A Mep2-dependent Transcriptional Profile Links Permease Function to Gene Expression during Pseudohyphal Growth in Saccharomyces cerevisiae

Julian C. Rutherford^*^,, Gordon Chua^,, Timothy Hughes, Maria E. Cardenas^*, and Joseph Heitman^*^,||

Departments of *Molecular Genetics and Microbiology and ^||Medicine, Duke University Medical Center, Durham, NC, 27710; and Banting and Best Department of Medical Research, University of Toronto, Toronto, Ontario, Canada M5G 1L6

Submitted January 16, 2008; Revised April 3, 2008; Accepted April 14, 2008
Monitoring Editor: Carole Parent

ABSTRACT

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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The ammonium permease Mep2 is required for the induction ofpseudohyphal growth, a process in Saccharomyces cerevisiae thatoccurs in response to nutrient limitation. Mep2 has both a transportand a regulatory function, supporting models in which Mep2 actsas a sensor of ammonium availability. Potentially similar ammoniumpermease-dependent regulatory cascades operate in other fungi,and they may also function in animals via the homologous Rhproteins; however, little is known about the molecular mechanismsthat mediate ammonium sensing. We show that Mep2 is localizedto the cell surface during pseudohyphal growth, and it is requiredfor both filamentous and invasive growth. Analysis of site-directedMep2 mutants in residues lining the ammonia-conducting channelreveal separation of function alleles (transport and signalingdefective; transport-proficient/signaling defective), indicatingtransport is necessary but not sufficient to sense ammonia.Furthermore, Mep2 overexpression enhances differentiation undernormally repressive conditions and induces a transcriptionalprofile that is consistent with activation of the mitogen-activatedprotein (MAP) kinase pathway. This finding is supported by epistasisanalysis establishing that the known role of the MAP kinasepathway in pseudohyphal growth is linked to Mep2 function. Together,these data strengthen the model that Mep2-like proteins arenutrient sensing transceptors that govern cellular differentiation.

INTRODUCTION

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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Ammonia is an important nutrient for many microorganisms andplants, and in animals the catabolism of amino acids producesammonia as a by-product that must be excreted from the bodyto prevent its toxic accumulation. The Amt/Mep/Rh proteins forman evolutionary conserved family of permeases that mediate ammoniumtransport across cell membranes (reviewed in Andrade and Einsle,2007). Structural and biochemical studies of bacterial membersof this transporter family reveal that the Amt/Mep/Rh proteinsform a trimeric complex that facilitates passive diffusion ofammonia gas (Khademi et al., 2004; Zheng et al., 2004; Andradeet al., 2005; Ishikita and Knapp, 2007). Conserved key residuesrequired for ammonium translocation have been identified bysite-directed mutagenesis and provide evidence that the mechanismof ammonium transport is evolutionarily conserved (Javelle,et al., 2006; Marini et al., 2006).

Previous studies support the model that certain members of theAmt/Mep/Rh family play a direct role in fungal development asammonium receptors. The high-affinity ammonium permeases ofSaccharomyces cerevisiae, Candida albicans, and Ustilago maydisare required for filamentous growth in response to low ammoniumconditions (Lorenz and Heitman, 1998a; Smith et al., 2003; Biswasand Morschhäuser, 2005). The fission yeast Schizosaccharomycespombe undergoes haploid invasive growth during ammonium limitation,and this is dependent on the ammonium permease Amt1, and, toa lesser extent, its paralogue, Amt2 (Mitsuzawa, 2006). Haploidinvasive growth and mating by the basidiomycetous fungus Cryptococcusneoformans is induced by ammonium limitation and requires thehigh-affinity ammonium permease, Amt2 (Rutherford et al., 2008).However, the mechanisms that link ammonium transport to developmentare not understood. One hypothesis is that these permeases actas ammonium sensors, or transceptors, that regulate downstreameffector molecules (Lorenz and Heitman, 1998a). This mechanismcouples the physical process of nutrient transport to nutrientsensing and is distinct from a regulatory mechanism that respondsto the changing metabolized levels of a transported nutrient(Holsbeeks et al., 2004).

Current evidence supports the hypothesis that fungal high-affinitypermeases function as ammonium sensors. S. cerevisiae cellslacking the high-affinity permease Mep2 do not undergo pseudohyphalgrowth or exhibit any change in the activity of nitrogen metabolicenzymes (Lorenz and Heitman, 1998a). The C-terminal cytoplasmicdomain of the C. albicans Mep2 protein is essential for theinduction of filamentous growth but dispensable for transportactivity (Biswas and Morschhäuser, 2005). Therefore, theroles of Mep2 in ammonium transport and induction of filamentousgrowth are separable. Independently of its role in pseudohyphalgrowth, Mep2 acts as a transceptor in the cAMP-independent activationof the protein kinase A (PKA) pathway after ammonium additionto starved cells (Van Nuland et al., 2006). This rapid responseis not dependent on ammonium metabolism and can be induced bythe transport of the nonmetabolizable ammonium analogue methylamine,which establishes the paradigm of Mep2 as a transceptor. Itis not clear whether Mep2 has an equivalent transceptor functionduring pseudohyphal growth or whether it interacts with anyof the established signal transduction pathways that are essentialfor this process. Epistasis analysis is consistent with theRAS-cAMP being a possible downstream target of Mep2 (Lorenzand Heitman, 1998a); however, a direct interaction between Mep2and any signaling pathway has not been demonstrated in relationto pseudohyphal growth.

In this report, we present evidence that Mep2 forms a multimericcomplex localized to the cell membrane during pseudohyphal growth.Similar to S. pombe and C. neoformans, haploid S. cerevisiaecells undergo invasive growth in response to ammonium limitationand exhibit morphological changes analogous to those observedin pseudohyphal cells. We find that invasive growth requiresMep2, the Npr1 kinase, and elements of the PKA and mitogen-activatedprotein (MAP) kinase pathways. Furthermore, Mep2-dependent pseudohyphaland invasive growth requires two conserved histidine residueswithin the hydrophobic channel of Mep2 that have been predictedto be essential for ammonium translocation through the permease.Remarkably, constitutive Mep2 expression induces pseudohyphalgrowth on nitrogen-replete medium. Under these conditions, Mep2induces a haploid- and diploid-specific transcriptional profilethat includes genes known or predicted to be differentiallyregulated during pseudohyphal growth. Included within this groupof genes are those controlled by the MAP kinase-regulated transcriptionfactor Ste12. Consistent with a functional link between Mep2and Ste12, constitutive MEP2 overexpression restores pseudohyphalgrowth in cells lacking PKA pathway elements but not in cellslacking Ste12. In accord with this finding, overexpression ofSte12, or of the MADS box transcription factor Mcm1, restorespseudohyphal growth in cells lacking Mep2 under ammonium limitingconditions. Therefore, the established role of the MAP kinasepathway in pseudohyphal growth may, in part, be due to its roleas a downstream effector of the ammonium receptor function ofMep2. Collectively, these data further support a role for theMep2 family of permeases as sensors of ammonium availability.

EXPERIMENTAL PROCEDURES

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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Strains and Growth Media
The S. cerevisiae strains used in this study are listed in Table 1.S. cerevisiae cells were grown in synthetic minimal medium witheither 2% glucose, raffinose, or galactose as the carbon source.To induce pseudohyphal growth, cells were grown with 50 µMammonium sulfate as the nitrogen source. Otherwise, cells weregrown with the standard concentration of ammonium sulfate inyeast nitrogen base (5 g/l). Yeast cells were transformed asdescribed previously (Schiestl and Gietz, 1989).

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Table 1. Yeast strains used in this study

Plasmids
The plasmids used in this study are listed in Table 2. All manipulationsof DNA fragments and plasmids were carried out using standardprocedures and the Escherichia coli strain DH5 ${alpha}$ (Sambrook etal., 1989

). All DNA sequences encoding Mep2, epitope-taggedMep2, and mutant derivatives of these were generated and insertedinto the vector pRS316 (URA3) by homologous recombination (Maet al., 1987

). In each case, the MEP2 gene included its ownpromoter (1 kb), and, except in the Mep2-green fluorescent protein(GFP) fusion encoding plasmid and its mutant derivatives, theMEP2 terminator. The Mep2-GFP encoding sequences were amplifiedfrom the relevant strain of the yeast GFP clone collection toinclude the ADH1-terminating sequences (Huh et al., 2003

). AllMep2-FLAG fusions contain the N4Q mutation to prevent glycosylationof Mep2 (Marini and André, 2000

). MCM1, including itsown promoter and terminator, was inserted into the vector pRS426(URA3) by homologous recombination. All newly generated plasmidinserts were verified by DNA sequencing. The plasmid pYes2.1-Mep2,a kind gift from Mike Perlin (University of Louisville, Louisville,KY), was used to express MEP2 to high levels from the galactose-induciblepromoter (Smith et al., 2003

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Table 2. Plasmids used in this study

Membrane Preparation, Immunoprecipitation, and Western Immunoblotting
The preparation of cell membranes was carried out as describedpreviously (Galan et al., 1996

). Briefly, yeast cells in theexponential growth phase were harvested by centrifugation, washedin distilled water, and suspended in lysis buffer (0.1 M Tris-HCl,pH 7.5, 0.15 M NaCl, 5 mM EDTA) and a mixture of proteinaseinhibitors (cocktail IV; Calbiochem, San Diego, CA) and 0.5mM phenylmethylsulfonyl fluoride. Glass beads (0.45 µmin diameter) were added, and the cells were lysed by vigorousvortex mixing for 3 min. The resulting homogenate was dilutedthreefold with lysis buffer and centrifuged at 3000 rpm for3 min at 4°C. The plasma membrane-enriched fraction wascollected by centrifugation for 45 min at 12,000 rpm at 4°Cand then suspended in lysis buffer and trichloroacetic acid(10%). For Western analysis, the precipitates were neutralizedand dissolved in 20 µl of 1 M Tris base plus 80 µlof sample buffer (100 mM Tris-HCl, pH 6.8, 4 mM EDTA, 4% SDS,20% glycerol, and 0.02% bromphenol blue) containing 2% 2-mercaptoethanoland heated at 37°C for 15 min. For immunoprecipitation,2-mercaptoethanol was omitted from the samples, which were dilutedwith 0.6 ml of TNET buffer (50 mM Tris-HCl, pH 7.4, 150 mM NaCl,5 mM EDTA, and 1% Triton X-100) plus the proteinase inhibitorsdescribed. Western analysis was carried out using antibodies,either monoclonal ANTI-FLAG M2 (Sigma-Aldrich, St. Louis, MO),monoclonal anti-GFP (Roche Diagnostics, Indianapolis, IN), oranti-Pma1 (Cardenas et al., 1990

), and the relevant horseradishperoxidase-conjugated anti-IgG second antibody, followed byECL chemiluminescence (GE Healthcare, Chalfont St. Giles, UnitedKingdom). In the experiments using the npr1 ${Delta}$ strain, relativeabundance of Mep2-FLAG was quantified using Quantity One version4.6.2. (Bio-Rad, Hemel Hempstead, United Kingdom). Immunoprecipitationwas carried out as described previously (Harashima and Heitman,2002

) by using EZview Red ANTI-FLAG M2 affinity gel (Sigma-Aldrich).Native Mep2 was resolved by suspending membrane samples in 1xTris-glycine native sample buffer and separating on 6% NOVEXTris-glycine gels with Tris-glycine native running buffer (Invitrogen).

Protein Localization
Cells containing plasmid expressed Mep2-GFP were grown in syntheticminimal media and examined for protein localization under afluorescent microscope (Axioskop2 Plus; Carl Zeiss, Thornwood,NY).

Pseudohyphal and Invasive Growth
Cells undergoing pseudohyphal and invasive growth assays weregrown for 6 d on low-ammonium SLAD medium (50 µM ammoniumsulfate) and investigated as described previously (Harashimaet al., 2006).

Microarray Analysis
S288C haploid and ${sum}$ 1278b diploid wild-type strains containinga 2µ plasmid consisting of a GAL1/10-driven MEP2 genewere grown concurrently with isogenic strains containing anempty vector to mid-log phase in selective liquid medium plus2% raffinose. MEP2 gene expression was induced for 3 h in 2%galactose. Comparison of the S288C and ${sum}$ 1278b diploid wild-typestrains was carried out in synthetic complete medium with 2%glucose. RNA preparation, hybridization, image acquisition,and data processing for microarrays were performed as describedpreviously (Grigull et al., 2004). Each microarray experimentwas replicated in dye reverse.

RESULTS

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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Mep2 Forms a Multimeric Complex In Vivo
To facilitate studies of the role of Mep2 in the initiationof pseudohyphal growth, a plasmid was generated expressing Mep2fused to a C-terminal FLAG epitope (Mep2-N4Q-FLAG) from theMEP2 endogenous promoter. In this allele, the fourth asparagineresidue of Mep2 was substituted with glutamine, which preventsglycosylation but does not significantly influence the abilityof Mep2 to transport ammonium or induce pseudohyphal growth(Marini and André, 2000). The Mep2-N4Q-FLAG protein isfunctional; transformation of cells lacking endogenous Mep2with the Mep2-N4Q-FLAG plasmid restored pseudohyphal growthand growth under ammonium limiting conditions (Figure 5).

The bacterial Amt ammonium permeases form trimeric membraneprotein complexes (Conroy et al., 2004; Zheng et al., 2004).Potential multimeric forms of S. cerevisiae Mep2 have also beendetected following SDS electrophoresis (Marini and André,2000). We observed that Mep2-N4Q-FLAG migrated at a size consistentwith that of a trimeric complex under native electrophoresisconditions (Figure 1A). To confirm that Mep2 monomers interactin vivo, Mep2-N4Q-FLAG was coexpressed with Mep2 fused to greenfluorescent protein. Immunoprecipitation of Mep2-N4Q-FLAG resultedin coimmunoprecipitation of Mep2-GFP, confirming the two epitope-taggedMep2 derivatives interact (Figure 1B).

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Figure 1. Mep2 forms a multimeric complex and is membrane localized in cells undergoing pseudohyphal growth. (A) Membrane fractions from haploid mep2 ${Delta}$ cells containing a plasmid expressing Mep-N4Q-FLAG or a control vector that had been grown in low-ammonium medium (SLAD) were resolved under native conditions, and the FLAG epitope was detected by Western analysis. (B) Mep2-FLAG was immunoprecipitated from control cells and cells expressing an Mep2-GFP fusion protein that had been grown in SLAD medium. Diploid MLY108a/ ${alpha}$ cells (mep2 ${Delta}$ /mep2 ${Delta}$ ) expressing Mep2-GFP were grown on low-ammonium medium (SLAD) plates for 6 d. The Mep2 fusion protein was localized by direct epifluorescence microscopy in cells at the center of the colony (C), within cells that had formed pseudohyphae (D), and at the edge of the colony (E).

Mep2 Localization on the Cell Membrane Requires the Exocyst Complex
Diploid S. cerevisiae cells undergo polarized growth duringpseudohyphal growth that is, in some respects, similar to polarizedgrowth of haploid cells during mating. In response to matingpheromone, cells develop a mating projection, or shmoo, thatgrows toward the mating partner to enable cell–cell contact(Jackson and Hartwell, 1990

). Proteins important for polarizedgrowth during mating are localized to the shmoo (Bagnat andSimons, 2002

). Because pseudohyphal growth involves polarizedgrowth, the extent to which Mep2 is localized to the growingtip of a filament during pseudohyphal growth was examined.

Cells expressing the Mep2-GFP fusion protein were grown on solidagar under pseudohyphal conditions. Within the center of thecolony, cells were oval in shape (Figure 1C), whereas cellsat the colony edge exhibited the elongated morphology characteristicof pseudohyphal growth (Figure 1E). In both cases, Mep2-GFPwas expressed and localized throughout the cell membrane. Inaddition, Mep2-GFP was localized throughout the cell membraneof cells that had grown away from the center of the colony (Figure 1D).Unlike the signaling components important for mating, Mep2-GFPdoes not exhibit any preferential localization to any discretearea in the cell membrane or at the growing tip of the cellduring pseudohyphal growth.

We next examined whether Mep2 might be transiently localizedduring its initial expression after the transition from high-to low-ammonium media (Marini et al., 1997) (Figure 2A). Underthese conditions, Mep2-GFP localizes to the entire cell membranewithin 2 h (Figure 2A). In budding cells, however, Mep2-GFPis initially (within 30 min) localized to small daughter cells,and in larger daughter cells, to the bud neck (Figure 2B). Longerincubation periods resulted in Mep2-GFP becoming gradually localizedthroughout more of the cell membrane, until Mep2-GFP coveredthe entire cell membrane by 2 h. The polarized transport ofvesicles to the mother-bud neck or the bud tip is dependenton the actin cytoskeleton and the Myo2 myosin motor protein(Pruyne et al., 1998; Karpova et al., 2000). An alternativemechanism to ensure daughter-cell–specific protein expressionis myosin-dependent mRNA transport from mother to daughter cell(Takizawa et al., 1997). To distinguish between these two mechanisms,the localization of Mep2-GFP was analyzed in cells lacking theShe2 protein and cells that contain the temperature-sensitivesec6-4 allele. She2 is an RNA binding protein essential fordaughter-cell–specific mRNA transport (Long et al., 2000),whereas Sec6 is an integral component of the exocyst complexthat mediates polarized targeting of secretory vesicles to sitesof active exocytosis (TerBush et al., 1996; TerBush and Novick,1995). Mep2-GFP exhibited a wild-type pattern of localizationin a she2 ${Delta}$ mutant strain; however, this pattern of localizationwas absent in sec6-4 cells grown at the restrictive temperature(Figure 2C). Thus, Mep2 distribution on the cell membrane involvesthe exocyst complex.

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Figure 2. Mep2 is localized to the cell membrane via the exocyst complex. Direct epifluorescence microscopy of cells expressing Mep2-GFP was performed with wild-type cells that were grown in high-ammonium medium, pelleted, washed and then grown in high- or low (50 µM)-ammonium sulfate medium for 2 h (A), wild-type and she2 ${Delta}$ cells that were transferred from growth in high-ammonium to low-ammonium medium and grown for 20 min (B), and sec6-4 cells that were grown at the permissive and nonpermissive temperature in low-ammonium medium (C).

Mep2 Is Correctly Localized in Mutants Lacking Npr1 and Ure2 and Is Required for Pseudohyphal Growth on Nitrogen Sources Other Than Ammonium
To further analyze the link between Mep2 localization and pseudohyphalsignaling, the localization of Mep2 was analyzed in mutantslacking Ure2 and Npr1 that do not form pseudohyphae (Lorenzand Heitman, 1998a

). Ure2 is a regulatory protein that bindsto the Gln3 transcription factor and thereby represses transcriptionof nitrogen catabolite-regulated genes (Blinder et al., 1996

).The Npr1 kinase regulates sorting and localization of the generalamino acid permease Gap1 (De Craene et al., 2001

). We observedthat Mep2-GFP is normally localized to the plasma membrane inboth ure2 and npr1 mutant strains when grown under high andlow levels of ammonium (Figure 3A). Therefore, the loss of eitherUre2 or Npr1 results in the derepression of MEP2 gene expression,and the lack of pseudohyphal growth of these mutants cannotbe attributed to the lack of Mep2 localization to the cell membrane.In addition, the GFP fluorescence observed in npr1 ${Delta}$ cells expressingMep2-GFP was greater than in wild-type cells, and Mep2-N4Q-FLAGexpression was also $~$ 30% higher in these cells as detected byWestern blotting (Figure 3B).

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Figure 3. Mep2 is correctly localized in mutants lacking Npr1 and Ure2, and it is required for pseudohyphal growth on nitrogen sources other than ammonium. (A) Epifluorescence microscopy of ure2 ${Delta}$ and npr1 ${Delta}$ cells containing Mep2-GFP that had been grown in high-ammonium medium, pelleted, washed, and then grown in high- or low-ammonium sulfate medium for 2 h. (B) The levels of Mep2-N4Q-FLAG within the membrane fraction of wild-type and npr1 ${Delta}$ cells grown in low (50 µM) ammonium sulfate medium were quantified by Western analysis. Levels of the plasma membrane H⁺-ATPase Pma1 served as a loading control. Cells not expressing Mep2-N4Q-FLAG served as a negative control. (C) Diploid wild-type and mep2 ${Delta}$ cells containing either a control plasmid or low copy plasmid expressing MEP2 from its own promoter were grown with either glutamine (100 µM) or proline (100 µM) as the sole nitrogen source for 6 d.

Our previous studies reported that Mep2 induced pseudohyphalgrowth in response to growth on ammonium alone and not whencells were grown on alternative sources of nitrogen (Lorenzand Heitman, 1998a

). This suggested that ammonium transportthrough Mep2 is required for the initiation of pseudohyphalgrowth. Conversely, studies in C. albicans have found that Mep2is required for the induction of filamentous growth in responseto nitrogen sources other than ammonium (Biswas and Morschhäuser,2005

). We reanalyzed the growth of diploid mep2 ${Delta}$ mutants on agarmedia containing either glutamine or proline as a nitrogen source.Under these conditions, wild-type cells produced pseudohyphae,whereas the diploid mep2 ${Delta}$ mutant strain did not (see Discussion).Expression of the MEP2 gene in the diploid mep2 ${Delta}$ strain froma centromeric plasmid restored the ability of the mutant strainto undergo pseudohyphal growth (Figure 3C). Therefore, consistentwith what has been described in C. albicans, Mep2 is requiredfor the initiation of pseudohyphal growth on nitrogen sourcesother than ammonium.

Mep2 Induces Haploid Invasive Growth in Response to Ammonium Limiting Conditions
Dimorphic growth by S. cerevisiae in response to ammonium limitationhas traditionally been investigated using diploid cells. HaploidS. cerevisiae cells undergo invasive growth when grown in richmedium or in response to fusel alcohols (Roberts and Fink, 1994;Lorenz et al., 2000b), but their response to ammonium levelshas not been extensively studied. The finding that the basidiomycetousfungus C. neoformans and the fission yeast S. pombe undergohaploid invasive growth in response to ammonium limitation suggeststhat this pattern of growth may be conserved within fungi (Mitsuzawa,2006; Rutherford et al., 2008). Growth of wild-type cells onlow-ammonium media resulted in invasive growth and was dependenton the presence of Mep2 but not on the presence of the Mep1or Mep3 ammonium permeases (Figure 4A). Complementation of themep2 ${Delta}$ mutation with MEP2 regulated by its native promoter froma low copy number centromeric plasmid restored invasive growth(Figure 5D). Microscopic examination of the areas of invasivegrowth revealed formation of chains of elongated cells (Figure 4B).Consistent with the morphology of cells undergoing pseudohyphalgrowth, some haploid cells exhibited an elongated cell shapewhen grown under ammonium Limiting conditions (Figure 4C).

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Figure 4. Mep2 is required for haploid invasive growth under nitrogen limiting conditions. (A) Haploid wild-type and mutant cells containing a control plasmid were spotted onto low ammonium sulfate (50 µM) solid medium lacking uracil and grown for 6 d. Panels show cells before (left) and after (right) cells have been washed off the surface of the plate to reveal the extent of invasive growth. (B) The morphology of invading cells was visualized with a Zeiss Axiophot 2 Plus fluorescence microscope revealing, in some areas, filaments of pseudohyphal-like chains of cells. (C) Wild-type cells expressing Mep2-GFP that had undergone haploid invasive growth exhibit either morphology consistent with cell cycle arrest or pseudohyphal-like elongation.

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Figure 5. Mep2 transport function is linked to pseudohyphal differentiation. (A) The levels of Mep2-N4Q-FLAG and derived mutants within the membrane fraction of cells grown in low- (50 µM) ammonium sulfate medium were quantified by Western analysis. Levels of the plasma membrane H⁺-ATPase Pma1 served as a loading control. (B) Localization of Mep2 was visualized using diploid mep2 ${Delta}$ /mep2 ${Delta}$ cells that contained plasmids expressing wild-type and mutant GFP-tagged Mep2 that had been grown in low-ammonium sulfate (50 µM) medium for 2 h. (C) Pseudohyphal growth was assayed using diploid mep2 ${Delta}$ /mep2 ${Delta}$ cells that contained plasmids expressing wild-type and mutant Mep2 that were grown on low ammonium sulfate (50 µM) medium for 6 d. (D) Haploid mep2 ${Delta}$ mutant cells containing relevant plasmids were spotted onto low-ammonium sulfate (50 µM) medium lacking uracil and grown for 6 d. Panels show cells before (left) and after (right) cells have been washed off the surface of the medium to reveal the extent of invasive growth. (E) Wild-type and mutant cells containing the relevant plasmids were grown overnight in complete medium (CMD-ura), washed, and serially diluted onto medium containing high or low (50 µM) levels of ammonium sulfate.

The extent of invasive growth under low ammonium conditionswas then analyzed in mutant strains lacking genes involved indiploid pseudohyphal growth. Tpk1, Tpk2, and Tpk3 are the PKAcatalytic subunits, and Ste12 and Tec1 are transcription factorsregulated by the MAP kinase pathway. Mutants lacking Npr1, Tpk2,Ste12, or Tec1 exhibited reduced invasive growth under ammoniumlimiting conditions. Interestingly, a tpk1 tpk3 double mutantexhibited increased invasive growth under the same conditions.The link between ammonium-responsive invasive growth is consistentwith the finding that cAMP can restore invasive growth in aS. pombe mutant that lacks amt1 ${Delta}$ (Mitsuzawa, 2006

). The Gpr1G protein-coupled receptor and the G ${alpha}$ subunit Gpa2 activate thecAMP–PKA pathway and are required for pseudohyphal growth.Ras2 is a guanosine triphosphate-binding protein that activatesboth the cAMP–PKA and the MAP kinase pathways (reviewedin Pan et al., 2000

). Mutants lacking Gpr1, Gpa2, Ras1, or Ras2exhibited invasive growth equivalent to wild-type haploid cellsunder ammonium limiting conditions (Figure 4A).

Ammonium Transport Is Linked to Pseudohyphal and Invasive Growth
Transceptors bind and/or transport nutrients as part of theirsensing mechanism. If Mep2 functions as a transceptor, thenmutations that affect transport would be predicted to play arole in pseudohyphal differentiation. In contrast, if Mep2 signalsin the absence of its ligand, then mutations that prevent Mep2from binding or transporting ammonia/ammonium might mimic theligand free receptor state and activate pseudohyphal growth.These opposing models were tested by identifying and mutatingresidues involved in Mep2 transport function. An aspartate residuein AmtB that is conserved throughout the Mep/Amt/Rh family isrequired for ammonium transport (Javelle et al., 2004). In addition,two conserved histidine residues that line the hydrophobic channelof the ammonium permease family are essential for ammonium transportby AmtB (Javelle et al., 2006). These residues are equivalentto D186, H194, and H348 in Mep2 of S. cerevisiae.

Individual alanine substitutions of residues D186, H194, andH348 were generated in the Mep2-N4Q-FLAG and Mep2-GFP fusionproteins. The H194A and H348A Mep2 proteins were stably expressedbased on Western blot analysis, and they were also localizedto the surface of the plasma membrane in the context of a GFPfusion protein (Figure 5, A and B, and Table 3). In contrast,the Mep2^D186A mutant protein was unstable, and instead of plasmamembrane localization, it seemed to be localized to endogenousmembranes, consistent with a recent report (Marini et al., 2006).Cells expressing the Mep2^H194A and Mep2^H348A proteins did notundergo pseudohyphal growth in response to low ammonium, eventhough both proteins were stably expressed and correctly localized(Figure 5C) (Table 3). Under ammonium limiting conditions, theMep2^H194A protein did not support growth of a strain lackingthe three Mep permeases of S. cerevisiae, whereas cells expressingMep2^H348A grew to the same extent as wild-type cells. Thus,neither the transport-defective H194A mutant nor the transport-proficientH348A mutant support pseudohyphal differentiation, indicatingthat transport is not sufficient for signaling, and that signalingrequires functions in addition to transport (Figure 5E and Table 3).

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Table 3. Summary of phenotypes of diploid (pseudohyphal growth, growth on low ammonium) and haploid (invasive growth) mep1,2,3 ${Delta}$ cells expressing wild-type or mutant Mep2 permeases (see Fig. 5)

In addition, the ability of these Mep2 mutants to support haploidinvasive growth under ammonium limiting conditions was assessed.Consistent with the analysis of diploid pseudohyphal growth,haploid cells expressing the Mep2^H194A and Mep2^H348A proteinsfailed to undergo invasive growth in response to low ammonium.Conversely, expression of a Mep2^T288A mutant protein that exhibitsdefects in pseudohyphal growth supported haploid invasive growthunder the same conditions (Figure 5D). The T288 residue of Mep2is a potential PKA phosphorylation site that may link the PKAsignaling cascade to Mep2 signaling activities under certainconditions (Smith et al., 2003

Mep2 Levels Correlate with Extent of Pseudohyphal Growth
Analysis in C. albicans has established that the ability ofMep2 to induce pseudohyphal growth is dependent on its expressionlevels (Biswas and Morschhäuser, 2005). In accord withthese studies, we have found that in S. cerevisiae, Mep2 expressionlevels are important for its regulatory function. MEP2 expressionfrom a high copy plasmid resulted in more robust pseudohyphalgrowth compared with expression from a low copy number centromericplasmid (Figure 6A). Similarly, growth of cells on galactoseas opposed to glucose resulted in a significant reduction inthe level of pseudohyphal growth, and this was correlated withreduced Mep2-N4Q-FLAG expression (Figure 6, B and C).

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Figure 6. Mep2 function correlates with its expression levels. Pseudohyphal growth was assayed after growth for 6 d by using diploid mep2 ${Delta}$ /mep2 ${Delta}$ cells that contained either low or high copy plasmids expressing MEP2 (A); wild-type cells grown with either glucose or galactose as the carbon source (B), wild-type cells grown with or without galactose-regulated MEP2 were grown on synthetic medium with galactose as the carbon source and high levels of ammonium (D); and diploid mep2 ${Delta}$ /mep2 ${Delta}$ cells or diploid mep1,2,3 ${Delta}$ /mep1,2,3 ${Delta}$ cells expressing the Mep2^T288A variant (E). The levels of Mep2-FLAG within wild-type cells grown on different carbon sources and low (50 µM)-ammonium sulfate (C) or Mep2^T288A-FLAG within diploid mep2 ${Delta}$ /mep2 ${Delta}$ cells and diploid mep1,2,3 ${Delta}$ /mep1,2,3 ${Delta}$ cells grown in low (50 µM)-ammonium sulfate medium (F) were quantified by Western analysis. Levels of the plasma membrane H⁺-ATPase Pma1 served as a loading control.

These findings, together with studies on C. albicans Mep2, suggestedthat uncoupling MEP2 expression from nitrogen catabolite repressionmight induce pseudohyphal growth under noninducing conditions.To test this hypothesis, a diploid wild-type strain was transformedwith a plasmid expressing MEP2 from a galactose-inducible promoter.Limited, but distinct, pseudohyphae were observed in cells grownin galactose nitrogen-replete conditions, whereas no pseudohyphaewere observed in control cells (Figure 6D). This establishesthat ammonium limitation per se is not required for the inductionof the ammonium-responsive dimorphic switch in S. cerevisiae.

The influence of Mep2 expression levels suggested an explanationfor an intriguing observation with the Mep2^T288A mutant protein.Mep2^T288A lacks a putative PKA phosphorylation site and doesnot induce pseudohyphal growth in mep2 mutant cells (Smith etal., 2003) (Figure 6E). However, when the Mep2^T288A proteinis expressed in cells lacking all three ammonium permeases pseudohyphalgrowth is induced at the wild-type level (Figure 6E). One potentialexplanation for this phenotype is that cells lacking all threeammonium permeases are more starved for nitrogen and thereforeinduce the expression of Mep2-T288A to a higher level. Thisincreased expression could compensate for the reduced activityof the Mep2^T288A protein. When levels of Mep2-FLAG and Mep2^T288A-FLAGwere analyzed in mep2 versus mep1, -2, and -3 mutant cells,both Mep2 proteins were more highly expressed in the mep1,2,3 ${Delta}$ strain (Figure 6F), supporting the interpretation that increasedlevels of the signaling compromised T288A mutant enable signalingfunction.

MEP2 Overexpression Induces Transcription of Genes Implicated in Filamentous Growth and Known Targets of Ste12
One hypothesis that is consistent with the role of Mep2 as asensor of ammonium availability is that it interacts with asignal transduction pathway that activates downstream effectorsthat control gene expression. To test this hypothesis, the transcriptionalprofile of S288C haploid cells expressing the galactose-inducibleMEP2 allele was assessed during growth in ammonium-rich medium.Initially we determined whether the polymorphisms in the ${sum}$ 1278bgenome would affect hybridizations on our yeast open readingframe (ORF) microarrays by comparing global gene expressionbetween S288C and ${sum}$ 1278b diploid wild-type strains. Only 24 and43 genes exhibited a greater than twofold increase and decreasein expression, respectively, between the two genetic backgrounds.Among the differentially regulated genes, the only functionalenrichment observed was for glycolysis genes (CDC19, TDH1–3)that were down-regulated greater than twofold in ${sum}$ 1278b (GeneOntology: 0006096; p = 2.7 x 10^–6). These results indicatethat the polymorphisms in the ${sum}$ 1278b strains have minimal effectson hybridization of our yeast ORF microarrays.

The high expression of MEP2 under ammonium-rich conditions comparedwith cells with normal endogenous MEP2 expression levels resultedin induction of 219 genes that exhibited a twofold or greaterincrease in expression or more (Supplemental Table 1). Theseinclude genes involved in the cell cycle (e.g., CLB1, STB1,FAR3, SIC1, and WHI5), cell wall maintenance (e.g., MOB2, SKG1,and EXG1) and signal transduction (e.g., CDC25, SDC25, STE12,RGA1, and RTS1). The most striking feature of the MEP2-inducedprofile in haploid cells was the induction of 35 transposableelement genes, consisting mainly of members of the Ty1 familyof retrotransposons (Supplemental Table 1). These mobile geneticelements replicate through an RNA intermediate and consist oftwo direct long terminal repeats that flank the TYA and TYBopen reading frames. The promoter of Ty1 elements contains bindingsites for multiple transcription factors. Important for thisstudy, the Ty1 promoter contains a filamentation response elementwithin its promoter that responds to nitrogen limitation viathe combinatorial activity of Ste12 and Tec1 (Conte et al.,1998; Morillon et al., 2002). Interestingly, in addition tothe Ty1 genes, other genes where Ste12 is known to bind to theirpromoters were also induced in response to constitutive MEP2expression. These genes include AGA1, SCW11, HXK1, GAP1, PRY3,and PRM6 (Zeitlinger et al., 2003; Borneman et al., 2006, 2007).This profile, when considered in conjunction with those datathat support a signaling role for Mep2, suggests that the Ste12transcription factor is a downstream effector of Mep2 function.

The identification of a Mep2-dependent transcriptional profilein haploid cells that included genes involved in pseudohyphalgrowth prompted similar experiments in pseudohyphal-competent ${Sigma}$ 1278b diploid yeast cells. The transcriptional profile of wild-typediploid cells was compared with diploid cells expressing MEP2.Remarkably, the profile of genes exhibiting twofold or greaterdifferential expression was the reciprocal of that identifiedin the haploid experiment. Therefore, in most cases, genes thatwere induced by the constitutive expression of MEP2 in haploidcells were repressed in diploid cells. Conversely, genes inducedin diploid cells containing the GAL-MEP2 plasmid were repressedin haploid cells (Figure 7).

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Figure 7. Transcriptional profiles of MEP2 overexpression in a S288C haploid (middle) and ${sum}$ 1278b diploid (right) wild-type strain. Genes that are differentially regulated greater than twofold in at least one of the microarray experiments are shown in the clustergram. The control experiment (left) compares S288C and ${sum}$ 1278b diploid wild-type strains to determine whether hybridizations differ between the two genetic backgrounds on the yeast ORF microarrays. Only 77 genes were differentially regulated greater than twofold between the two genetic backgrounds. The bottom bar indicates MEP2 expression in each microarray experiment.

The genes induced in diploid cells by MEP2 expression are involvedin similar cellular processes as those identified in haploidcells, although the same individual genes are rarely inducedin both experiments. Therefore, genes involved in cell wallmaintenance, the cell cycle, and mitochondrial function wereinduced in response to MEP2 overexpression in diploid cells(Supplemental Table 2). In contrast to the haploid profile,however, the transposable element genes were not collectivelyinduced. This observation may be due in part to lower transcriptionrates of Ty1 elements reported in diploid cells compared withhaploid cells (Morillon et al., 2002

). In addition, a largenumber of genes involved in glucose, methionine, and sulfurmetabolism were uniquely induced in diploid cells. Several geneslinked to dimorphic growth were induced, including BEM4 (budemergence), CBK1 (protein kinase), and with just under a twofoldinduction, GIC2 (bud emergence), FLO11 (cell surface glycoprotein),and DIA1 (invasive growth). Interestingly, FLO11 (MUC1), whichis essential for pseudohyphal growth, is induced to a higherlevel in diploid cells (1.8-fold increase) than in haploid cells(1.3-fold increase) in response to Mep2 overexpression. Similarto the Mep2 induced profile in haploid cells, many genes thatare targets of Ste12 were induced in diploid cells. These genesinclude GIC2, CDC19, SCH9, FLO11, CWP2, and AGA1 (Zeitlingeret al., 2003

; Borneman et al., 2006

, 2007

The Mep2 transcriptional profile also included genes that havea role in cell signaling in addition to the MAPK–Ste12pathway. TSC11 encodes a member of the TORC2 complex. Consistentwith the involvement of Tor signaling, the gene encoding theTsc11 subunit of the TORC2, which is proposed to regulate actincytoskeleton polarization and cell integrity, is induced byMep2 expression in diploid cells (Barbet et al., 1996; Schmidtet al., 1996; Schmidt et al., 1997; Cutler et al., 2001; Wedamanet al., 2003). SCH9 encodes a protein kinase recently shownto be a major target of TORC1 for regulating ribosome biogenesis,translation initiation, and entry into G0 phase, was similarlyinduced (Urban et al., 2007). The product of RTS3 is predictedto form part of the protein phosphatase type 2A complex (PP2A)and physically interacts with catalytic and regulatory subunitsof protein phosphatase 2A and the PP2A-related phosphatase Sit4–Sap185complex (Ho et al., 2002; Samanta and Liang, 2003; Gavin etal., 2006). Interestingly, RTS3 is one of the few genes to beinduced in both haploid and diploid cells overexpressing Mep2.In addition, the functional homologue of RTS3, RTS1, and theregulator of PP2A activity, RRD2, were induced by Mep2 expressionin haploid and diploid cells, respectively. Rrd2 interacts withthe Tap42-PP2Ac complex that is required for a Tor-dependentfilamentous signaling pathway (Cutler et al., 2001; Zheng andJiang, 2005). This suggests that Mep2 expression under nitrogen-sufficientconditions results in the differential regulation of PP2A activity,which might explain the number of identified genes that areinvolved in both the cell cycle and cell wall integrity andcAMP pathways (Cutler et al., 2001).

Constitutive Mep2 Expression Restores Pseudohyphal Growth in Mutants Lacking cAMP–PKA Signaling but Not the MAP Kinase-regulated Transcription Factor Ste12
The established role of the MAP kinase pathway in pseudohyphalgrowth suggested that Mep2-dependent induction of Ty1 elementsresulted from activity of the Ste12/Tec1 transcription factors.The absence of induction of the equivalent elements in diploidcells could be the result of loss of Ste12/Tec1 activity indiploid cells or to a cell-type–specific regulatory mechanism.The pleiotropic transcriptional regulator Mcm1 is a MADS boxprotein involved in cell cycle progression, arginine metabolism,cell wall maintenance, cell type determination, pheromone response,and mating (Sengupta and Cochran, 1990; Lydall et al., 1991;Messenguy and Dubois, 1993). The transcriptional activationof a-specific genes results from dimerization of Ste12 and Mcm1at target promoters (Sengupta and Cochran, 1990; Mueller andNordheim, 1991). Conversely, Mat ${alpha}$ 2–Mcm1 complexes repressthe expression of a-specific genes in diploid cells (Keleheret al., 1989). In addition, Mcm1 regulates Ty1 expression andbinds to regulatory sequences independent of Ste12, unlike thepheromone-induced genes that are regulated by a Mcm1–Ste12heterodimer (Errede, 1993). The cell-type–specific responseto Mep2 expression observed in the microarray studies and theidentification of genes regulated by Ste12 and the cell cyclesuggested that Ste12 and/or Mcm1 could be downstream effectorsof Mep2.

To examine this hypothesis, the ability of the GAL-MEP2 alleleto induce pseudohyphal growth in mutants lacking componentsof the PKA pathway or Ste12 was analyzed. MEP2 overexpressionrestored pseudohyphal growth in mutants lacking Tpk2, Gpa2,Gpr1, or Ras2 (Figure 8A). However, MEP2 overexpression didnot restore pseudohyphal growth in a strain lacking Ste12 (Figure 8A).As a control, complementation of the ste12 ${Delta}$ mutant with a plasmidexpressing STE12 or a hyperactive RAS2 allele restored wild-typepseudohyphal growth in the ste12 ${Delta}$ strain (Figure 8B). Analogousexperiments were conducted to determine whether activation ofeither the PKA or the MAP kinase pathway restores pseudohyphalgrowth in a mep2 ${Delta}$ mutant. Expression of alleles that constitutivelyactivate the PKA pathway, the MAP kinase pathway, as well asoverexpression of Ste12, all restored pseudohyphal growth ofthe mep2 ${Delta}$ mutant (Figure 8C). Together, these experiments areconsistent with Mep2 and Ste12 acting in either the same pathwayduring pseudohyphal growth or in parallel interdependent pathways.Overexpression of the Ste12 interacting transcription factorMcm1 also restored pseudohyphal growth in the mep2 ${Delta}$ strain, providingfurther functional evidence linking Mep2 and the MAP kinasepathway (Figure 8C).

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Figure 8. Epistasis analysis provides evidence that Mep2 and Ste12 are functionally related. After growth on galactose low-ammonium sulfate (50 µM) plates for 6 d at 30°C, pseudohyphal growth was assayed in diploid mutants lacking Tpk2, Gpa2, Gpr1, Ras2 and Ste12 that expressed MEP2 from a galactose-inducible promoter (A) and diploid ste12 ${Delta}$ /ste12 ${Delta}$ cells that contained either a galactose-inducible STE12 gene or the RAS2^Val19 allele (B). (C) Cells lacking Mep2 and containing plasmids expressing MCM1, the RAS2^Val19 allele, the STE11-4 allele, GAL-MEP2, or GAL-STE12.

	DISCUSSION

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

Nitrogen availability regulates the initiation of diploid filamentousgrowth, haploid invasive growth, and mating in different modelfungi. These developmental processes occur when ammonium islimiting, and they are dependent on members of the AmtB/Mep/Rhfamily of ammonium permeases. Here, we present evidence thatsupports the hypothesis that Mep2 functions as an ammonium sensor;importantly, we document that the transport activity of Mep2is linked to both differentiation and the control of gene expression.

The localization and oligomerization state of Mep2 are consistentwith other members of the AmtB/Mep2/Rh family of transporters.We have demonstrated that Mep2 monomers interact to form a trimericcomplex. Our data doe not exclude the possibility that Mep2could form heterotrimeric complexes with the nonpseudohyphal-inducingMep1 and Mep3 ammonium permeases. When initially expressed,Mep2 is localized to the growing bud or the bud neck, a processthat is dependent on the exocyst complex. Thereafter, Mep2 islocalized throughout the plasma membrane.

A central question relating to Mep2 function is the extent towhich ammonium binding, transport, or both are necessary toinduce pseudohyphal growth. In previous studies, it was reportedthat Mep2-dependent pseudohyphal growth occurs only with limitingammonium as a nitrogen source (Lorenz and Heitman, 1998a). Thissuggested that ammonium binding/transport via Mep2 is importantfor its regulatory function. Contrary to this, studies withC. albicans found that Mep2-dependent pseudohyphal growth occurswhen this yeast is grown on a variety of nitrogen sources (Biswasand Morschhäuser, 2005). Similarly we find that S. cerevisiaealso undergoes Mep2-dependent pseudohyphal growth in responseto growth on glutamate and proline. In our previous S. cerevisiaestudies, growth and filamentation assays were conducted on nobleagar or agarose (Lorenz and Heitman, 1998a). Under these conditions,pseudohyphal growth is more limited, and even more so with glutamineor proline as the nitrogen source in which there was no clearobligate role for Mep2 in pseudohyphal growth. When growth assaysare conducted on standard SLAD medium containing agar (includingcontaminating minor nitrogen sources), more robust pseudohyphalgrowth occurs and under these conditions Mep2 plays a clearlydemonstrable role in promoting pseudohyphal differentiation,even with glutamine and proline as nitrogen source. During thecourse of this work, Marini and colleagues published similarfindings implicating Mep2 in physiological roles during growthon nitrogen sources other than ammonium (Boeckstaens et al.,2007). They found that cells leak ammonium when grown on a varietyof nitrogen sources, and they advanced the hypothesis that onerole for Mep2 is to reimport ammonium that exits the cell duringgrowth on alternative nitrogen sources. In the context of thismodel, pseudohyphal growth on nitrogen sources such as glutamineand proline still requires the ability of Mep2 to transportand sense ammonia, in this case involving ammonia that exitsthe cell from internal sources.

Mutational analysis of Mep2 supports the hypothesis that ammoniumtransport through Mep2 is required for the induction of pseudohyphalgrowth. A Mep2^D186E variant that is correctly expressed andlocalized to the plasma membrane fails to transport ammoniumand does not induce pseudohyphal growth (Marini et al., 2006).Our present study establishes that residues H194 and H348, whichare conserved residues lining the pore of Mep2, are importantin the initiation of pseudohyphal growth. The conservation ofthese residues throughout the AmtB/Mep/Rh family, and theirposition within the hydrophobic pore, suggest that their functionis to bind ammonium as it translocates through the protein (Khademiet al., 2004). The importance of these residues for ammoniumtransport has been underscored by mutational analysis of theequivalent residues in AmtB from E. coli (Javelle et al., 2006).In S. cerevisiae, the Mep2^H194A and Mep2^H348A variants are stablyexpressed and localized to the cell membrane. The Mep2^H194Aprotein has a significantly reduced ability to transport ammoniumand does not induce pseudohyphal growth. The Mep2^H348A proteintransports ammonium but does not signal pseudohyphal growth.Somewhat unexpectedly, the ability of Mep2^H348A to support growthon low ammonium contrasts to the lack of transport activityresulting from the equivalent mutation in AmtB from E. coli.Together, these data suggest ammonium translocation throughMep2 is required to initiate pseudohyphal growth and that mutationof residues D186 and H194 prevents this signaling process. Thephenotype of the Mep2^H348A protein suggests that the bindingof ammonium ions to this residue could cause a conformationalchange in Mep2 that initiates pseudohyphal growth. Consistentwith this, a Mep2 mutant that is hyperactive for both ammoniumtransport and pseudohyphal growth contains a mutation in theadjacent residue, G349 (Boeckstaens et al., 2007).

The requirement for Mep2 transport activity may explain theinability of mutants lacking the Npr1 kinase to undergo pseudohyphalgrowth (Lorenz and Heitman, 1998a). Our data establish thatMep2 is clearly localized to the plasma membrane and highlyexpressed in mutants lacking the Npr1 kinase. However, in theabsence of Npr1, Mep2 does not transport ammonium (Boeckstaenset al., 2007). The Mep2^G349C variant has increased transportactivity and restores pseudohyphal growth in an npr1 ${Delta}$ strain(Boeckstaens et al., 2007). This is consistent with Npr1 beingrequired to activate Mep2-dependent ammonium transport, butnot expression or localization, which then enables a Mep2-dependentinduction of pseudohyphal growth. Interestingly, Mep2 is alsocorrectly localized in a mutant lacking the Ure2 transcriptionalrepressor. Further studies will be required to determine whetherthe inability of a ure2 ${Delta}$ mutant to initiate dimorphic growthis a result of a loss of Mep2 transport function or some otherregulatory process in which constitutive induction of the nitrogencatabolite repression response blocks pseudohyphal growth.

We have established a correlation between the level of Mep2expression and the degree of pseudohyphal growth in S. cerevisiae.Increased expression of Mep2 results in greater pseudohyphalgrowth and a modest increase in Mep2 expression can compensatefor the pseudohyphal growth induction defect in cells expressingthe Mep2^T288A protein. In C. albicans, high expression levelsof Mep2 are required for its ability to induce hyphal growth(Biswas and Morschhäuser, 2005). It is interesting to notethat in each yeast that undergoes ammonium-dependent development,the relevant inducing permease is the most highly expressedof the family of ammonium permeases (Marini et al., 1997; Smithet al., 2003; Biswas and Morschhäuser, 2005; Rutherfordet al., 2008). Mep2 is required for the induction of haploidinvasive growth in response to low-ammonium growth, similarto other haploid yeasts. This takes place under conditions thatare distinct from the invasive growth that occurs in responseto carbon source availability and the presence of fusel alcohols(Lorenz et al., 2000b), which probably accounts for the novelfinding of the involvement of Mep2 in this process. Similarto the diploid Mep2 pseudohyphal pathway, the Tpk2 catalyticsubunit of PKA, the Npr1 kinase, and the Ste12 and Tec1 transcriptionfactors are required for haploid invasive growth. The Tpk1/Tpk3catalytic subunits of PKA repress ammonium-responsive invasivegrowth and Mep2 mutants altered in the conserved H194 and H348residues do not undergo invasive growth. Cells that have undergoneinvasive growth in response to ammonium limitation can adoptan elongated morphology similar to that observed during diploidpseudohyphal growth. Together, these data support the view thatthe Mep2-dependent signaling processes that occur during haploidinvasive growth are similar to those occurring during pseudohyphalgrowth. Our data contradict a previous study that reported thatMep2 is not required for haploid invasive growth when cellsare grown on medium lacking or containing minimal (100 µM)ammonium (Van Nuland et al., 2006). The complementation of themep2 ${Delta}$ strain with MEP2 expressed from a plasmid confirms thatunder these conditions, Mep2 is required for ammonium inducedhaploid invasive growth. Ammonium permease haploid invasivegrowth may be widely conserved within yeast, because this conservationhas now been observed in haploid S. pombe, C. neoformans, andS. cerevisiae.

The expression of Mep2 under conditions that do not normallyinduce pseudohyphal growth generates a transcriptional profilethat includes genes that are involved in cellular processesthat are likely to be differentially regulated during pseudohyphalgrowth. Of particular interest is a group of genes controlledby Ste12 involved in the cell wall (AGA1, SED1, and CWP2), cellcycle (CLB1 and SCH9), MAP kinase pathway (GIC2), PKA pathway(SCH9), and pseudohyphal growth (STE12, FLO11, and HMS1). Alsoof interest is the induction of genes involved in the activityof Cdc42, a GTPase that establishes cell polarity and is alsoa component of the MAP kinase pathway (CDC25, SDC25, RGA1, andGIC2). Therefore, Mep2 expression results in the induction ofa subset of Ste12-regulated genes and genes involved in theregulation of the MAP kinase pathway, indicative of Mep2-dependentdifferential activation of the pathway.

Consistent with a link between Ste12 and Mep2, activation ofthe MAP kinase pathway, through either overexpression of Ste12or the hyperactive STE11-4 allele restored pseudohyphal growthin a diploid strain lacking Mep2, in contrast to a previousreport (Lorenz and Heitman, 1998a). In addition, overexpressionof Mep2 from the GAL promoter restored pseudohyphal growth inmutants lacking elements of the RAS–cAMP pathway but notin a mutant that lacks Ste12. This evidence strongly supportsa link between Ste12 activity and the putative transceptor roleof Mep2 during pseudohyphal growth. This, together with previousdata that pseudohyphal growth in a S. cerevisiae strain lackingMep2 can be restored by the exogenous addition of cAMP to cells(Lorenz and Heitman, 1998a), is similar to the epistatic relationshipof C. albicans Mep2 and the PKA and MAP kinase pathways duringfilamentous growth. This mechanistic conservation in differentfungi is consistent with the finding that the expression ofcertain Mep2 fungal homologues restores pseudohyphal growthin an S. cerevisiae strain lacking the endogenous Mep2, suggestingthat significant aspects of the signaling role of these homologuesis conserved in some fungal species (Montanini et al., 2002;Javelle et al., 2003; Smith et al., 2003).

Although the constitutive expression of Mep2 induces pseudohyphalgrowth under normally repressing conditions, overexpressionof Ste12 under the same conditions does not (Borneman et al.,2007). This may be due to the increased turnover of Ste12 innitrogen-sufficient conditions, a process regulated by the Srb10cyclin-dependent kinase, which itself becomes depleted duringnitrogen limitation (Nelson et al., 2003). This therefore arguesagainst a simple model whereby Mep2 only activates the MAP kinasepathway. Mep2 could influence the turnover of Ste12 and/or regulatepathways that influence Ste12 activity. It is possible thatmechanisms that regulate the differential output of the MAPkinase in haploid and diploid cells are responsible for thetranscriptional profiles that we have identified. Interestingly,we have shown here and in previous work that Mcm1 and Tec1,two transcription factors that interact with Ste12 to modulateits activity, suppress the loss of pseudohyphal growth in cellslacking Mep2 (Lorenz and Heitman, 1998a). Additional candidatesfor signaling pathways that Mep2 might interact with were alsoidentified in microarray experiments including PP2A and theTor kinases.

Together, our data suggest a novel model of Mep2 function (Figure 9).The requirement for ammonium transport by Mep2 suggests thatthe lack of ammonium in the environment is not the initiatingsignal for pseudohyphal growth as has been proposed. This issupported by the Mep2 dependent induction of pseudohyphal growthunder ammonium-sufficient growth because presumably, under theseconditions, Mep2 is transporting ammonium into the cell. Thisstrongly suggests that the importance of Mep2 does not relateto its influence on the internal levels of nitrogen, becauseit will induce pseudohyphal growth irrespective of ammoniumlevels when expressed, further supporting the designation ofMep2 as a transceptor. We propose that when ammonium is absentfrom the external environment, Mep2 is expressed and localizedon the plasma membrane (Figure 9). Under these conditions, Mep2does not transport ammonium and the lowering of internal nitrogenlevels prevents growth. When low levels of ammonium become available,the transport of ammonium through Mep2 triggers conformationalchanges that most likely involve the C-terminal domains, whichsignal to the cell that there is sufficient ammonium for growth.Support for the conformational fluidity of Mep2 comes from thefinding that the C-terminal domain of each monomer of the Arabidopsisthaliana Mep2 homologue Amt1;1 interacts with the adjacent monomerto confer allosteric regulation (Loqué et al., 2007).The physical act of transport through Mep2 enables the permeaseto engage signaling components that result in Ste12 activationand the possible regulation of the Tor and PP2A pathways. Together,these result in the induction of pseudohyphal growth. If increasedlevels of ammonium become available, the transcription of theMEP2 gene is repressed via catabolite repression (Marini etal., 1997), and Mep2 is internalized, localized to the vacuole,and degraded (Zurita-Martinez et al., 2007). Under these conditions,ammonium is able to diffuse through the plasma membrane, andthe loss of the pseudohyphal-inducing signal from Mep2 resultsin the repression of pseudohyphal growth.

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Figure 9. Model of Mep2 signaling during pseudohyphal growth. Mep2 forms a trimer within the membrane and acts as a sensor of ammonium availability. When no ammonium is present in the environment the signaling function of Mep2 is repressed. When limiting ammonium becomes available, its transport causes a conformational change in Mep2, which enables the permease to engage signaling partners that initiate pseudohyphal growth. High levels of ammonium result in the loss of Mep2 signaling because Mep2 is removed from the membrane and MEP2 transcription is repressed.

Ammonium permeases have been implicated in regulating haploidinvasive growth, diploid pseudohyphal growth, and mating indifferent model fungal systems. Members of the Amt/Mep/Rh familyare also required for certain aspects of the development ofDictyostelium discoideum (Kirsten et al., 2005

; Singleton etal., 2006

). Together, these systems suggest that ammonium permease-mediatedcontrol of development may be widespread throughout unicellular,and possibly also multicellular, eukaryotic organisms. The molecularmechanisms that link Mep2 to pseudohyphal differentiation maytherefore be conserved and relevant for studies in other modeldevelopmental systems. The present study establishes for thefirst time, Mep2-dependent regulation of gene expression thatlikely involves, at least in part, the transcription factorSte12. The challenge now is to identify the putative regulatoryproteins that physically interact with Mep2 to govern transcriptionalcascades that evoke novel cellular fates in response to externalnutrient sources.

ACKNOWLEDGMENTS

We thank Mike Perlin and Ralf-Peter Jansen for useful discussionsand Mike Perlin for the gift of pYES2.1-MEP2. This researchwas funded by a National Institutes of Health/National Instituteof Allergy and Infectious Diseases grant AI39115 and Departmentof Defense award W81xwh-04-01-0208 (to J.H.). Support was alsoprovided in part by grant CA114107 from the National CancerInstitute (to M.E.C.) and by a grant from Genome Canada andthe Natural Sciences and Engineering Research Council (to T.H.).G.C. was supported by a Charles H. Best postdoctoral fellowship,and J.C.R. is supported by a Research Councils (United Kingdom)Academic Fellowship.

Footnotes

This article was published online ahead of print in MBC in Press(http://www.molbiolcell.org/cgi/doi/10.1091/mbc.E08-01-0033)on April 23, 2008.

Present addresses: Institute for Cell and Molecular Biosciences,Medical School, Newcastle University, United Kingdom;

Department of Biological Sciences, University of Calgary, Canada.

Address correspondence to: Joseph Heitman (heitm001{at}duke.edu)

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TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

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