heinisch, J. J. (1998). A screen for upstream components of the yeast protein kinase C signal transduction pathway identifies the product of the SLG1 gene. Mol Gen Genet 258, 148–155.[CrossRef][Medline]

Johnson, D. I. & Pringle, J. R. (1990). Molecular characterization of CDC42, a Saccharomyces cerevisiae gene involved in the development of cell polarity. J Cell Biol 111, 143–152.[Abstract/Free Full Text]

Kamada, Y., Jung, U. S., Piotrowski, J. & Levin, D. E. (1995). The protein kinase C-activated MAP kinase pathway of Saccharomyces cerevisiae mediates a novel aspect of the heat shock response. Genes Dev 9, 1559–1571.[Abstract/Free Full Text]

Kamada, Y., Qadota, H., Python, C. P., Anraku, Y., Ohya, Y. & Levin, D. E. (1996). Activation of yeast protein kinase C by Rho1 GTPase. J Biol Chem 271, 9193–9196.[Abstract/Free Full Text]

Ketela, T., Green, R. & Bussey, H. (1999). Saccharomyces cerevisiae mid2p is a potential cell wall stress sensor and upstream activator of the PKC1–MPK1 cell integrity pathway. J Bacteriol 181, 3330–3340.[Abstract/Free Full Text]

Kosodo, Y., Imai, K., Hirata, A., Noda, Y., Takatsuki, A., Adachi, H. & Yoda, K. (2001). Multicopy suppressors of the sly1 temperature-sensitive mutation in the ER-Golgi vesicular transport in Saccharomyces cerevisiae. Yeast 18, 1003–1014.[CrossRef][Medline]

Lee, K. S., Irie, K., Gotoh, Y., Watanabe, Y., Araki, H., Nishida, E., Matsumoto, K. & Levin, D. E. (1993). A yeast mitogen-activated protein kinase homolog (Mpk1p) mediates signalling by protein kinase C. Mol Cell Biol 13, 3067–3075.[Abstract/Free Full Text]

Lodder, A. L., Lee, T. K. & Ballester, R. (1999). Characterization of the Wsc1 protein, a putative receptor in the stress response of Saccharomyces cerevisiae. Genetics 152, 1487–1499.[Abstract/Free Full Text]

Lommel, M., Bagnat, M. & Strahl, S. (2004). Aberrant processing of the WSC family and Mid2p cell surface sensors results in cell death of Saccharomyces cerevisiae O-mannosylation mutants. Mol Cell Biol 24, 46–57.[Abstract/Free Full Text]

Martin, H., Rodriguez-Pachon, J. M., Ruiz, C., Nombela, C. & Molina, M. (2000). Regulatory mechanisms for modulation of signaling through the cell integrity Slt2-mediated pathway in Saccharomyces cerevisiae. J Biol Chem 275, 1511–1519.[Abstract/Free Full Text]

Matsui, Y. & Toh-e, A. (1992a). Isolation and characterization of two novel ras superfamily genes in Saccharomyces cerevisiae. Gene 114, 43–49.[CrossRef][Medline]

Matsui, Y. & Toh-e, A. (1992b). Yeast RHO3 and RHO4 ras superfamily genes are necessary for bud growth, and their defect is suppressed by a high dose of bud formation genes CDC42 and BEM1. Mol Cell Biol 12, 5690–5699.[Abstract/Free Full Text]

Nanduri, J. & Tartakoff, A. M. (2001). The arrest of secretion response in yeast: signaling from the secretory path to the nucleus via Wsc proteins and Pkc1p. Mol Cell 8, 281–289.[CrossRef][Medline]

Ng, D. T. (2001). Interorganellar signal transduction: the arrest of secretion response. Dev Cell 1, 319–320.[CrossRef][Medline]

Nonaka, H., Tanaka, K., Hirano, H., Fujiwara, T., Kohno, H., Umikawa, M., Mino, A. & Takai, Y. (1995). A downstream target of RHO1 small GTP-binding protein is PKC1, a homolog of protein kinase C, which leads to activation of the MAP kinase cascade in Saccharomyces cerevisiae. EMBO J 14, 5931–5938.[Medline]

Philip, B. & Levin, D. E. (2001). Wsc1 and Mid2 are cell surface sensors for cell wall integrity signaling that act through Rom2, a guanine nucleotide exchange factor for Rho1. Mol Cell Biol 21, 271–280.[Abstract/Free Full Text]

Rajavel, M., Philip, B., Buehrer, B. M., Errede, B. & Levin, D. E. (1999). Mid2 is a putative sensor for cell integrity signaling in Saccharomyces cerevisiae. Mol Cell Biol 19, 3969–3976.[Abstract/Free Full Text]

Riezman, H., Hase, T., van Loon, A. P., Grivell, L. A., Suda, K. & Schatz, G. (1983). Import of proteins into mitochondria: a 70 kilodalton outer membrane protein with a large carboxy-terminal deletion is still transported to the outer membrane. EMBO J 2, 2161–2168.[Medline]

Robinson, N. G., Guo, L., Imai, J., Toh-e. A., Matsui, Y. & Tamanoi, F. (1999). Rho3 of Saccharomyces cerevisiae, which regulates the actin cytoskeleton and exocytosis, is a GTPase which interacts with Myo2 and Exo70. Mol Cell Biol 19, 3580–3587.[Abstract/Free Full Text]

Rose, A. H. (1975). Growth and handling of yeasts. Methods Cell Biol 12, 1–16.[Medline]

Roumanie, O., Peypouquet, M. F., Bonneu, M., Thoraval, D., Doignon, F. & Crouzet, M. (2000). Evidence for the genetic interaction between the actin-binding protein Vrp1 and the RhoGAP Rgd1 mediated through Rho3p and Rho4p in Saccharomyces cerevisiae. Mol Microbiol 36, 1403–1414.[CrossRef][Medline]

Roumanie, O., Weinachter, C., Larrieu, I., Crouzet, M. & Doignon, F. (2001). Functional characterization of the Bag7, Lrg1 and Rgd2 RhoGAP proteins from Saccharomyces cerevisiae. FEBS Lett 506, 149–156.[CrossRef][Medline]

Roumanie, O., Peypouquet, M. F., Thoraval, D., Doignon, F. & Crouzet, M. (2002). Functional interactions between the VRP1-LAS17 and RHO3-RHO4 genes involved in actin cytoskeleton organization in Saccharomyces cerevisiae. Curr Genet 40, 317–325.[CrossRef][Medline]

Roumanie, O., Wu, H., Molk, J. N., Rossi, G., Bloom, K. & Brennwald, P. (2005). Rho GTPase regulation of exocytosis in yeast is independent of GTP hydrolysis and polarization of the exocyst complex. J Cell Biol 170, 583–594.[Abstract/Free Full Text]

Schmitz, H. P., Huppert, S., Lorberg, A. & Heinisch, J. J. (2002). Rho5p downregulates the yeast cell integrity pathway. J Cell Sci 115, 3139–3148.[Abstract/Free Full Text]

Sekiya-Kawasaki, M., Abe, M., Saka, A., Watanabe, D., Kono, K., Minemura-Asakawa, M., Ishihara, S., Watanabe, T. & Ohya, Y. (2002). Dissection of upstream regulatory components of the Rho1p effector, 1,3- $beta$ -glucan synthase, in Saccharomyces cerevisiae. Genetics 162, 663–676.[Abstract/Free Full Text]

Sherman, F., Fink, G. R. & Hicks, J. B. (1986). Methods in Yeast Genetics: a Laboratory Course Manual. Cold Spring Harbor, NY: Cold Spring Harbor Laboratory.

Silve, S., Volland, C., Garnier, C., Jund, R., Chevallier, M. R. & Haguenauer-Tsapis, R. (1991). Membrane insertion of uracil permease, a polytopic yeast plasma membrane protein. Mol Cell Biol 11, 1114–1124.[Abstract/Free Full Text]

Van Aelst, L. & D'Souza-Schorey, C. (1997). Rho GTPases and signaling networks. Genes Dev 11, 2295–2322.[Free Full Text]

Verna, J., Lodder, A., Lee, K., Vagts, A. & Ballester, R. (1997). A family of genes required for maintenance of cell wall integrity and for the stress response in Saccharomyces cerevisiae. Proc Natl Acad Sci U S A 94, 13804–13809.[Abstract/Free Full Text]

Winston, F., Dollard, C. & Ricupero-Hovasse, S. L. (1995). Construction of a set of convenient Saccharomyces cerevisiae strains that are isogenic to S288C. Yeast 11, 53–55.[CrossRef][Medline]

Received 26 May 2005; revised 11 November 2005; accepted 23 November 2005.

This article has been cited by other articles:

V. Prouzet-Mauleon, F. Lefebvre, D. Thoraval, M. Crouzet, and F. Doignon
Phosphoinositides Affect both the Cellular Distribution and Activity of the F-BAR-containing RhoGAP Rgd1p in Yeast
J. Biol. Chem., November 28, 2008; 283(48): 33249 - 33257.
[Abstract] [Full Text] [PDF]

D. J. Wright, E. Munro, M. Corbett, A. J. Bentley, N. J. Fullwood, S. Murray, and C. Price
The Saccharomyces cerevisiae Actin Cytoskeletal Component Bsp1p Has an Auxiliary Role in Actomyosin Ring Function and in the Maintenance of Bud-Neck Structure
Genetics, April 1, 2008; 178(4): 1903 - 1914.
[Abstract] [Full Text] [PDF]

H.-O. Park and E. Bi
Central Roles of Small GTPases in the Development of Cell Polarity in Yeast and Beyond
Microbiol. Mol. Biol. Rev., March 1, 2007; 71(1): 48 - 96.
[Abstract] [Full Text] [PDF]

This Article

Abstract

Full Text (PDF)

Supplementary data

Alert me when this article is cited

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via CrossRef

Citing Articles via Google Scholar

Google Scholar

Articles by Fernandes, H.

Articles by Crouzet, M.

Search for Related Content

PubMed

PubMed Citation

Articles by Fernandes, H.

Articles by Crouzet, M.

Agricola

Articles by Fernandes, H.

Articles by Crouzet, M.

INT J SYST EVOL MICROBIOL	MICROBIOLOGY	J GEN VIROL
J MED MICROBIOL	ALL SGM JOURNALS

				D. J. Wright, E. Munro, M. Corbett, A. J. Bentley, N. J. Fullwood, S. Murray, and C. Price The Saccharomyces cerevisiae Actin Cytoskeletal Component Bsp1p Has an Auxiliary Role in Actomyosin Ring Function and in the Maintenance of Bud-Neck Structure Genetics, April 1, 2008; 178(4): 1903 - 1914. [Abstract] [Full Text] [PDF]

				H.-O. Park and E. Bi Central Roles of Small GTPases in the Development of Cell Polarity in Yeast and Beyond Microbiol. Mol. Biol. Rev., March 1, 2007; 71(1): 48 - 96. [Abstract] [Full Text] [PDF]