Identification and Characterization of a Candida albicans Mating Pheromone

Candida albicans, the most prevalent fungal pathogen of humans,has recently been shown to undergo mating. Here we describea mating pheromone produced by C. albicans ${alpha}$ cells and show thatthe gene which encodes it (MF ${alpha}$ ) is required for ${alpha}$ cells, but nota cells, to mate. We also identify the receptor for this matingpheromone as the product of the STE2 gene and show that thisgene is required for the mating of a cells, but not ${alpha}$ cells.Cells of the a mating type respond to the ${alpha}$ mating pheromoneby producing long polarized projections, similar to those observedin bona fide mating mixtures of C. albicans a and ${alpha}$ cells. Duringthis process, transcription of approximately 62 genes is induced.Although some of these genes correspond to those induced inSaccharomyces cerevisiae by S. cerevisiae ${alpha}$ -factor, most arespecific to the C. albicans pheromone response. The most surprisingclass encode cell surface and secreted proteins previously implicatedin virulence of C. albicans in a mouse model of disseminatedcandidiasis. This observation suggests that aspects of cell-cellcommunication in mating may have been evolutionarily adoptedfor host-pathogen interactions in C. albicans.

INTRODUCTION

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Introduction

Candida albicans is the most common fungal pathogen in humansand is responsible for a wide variety of mucosal and systemicinfections (9). Two aspects of C. albicans biology are examinedin this paper. The first is a group of hypha-specific gene productsrequired for full virulence in a disseminated model of candidiasis.These genes include HWP1 (whose product is required for efficientattachment to epithelial cells) (38), SAP4, SAP5, and SAP6 (whichencode aspartyl proteases required for tissue invasion) (6,12), RBT1 and ECE1 (which encode cell surface proteins of unknownfunction), and RBT4 (which encodes a secreted protein of unknownfunction) (2). All of these genes encode secreted or membrane-boundproteins, and all are induced when C. albicans makes the transitionfrom the blastospore to filamentous forms. On rich laboratorymedia, C. albicans typically grows as single, ellipsoidal cells(blastospores) which divide by budding. However, under a varietyof other conditions (for example, in the presence of serum,high temperature, neutral pH, or nutrient-poor media), C. albicansassumes a variety of filamentous forms (3, 23, 31, 33, 41).These filamentous forms range from pseudohyphae (in which cellsare attached and elongated but still ellipsoidal) to true hyphae(in which cells are attached, highly elongated, and cylindrical).These changes in cell morphology are believed to allow C. albicansto rapidly colonize and disseminate in host tissues, facilitatingthe spread of infection. Although the synthesis of the virulencegenes mentioned above is induced when C. albicans makes thetransition from the blastospore to the filamentous forms ofgrowth, these gene products are not required for filamentousgrowth per se (3, 23, 31, 33, 41). Rather, they are believedto endow the filamentous forms with specialized properties relatedto tissue adhesion and invasion.

The second aspect of C. albicans biology relevant to this paperis the recently discovered ability of this organism to undergosexual mating. Most clinical isolates of C. albicans (includingthe most common laboratory strain, CAF2-1) are the a/ ${alpha}$ type andare unable to mate. If these strains are converted to a and ${alpha}$ strains through specific mutations or through chromosome loss,a cells can mate with ${alpha}$ cells to form tetraploid cells (17, 29).These tetraploids can, in turn, lose chromosomes to producediploid a and ${alpha}$ cells, thereby completing a parasexual cycle(1). Naturally occurring a and ${alpha}$ clinical isolates have alsobeen identified (26), and these, too, can undergo mating (25).However, for a and ${alpha}$ cells (regardless of their origin) to becomemating competent, they must first undergo a heritable, but reversible,transition from the so-called white phase to the opaque phase(30). This switch involves changes in the expression of manygenes, including a number of genes implicated in mating (21).

In this paper, we identify the ${alpha}$ mating pheromone ( ${alpha}$ -factor) ofC. albicans and characterize the response it elicits in recipienta cells. The gene encoding ${alpha}$ -factor is predicted to encode aprecursor protein that is processed into three identical tridecapeptidesrepresenting the mature ${alpha}$ -factor. We show that a synthetic tridecapeptideof this sequence produces long polarized projections in C. albicansa cells, but only when those cells were in the opaque (mating-competent)form; those projections had been previously observed in bonafide mating mixtures (25, 30). The tridecapeptide failed toelicit any morphological response in ${alpha}$ cells (white or opaque)or in a/ ${alpha}$ cells. Additional support for this tridecapeptide beingan authentic ${alpha}$ -factor comes from the demonstration, using geneknockout strains, that the C. albicans STE2 gene, which is homologousto the Saccharomyces cerevisiae ${alpha}$ -factor receptor gene (15, 19),is required for the morphological response of a cells to ${alpha}$ -factor.To complete the link between the tridecapeptide and mating,we also show that ${alpha}$ cells (but not a cells) with the ${alpha}$ -factorgene (MF ${alpha}$ ) deleted are deficient in mating; likewise, a cells(but not ${alpha}$ cells) with the gene encoding the ${alpha}$ -factor receptordeleted (STE2) are mating deficient. Microarray analysis ofthe transcriptional response of a opaque cells to ${alpha}$ -factor revealed62 genes that are induced more than threefold. These genes canbe divided into several categories. As expected, one group ofC. albicans pheromone-induced genes (18 in all) closely resemblegenes previously implicated in mating in S. cerevisiae. However,the C. albicans and S. cerevisiae pathways have diverged considerably,and the majority of the pheromone-induced genes in C. albicansare specific to that organism. These genes include 18 open readingframes (ORFs) with no close relatives in any sequenced genome(including that of S. cerevisiae) and 15 ORFs with at leastone close relative but no obvious clues to specific function.The most surprising group of pheromone-induced genes in C. albicansare a set of seven cell surface and secreted proteins that werepreviously shown to be required for virulence in a mouse modelof disseminated candidiasis. This observation indicates thatC. albicans utilizes a number of the same cell surface and secretedproteins for both mating and pathogenesis and suggests an evolutionarylink between the two processes.

MATERIALS AND METHODS

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Materials and Methods

Media and pheromone. Media were prepared as described previously (14). ${alpha}$ -Factor (synthesizedby Genemed Synthesis) was dissolved in dimethyl sulfoxide (DMSO)at a concentration of 100 mg/ml and then brought to a finalconcentration of 10 mg/ml in 10% DMSO. ${alpha}$ -Factor was added tomedia at a final concentration of 10 µg/ml unless otherwisenoted.

Strains. C. albicans CAF2-1 (URA3/ ${Delta}$ ura3::imm434) (13), the ${alpha}$ mating typestrain, CHY247 (a1::hisG-URA3-hisG), and the a mating type strain,CHY420 ( ${alpha}$ 1::hisG-URA3-hisG ${alpha}$ 2::hisG) have been described previously(30). Strains RBY731 (MTLa/MTLa) and RBY734 (MTL ${alpha}$ /MTL ${alpha}$ ) were derivedfrom strain CAI4 ( ${Delta}$ ura3::imm434/ ${Delta}$ ura3::imm434) (13) by growthon sorbose-containing medium for 7 days at 37°C, which selectsfor loss of one copy of chromosome 5, the chromosome containingthe MTL locus (18, 29). Following loss of a single copy of chromosome5, strains were grown on yeast extract-peptone-dextrose, andfaster growing colonies were chosen. This step has been proposedto select for duplication of the remaining chromosome 5, resultingin homozygosis of the MTL locus (18). These strains will bereferred to in this paper as a/a or ${alpha}$ / ${alpha}$ . A ste2/ste2 strain wasconstructed by the method of Wilson et al. (42) in strain CAI4.Both alleles of STE2 were deleted using a construct derivedby PCR from pDDB57, and Ura^- colonies were generated on mediumcontaining 5-fluoroorotic acid. Two completely independent ste2/ste2strains were constructed in this way. MTLa (MMY566 and MMY567)and MTL ${alpha}$ (MMY565 and MMY568) strains were then generated fromthe ste2/ste2 strains by growth on sorbose-containing medium,as described above. Similarly, mf ${alpha}$ /mf ${alpha}$ strains were constructedusing a PCR construct based on pDDB57, Ura^- colonies were generatedon 5-fluoroorotic acid-containing medium, and MTLa (MMY563)and MTL ${alpha}$ (MMY563) derivatives were selected on sorbose-containingmedium. Control strains for the quantitative mating assays wereCHY257, CHY439, CHY477, and MMY278 (30). The mating type ofall mating strains was periodically confirmed by PCR as previouslydescribed (30).

Mating assays of C. albicans. Quantitative mating analysis of C. albicans strains was performedas described previously (30). Briefly, Ade^- and Ura^- matingstrains in the opaque phase were grown at 25°C overnight,and approximately 3 x 10⁷ cells of each strain were mixed anddeposited onto 0.8-µm-pore-size nitrocellulose filtersusing a Millipore 1225 vacuum sampling manifold. The filterswere then grown on the surface of a yeast extract-peptone-dextroseplate containing 55 µg of adenine per ml and incubatedfor 6 days at 23°C. Cells were collected from the filtersand plated onto Ade^- Ura^- media to select for conjugants andonto Ade^- and Ura^- plates to monitor each parent populationand conjugants.

Construction of C. albicans microarray. A C. albicans microarray containing $~$ 11,000 spots was constructedby PCR amplification of predicted ORF sequences derived fromsequencing the C. albicans genome (http://www-sequence.stanford.edu/group/candida).Primer design and ORF amplification were performed in collaborationwith the laboratory of Gerald Fink, Whitehead Institute, MassachusettsInstitute of Technology (MIT). Successful PCR products wereethanol precipitated and printed onto glass slides as previouslydescribed (8). Printed slides were rehydrated and snap dried,and the DNA was cross-linked (8). Slides were then blocked withbovine serum albumin by incubation in a solution containing0.5 M sodium chloride, 0.05 M sodium citrate, 0.1% sodium dodecylsulfate, and 1% bovine serum albumin for 5 min at room temperaturefollowed by 5 min at 42°C. Slides were rinsed and spun dryin a clinical centrifuge and used within 1 h of processing.

Preparation of cDNA for microarray experiments. Five-milliliter cultures were grown overnight at 23°C andused to inoculate a large overnight culture (4 liters). Whenthe optical density of the culture reached 1.0, a sample ofthe culture was harvested and frozen (zero time point). To theremainder of the culture, 10% DMSO or ${alpha}$ -factor dissolved in 10%DMSO was added (final concentration, 10 µg/ml). Samples(500 ml) were taken from the ${alpha}$ -factor- or mock-treated culturesafter 20 min, 1 h, 2 h, or 4 h. The cells were collected byfiltration and stored at -80°C.

Total RNA was obtained from cells using a hot phenol protocolas previously described (30). Poly(A) RNA was isolated usingthe Qiagen Oligotex mRNA isolation mini kit. Each cDNA poolwas generated from 4 µg of poly(A) by first annealingthe poly(A) RNA with oligo(dT) (10 µg) and pdN6 (10 µg).cDNA was then synthesized using Stratascript reverse transcriptase(Stratagene;100 units of reverse transcriptase) in reactionmixtures containing 0.5 mM (total) deoxynucleoside triphosphates(aminoallyl-dUTP and deoxynucleoside triphosphates [3:2]). AftercDNA synthesis for 2 h at 42°C, the RNA was hydrolyzed with0.2 N NaOH and 0.1 M EDTA. The reaction was neutralized with0.33 M Tris (pH 7.4), and the cDNA washed several times withH₂O in a Microcon-30 filter. The cDNA was recovered and driedin a speed-vac.

Coupling of cDNA and hybridization to microarrays. The cDNA was coupled with fluorescent dyes by resuspension in0.05 M sodium bicarbonate buffer, pH 9.0, and incubation witheither Cy3 or Cy5 dye (Amersham Biosciences) for 1 h at roomtemperature in the dark. Unincorporated dye was removed usinga Qiagen PCR purification kit, and the samples were dried ina speed-vac. The samples of cDNA coupled with fluorescent dyeswere resuspended in a solution containing 50% formamide, 1 Msodium chloride, 0.1 M sodium citrate, and 0.2% sodium dodecylsulfate. The appropriate Cy3-cDNA and Cy5-cDNA samples werethen mixed and heated for 3 min at 100°C before the sampleswere applied to the microarray slide. Samples were hybridizedfor 18 to 24 h at 45°C, and the slides washed, dried, andthen analyzed as described below.

Analysis of microarrays. Arrays were scanned on a GenePix 4000 scanner (Axon Instruments,Foster City, Calif.), and data were quantified by using GENEPIXPRO version 3.0 and further processed by using NOMAD (http://ucsf-nomad.sourceforge.net/).Pairwise average linkage clustering analysis was performed byusing the program CLUSTER and visualized by using TREEVIEW (10).Genes whose expression changed by threefold or more (in twoexperiments) relative to the zero time point were selected forfurther analysis. The Saccharomyces Genome Database (http://www.yeastgenome.org/)and the Stanford Candida database (http://sequence-www.stanford.edu/group/candida/index.html)were used to facilitate further analysis.

RESULTS

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Results

Identification and characterization of C. albicans ${alpha}$ -factor. We utilized conserved features of the ${alpha}$ -factor pheromone familyto devise a computer algorithm to search for putative ${alpha}$ -factorcandidates in the publicly available database of C. albicans(http://www-sequence.stanford.edu/group/candida). This searchrevealed one gene (ORF6.4306) with several features characteristicof the ${alpha}$ -factor family (Fig. 1). Conceptual translation of thisgene produced a hydrophobic leader sequence, consensus Kex2protease processing sites, and three repeats of a 13-amino-acidsequence, GFRLTNFGYFEPG. These repeats were predicted to beprocessed into the mature pheromone (Fig. 1). This predictedprocessing scheme is supported by the observation that the KEX2gene is required for mating of ${alpha}$ cells in C. albicans (28); additionalprocessing steps were suggested on the basis of analogy withthose of S. cerevisiae and should be regarded as provisional.The overall structure of the C. albicans gene is similar tothat of the S. cerevisiae MF ${alpha}$ genes, MF ${alpha}$ 1 and MF ${alpha}$ 2 (Fig. 1), althoughthere is no amino acid sequence similarity between the S. cerevisiaemature ${alpha}$ -factor and the predicted C. albicans ${alpha}$ -factor. Newportet al. (34) had previously noted that ORF6.4306 may encode an ${alpha}$ -factor.

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FIG. 1. Schematic diagram of the proposed C. albicans ${alpha}$ -factor pheromone precursor. The conceptually translated protein consists of a hydrophobic leader sequence and three copies of a 13-amino-acid (aa) sequence. For comparison, the two ${alpha}$ -factor genes from S. cerevisiae are also shown. The mature S. cerevisiae ${alpha}$ -factor peptide is formed by several protein processing steps, including cleavage by the Kex2 protease (37).

To experimentally test the possibility that this gene encodesan ${alpha}$ -factor, the GFRLTNFGYFEPG tridecapeptide was synthesizedin vitro and added at 10 µg/ml to C. albicans cells ofthe following types: ${alpha}$ white, ${alpha}$ opaque, a white, a opaque, anda/ ${alpha}$ white cells (a/ ${alpha}$ cells cannot form opaque cells). The constructionof these strains and the isolation of white and opaque formsare described in Materials and Methods. We observed that onlya opaque cells morphologically responded to the tridecapeptide:they produced long polarized projections which were easily distinguishablefrom pseudohyphal or other elongated cell types by the absenceof a constriction at the site of polarized growth (Fig. 2).These projections, which closely resemble those observed inbona fide mating mixtures of a and ${alpha}$ opaque cells (25, 30), werefirst observed after 2 h of peptide exposure (Fig. 3 and Table1). No change in the response of any of the cell types was detectedwhen the concentration of the peptide was increased 10-foldto 100 µg/ml: a slight decrease in the response of a opaquecells was observed at peptide concentrations of 1 µg/ml(data not shown). Because the response of C. albicans to thistridecapeptide is highly cell type specific, we will hereafterrefer to it as ${alpha}$ -factor. Additional evidence presented belowverifies this initial identification.

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FIG. 2. Response of C. albicans cells to synthetic ${alpha}$ -factor. C. albicans a and ${alpha}$ cell types in both the white phase (A) and the opaque phase (B) were treated with 10% DMSO or ${alpha}$ -factor (10 µg/ml) dissolved in 10% DMSO. Cells were examined after 4 h of incubation at 25°C. The a and ${alpha}$ cell types were generated by gene knockouts (e.g., ${Delta}$ a1/ ${alpha}$ 1 ${alpha}$ 2) or by selection on medium containing sorbose (e.g., MTL ${alpha}$ /MTL ${alpha}$ ), as described in Materials and Methods.

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FIG. 3. Time course of the response of a cells to ${alpha}$ -factor. Cells were treated with ${alpha}$ -factor (10 µg/ml) or mock treated with DMSO and incubated at 25°C. Samples were taken and analyzed for their response to ${alpha}$ -factor at 0, 1, 2, and 4 h.

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TABLE 1. Response of C. albicans strains to ${alpha}$ -factor^a

As described in Materials and Methods, C. albicans a cells wereconstructed both by disrupting genes in the MTL (mating type)locus and by homozygosis of the MTL locus using sorbose selection.Both types of a cells responded to the synthetic ${alpha}$ -factor oncethey were switched to the opaque form. However, the a/a strainsshowed a more pronounced morphological response to ${alpha}$ -factor thandid the a/ ${Delta}$ ${alpha}$ 1 ${Delta}$ ${alpha}$ 2 strains (Table 1). For example, roughly 20% ofthe a/ ${Delta}$ ${alpha}$ 1 ${Delta}$ ${alpha}$ 2 strains exhibited polarized projections by 4 h, whereas50% of the a/a strains had projections at the same time point.This difference may be due to a haploinsufficiency effect atthe MTLa locus, as haploinsufficiency has been observed formany other genes in C. albicans (20, 40).

We also investigated whether the C. albicans ${alpha}$ -factor causedcell cycle arrest, as has been observed for S. cerevisiae. Tothis end, we performed halo assays by spotting ${alpha}$ -factor on filters(at concentrations of 10 mg/ml, 1 mg/ml, and 100 µg/ml)placed on lawns of a opaque cells (approximately 2,000 colonies/plate).We observed no inhibition of cell proliferation by ${alpha}$ -factor,as judged by colony size (data not shown). However, coloniesof a opaque cells exposed to ${alpha}$ -factor had a marked wrinkled appearance,and individual cells within the colony exhibited mating projectionsas described above. In contrast, this same type of experimentperformed with S. cerevisiae reveals pronounced areas of growtharrest (halos) around the ${alpha}$ -factor spots. These observationssuggest that C. albicans, unlike S. cerevisiae, does not undergoprolonged growth arrest in the presence of ${alpha}$ -factor. It is, ofcourse, possible that cell cycle arrest occurs only transientlyin C. albicans, that it occurs in only a subset of the population,or that the synthetic ${alpha}$ -factor is unstable or improperly modified.

MF ${alpha}$ is required for ${alpha}$ cells to mate. We next determined whether deletion of the C. albicans ${alpha}$ -factorstructural gene (MF ${alpha}$ ) affected the mating efficiency of a and ${alpha}$ cells. Both alleles of the MF ${alpha}$ gene were deleted in a CAI4 strainof C. albicans, and a and ${alpha}$ strains were isolated by selectingfor loss of a homolog of chromosome 5 on medium containing sorbose.a and ${alpha}$ Ura^- white strains (either wild-type or MF ${alpha}$ mutant strains)were switched to opaques and mated with Ade^- control matingstrains. From the fraction of prototrophs obtained, mating efficiencycould be estimated (for details, see Materials and Methods).Deletion of the MF ${alpha}$ gene from opaque a cells did not significantlyaffect the efficiency of mating of these cells (Table 2). Incontrast, the mating of ${alpha}$ cells in which the MF ${alpha}$ gene had beendeleted was drastically lower (more than a millionfold) thanthat of the parental strain (compare strains MMY564 and MMY563in Table 2). The MF ${alpha}$ gene is therefore specifically requiredfor the mating of ${alpha}$ cells. This analysis also indicates thatC. albicans has only one gene encoding a functional ${alpha}$ -factor,whereas S. cerevisiae has two (MF ${alpha}$ 1 and MF ${alpha}$ 2), either of whichcan support mating (Fig. 1).

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TABLE 2. Mating efficiency of mf ${alpha}$ and ste2 mutants of C. albicans^a

The C. albicans STE2 gene is required for mating and the formation of mating projections in response to ${alpha}$ -factor. In S. cerevisiae, the STE2 gene encodes the receptor for ${alpha}$ -factor(15, 19). C. albicans has a closely related gene (also calledSTE2) (39), and we tested whether this gene is required fora cells to respond to ${alpha}$ -factor. In the experiment shown in Fig.4, wild-type a opaque cells and ste2/ste2 a opaque cells (seeMaterials and Methods for strain construction details) weretreated with ${alpha}$ -factor for 4 h and analyzed microscopically formorphological changes. The wild-type cells responded as describedabove, forming mating projections with approximately 50% ofcells responding (Fig. 4B). In contrast, the a ste2/ste2 opaquecells showed no morphological response to ${alpha}$ -factor (compare Fig.4C and D). We note that deletion of the STE2 gene did not affectthe ability of a cells to switch from the white form to theopaque form. Moreover, prior to the addition of ${alpha}$ -factor, wild-typeand ste2/ste2 a opaque cells both formed similar ellipticalcells characteristic of the opaque phase (Fig. 4A and C). TheSTE2 gene in C. albicans is therefore not required for formationof opaque cells but is required for a opaque cells to form matingprojections in response to synthetic ${alpha}$ -factor.

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FIG. 4. The STE2 gene is required for the response of a cells to ${alpha}$ -factor. Opaque a cells or opaque ${Delta}$ ste2/ ${Delta}$ ste2 MTLa cells were treated with 10 µg of ${alpha}$ -factor per ml and incubated for 4 h at 25°C. The ste2/ste2 mutant showed no response to ${alpha}$ -factor.

We next tested, by constructing gene knockout strains, whetherthe STE2 gene was required for mating. When C. albicans opaquea ste2/ste2 cells were mated with wild-type ${alpha}$ cells, the matingfrequency was reduced by more than a millionfold relative tothe parental strain (strains MMY566, MMY565, MMY567, and MMY568[Table 2]). In contrast, deletion of ste2 from ${alpha}$ opaque cellsdid not significantly affect mating efficiency. These resultsshow that the C. albicans STE2 gene encodes the receptor for ${alpha}$ -factor and that this is required for mating only in a cells.

Genome-wide expression profiling of the response of C. albicans to mating pheromone. To identify the genome-wide changes in transcription that accompanythe response to ${alpha}$ -factor, C. albicans a and ${alpha}$ opaque strains weretreated with ${alpha}$ -factor and the transcriptional response was monitoredusing microarrays. The microarrays used in this analysis contained11,325 spots representing approximately 6,550 protein-encodingnuclear genes, at least 95% of the estimated number of thesegenes in the C. albicans genome. For this experiment, a/a and ${alpha}$ / ${alpha}$ strains were generated by chromosome loss on sorbose-containingmedium, and opaque cells of each mating type were isolated (seeMaterials and Methods for details on the isolation of forms).Two time course experiments studying the response to ${alpha}$ -factor(10 µg/ml) were performed. In one, samples were takenat 20 min, 1 h, and 4 h, while in the second, samples were takenat 1, 2, and 4 h. Cells were also examined microscopically toconfirm that the morphological changes described earlier hadtaken place; as expected, the a opaque cells exhibited polarizedgrowth in response to ${alpha}$ -factor (approximately 50% of the population),while the ${alpha}$ opaque cells (a control for the experiment) showedno apparent morphological response.

As shown in Fig. 5, the expression of many C. albicans geneschanges in both a and ${alpha}$ cells on exposure to DMSO, the solventused for the synthetic ${alpha}$ -factor. However, an obvious clusterof 62 genes was induced only in a cells and only when ${alpha}$ -factorwas present in the DMSO (Fig. 5 and Table 3). Moreover, thisset of genes was reproducibly induced during both time courseexperiments. Although a few genes were induced 1 h after pheromoneaddition, most show maximal induction after 2 to 4 h. In comparison,the response to ${alpha}$ -factor in S. cerevisiae has been shown to bemuch more rapid, with increased expression of many pheromone-responsivegenes observed after only 15 min (35). Although there are minordifferences in the medium conditions used for the microarrayanalysis, it appears that the pheromone response occurs moreslowly in C. albicans than in S. cerevisiae.

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FIG.5. Microarray analysis of the response of a and ${alpha}$ opaque cells to ${alpha}$ -factor. All spots on the microarray that were induced more than threefold in at least two of the time points are shown. In the first time course experiment (EXPT 1), samples were taken 20 min, 1 h, and 4 h after the addition of DMSO (lanes 2 to 4) or ${alpha}$ -factor (lanes 5 to 7) to a cells. In the second time course experiment, samples were taken at 1, 2, and 4 h after the addition of DMSO (lanes 9 to 11) or ${alpha}$ -factor (lanes 12 to 14). As an additional control, DMSO or ${alpha}$ -factor were also added to ${alpha}$ cells, and samples were taken after 4 h (lanes 16 and 17, respectively). All samples were normalized to the opaque a cells at the zero time point. The array results clustered into six sets of genes: a- and ${alpha}$ -specific genes (including the MTL genes), DMSO-induced or -repressed genes, and ${alpha}$ -factor-induced or -repressed genes. The cluster corresponding to ${alpha}$ -factor-induced genes is shown enlarged on the right. Selected genes are indicated to the right of the cluster. Note that many genes are represented by multiple spots on the array (the duplicates are not labeled).

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TABLE 3. Genes whose transcription is induced more than three-fold in a opaque cells in response to ${alpha}$ -factor^a

One large group of genes induced by ${alpha}$ -factor (18 of 62) encodeproteins of unknown function, with no known close relativesin other organisms, including S. cerevisiae (Table 3 and Fig.6). Another group (15 of 62) includes genes with at least oneclose relative but no obvious clue to specific function. Aswill be discussed in more detail below, the remainder of theinduced genes include homologs of 18 genes involved in matingin S. cerevisiae, several genes previously implicated in thecontrol of filamentous growth in C. albicans, and several genespreviously shown to be required for virulence in C. albicans.In addition to the 62 C. albicans genes induced by ${alpha}$ -factor,a few genes showed reproducible pheromone-induced repression,and we discuss these first.

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FIG. 6. Pie chart of genes induced by ${alpha}$ -factor in C. albicans opaque a cells.

Genes repressed by ${alpha}$ -factor in C. albicans. In S. cerevisiae, more than 200 genes are repressed in responseto pheromone treatment (35). The large majority of these genesare shut down as part of the cell cycle arrest in G₁, whichprecedes polarized growth and formation of mating projections.Virtually all gene repression in S. cerevisiae is mediated bythe Far1 protein, a cyclin-dependent kinase inhibitor (4, 35).In contrast to S. cerevisiae, pheromone treatment of C. albicanscells resulted in lowered expression of only very few genes.In part, this may reflect the fact that only a fraction (atmost 50%) of a opaque cells form projections in response to ${alpha}$ -factor. Therefore, it might be difficult to observe gene repressionthat occurs only in a subset of cells. Nonetheless, severalgenes do show significant repression in the population as awhole, including several that function in DNA replication (MCM6,MCM7, PRI, and POL5a). The apparent lack of widespread generepression supports the earlier observations that C. albicansdoes not appear to undergo whole-scale cell cycle arrest inresponse to ${alpha}$ -factor. It is possible, however, that C. albicanstransiently arrests DNA replication in response to ${alpha}$ -factor.

Induction of mating genes by C. albicans ${alpha}$ -factor. Fifteen genes are induced in both C. albicans and S. cerevisiaeby ${alpha}$ -factor (Table 3). Among these 15 genes are genes that encodethe STE2 ${alpha}$ -factor receptor and various components of the mitogen-activatedprotein (MAP) kinase cascade that mediate the response to ${alpha}$ -factorin S. cerevisiae (37). Additional genes induced by ${alpha}$ -factor inboth yeasts include KAR4 and KAR5 required for karyogamy aftercell fusion, SST2 and CPP1 (MSG5 in S. cerevisiae) requiredfor pheromone adaptation, and AXL1 and HST6 (STE6 in S. cerevisiae),which are required for a-factor processing and export, respectively.

Interestingly, the RAM1 and RAM2 genes are induced (seven- andfivefold, respectively) by ${alpha}$ -factor in C. albicans but not inS. cerevisiae. The S. cerevisiae gene products do, however,act in the mating pathway by prenylating a-factor prior to itsexport. Similarly, the KAR9 gene (required for karyogamy) isinduced by ${alpha}$ -factor in C. albicans but not in S. cerevisiae.Thus, even for genes likely to be involved in mating in bothorganisms, the precise induction pattern in response to ${alpha}$ -factordiffers between S. cerevisiae and C. albicans. Although a-factorhas not yet been identified in C. albicans, the pheromone-inducedtranscription of AXL1, HST6, RAM1, and RAM2, in combinationwith the observation that HST6 mutants of C. albicans are deficientin mating (28), strongly support its existence. In all, C. albicans ${alpha}$ -factor induces 18 genes implicated in mating, and this observationsupports the idea that mating is an elaborate process in thisorganism involving many of the same genes described previouslyfor S. cerevisiae.

Overlap between pheromone induction and filamentous growth. A number of C. albicans genes required for proper regulationof the blastospore-filament transition have been identified(for reviews, see references 3, 23, 31, 33, and 41), and severalof these genes were observed to be significantly up-regulatedin a opaque cells by ${alpha}$ -factor, including CPH1, CEK1, and FGR23(Table 3). As in the case of the mating genes, this result isnot surprising, as a close relationship between mating and filamentousgrowth has been described for S. cerevisiae. While S. cerevisiaedoes not exhibit true hyphal growth, diploid strains grow aspseudohyphae on medium low in nitrogen, and haploid strainsundergo invasive growth on rich medium (27). It was discoveredthat a number of genes in the mating pheromone signaling pathwayalso function in the signaling pathway for pseudohyphal andinvasive growth. These genes include STE20, STE11, and STE7(components of a MAP kinase cascade) and STE12, a transcriptionalregulator that is a target of this cascade. Some of these samegene products were previously shown to be involved in matingand filamentous growth in C. albicans including CST20 (the STE20homolog), HST7 (the STE7 homolog), and CPH1 (the STE12 homolog)(5, 7, 20, 22, 24, 28, 36). Thus, a signaling pathway requiredfor mating in C. albicans (and presumably for pheromone induction)utilizes some of the same signaling components used in filamentousgrowth.

In addition to the overlap of mating and filamentation signalingpathways in S. cerevisiae, there appears to be a functionaloverlap under certain conditions. For example, a cells of S.cerevisiae respond to low doses of ${alpha}$ -factor by forming filamentssimilar to pseudohyphal cells and by growing as invasive colonieson agar plates (11, 35). This association makes intuitive sense,as both processes require the formation of polarized outgrowth.Consistent with this idea are the recent observations of Hazanand Liu (16) showing that hyphal formation in C. albicans isaccompanied by a localization of Cdc42 to the cell tip, a processthat requires an intact actin cytoskeleton. Actin-dependentCdc42 localization to the cell tip is also observed during shmooformation in S. cerevisiae (43), suggesting an important cellularand biological link between these processes. Thus, in both C.albicans and S. cerevisiae, there seems to be significant overlapbetween mating and filamentation. The mating and filamentationpathways presumably diverged from a common ancestral pathwaybut have maintained several components still shared by both.This appears to be particularly true in C. albicans, where theelongated mating projections resemble filamentous cells muchmore so than their S. cerevisiae counterparts. In any case,the observation that C. albicans ${alpha}$ -factor induces transcriptionof genes previously implicated in the control of filamentousgrowth supports a large body of evidence that these two processesare closely linked.

Overlap between the pheromone response and virulence in C. albicans. Perhaps the most surprising aspect of the response of C. albicansa opaque cells to ${alpha}$ -factor is the induction of seven genes (HWP1,SAP4, SAP5, SAP6, ECE1, RBT1, and RBT4) encoding cell surfaceor secreted proteins previously shown to be required for fullvirulence in the mouse tail vein model for disseminated candidiasis(discussed in the introduction). Although these genes are highlyinduced during filamentous growth, they are not required forfilamentous growth per se, as mutants with these genes deletedstill form hyphae and pseudohyphae. Most of these genes do nothave clear homologs in S. cerevisiae and are therefore thoughtto define aspects of C. albicans-host interactions (3, 23, 31,33, 41).

HWP1 is highly induced (more than 20-fold) when a opaque cellswere exposed to ${alpha}$ -factor. This gene encodes a glycosylphosphatidylinositol(GPI)-modified cell wall protein that is strongly induced duringhyphal growth and mediates attachment of C. albicans to hostepithelial cells (38). Three members of the secreted aspartylproteinase family of genes, SAP4, SAP5, and SAP6, were alsoinduced (between 9- and 15-fold) by ${alpha}$ -factor. (Since these threeSAP genes have similar nucleotide sequences, it is difficult,due to potential cross-hybridization on the microarray, to rigorouslydetermine each induction ratio.) The three SAP genes are differentiallytranscribed when hyphal growth is induced and are known to contributeto the virulence of C. albicans in the mouse model, probablyby allowing C. albicans to proteolyze tissues during invasion(6, 12). Other genes induced by ${alpha}$ -factor include two additionalcell wall proteins (ECE1 and RBT1) and one secreted protein(RBT4). The functions of these latter proteins are not wellunderstood, but all these proteins are highly induced duringfilamentous growth and are required for full virulence in themouse model.

It should be noted that only a subset of C. albicans hypha-specificgenes was induced by ${alpha}$ -factor. Transcription profiling has shownthat the expression of 18 genes was increased at least twofoldduring the transition from yeast form to hyphal cells and inducedby addition of serum to the growth medium (32). ${alpha}$ -Factor significantlyincreased the expression of only seven of these genes, namely,the genes discussed above (HWP1, ECE1, RBT1, RBT4, SAP4, SAP5,and SAP6). These observations indicate that the genes inducedduring hyphal growth and upon pheromone treatment overlap butthat there are also many genes that are specific to each condition.

DISCUSSION

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Discussion

We have identified an ${alpha}$ -factor mating pheromone in C. albicansand shown that mating-competent (i.e., opaque) a cells respondto it by forming projections characteristic of those observedin bona fide mating reactions. We also show that this responseis blocked by mutation of the STE2 gene, which we identify asthe ${alpha}$ -factor receptor. The gene encoding the ${alpha}$ -factor (MF ${alpha}$ ) isrequired for mating, but only by ${alpha}$ cells; likewise, the receptor(STE2) is required for mating, but only by a cells.

Full genome transcriptional profiling of the response of a opaquecells to ${alpha}$ -factor revealed 62 genes that were specifically induced.Eighteen genes induced by C. albicans ${alpha}$ -factor had previouslybeen implicated in mating in S. cerevisiae, and fifteen of thesegenes are also induced by S. cerevisiae ${alpha}$ -factor. Overall, thisoverlap is not surprising and is consistent with the idea thatC. albicans and S. cerevisiae share a conserved set of matinggenes (5, 28, 39). What is perhaps unexpected is how differentthe sets of pheromone-induced genes are in the two organisms;with the exception of the known mating genes, the response ofa cells to ${alpha}$ -factor is highly distinctive for each organism.The largest class of pheromone-induced genes in C. albicansare ORFs with no known homologs in any other organism and ORFswith only poorly defined relatives. Clearly, much work remainsin understanding mating in C. albicans. Given that many of thesegenes are not present in the genome of S. cerevisiae, it ispossible that some of these genes function to promote matingof C. albicans in the hostile environment of a mammalian host.

Of particular interest are a set of seven C. albicans pheromone-inducedgenes (HWP1, ECE1, RBT1, RBT4, SAP4, SAP5, and SAP6) that encodecell surface or secreted proteins. As shown in previous work,each of these genes is required for full virulence of C. albicansin a mouse model of disseminated candidiasis (for references,see the introduction). These observations suggest that matingand virulence pathways in C. albicans share some of the samegene products to mediate cell-cell interactions. Consistentwith this idea, preliminary experiments indicate that deletionof RBT1 and HWP1 in both mating partners reduced mating efficiencyby a factor of approximately 20 (R. J. Bennett and A. D. Johnson,unpublished observations). (RBT1 and HWP1 are closely relatedproteins, and deletion of a single protein did not significantlyaffect mating.) It is tempting to speculate that since S. cerevisiaeand C. albicans diverged from a common ancestor some 100 to200 million years ago, structural components of the mating apparatuswere adapted by C. albicans for use in interacting with itsmammalian host.

ADDENDUM IN PROOF

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Addendum in proof

Since this paper was accepted, we have found through ongoingannotation efforts that three additional genes have been foundthat are induced by ${alpha}$ -factor in a opaque cells. These are ORF6.2919(no close homologs), ORF6.2933 (a homolog of RBT1 and HWP1),and ORF6.4306 (MF ${alpha}$ ).

ACKNOWLEDGMENTS

Richard J. Bennett and M. Andrew Uhl contributed equally tothis work.

We are grateful to Diane Inglis (UCSF), Joe DeRisi (UCSF), MikeLorentz (MIT) and Gerald Fink (MIT) for the collaboration thatproduced the DNA microarrays used in this paper. We are alsograteful to the Stanford Genome Technology Center (http://www-sequence.stanford.edu/group/candida)for providing sequence data for C. albicans. We thank DavidKadosh for communicating results prior to publication, HitenMadhani and Diane Inglis for comments on the manuscript, andAnnie Tsong, Anita Sil, Burk Braun, and Bethann Hromatika forhelp with the microarrays.

This work was supported in part by grants from the BurroughsWellcome Fund (993218) and NIH (R01 AI49187) to A.D.J. Sequencingof the C. albicans genome was accomplished with the supportof the NIDR and the Burroughs Wellcome Fund. M.G.M. is a HowardHughes Medical Institute Fellow.

FOOTNOTES

* Corresponding author. Mailing address: Department of Microbiology and Immunology, 600 16th St., Suite N372, San Francisco, CA 94143-2200. Phone: (415) 476-8783. Fax: (415) 502-4315. E-mail: ajohnson{at}cgl.ucsf.edu.

REFERENCES

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