Saccharomyces cerevisiae Mid2p Is a Potential Cell Wall Stress Sensor and Upstream Activator of the PKC1-MPK1 Cell Integrity Pathway

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Journal of Bacteriology, June 1999, p. 3330-3340, Vol. 181, No. 11
0021-9193/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Saccharomyces cerevisiae Mid2p Is a Potential Cell Wall Stress Sensor and Upstream Activator of the PKC1-MPK1 Cell Integrity Pathway

Troy Ketela, Robin Green, and Howard Bussey^*

Department of Biology, McGill University, Montreal, Quebec, Canada H3A 1B1

Received 20 January 1999/Accepted 15 March 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

The MID2 gene of Saccharomyces cerevisiae encodes a protein with structural features indicative of a plasma membrane-associatedcell wall sensor. MID2 was isolated as a multicopy activator ofthe Skn7p transcription factor. Deletion of MID2 causes resistanceto calcofluor white, diminished production of stress-induced cellwall chitin under a variety of conditions, and changes in growthrate and viability in a number of different cell wall biosynthesismutants. Overexpression of MID2 causes hyperaccumulation of chitinand increased sensitivity to calcofluor white. $alpha$ -Factor hypersensitivityof mid2 $Delta$ mutants can be suppressed by overexpression of upstreamelements of the cell integrity pathway, including PKC1, RHO1,WSC1, and WSC2. Mid2p and Wsc1p appear to have overlapping rolesin maintaining cell integrity since mid2 $Delta$ wsc1 $Delta$ mutants are inviableon medium that does not contain osmotic support. A role for MID2in the cell integrity pathway is further supported by the findingthat MID2 is required for induction of Mpk1p tyrosine phosphorylationduring exposure to $alpha$ -factor, calcofluor white, or high temperature.Our data are consistent with a role for Mid2p in sensing cellwall stress and in activation of a response that includes bothincreased chitin synthesis and the Mpk1p mitogen-activated proteinkinase cell integrity pathway. In addition, we have identifiedan open reading frame, MTL1, which encodes a protein with bothstructural and functional similarity toMid2p.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

The cell wall is an essential organelle in fungal species. In Saccharomyces cerevisiae it is composed of four polysaccharidepolymer classes: $beta$ -1,3-glucan, $beta$ -1,6-glucan, mannan, and chitin.The functions provided by the yeast cell wall include the determinationof cell shape, protection of osmotic integrity, and scaffoldingfor extracellular proteins important for nutrient uptake and agglutinationbetween mating partners. Recent research has emphasized the dynamicnature of this structure (see references 10 and 37 for reviews),which undergoes major changes in shape and composition duringthe vegetative budding cycle and the alternative developmentalpathways of mating andsporulation.

Stress can lead to alteration of polymer levels in the yeast cell wall. This effect is perhaps best documented for chitin.Schekman and Brawley (44) noted that during shmoo formation,a process during which the cell wall is rapidly remodeled, additionalchitin is synthesized and deposited at the base and neck regionof the mating projection. Roncero and Duran (43) noted thatexposure to calcofluor white, a substance which binds primarilychitin in the yeast cell wall, interferes with proper wall synthesisand induces elevated chitin synthesis in vivo. Recently, Popoloet al. (39) and Ram et al. (41) observed that mutational disruptionof cell wall biosynthesis caused increased chitin deposition.This finding led to the proposal that alterations in cell wallassembly cause yeast to engage a compensation mechanism that includesincreased chitinsynthesis.

The PKC1-MPK1 signal transduction pathway plays an essential role in maintaining the integrity of the cell wall during bothmating and vegetative growth. Igual et al. (20) showed thatat least part of this influence on cell wall construction is theresult of control of transcription of a variety of genes involvedin cell wall biosynthesis. Pkc1p, a serine/threonine protein kinase(28), serves to stimulate a mitogen-activated protein (MAP)kinase cascade comprised of Bck1p (Slk1p) (11, 26, 29),Mkk1p/Mkk2p (21), and Mpk1p (Slt2p) (27). Mutation of componentsin the PKC1-MPK1 pathway have a range of effects, such as celllysis, caffeine sensitivity, cell cycle progression defects, anddefective cytoskeletal organization. The molecular basis of yeastPkc1p stimulation is not yet fully understood; however, the GTP-boundform of the small G-protein, Rho1p, has been shown to physicallyassociate with Pkc1p, resulting in Pkc1p activation (14, 24,35).

Studies of the extracellular matrix of mammalian cells, a structure analogous to the yeast cell wall, have revealed a classof protein receptors known as integrins. Integrins possess a largeextracellular domain, a single membrane-spanning region, and ashort cytoplasmic domain. Activation of protein kinases and smallGTP-binding proteins such as RhoAp by integrins affects cell adhesion,cellular ion levels, and polarized growth. Recently, Bickle etal. (3) have proposed that disturbances in the cell wall causeactivation of the Rho1p GTPase via the Rom2p exchange factor ina manner analogous to integrin signaling. Although the proteomeof S. cerevisiae does not include integrin homologs, there area number of cell surface proteins topologically resembling integrinsthat could potentially carry out equivalent extracellular sensing/intracellularsignaling processes. These proteins, usually type I in orientation,contain large extracellular regions rich in serine and threonineresidues, single transmembrane domains, and relatively small cytoplasmicregions.

WSC1 (HCS77/SLG1) encodes a protein with sensor/signaler-like characteristics that has recently been identified as an upstreamactivator of Pkc1p (19, 22, 47). Three homologous proteins,encoded by the WSC2, WSC3, and WSC4 genes, appear to have overlappingactivity with Wsc1p since their deletion can increase the severityof wsc1 $Delta$ phenotypes (47). wsc $Delta$ mutants display characteristicsof cells with decreased Pkc1p activity, namely, reduced growthrate and sorbitol-suppressible, temperature-dependent cell lysis.Overexpression of genes presumably downstream of the WSC family,such as RHO1 and PKC1, can suppress some of the effects of WSCgene deletions. The mechanism by which Wsc proteins stimulatePkc1p activity is not yet known, but it has been suggested thatWsc1p might somehow regulate Rho1p activity and thereby affectdownstream targets of Rho1p such as Pkc1p (2).

Mid2p, although not a member of the WSC family, is another potential extracellular sensor that has been identified as a participantin a number of cellular processes. In wild-type MATa cells,transcription of MID2 increases severalfold in response to $alpha$ -factorand cells lacking Mid2p die during exposure to $alpha$ -factor (36).Multicopy MID2 has been found to suppress a variety of mutantphenotypes, including the temperature sensitivity of mpt5 $Delta$ mutants(46), growth in profilin (pfy1 $Delta$ )-deficient cells (32), andtemperature-sensitive growth in cik1 $Delta$ and kar3 $Delta$ mutants (31).Additionally, KAI1, an internal fragment of MID2 was identifiedas a multicopy inhibitor of excessive protein kinase A (TPK1)activity (12).

We identified MID2 as a high-copy-number activator of the Skn7p transcription factor. A relationship between Mid2p and thecell wall is suggested by a number of genetic interactions betweenMID2 and cell wall biosynthesis genes. Alteration of MID2 genedosage affects stress-related cell wall chitin deposition, suggestingthat MID2 is partly required for induction of cell wall stress-inducedchitin synthesis. Furthermore, genetic interactions between MID2and elements of the PKC1-MPK1 pathway, as well as a requirementfor MID2 during induction of Mpk1p tyrosine phosphorylation undera variety of stress conditions, together suggest a role for Mid2pupstream of the PKC1-MPK1 cell wall integritypathway.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Plasmids, strains, and gene deletion constructs. Oligonucleotides used in this study are listed in Table 1. Yeast strains used in this study are listed in Table 2. The MID2locus, contained within a 2.45-kb NheI-XhoI genomic DNA fragment,was subcloned into pBluescript II (pBSII) SK+ at compatible XbaIand SalI restriction sites. A 2.5-kb KpnI-SstI fragment containingMID2 was excised from this plasmid and then inserted into pRS316,pRS425, and pRS426 at corresponding KpnI-SstI sites in the polylinker.Deletion of the entire MID2 open reading frame (ORF) was accomplishedby integration of a mid2 $Delta$ ::KANMX2 cassette (48). mid2 $Delta$ ::KANMX2was generated by using the oligonucleotides mid2 $Delta$ up and mid2 $Delta$ down.Correct insertion of the cassette and deletion of the readingframe was confirmed by PCR analysis of yeast colonies using theoligonucleotides mid2 $Delta$ test and KANMX2 internal. Deletion of WSC1was accomplished by replacement of the WSC1 reading frame witha wsc1 $Delta$ ::KANMX2 cassette generated by the oligonucleotides wsc1 $Delta$ upand wsc1 $Delta$ down. Integration was confirmed by using the KANMX2 internaltest oligonucleotide and the wsc1 $Delta$ test oligonucleotide. Deletionof RHO1 was accomplished by using a GFP-HIS3 cassette (34) andthe oligonucleotides rho1 $Delta$ up and rho1 $Delta$ down to create rho1 $Delta$ ::GFP-HIS3.Correct integration of the deletion cassette into the SEY6210² (diploid) strain was confirmed by using the oligonucleotidesrho1 $Delta$ test and GFP-HIS3 internal; 2:2 segregation of viable andinviable meiotic products was observed after dissection of tetradsderived from heterozygous rho1::GFP-HIS3 RHO1 diploids. Deletionof PKC1 was achieved by using the oligonucleotides pkc1 $Delta$ up andpkc1 $Delta$ down to generate the pkc1 $Delta$ ::GFP-HIS3 cassette. Integrationof the PCR product was confirmed by using the oligonucleotidespkc1 $Delta$ test and GFP-HIS internal. Deletion of MTL1 was accomplishedby replacement of the MTL1 reading frame with a mtl1 $Delta$ ::GFP-HIS3cassette generated by the nucleotides mtl1 $Delta$ up and mtl1 $Delta$ down. Correctintegration was confirmed by using the GFP-HIS3 internal and mtl1 $Delta$ testnucleotides.

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TABLE 1. Oligonucleotide sequences

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TABLE 2. Strains used

The RHO1 and MTL1 genes were amplified from SEY6210 genomic DNA by using Expand polymerase (Boehringer Mannheim) and the oligonucleotidesrho1 clone for and rho1 clone rev to generate RHO1 and mtl1 clonerev and either mtl1 clone for prom or mtl1 clone for start togenerate clones of MTL1 containing 916 nucleotides of promotersequence or a promoterless clone with only 65 nucleotides 5' ofthe ATG codon, which was used for fusion to the ADH1promoter.

Mid2p-HA was created by the insertion of a single copy of the hemagglutinin (HA) epitope (YPYDVPDYA) between residues 375and 376 via site-directed mutagenesis (Kunkel method [25]) onMID2 contained in pBSII KS $-$ , using the oligonucleotide HA-insert.Fidelity of incorporation of the HA epitope was confirmed by DNAsequencing. A KpnI-SstI fragment containing MID2-HA was then subclonedinto pRS316 and pRS426 at corresponding KpnI and SstI sites. Mid2p-HAwas demonstrated to be functional by the observation that pRS316-MID2-HAwas fully able to complement a mid2 $Delta$ mutant in a test for hypersensitivityto $alpha$ -factor(Sigma).

Removal of the serine/threonine-rich region was accomplished by generating an EcoRI restriction site by modification of thesequence AAGTTC (nucleotides 641 to 646 in the MID2 reading frame)to GAATTC via site-directed mutagenesis using the oligonucleotideEcoRI Insert. A second EcoRI restriction site occurs naturallyat positions 102 to 107 in the reading frame. This construct wasthen digested with EcoRI, releasing a 540-bp fragment coding forthe bulk of the serine/threonine-rich region. The remaining plasmidfragment was gel purified (Pharmacia) and religated, creatingthe continuous in-frame ORF $Delta$ S/T-MID2.

Western blots and membrane association tests. For membrane association tests, total cell extracts were prepared from mid-log-phase cultures grown in selective medium byvigorous vortexing in lysis buffer (50 mM Tris [pH 7.5], 1 mMEDTA, 5% glycerol) in the presence of glass beads and proteaseinhibitors (Complete protease inhibitor cocktail; Boehringer Mannheim).The resulting slurry was centrifuged at 2,500 × g at 4°C for 5min to remove cell walls and unbroken cells. The resulting supernatantwas then divided, and the individual aliquots were subjected toeither centrifugation at 15,000 × g at 4°C for 30 min or treatmentwith sodium chloride, sodium carbonate, urea, or Triton X-100and then subjected to centrifugation at 60,000 × g at 4°C for30 min. Postcentrifugation, supernatants were withdrawn, and pelletswere resuspended in a volume of lysis buffer equal to the supernatant.Samples were resolved by sodium dodecyl sulfate-polyacrylamidegel electrophoresis (SDS-PAGE) and then subjected to Western blotting.Immunodetection of Mid2p-HA was achieved by using anti-HA monoclonalantibody 12CA5 (Babco) at 1:1,000 dilution and horseradish peroxidase-conjugatedanti-mouse secondary antibody (Amersham Life Sciences) at a 1:1,000.Bands were visualized using by enhanced chemiluminescence (AmershamLife Sciences). For other SDS-PAGE and Western blotting procedures,total cell lysates were prepared with lysis buffer (2% Triton-X100,1% SDS, 100 mM NaCl, 10 mM Tris-HCl [pH 8.0], 1 mMEDTA).

Localization of Mid2p. A MID2-GFP fusion was generated by modifying the coding sequence of MID2 (contained in pBSII KS $-$ ) immediately upstream ofthe TAA stop codon (TTATTA) via site-directed mutagenesis to aKpnI restriction site (GGTACC), using the oligonucleotide KpnIInsert. Clones positive for the incorporation of the KpnI sitewere then confirmed by sequencing. Creation of an in-frame fusionof MID2 to GFP (F64L S65T; kindly provided by U. Stochaj) wasaccomplished by a three-way ligation involving pRS426 or pRS316(with XhoI/EcoRI ends) MID2 (with XhoI/KpnI ends) and GFP (withKpnI/EcoRI ends). Correct orientation of the ligation productswas confirmed by diagnostic restriction digests. Function of theMID2-GFP fusion was demonstrated by observation that pRS316-MID2-GFPfully complements mid2 $Delta$ mutants for $alpha$ -factor hypersensitivity.Localization of Mid2p-GFP (green fluorescent protein) was accomplishedby examination of live, mid-log-phase mid2 $Delta$ cells carrying pRS316-MID2-GFPand pRS426-MID2-GFP.

Calcofluor white tests. To test strains for sensitivity to calcofluor white, mid-log-phase cells were diluted, then spotted either onto rich YEPDagar plates containing the indicated amount of calcofluor whiteor onto selective medium buffered with 10 g of morpholineethanesulfonicacid per liter and adjusted to pH 6.2. Plates were incubated for48 to 72 h at 30°C in a darkenvironment.

Multicopy suppression of $alpha$ -factor-induced death. Cultures of cells containing either control plasmids or plasmids bearing genes of interest were diluted to 3 × 10⁴ cells/ml in buffered (85 mM succinic acid, 19 mM sodium hydroxide)YNB liquid medium containing appropriate amino acids. Triplicatealiquots of each strain were removed and spread on selective solidmedium. $alpha$ -Factor was then added to liquid cultures to a finalconcentration of 1 µM, and these cultures were incubated at 30°Cfor 330 min before a second series of aliquots were removed andplated. Petri dishes were incubated for 48 h at 30°C, resultingin the formation of colonies derived from single cells. The numberof colonies on each petri dish was counted, and survival of $alpha$ -factorexposure was measured by the difference between the number ofcolonies on pre- and post- $alpha$ -factor petri dishes for eachstrain.

Chitin assays. Total cellular chitin was measured essentially as described by Bulawa et al. (9) and outlined here (8a). Washed cells(~50 mg [wet weight]) were suspended in 500 µl of 6% KOH and incubatedat 80°C for 90 min. After cooling to room temperature, 50 µl ofglacial acetic acid was added. Insoluble material was washed twicewith water and resuspended in 250 µl of 50 mM sodium phosphate(pH 6.3); 2 mg of Streptomyces griseus chitinase (Sigma) was added,and tubes were incubated at 25°C with gentle agitation for 2 h.Tubes were centrifuged at 15,000 × g for 5 min at room temperature,and 250 µl of supernatant was transferred to a fresh tube to which1 mg of Helix pomatia $beta$ -glucuronidase (Sigma) was added. Tubeswere incubated at 37°C for 2 h with gentle agitation and thenassayed for N-acetylglucosaminecontent.

Measurement of Mpk1p-HA phosphotyrosine content. Mid-log-phase cultures of cells expressing Mpk1p-HA or a vector-only control were exposed to calcofluor white (40 µg/ml for30 min), $alpha$ -factor (4 µM for 3 h), or high temperature (37°C for3 h); 1 ml of culture was centrifuged (15,000 × g, 30 s, roomtemperature), the supernatant was aspirated, and the cell pelletwas resuspended in 50 µl of 1× SDS loading buffer and boiled for4 min. Cell debris was pelleted by centrifugation, and 10 µl ofsupernatant per sample was subjected to SDS-PAGE and Western blotting.Tyrosine phosphorylation of proteins was visualized by incubationof blots with the phosphotyrosine-specific antibody 4G10 (giftfrom J. Lee) at 1:3,300 dilution and anti-mouse horseradish peroxidase-conjugatedsecondary antibody at 1:2,000. Blots were then stripped and reprobedwith the anti-HA monoclonal antibody 12CA5 to verify equal loadingof Mpk1p-HA in eachlane.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

MID2 stimulates Skn7p transcriptional activity. Skn7p, a transcription factor containing a region of homology to bacterial two-component response-regulator proteins, wasisolated by Brown et al. (6) as a high-copy-number suppressorof growth defects in kre9 $Delta$ mutants. A screen was performed toidentify genes which, when overexpressed, would stimulate theSkn7p-LexA-dependent transcription of a (lexA_op)₄-HIS3 reporter(38). In this procedure, the L40 reporter strain carrying Skn7p-LexAwas transformed with a Yep13-based multicopy genomic bank. Plasmidclones were extracted from colonies which could grow on syntheticmedium lacking histidine and including 10 mM 3-amino-1,2,4-triazole(3AT) to squelch His3p activity resulting from basal transcriptionof HIS3.

Ten groups of activator of SKN7 (ASK) clones, ASK1 to ASK10, were identified. Sequence analysis revealed that ASK5, ASK7,and ASK9 contained a common gene, YLR332W (MID2). We subclonedthe MID2, gene including 627 nucleotides 5' of the codon for thestart methionine and 737 nucleotides 3' of the stop codon, intopRS425 and directly tested the ability of MID2 to stimulate Skn7p-LexAtranscriptional activity. Multicopy MID2 is able to strongly induceSkn7p-LexA activity compared to a vector-only control, permittingreporter strain growth on medium lacking histidine and containing30 mM 3AT (Fig. 1). This effect is dependent on an interactionbetween MID2 and LEXA-SKN7 since overexpression of MID2 alonedoes not activate transcription of the reporter (not shown). Wealso measured the induction of $beta$ -galactosidase activity from the(lexA_op)₈-lacZ locus and found that multicopy MID2 was able toinduce a 7- to 10-fold, Skn7-LexA-dependent increase in $beta$ -galactosidaseactivity (not shown).

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FIG. 1. Multicopy MID2 activates Skn7p-LexA-dependent transcription of HIS3, which allows growth on medium lacking histidine. Reporter strains containing Skn7p-LexA and either pRS425 (TK60) or pRS425-MID2 (TK61) were grown on selective medium lacking histidine and containing 30 mM 3AT.

Characterization and subcellular localization of Mid2p. MID2 is predicted to encode a type I membrane-spanning protein containing an N-terminal secretion signal sequence followedby a domain of approximately 200 amino acids consisting of ~62%serine and threonine residues. The C-terminal third of the proteincontains a single predicted transmembrane domain and a short chargeddomain rich in aspartic acid residues, suggested to resemble acalcium binding domain (36). Although Mid2p has overall structuralsimilarity to members of the WSC family, there are two importantdifferences. Firstly, Mid2p does not contain an extracellularcysteine-rich motif that is characteristic of the Wsc proteins.Second, apart from the repetitive serine/threonine-rich region,there is no statistically significant amino acid residue sequencesimilarity between Mid2p and Wscproteins.

To examine physical characteristics of Mid2p, a functional HA-tagged protein (Mid2p-HA) was generated. After proteolytic processingof the signal peptide, Mid2p-HA is predicted to have a molecularmass of approximately 39 kDa. However, Mid2p-HA migrates withan apparent molecular mass of approximately 200 kDa on SDS-PAGE(Fig. 2A, lane b). The predicted type I orientation of Mid2p suggeststhat if Mid2p were plasma membrane localized, the serine/threonine-richregion would reside on the exterior face of the cell. Since serine/threonine-richregions of extracellular protein domains can receive O-linkedmannosylation as the protein travels through the secretory pathway(45), we examined Mid2p for evidence of this modification. Whenisolated from pmt1 $Delta$ pmt2 $Delta$ mutants (deficient in O-linked mannosylation[30]), Mid2p-HA migrates on SDS-PAGE close to the predictedsize of 39 kDa (Fig. 2A, lane d), displaying a shift of roughly160 kDa compared to Mid2p-HA expressed in wild-type cells. Toverify that it was the serine/threonine domain that was the recipientof the O-mannosylation, we excised this region from Mid2p-HA,generating $Delta$ S/T Mid2p-HA. On SDS-PAGE, $Delta$ S/T Mid2p-HA also migratesnear its predicted molecular mass of 23 kDa (Fig. 2B), stronglysuggesting that the serine/threonine-rich region is the recipientsite of O-linked mannosylation. $Delta$ S/T Mid2p-HA localizes to thesame subcellular location as Mid2p-HA (not shown; see below);however, pRS316- $Delta$ S/T Mid2p-HA is unable to complement a mid2 $Delta$ mutant for sensitivity to $alpha$ -factor, indicating that Mid2p requiresthe serine-threonine rich domain for activity. Together, theseresults suggest that extensive, functionally important modificationof Mid2p occurs on the extracellular serine/threonine-rich region.

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FIG. 2. Cell biology of Mid2p. (A) Immunoblot analysis of cell extracts from TK82 (vector only) (lane a), TK84 (MID2-HA) (lane b), pmt1 $Delta$ pmt2 $Delta$ (vector only) (lane c), and pmt1 $Delta$ pmt2 $Delta$ (MID2-HA). (B) Immunoblot analysis of cell extracts from TK82 (vector only) (lane a) and TK85 ( $Delta$ S/T-Mid2p-HA) (lane b). (C) Immunoblot analysis of cell fractions from TK84 to demonstrate membrane association of Mid2p. LSS, low-speed-spin pellet fraction. (D) In cells expressing pRS426-MID2-GFP (TK98), Mid2p-GFP is localized to the cell periphery.

To verify the prediction that Mid2p is an integral membrane protein, partially purified extracts from cells expressing Mid2p-HAwere fractionated into supernatant (soluble) and pellet (membrane-containing)portions by centrifugation. Mid2p-HA is found exclusively in thelow-speed (15,000 × g)-spin pellet fraction, implying membraneassociation (Fig. 2C). To test whether this membrane associationwas peripheral or integral, partially purified, membrane-containingcell extracts were treated prior to ultracentrifugation with sodiumchloride, sodium carbonate, or urea to disrupt peripheral interactionsor with Triton X-100 to disrupt integral membrane association.Only Triton X-100 was capable of solubilizing a significant proportionof Mid2p-HA (Fig. 2C), strongly suggesting that Mid2p-HA is anintegral membrane protein. There does not appear to be a fractionof Mid2p-HA covalently associated with the cell wall since treatmentof purified cell wall fractions with $beta$ -1,3-glucanase (either laminarinaseor Quantazyme) before solubilization of proteins by treatmentwith SDS does not release any detectable Mid2p-HA (notshown).

Direct immunofluorescence microscopy was performed to establish the subcellular localization of Mid2p. A functional Mid2p-GFPfusion protein was constructed by inserting GFP immediately upstreamof the MID2 stop codon. Examination of fluorescing cells maintainingeither centromeric (not shown) or multicopy (Fig. 2D) Mid2p-GFPreveals Mid2p-GFP distribution to be largely confined to the peripheryof cells, consistent with a plasma membrane localization. Expressionof native GFP alone produces a diffuse fluorescence pattern throughoutthe cell (not shown). Indirect immunofluorescence of cells expressingMid2p-HA revealed an identical pattern of staining (not shown).No polarized localization of Mid2p-GFP to specific regions ofthe surface such as the bud tip or bud neck was detected; however,approximately 20% of $alpha$ -factor-treated cells (n = 100) displayfaint preferential staining at the subapical region of the matingprojection (notshown).

Interactions between MID2 and cell wall biosynthesis genes. Since the O-mannosylated, extracellular domain of Mid2p is predicted to be oriented toward the cell wall, we explored a possiblerelationship between Mid2p and the cell wall by searching forgenetic interactions between MID2 and genes known to be involvedin cell wall construction. Deletion of MID2 in two viable butslow-growing $beta$ -1,6-glucan synthesis mutants, kre6 $Delta$ (42) andkre9 $Delta$ (5), partially restores growth rate (Fig. 3A, and B).This effect is not due to differential timing of spore germinationsince increased growth rate in the absence of MID2 (~20% reductionin doubling time) is observed for kre6 $Delta$ cells cultured in liquidmedium. Also, reintroduction of MID2 on a centromeric plasmidcauses kre6 $Delta$ mid2 $Delta$ cells and kre9 $Delta$ mid2 $Delta$ cells to resume slowergrowth (not shown). Interestingly, high-copy-number expressionof MID2 in the kre6 $Delta$ mutant has a strong negative effect on growthrate (Fig. 3C). Optical density measurement of cell growth inliquid culture revealed that high-copy-number expression of MID2(pRS426-MID2)in kre6 $Delta$ cells resulted in a ~300% increase in doubling time comparedto a vector-only control. This reduction in growth rate is muchmore pronounced in kre6 $Delta$ mutants than in wild-type cells, wheredoubling time increases by only 15% over a vector-only controlfor cells carrying pRS426-MID2. Interestingly, high-copy-numberexpression of MID2 in the growth-deficient pmt1 $Delta$ pmt2 $Delta$ mutants,where Mid2p is undermannosylated, also results in a reductionin growth rate. This finding suggests that although the serine/threonine-richdomain itself is indispensable for Mid2p activity, extensive O-linkedmannosylation of this region may not be totally essential forMid2p function.

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FIG. 3. Deletion of MID2 has effects on growth of different cell wall mutants. (A) Representative tetratype tetrad from TK101 (kre6 $Delta$ mid2 $Delta$ heterozygous diploid). (B) Representative tetratype tetrad from TK102 (kre9 $Delta$ mid2 $Delta$ heterozygous diploid). (C) Single cells containing the indicated plasmids were placed on selective agar and grown at 30°C for 4 days. Photo is representative of effect seen in three isolates each of three transformations. (D) Representative tetratype tetrad from TK103 (fks1 $Delta$ mid2 $Delta$ heterozygous diploid).

Examination of cell wall glucan content revealed that wild-type and mid2 $Delta$ cells have no differences in $beta$ -1,6- and $beta$ -1,3-glucancontent. Similarly, kre6 $Delta$ and kre6 $Delta$ mid2 $Delta$ mutants have comparablelevels of both glucan species (not shown), suggesting that atleast for the kre6 $Delta$ mutant, increased growth rate induced by lossof MID2 is not caused by a restoration of $beta$ -1,6-glucan synthesis.To determine if MID2 genetically interacts with the $beta$ -1,3-glucansynthesis pathway, we examined the consequence of loss of MID2in fks1 $Delta$ mutants (13, 17, 40). In contrast to the restorativeeffect that deletion of MID2 had in $beta$ -1,6-glucan mutants, lossof MID2 in fks1 $Delta$ cells causes inviability (Fig. 3D). This phenotypeis not reversible by the addition of 1 M sorbitol or 30 mM calciumchloride (not shown). Overexpression of MID2 in an fks1 $Delta$ mutantdoes not result in an inhibition of growth like that seen in kre6 $Delta$ mutants with high-copy-number MID2 (notshown).

MID2 affects chitin synthesis under stress conditions. Although chitin comprises a small percentage of the cell wall weight, its contribution to wall integrity is vital. Calcofluorwhite is a fluorescent dye that intercalates into nascent chitinchains, preventing microfibril assembly (15). At sufficientconcentrations, calcofluor white can kill cells through interferencewith cell wall assembly. mid2 $Delta$ cells display significant resistanceto calcofluor white. At a calcofluor white concentration of 20µg/ml on rich medium, wild-type cells are killed whereas mid2 $Delta$ cells can grow without apparent inhibition (Fig. 4A).

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FIG. 4. Dosage of MID2 affects sensitivity to calcofluor white. Mid-log-phase cells were diluted to a concentration of 3 × 10⁶ cells/ml; 5 µl of this suspension and three subsequent 10-fold serial dilutions were each spotted onto the indicated medium. (A) SEY6210a (wild type) (row a) and TK88 (mid2 $Delta$ ) (row b) cells were spotted onto YEPD containing 0 and 20 µg of calcofluor white (CFW) per ml. (B) TK82 [wild type (pRS426)] (row a), TK83 [wild type (pRS426-MID2)] (row b), TK86 [wild type (pVT101U)] (row c), and TK87 [wild type (pVT101U-MID2)] (row d) were spotted on uracil dropout medium containing 0 and 2.5 µg of calcofluor white per ml. (C) TK86 (row a), TK87 (row b), TK99 [chs3 $Delta$ (pVT101U)] (row c), and TK100 [chs3 $Delta$ (pVT101U-MID2)] (row d) were spotted onto uracil dropout medium containing 0, 2.5, and 15 µg of calcofluor white per ml.

Since resistance to calcofluor white is a phenotype often associated with defects in chitin synthesis, one possibility isthat calcofluor white resistance of mid2 $Delta$ cells is a consequenceof reduced chitin synthesis. Measurement of chitin levels in wild-typeand mid2 $Delta$ cells revealed that they have identical chitin contentswhen grown in rich (YEPD) medium, suggesting that Mid2p is notrequired for basal chitin production under such optimum growthconditions (Table 3, condition A). Because exposure to calcofluorwhite increases chitin production in vivo (43), we tested whetherMID2 is required for synthesis of supplemental chitin by measuringthe chitin content of cells that had been challenged with sublethalconcentrations of calcofluor white. We then calculated the amountof new chitin synthesized in response to calcofluor white challengeby subtracting the amount of chitin produced under nonstressedconditions from the total chitin measured after calcofluor whiteexposure. Interestingly, mid2 $Delta$ mutants contained 40% less new,stress-induced, total cell wall chitin than wild-type cells whencultures were grown in the presence of 10 µg of calcofluor whiteper ml for 2 h prior to harvesting (Table 3, condition B). Thisattenuation of calcofluor white-induced chitin synthesis is likelyto be at least part of the cause of calcofluor white resistancein mid2 $Delta$ cells.

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TABLE 3. Measurement of total cellular chitin

To determine if Mid2p is required for supplementary chitin synthesis under a broader range of cell wall stresses, we lookedfor Mid2p-dependent changes in cellular chitin content in twoother circumstances. It has been observed that cell wall mutantstypically have higher cell wall chitin levels than wild-type cells(39, 41). Analysis of chitin content revealed that kre6 $Delta$ cellshave >2.5-fold more total chitin than wild-type cells. Similarto the effect seen in calcofluor white-challenged cells, lossof MID2 causes a small but significant decrease (~28%) in extentof stress-induced chitin synthesis in kre6 $Delta$ mutants (Table 3,condition C). Another situation known to increase chitin productionis shmoo formation in response to mating pheromone (44). Afterinduction of projection formation by $alpha$ -factor, MATa mid2 $Delta$ mutants had synthesized almost 80% less new chitin than wild-typecells (Table 3, condition D). These observations suggest thatMid2p is partially required for production of supplementary wallchitin under conditions of wall damage (by mutation or calcofluorwhite) or morphological change (shmooformation).

To further address the relationship between MID2 and chitin synthesis, growth of cells overexpressing MID2 was examined oncalcofluor white-containing medium. Cells harboring MID2 on a2 µm plasmid have reduced viability at a calcofluor white concentrationof 2.5 µg/ml, and cells expressing MID2 from the strong constitutiveADH1 promoter at 2 µm levels are completely inviable on calcofluorwhite at 2.5 µg/ml (Fig. 4B). Since calcofluor white resistancein mid2 $Delta$ cells is associated with reduced supplementary chitinsynthesis, this finding suggests that overexpression of MID2 maycause an increase in wall chitin content, conferring hypersensitivityto this drug. Indeed, analysis of total chitin revealed that cellscarrying ADH1 promoter-driven MID2 had approximately 250% morechitin than cells without multicopy MID2 (Table 1, conditionE).

Because Chs3p is responsible for the bulk of lateral wall and bud scar chitin, and deletion of CHS3 leads to a 10-fold reductionin total cellular chitin content and strong resistance to calcofluorwhite, we next tested whether the hypersensitivity to calcofluorwhite caused by MID2 overexpression is mediated through Chs3pactivity. Spot testing of chs3 $Delta$ cells containing multicopy MID2,with either its own or the ADH1 promoter, on calcofluor white-containingmedium revealed that CHS3 is required for high-copy-number MID2to confer calcofluor white hypersensitivity (Fig. 4C). This findingsuggests that Mid2p may ultimately affect extra chitin synthesisthrough some form of regulation of Chs3pactivity.

MID2 interacts with the cell integrity pathway. To identify additional MID2 interactors, we performed a screen for multicopy suppressors of the mid2 $Delta$ fks1 $Delta$ synthetic lethality[plasmids were selected for the ability to promote growth in mid2 $Delta$ fks1 $Delta$ (pRS316-FKS1) cells after loss of pRS316-FKS1 was promotedby replication onto medium containing 5-fluoro-orotic acid]. Twoof the genes identified as mid2 $Delta$ fks1 $Delta$ suppressors were PKC1 andWSC1. Several genetic interactions between MID2 and WSC1 suggestthat these genes possess overlapping activities. First, mid2 $Delta$ wsc1 $Delta$ cells are inviable at 22 or 30°C on YEPD medium. Inclusionof sorbitol (between 0.3 and 1 M) in medium permits partial restorationof growth, suggesting that mid2 $Delta$ wsc1 $Delta$ mutants, like pkc1 $Delta$ mutants,are prone to lysis without osmotic support (Fig. 5A). When transferredfrom osmotically supported medium to YEPD, mid2 $Delta$ wsc1 $Delta$ mutantsarrest growth with a small bud. After 36 h on YEPD, approximately85% of mid2 $Delta$ wsc1 $Delta$ cells have small buds, while between 6 and8% of wild-type, mid2 $Delta$ and wsc1 $Delta$ cells display a small bud (morethan 150 cells counted per genotype). Further suggesting a functionalrelationship between MID2 and WSC1, high-copy-number expressionof MID2 partially suppresses the growth defect of wsc1 $Delta$ mutants(not shown). Finally, overexpression of WSC1 is able to relievethe sensitivity of mid2 $Delta$ cells to $alpha$ -factor (Fig. 5B). Together,these findings indicate a functional overlap between Mid2p andWsc1p.

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FIG. 5. Genetic interactions between MID2 and members of the cell integrity pathway. (A) Representative tetratype tetrads of TK104 (mid2 $Delta$ wsc1 $Delta$ heterozygous diploid) dissected onto either YEPD or YEPD plus 1 M sorbitol. YEPD plates were incubated for 60 h at 30°C, YEPD-1 M sorbitol plates were incubated for 80 h at 30°C. WT, wild type. (B) Members of the cell integrity pathway suppress $alpha$ -factor-induced death in mid2 $Delta$ mutants. Wild-type cells containing pRS426 vector only and mid2 $Delta$ mutants carrying pRS426, YEP13-PKC1, pBM743-PKC1^R398A (GAL-driven, hyperactive PKC1), pRS426-RHO1, pRS426-WSC1, pRS426-WSC2, pRS316-BCK1-20 (hyperactive BCK1), YEP352-MPK1, and pRS425-MTL1 in liquid medium were exposed to $alpha$ -factor. Percentage of survival was measured by spreading liquid medium before and after $alpha$ -factor exposure (330 mn) on petri dishes and counting colonies derived from single cells.

Since Wsc1p and its homologs have been implicated in Pkc1p activation, and the mid2 $Delta$ wsc1 $Delta$ small-budded terminal phenotyperesembles that of cells lacking Pkc1p activity (28), we examinedthe possibility that Mid2p can also contribute to regulation ofthe PKC1-MPK1 pathway. Like pkc1 $Delta$ mutants, mid2 $Delta$ pkc1 $Delta$ cells areinviable on medium without osmotic support; however, these doublemutants are able to grow at a rate similar to that of pkc1 $Delta$ mutantson medium containing 1 M sorbitol at both 22 and 30°C (not shown).Moreover, multicopy MID2 does not alter the growth rate of pkc1 $Delta$ cells (not shown), suggesting that genetically, PKC1 acts downstreamof MID2.

To further explore the potential role of Mid2p in PKC1-MPK1 pathway regulation, we examined whether Mid2p influences Mpk1pactivation. The Mpk1p MAP kinase is activated through tyrosinephosphorylation during mating projection formation (8, 49).We found that compared to wild-type cells, mid2 $Delta$ mutants havesubstantially less tyrosine phosphorylation on Mpk1p-HA afterexposure of cells to $alpha$ -factor (Fig. 6A). This observation suggeststhat underactivation of the cell integrity pathway might be, atleast in part, responsible for pheromone-induced death in mid2 $Delta$ mutants. The finding that overexpression of PKC1, PKC1^R398A (a hyperactive allele), RHO1, WSC1, and WSC2 can suppress $alpha$ -factor-induceddeath in mid2 $Delta$ mutants (Fig. 5B) independently supports this conclusion.However, expression of either bck1-20 (a hyperactive allele ofBCK1), or MPK1 does not suppress this phenotype, and at high concentrationsof pheromone (>4 µM) only some of the most upstream elements ofthe cell integrity pathway, including RHO1, WSC1, and WSC2, canprevent mating pheromone-induced death (not shown).

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FIG. 6. Immunoblot analysis of Mpk1p-HA tyrosine phosphorylation. Lanes are loaded with equal amounts of extracts from strains TK96 [wild type (pFL44)] (lanes a), TK97 [wild type (pFL44-MPK1-HA)] (lanes b), TK93 [mid2 $Delta$ (pFL44)] (lanes c), and TK94 [mid2 $Delta$ (pFL44-MPK1-HA)] (lanes d). Cultures exposed to $alpha$ -factor (A), calcofluor white (B), or high-temperature growth (C) were harvested at the indicated times, and total cell proteins were subject to SDS-PAGE and Western blotting. In the top panel of each pair, tyrosine phosphorylation of Mpk1p-HA is detected by antiphosphotyrosine antibody 4G10. In the second panel of each pair, equal loading of Mpk1p-HA is demonstrated by anti-HA antibody HA11.

To explore the genetic relationship between MID2 and RHO1, we tested whether MID2 overexpression suppresses rho1 $Delta$ mutants.Because cells lacking Rho1p are inviable, even at low temperatureon medium with osmotic support, rho1 $Delta$ heterozygous diploids weretransformed with high-copy-number MID2 and then sporulated, andthe resulting asci were dissected. No viable rho1 $Delta$ mutants wererecovered from 36 tetrads analyzed, suggesting that high-copy-numberMID2 is unable to suppress the lack of Rho1p. Since overexpressionof RHO1 can suppress $alpha$ -factor-induced death in mid2 $Delta$ mutants buthigh-copy-number MID2 cannot suppress inviability of rho1 $Delta$ mutants,it appears that Mid2p may act upstream of, or in parallel with,Rho1p.

Interestingly, Mpk1p-HA tyrosine phosphorylation is also increased in wild-type cells in response to exposure to calcofluorwhite. This effect is dependent on the presence of Mid2p, sincethere is a deficit of this phosphorylation on Mpk1-HA in mid2 $Delta$ cells (Fig. 6B). MID2-dependent increase in tyrosine phosphorylationof native Mpk1p in response to calcofluor white and mating pheromoneis not readily apparent in Fig. 6A and B, perhaps due to lowerrelative abundance of native Mpk1p versus (2 µm-borne) Mpk1-HA.Also, for the chosen time points, a lower extent of tyrosine phosphorylationon Mpk1-HA is seen for calcofluor white and mating factor exposurethan is observed for high-temperature growth (Fig. 6C), suggestingthat differences in phosphorylation state for native Mpk1p inthese panels may be below the detection threshold. In other assayconditions, we observe clear MID2 dependence for native Mpk1ptyrosine phosphorylation in response to calcofluor white and matingfactor (not shown). Deletion of MPK1 results in calcofluor whitehypersensitivity, likely due to gross disturbances in cell wallconstruction. Saliently, overexpression of MPK1, like overexpressionof MID2, also results in a CHS3-dependent hypersensitivity tocalcofluor white (not shown). This effect is MID2-dependent sinceoverexpression of MPK1 does not bypass the resistance to calcofluorwhite displayed by mid2 $Delta$ cells (notshown).

Finally, we examined whether induction of tyrosine phosphorylation of Mpk1p-HA during periods of high-temperature stress requiresMID2. Although mid2 $Delta$ cells do not have a growth defect at 37°C,induction of tyrosine phosphorylation of Mpk1p-HA was significantlyimpaired in mid2 $Delta$ mutants compared to wild-type cells (Fig. 6C).Together, these observations suggest a role for Mid2p in activationof the Mpk1p MAP kinase cascade under a variety of stressconditions.

Identification of a Mid2p functional homolog. The S. cerevisiae genome contains a gene, YGR023W, which encodes a 551-amino-acid residue protein with both structural andamino acid sequence similarity to Mid2p [W. U. Blast V2.0 P(N)value of 1.2e²⁷]. We will refer to YGR023W as MTL1 (MID2-like 1). To initiatethe characterization of MTL1, we disrupted its entire ORF. Unlikemid2 $Delta$ cells, mtl1 $Delta$ mutants in the SEY6210 strain background haveno distinguishable phenotype when challenged with temperatureextremes, oxidative and osmotic stresses, $alpha$ -factor, calcofluorwhite, or mutation of the KRE6 or FKS1 cell wall synthesis gene(not shown). While mtl1 $Delta$ single mutants are not hypersensitiveto caffeine, mid2 $Delta$ cells are mildly more susceptible than wild-typecells, and mid2 $Delta$ mtl1 $Delta$ double mutants show strong sensitivityto this drug. This phenotype appears to be the result of celllysis since it is suppressible by the inclusion of 1 M sorbitolin the growth medium (not shown). Caffeine sensitivity of themid2 $Delta$ mtl1 $Delta$ mutant is also suppressible by overexpression of WSC2;however, multicopy WSC1, RHO1, PKC1, BCK1, and MPK1 do not bypassthis phenotype. Finally, although mid2 $Delta$ mtl1 $Delta$ double mutants areno more sensitive to $alpha$ -factor than mid2 $Delta$ cells (not shown), high-copy-numberexpression of MTL1 from either its own promoter or the ADH1 promoteris able to suppress the caffeine (not shown) and $alpha$ -factor sensitivityof mid2 $Delta$ cells (Fig. 5B), suggesting that MTL1 is a functionalgene and that the activity of Mtl1p may be related to or overlapthe activity ofMid2p.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

Mid2p is an O-mannosylated, plasma membrane protein. In this work, we offer evidence that Mid2p may potentially sense cell wall state and act to initiate a cellular response involvingboth chitin synthesis and the PKC1-MPK1 cell integrity pathway.Mid2p is a type I integral membrane protein which localizes tothe plasma membrane and contains a large, extensively O-mannosylatedextracellular serine/threonine-rich region. Removal of the serine/threonine-richregion does not affect the targeting of Mid2p; however, $Delta$ S/T Mid2pis unable to complement mid2 $Delta$ cells, suggesting that this domainis required for Mid2p activity. This observation contrasts withthe findings for Gas1p and Kre1p, two glycosyl phosphatidylinositol-anchoredproteins involved in cell wall synthesis, where deletion of theserine/threonine-rich sequences does not greatly affect functionof these proteins (4, 18). O-linked mannosylation could causethe extracellular region to adopt a stiff and extended conformation(23) that reaches from the plasma membrane toward the cell wall,perhaps interacting with it. In Mid2p, this region is unlikelyto play a direct enzymatic role since it is largely composed ofrepetitive noncomplex amino acid sequence, and it lacks any similarityto known enzymatic motifs. An intriguing possibility is that theextracellular domain can act as a sensor of cell wallstate.

MID2 interacts with genes required for cell wall construction and cell wall integrity signaling. We isolated MID2 as an activator of the Skn7p transcription factor. Skn7p appears to affect a number of cellular processes,including cell wall biosynthesis. SKN7 was identified by Brownet al. (6) as a high-copy-number suppressor of the kre9 $Delta$ mutant,and it was later demonstrated that Skn7p may function in parallelwith Pkc1p since overexpression of SKN7 can suppress the lysisdefect of pkc1 $Delta$ mutants, and skn7 $Delta$ pkc1 $Delta$ cells are inviable, evenon medium containing osmotic support (7). Recently, Albertset al. (1) have shown that Rho1p and Skn7p physically interactand that the domain in Skn7p that mediates this interaction isimportant for activity. It is not clear how Mid2p might stimulateSkn7p transcriptional activity. Since RHO1 appears to have interactionswith both SKN7 and MID2, one avenue of future research will beto examine whether Rho1p mediates a Mid2p-Skn7interaction.

Deletion of MID2 causes significant changes in growth rate or viability for a variety of cell wall synthesis mutants. It iscurious that for the $beta$ -1,6-glucan mutants examined, loss of MID2increases growth rate, while for the $beta$ -1,3-glucan mutant fks1 $Delta$ ,deletion of MID2 causes inviability. One possibility is that reductionof supplementary chitin levels caused by absence of Mid2p is acontributing factor. fks1 $Delta$ mutants seem to depend heavily on enhancedchitin synthesis to maintain viability since they are supersensitiveto nikkomycin Z, a chitin synthase inhibitor (16). Conversely,there is some evidence that attenuation of the chitin synthesisstress response may actually be beneficial in cells lacking proper $beta$ -1,6-glucan synthesis, specifically in kre9 $Delta$ mutants (33).Consistent with this hypothesis, overexpression of MID2, whichcauses hyperaccumulation of chitin, is deleterious to $beta$ -1,6-glucanmutants but has little effect on the $beta$ -1,3-glucan-deficient mutantfks1 $Delta$ .

Screens to identify genes which interact with MID2 uncovered a relationship between MID2 and several components of a pathwayknown to promote cell integrity and polarized growth. Caffeinesensitivity of the mid2 $Delta$ and mid2 $Delta$ mtl1 $Delta$ mutants is suppressedby overexpression of WSC2, high-copy-number WSC1 and PKC1 suppressmid2 $Delta$ fks1 $Delta$ synthetic lethality, and multicopy PKC1, RHO1, WSC1,and WSC2 suppress lethality in mid2 $Delta$ MATa cells exposedto $alpha$ -factor. Additionally, mid2 $Delta$ wsc1 $Delta$ mutants are inviable withoutosmotic support and exhibit defects similar to those observedin pkc1 $Delta$ mutants. Finally, we find that during shmoo formation,high-temperature growth, or exposure to calcofluor white, tyrosinephosphorylation of Mpk1p, a downstream target of Pkc1p, is reducedin mid2 $Delta$ cells. Interestingly, although mid2 $Delta$ mutants have reducedtyrosine phosphorylation of Mpk1p in response to high-temperaturegrowth, these cells are not deficient for growth at high temperature.It is possible that there is sufficient remaining Mpk1p activityto allow cells to survive high-temperature stress or that someother mechanism is able to compensate for underactivation of thispathway. Strain differences may also play some role here, sincewe do not observe high-temperature sensitivity in wsc1 $Delta$ mutantsas reported by Verna et al. (47).

Although mid2 $Delta$ cells have no apparent vegetative growth defects, shmoo formation, mutation of cell wall synthesis genes, andexposure to calcofluor white cause mid2 $Delta$ mutants to manifest phenotypes.One possibility is that Mid2p and perhaps members of the WSC familyact indirectly, through effects on cell wall structure, to activatethe PKC1-MPK1 pathway. In an alternative model, Mid2p might sensecell wall stress and directly act to increase activity in thecell integrity pathway to counteract damage (Fig. 7). Under nonstressedconditions, Mid2p activity might be low, or not be required, andWsc1p and its homologs may be largely responsible for Pkc1p activation.However, under circumstances of cell wall stress, in the absenceof Mid2p, the cell integrity machinery would be unresponsive andwould continue to function at a level more appropriate for lowor nonstress situations.

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FIG. 7. Model of Mid2p activity. Mid2p responds to cell wall stress by activating the cell integrity pathway and increasing chitin synthesis.

This model explains why some of the phenotypes observed in mid2 $Delta$ mutants contrast with those displayed by other mutants inthe cell integrity pathway. For example, strains carrying mutationssuch as wsc1/2/3 $Delta$ , pkc1 $Delta$ , bck1 $Delta$ , or mpk1 $Delta$ are prone to cell lysisin the absence of osmotic support. These genes are required fornormal function of the cell integrity pathway under all growthconditions. In their absence, construction and maintenance ofthe cell wall is defective, making the wall highly susceptibleto damage. mid2 $Delta$ mutants have apparently normal cell walls whengrown in ordinary conditions. However, in stress situations, suchas exposure to calcofluor white or $alpha$ -factor, mid2 $Delta$ mutants havean attenuated response compared to wild-type cells, as indicatedby the reduced amount of new chitin synthesized and by the reducedextent of tyrosine phosphorylation onMpk1p.

Preliminary investigation of MTL1, the only S. cerevisiae gene encoding a protein with significant sequence similarity toMid2p, revealed that it may have a function in common with MID2.Although mtl1 $Delta$ mutants do not display many of the phenotypes thatmid2 $Delta$ cells do, sensitivity to caffeine is much greater in mid2 $Delta$ mtl1 $Delta$ double mutants than in either single mutant. Additionally,multicopy MTL1 can suppress $alpha$ -factor sensitivity of mid2 $Delta$ cells.Further research may reveal whether Mtl1p is required for respondingto different stresses than Mid2p, signals to a different pathwaythan Mid2p, or is important under physiological conditions differentfrom those used in thisstudy.

The effect of Mid2p on chitin synthesis depends ultimately on Chs3p, since overexpression of MID2 in chs3 $Delta$ mutants cannotconfer hypersensitivity to calcofluor white. We suggest two waysin which Mid2p might affect chitin synthesis. Mid2p might directlyinteract with the chitin synthase complex, increasing its activityduring stress periods. Alternatively, the activity of Chs3p mightbe regulated by a downstream target of Mid2p, such asMpk1p.

Cells face a demanding variety of stresses in their natural environments and must respond accordingly. Our results providenew insights into the processes by which yeast cells sense andrespond to threats against their physical integrity. Mid2p hasbeen identified as a putative sensor of cell wall state that isrequired for stimulation of activity in the PKC1-MPK1 MAP kinasepathway under conditions of cell wall stress. Currently, the physiologicalroles of most serine/threonine-rich membrane proteins are poorlydefined. An interesting possibility is that as a class, theseproteins act as sensors for a range of environmental stressesand mediate a variety of cellularprocesses.

	ACKNOWLEDGMENTS

We thank S. Nagahashi, M. Rajavel, T. Roemer, and P. A. Delley for helpful and stimulating discussion; R. C. Stewart and J.L. Brown for designing and performing the original ASK screen;S. Véronneau and T. Nguyen for sequencing; and S. Shahinian forcritical input on the manuscript. We also thank C. Bulawa forassistance with the chitin assay protocol and for providing thechs3 $Delta$ ::LEU2 plasmid, M. Snyder for providing multicopy MPK1-HA,BCK1, MKK1, and PKC1, and M. Rajavel for providing pRS316-BCK1-20,and pBM743-PKC1^R398A.

This work was supported by an NSERC operatinggrant.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Biology, McGill University, 1205 Dr. Penfield Ave., Montreal, Quebec,Canada H3A 1B1. Phone: 1-514-398-6439. Fax: 1-514-398-8051. E-mail:hbussey{at}monod.biol.mcgill.ca.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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