Candida albicans Ecm33p Is Important for Normal Cell Wall Architecture and Interactions with Host Cells

Candida albicans ECM33 encodes a glycosylphosphatidylinositol-linkedcell wall protein that is important for cell wall integrity.It is also critical for normal virulence in the mouse modelof hematogenously disseminated candidiasis. To identify potentialmechanisms through which Ecm33p contributes to virulence, weinvestigated the interactions of C. albicans ecm33 ${Delta}$ mutants withendothelial cells and the FaDu oral epithelial cell line invitro. The growth rate of blastospores of strains containingeither one or no intact copies of ECM33 was 50% slower thanthat of strains containing two intact copies of ECM33. However,all strains germinated at the same rate, forming similar-lengthhyphae on endothelial cells and oral epithelial cells. Strainscontaining either one or no intact copies of ECM33 had modestlyreduced adherence to both types of host cells, and a markedlyreduced capacity to invade and damage these cells. Saccharomycescerevisiae expressing C. albicans ECM33 did not adhere to orinvade epithelial cells, suggesting that Ecm33p by itself doesnot act as an adhesin or invasin. Examination of ecm33 ${Delta}$ mutantsby transmission electron microscopy revealed that the cell wallof these strains had an abnormally electron-dense outer mannoproteinlayer, which may represent a compensatory response to reducedcell wall integrity. The hyphae of these mutants also had aberrantsurface localization of the adhesin Als1p. Collectively, theseresults suggest that Ecm33p is required for normal cell wallarchitecture as well as normal function and expression of cellsurface proteins in C. albicans.

INTRODUCTION

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Introduction

Candida albicans causes both hematogenously disseminated andoropharyngeal disease. During hematogenously disseminated candidiasis,the blood-borne organisms must adhere to and penetrate the endothelialcell lining of the blood vessels to invade the deep tissuesof the target organs. These target organs include the kidney,liver, spleen, heart, brain, and eye (6). During oropharyngealcandidiasis, C. albicans not only adheres to the epithelialcells of the oral mucosa, but also invades these cells. Invasioninto the epithelial cell lining of the oral mucosa is characteristicof both human and experimental animal models of oropharyngealcandidiasis (3, 7, 15, 18, 23).

The mechanism by which C. albicans invades endothelial cellsand oral epithelial cells has been investigated in vitro. Thesein vitro studies demonstrate that one mechanism by which C.albicans invades both endothelial cells and oral epithelialcells is by inducing its own endocytosis (8, 20, 21). Once C.albicans is endocytosed by either endothelial cells or oralepithelial cells, it damages these cells. In vitro, host celldamage requires the endocytosis of live organisms (8, 20). Importantly,we have found that mutants of C. albicans that are endocytosedpoorly and cause little damage to endothelial cells and oralepithelial cells have significantly reduced virulence in mousemodels of hematogenously disseminated or oropharyngeal candidiasis(20, 21, 25). The association between the inability of thesestrains to invade and damage host cells in vitro and their attenuatedvirulence suggests that fungal invasion and damage of endothelialcells and oral epithelial cells contribute to the pathogenesisof hematogenously disseminated and oropharyngeal candidiasis,respectively.

The cell wall represents the initial point of interaction betweenthe host and pathogen. The C. albicans ECM33 gene product ispredicted to be a glycosylphosphatidylinositol (GPI)-linkedcell wall protein (5). Recently, it was found that Ecm33p isrequired for normal cell wall integrity and the yeast-to-hyphatransition in vitro (16). Blastospores of a C. albicans ecm33 ${Delta}$ /ecm33 ${Delta}$ mutant were larger and flocculated more extensively than blastosporesof the wild-type strain. The mutant also exhibited enhancedsusceptibility to compounds, such as calcofluor white and Congored, that interfere with cell wall integrity. In addition, theecm33 ${Delta}$ /ecm33 ${Delta}$ mutant had delayed hypha formation in liquid andsolid media. Consistent with these in vitro defects, this mutanthad severely attenuated virulence in the mouse model of hematogenouslydisseminated candidiasis. Finally, these investigations showedthat both copies of ECM33 were required for a normal phenotype.The phenotype of strains that contained only one copy of ECM33was more similar to that of the homozygous ecm33 ${Delta}$ /ecm33 ${Delta}$ mutantthan to that of strains that contained two copies of ECM33.

We hypothesized that an additional reason Ecm33p is requiredfor normal virulence is that this protein is necessary for specificinteractions of C. albicans with endothelial and oral epithelialcells. Therefore, we investigated the role of Ecm33p in theability of C. albicans to adhere to, invade, and damage endothelialcells and an oral epithelial cell line in vitro.

MATERIALS AND METHODS

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Materials and Methods

Organisms, media, and plasmids. The C. albicans and Saccharomyces cerevisiae strains used inthis study are listed in Table 1. All C. albicans strains weremaintained on YPD (1% yeast extract, 2% peptone, 2% glucose)agar plates at 37°C. This medium was supplemented with 80µg of uridine per ml for growing Ura^– strains. Ura⁺transformants were selected on synthetic complete medium withouturidine (2% glucose, 0.67% yeast nitrogen base without aminoacids, 0.065% synthetic complete supplement mixture withouturidine) (Qbiogene, Carlsbad, CA). To select Ura^– strains,the organisms were grown on synthetic complete medium containinguridine and 0.1% 5-fluoroorotic acid (Zymo Research, Orange,CA). For use in the experiments, all organisms were grown inliquid YPD medium on a rotary shaker overnight at 30°C,harvested by centrifugation, and washed twice in Dulbecco'sphosphate-buffered saline (PBS). The organisms were resuspendedto the appropriate concentration in RPMI 1640 medium (IrvineScientific, Santa Ana, CA).

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TABLE 1. Strains of C. albicans and S. cerevisiae used in this study

Strain construction. The C. albicans ECM33 mutants used in the previous study allhad URA3 integrated at the ECM33 locus (16). The chromosomallocus at which URA3 is integrated can influence the proteomeof C. albicans, its adherence to host cells in vitro, and itsvirulence (2, 4, 28, 29). Therefore, to avoid the potentialconfounding effects of the chromosomal location of URA3 on thephenotypes of the ECM33 mutants, we modified them so that URA3was integrated at its native locus in all strains. The ura3 ${Delta}$ /ura3 ${Delta}$ strains RML1a (ECM33/ecm33 ${Delta}$ ), RML2a (ecm33 ${Delta}$ /ecm33 ${Delta}$ ), and RML3a(ecm33 ${Delta}$ /ecm33 ${Delta}$ ::ECM33) were transformed with a 3.9-kb NheI/PstIfragment encompassing the C. albicans URA3 and adjacent IRO1genes, as described previously (20), to produce RML1U, RML2U,and RML3U, respectively. Integration of the URA3-IRO1 fragmentinto the correct chromosomal locus was confirmed by PCR usingthe primers 5'-TGCTGGTTGGAATGCTTATTTG-3' and 5'-TGCAAATTCTGCTACTGGAGTT-3'.

A Ura^– clone of strain RML4 (ecm33 ${Delta}$ ::ECM33/ecm33 ${Delta}$ ::ECM33)was selected by plating it on 5-fluoroorotic acid. This Ura^–clone was named RML4a. The absence of URA3 in RML4a was confirmedby PCR using the primers 5'-TAGGACGTGACAAGATACAGGATCGCA-3' and5'-GTTTTCCGCCATCGCAATCAGGC-3'. Next, RML4a was transformed withthe URA3-IRO1 fragment as outlined above to make RML4U. Theintegration of URA3 into the correct locus was confirmed bySouthern blotting (Fig. 1).

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FIG. 1. Southern blot analysis of restoration of the URA3 locus in the various C. albicans strains. Genomic DNA from the indicated strains was digested with EcoRI. and the blot was probed with an EcoRI fragment encompassing URA3 and its 3'-flanking region.

Growth rate determination. The doubling times of the C. albicans strains were determinedby growing them in liquid YPD medium on a rotary shaker at 30°C.At 1-hour intervals, an aliquot was removed and sonicated briefly,and then the optical density at 600 nm was measured.

Expression of C. albicans ECM33 in S. cerevisiae. To analyze the effects of expression of C. albicans ECM33 (CaECM33)in S. cerevisiae, the plasmid pYEPCaECM33, which contained theCaECM33 protein coding sequence, 330 bp of promoter sequence,and 495 bp of 3' untranslated region, was used (16). As a control,plasmid pYEPScerevisiaeECM33, containing the protein codingsequence of S. cerevisiae ECM33 (ScECM33), 1,102 bp of promoter,and 565 bp of 3' untranslated region, was used (16). An additionalcontrol was the empty plasmid pYEP352. The plasmids containingCaECM33 and ScECM33 were transformed into strains of S. cerevisiaewith either an intact copy of ScECM33 (strain BY4741) or a disruptedcopy of this gene (strain Y03215) (Table 1).

Endothelial cells and oral epithelial cells. Endothelial cells were isolated from the veins of human umbilicalcords by the method of Jaffe et al. (14). They were grown inM-199 medium (Gibco-BRL, Gaithersburg, MD) containing 10% fetalbovine serum and 10% defined bovine calf serum (both from GeminiBioProducts, Inc., Calabasas, CA), and supplemented with 2 mML-glutamine with penicillin and streptomycin (Irvine Scientific)as described previously (8).

The FaDu oropharyngeal epithelial cell line was purchased fromthe American Type Culture Collection (Manassas, VA). It wasmaintained in Eagle's minimal essential medium with Earle'sbalanced salt solution (Irvine Scientific) adjusted to contain1.5 g/liter sodium bicarbonate, 2 mM L-glutamine, 0.1 mM nonessentialamino acids, and 1.0 mM sodium pyruvate. This medium was supplementedwith 10% fetal bovine serum, penicillin, and streptomycin.

Both cell types were grown at 37°C in a humidified environmentcontaining 5% CO₂ and used at 95% confluence in all experiments.

Endocytosis assay. The number of organisms that were endocytosed by the endothelialcells and FaDu oral epithelial cells was determined using adifferential fluorescence assay exactly as described previously(20, 22). Briefly, endothelial cells or FaDu cells were grownon fibronectin-coated glass coverslips and infected with 10⁵cells of either C. albicans or S. cerevisiae in RPMI 1640 medium.After incubating for 90 min, the cells were rinsed once withHanks' balanced salt solution (Irvine Scientific) and then fixedin 3% paraformaldehyde. The nonendocytosed organisms were stainedwith an anti-C. albicans rabbit serum (Biodesign International,Kennebunkport, ME) conjugated with Alexa 568 (Molecular Probes,Eugene, OR). This antiserum recognizes both C. albicans andS. cerevisiae (27). Afterwards, the FaDu cells were rinsed extensivelywith PBS and then permeabilized with 0.2% (vol/vol) Triton X-100(Sigma-Aldrich, St. Louis, MO) in PBS. Next, the cell-associatedorganisms (the endocytosed plus nonendocytosed organisms) werestained with the anti-C. albicans rabbit serum conjugated withAlexa 488 (Molecular Probes). The coverslips were observed withan epifluorescence microscope. The number of organisms endocytosedby the host cells was determined by subtracting the number ofcell-associated organisms (labeled with Alexa 568, which fluorescesred) from the total number of organisms (labeled with Alexa488, which fluoresces green). At least 100 organisms were countedon each coverslip, and all experiments were performed in triplicate.

Damage assay. The extent of damage caused by the various C. albicans strainsto the endothelial cells and the FaDu cell line was measuredusing a ⁵¹Cr release assay as described previously (1, 20, 21).The host cells were grown in a 96-well tissue culture platewith detachable wells and incubated overnight with Na₂⁵¹CrO₄(MP Biomedicals, Inc., Irvine, CA) per well. The following day,the unincorporated tracer was removed by rinsing. When endothelialcells were used, they were infected with 4 x 10⁴ organisms inRPMI 1640. Because FaDu cells are less susceptible to damageby C. albicans, they were infected with 10⁵ organisms in thesame medium. To measure the spontaneous release of ⁵¹Cr, uninfectedhost cells were exposed to medium alone. After a 3-h incubation,the upper 50% of medium was removed from each well and thenthe wells were manually detached from one another. The amountof ⁵¹Cr in the aspirates and the well was determined by gammacounting. After correcting for the amount of ⁵¹Cr incorporatedin each well, the specific release of ⁵¹Cr was calculated bythe formula (experimental release – spontaneous release)/(totalincorporation – spontaneous release). Experimental releasewas the amount of ⁵¹Cr released into the medium by cells infectedwith C. albicans. Spontaneous release was the amount of ⁵¹Crreleased into the medium by uninfected host cells. Total incorporationwas the sum of the amount of ⁵¹Cr released into the medium andremaining in the host cells.

Transmission electron microscopy. Samples for transmission electron microscopy were prepared accordingto the protocol described by Miret et al. (17). Briefly, 2 x10⁷ blastospores of each strain were collected after 24 h ofgrowth in liquid YPD medium and fixed at 4°C for 24 h in500 µl fixative solution (sodium cacodylate buffer, pH7.2, containing 1.2% glutaraldehyde and 2% paraformaldehyde).The samples were then washed with saline and postfixed for 90min with 1% potassium permanganate. The fixed cells were dehydratedthrough a graded series of ethanol and embedded in Embed 812resin (Electron Microscopy Sciences, Hatfield, PA). Thin sectionswere stained with uranyl acetate and lead citrate and then imagedwith a Zeiss EM902 electron microscope. Multiple cells of eachstrain were imaged.

Detection of Als1p on the surface of C. albicans. The localization of the adhesin, Als1p on the surface of thevarious strains of C. albicans was determined by direct immunofluorescenceusing a modification of our previously described method (10).Briefly, 2 x 10⁵ blastospores of the different C. albicans strainswere incubated for 90 min with endothelial cells on glass coverslipsas in the endocytosis assay. Next, the cells were rinsed oncewith Hanks' balanced salt solution, fixed with 3% paraformaldehyde,and blocked with 1% goat serum containing 1% Triton X-100. Thecells were incubated with an Alexa 488-conjugated murine monoclonalantibody directed against the N terminus of Als1p (10). Afterextensive rinsing with PBS, the cells were stained with theAlexa 568-conjugated rabbit anti-C. albicans antiserum and viewedby confocal microscopy. To enable comparison of the intensityof staining among the different strains, the image acquisitionparameters were set using the wild-type strain and these parameterswere used for imaging all of the other strains. The final confocalimages were produced by combining optical sections taken throughthe z axis.

To determine if some fraction of Als1p was not detected by theanti-Als1p antibody because it was buried in the cell wall,3 x 10⁶ blastospores of the different strains were added toendothelial cells in a six-well tissue culture plate and allowedto germinate for 90 min. Next, the medium was aspirated andreplaced with distilled water to lyse the endothelial cells.The germ tubes were scraped from the wells into 1.5-ml centrifugetubes, fixed in 3% paraformaldehyde for 15 min, and washed twicewith PBS. They were resuspended in KS buffer (0.1 M potassiumphosphate buffer, 1 M sorbitol, pH 7.0,) containing 0.5 unitsof zymolyase (Zymo Research Corporation, Orange, Calif.) perml. The germ tubes were allowed to settle onto poly-L-lysinecoated coverslips where they were incubated for 5 to 30 min.At each time point, the coverslips were washed three times withKS buffer, blocked with 1% bovine serum albumin in PBS, andthen stained with the anti-Als1p monoclonal antibody, followedby the rabbit anti-C. albicans antiserum as above.

Statistical analysis. Differences among the various strains of C. albicans in theirinteractions with endothelial cells and the FaDu oral epithelialcell line were compared by analysis of variance. P values of $≤$ 0.05 were considered significant.

RESULTS

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Results

Strains lacking one or both copies of ECM33 had slower growth rates in vitro than strains containing two copies of ECM33. Strains of C. albicans that grow slowly in vitro frequentlyhave attenuated virulence when tested in the mouse model ofhematogenously disseminated candidiasis (24). Growth rate isalso likely to be an important factor for virulence during oropharyngealcandidiasis. Therefore, we determined the growth rates of blastosporesof the various ECM33 strains in vitro. The doubling time ofall C. albicans strains containing either one or no copies ofECM33 was approximately 50% longer than that of either the wild-typestrain or the ecm33 ${Delta}$ ::ECM33/ecm33 ${Delta}$ ::ECM33 double-complementedstrain (Table 1). Therefore, both copies of ECM33 are criticalfor the normal growth of C. albicans blastospores in vitro andprobably in vivo.

Hyphal formation on endothelial cells and the FaDu oral epithelial cell line is independent of ECM33. The slow growth rates of the ecm33 ${Delta}$ strains precluded a meaningfulanalysis of the contribution of Ecm33p to virulence in relevantanimal models of candidiasis. Therefore, for a surrogate forvirulence studies, we examined the interactions of the ECM33mutants with endothelial cells and an oral epithelial cell linein vitro. Although the organisms were added to these host cellsas blastospores, they began germinating within 45 min. Previously,it was reported that ecm33 ${Delta}$ mutants had filamentation defectson some liquid and solid media (16). Interestingly, we observedthat all of the mutant strains produced normal length hyphaeon the endothelial cells and oral epithelial cells after 90min of incubation (Fig. 2). Therefore, the slow doubling timeof the blastospores did not translate into delayed hyphal formationor elongation under the conditions used in the assays.

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FIG. 2. ECM33 is not required for hyphal formation on endothelial cells, but it does influence the localization of Als1p on the hyphal surface. Endothelial cells were infected with the indicated strains of C. albicans. After 90 min, the cells were fixed and stained with an anti-Als1p monoclonal antibody (green) and an anti-C. albicans antiserum (red). The cells were viewed by confocal microcopy and the images were produced by merging the red and green channels. The white brackets indicate the extent of Als1p expression on the surface of the hyphae.

ECM33 is required for maximal C. albicans adherence to and invasion of endothelial cells and the FaDu oral epithelial cell line. The capacity of each ECM33 mutant strain to adhere to endothelialcells and the FaDu oral epithelial cell line after 90 min ofinfection was investigated. Fewer organisms of the heterozygousecm33 ${Delta}$ /ECM33 mutant were cell-associated (defined as the sumof the adherent and endocytosed organisms) with either typeof host cell compared to the wild-type strain (Fig. 3). Thenumber of cell-associated organisms was even lower when thehost cells were infected with the homozygous ecm33 ${Delta}$ /ecm33 ${Delta}$ strain,suggesting that there was a gene dosage effect. When the homozygousecm33 ${Delta}$ /ecm33 ${Delta}$ strain was complemented with a single copy of wild-typeECM33, the number of organisms that were cell associated witheither type of host cell was similar to that of the heterozygousecm33 ${Delta}$ /ECM33 mutant. Complementing the homozygous ecm33 ${Delta}$ /ecm33 ${Delta}$ strain with two copies of ECM33 resulted in a phenotype thatwas indistinguishable from that of the wild-type strain. Theseresults indicate that both copies of ECM33 are required formaximal adherence to both endothelial cells and oral epithelialcells.

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FIG. 3. Two copies of ECM33 are required for maximal C. albicans adherence to and endocytosis by endothelial cells and FaDu oral epithelial cells. The indicated strains of C. albicans were incubated with either endothelial cells or the FaDu oral epithelial cell line for 90 min, after which the numbers of endocytosed and cell-associated organisms were determined by a differential fluorescence assay. Results are the mean ± standard deviation of three experiments, each performed in triplicate. *, P < 0.01 compared to either the wild-type ECM33/ECM33 or the ecm33 ${Delta}$ ::ECM33/ecm33 ${Delta}$ ::ECM33 strain. ${dagger}$ , P < 0.02 compared to all other strains. $§$ , P = 0.06 compared to the ECM33/ecm33 ${Delta}$ strain and P < 0.02 compared to all other strains. HPF, high-power field.

Strains containing either one or no copies of ECM33 were alsoendocytosed poorly by both endothelial cells and FaDu oral epithelialcells (Fig. 3). The homozygous ecm33 ${Delta}$ /ecm33 ${Delta}$ strain had a greaterendocytosis defect than did the strains containing a singlecopy of wild-type ECM33. Paralleling the adherence results,the endocytosis defect of the ecm33 ${Delta}$ /ecm33 ${Delta}$ :: ECM33 singly complementedstrain was similar to that of the ECM33/ecm33 ${Delta}$ heterozygous strain,whereas the ecm33 ${Delta}$ ::ECM33/ecm33 ${Delta}$ ::ECM33 double-complemented strainhad no endocytosis defect.

For strains containing either one or no intact copies of ECM33,the reduction in endocytosis was greater than the reductionin adherence (Fig. 3). For example, 24% fewer cells of the homozygousecm33 ${Delta}$ /ecm33 ${Delta}$ mutant were cell associated with endothelial cells,compared to the wild-type strain. In contrast, 65% fewer cellsof the ecm33 ${Delta}$ /ecm33 ${Delta}$ mutant were endocytosed by endothelial cellscompared to the wild-type strain. Therefore, the endocytosisdefect of the ecm33 ${Delta}$ strains was not merely the result of decreasedadherence.

ECM33 is essential for C. albicans to cause maximal damage to oral epithelial cells in vitro. We compared the extent of damage caused by the different C.albicans strains to endothelial cells and FaDu oral epithelialcells. Strains containing a single intact copy of ECM33 causedslightly less damage to both types of host cells compared tothe wild-type strain. The homozygous ecm33 ${Delta}$ /ecm33 ${Delta}$ mutant wasthe only strain that consistently caused significantly lessdamage to both endothelial and epithelial cells than did thewild-type strain (P = 0.003 and P < 0.0001, respectively)(Fig. 4).

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FIG. 4. Role of ECM33 in C. albicans-induced damage to endothelial cells and FaDu oral epithelial cells. The indicated host cells were loaded with ⁵¹Cr and then incubated with the indicated strains of C. albicans for 3 h. The extent of host cell damage was measured by the release of ⁵¹Cr into the medium. Results are the mean ± standard deviation of at least independent experiments, each performed in triplicate. *, P < 0.04 compared to both the wild-type ECM33/ECM33 and the ecm33 ${Delta}$ ::ECM33/ecm33 ${Delta}$ ::ECM33 strain. ${dagger}$ , P = 0.03 compared to the ecm33 ${Delta}$ /ECM33 strain and P = 0.19 compared to the ecm33 ${Delta}$ /ecm33 ${Delta}$ ::ECM33 strain. $§$ , P < 0.002 compared to both the ECM33/ecm33 ${Delta}$ and the ecm33 ${Delta}$ /ecm33 ${Delta}$ ::ECM33 strains.

ecm33 ${Delta}$ mutants have aberrant cell wall architecture. There are at least two nonexclusive explanations for the defectsin the interactions of the ecm33 ${Delta}$ mutants with endothelial andoral epithelial cells. Biochemical studies have indicated thatEcm33p is present in the cell wall of C. albicans, and it maybe expressed on the cell surface (5). Therefore, it is possiblethat Ecm33p functions as an adhesin or invasin. However, itis also known that Ecm33p is required for normal cell wall integrityin C. albicans (16). Similarly, in Saccharomyces cerevisiae,Ecm33p is necessary for normal cell wall architecture (19).Thus, it is also possible that Ecm33 is required for the normalfunctioning of other C. albicans cell wall proteins that areadhesins or invasins.

To investigate whether Ecm33p itself mediates adherence to orinvasion of host cells, we expressed either CaECM33 or ScECM33in both a wild-type and an Scecm33 ${Delta}$ mutant strain of S. cerevisiae.We then measured the adherence to and endocytosis of these strainsby the FaDu oral epithelial cell line. For a negative control,we also tested the same strains of S. cerevisiae transformedwith empty plasmid. We found that all strains had similarlylow levels of adherence and endocytosis (data not shown). CaECM33was functional in S. cerevisiae because it reversed the cellwall integrity defects of the Scecm33 ${Delta}$ strain (16). These resultssuggest that Ecm33p by itself is not sufficient to mediate adherenceor endocytosis, at least in S. cerevisiae.

Next, we used transmission electron microscopy to investigatethe structure of the cell walls of the ecm33 ${Delta}$ mutants. Multiplecells of each strain were imaged and several different sectionswere viewed. The wild-type and ecm33 ${Delta}$ ::ECM33/ecm33 ${Delta}$ ::ECM33 double-complementedstrains both had normal cell wall architecture, consisting ofan electron dense outer layer of mannoproteins, and an electronlucent inner layer composed mainly of 1,3 ß-glucanand chitin (Fig. 5A and B). In contrast, the cell walls of allstrains containing either one or no functional copies of ECM33were consistently abnormal. In the strains with only one copyof ECM33, the outer mannoprotein layer of the cell wall wasabnormally wide and electron dense (Fig. 5C and D). In the homozygousecm33 ${Delta}$ /ecm33 ${Delta}$ mutant, not only was the outer layer of the cellwall abnormally electron dense, but the electron lucent innerlayer was also much wider and appeared to be less electron densethan that of the other strains (Fig. 5E and F). These resultsindicate that ECM33 is required for the normal cell wall architectureof C. albicans.

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FIG. 5. ECM33 is necessary for the normal cell wall architecture of C. albicans. Representative transmission electron micrographs of the cell walls of blastospores of the wild-type (A), ecm33 ${Delta}$ ::ECM33/ecm33 ${Delta}$ ::ECM33 (B), ecm33 ${Delta}$ /ECM33 (C), ecm33 ${Delta}$ /ecm33 ${Delta}$ ::ECM33 (D), and ecm33 ${Delta}$ /ecm33 ${Delta}$ (E and F) strains. White, double-headed arrows indicate the thickness of the internal layer of 1,3 ß-glucans and chitin. Open, single-headed arrows indicate the outer mannoprotein layer. Scale bars indicate 100 nm.

ECM33 is necessary for normal Als1p localization on hyphae. The aberrant cell wall architecture of the ecm33 ${Delta}$ mutants suggestedthat there may be alteration in the surface expression or localizationof other proteins in these strains. Therefore, we analyzed theexpression of Als1p on the surface of the various strains byusing direct immunofluorescence with a monoclonal antibody directedagainst the N terminus of Als1p. Als1p is a GPI-linked proteinthat is expressed on the surface of C. albicans hyphae, whereit functions as an adhesin (10, 11, 27). In the wild-type andthe ecm33 ${Delta}$ ::ECM33/ecm33 ${Delta}$ ::ECM33 double-complemented strains, Als1pwas observed to be present in a relatively narrow band at thebase of the hyphae, adjacent to the blastospore-hyphal junction(Fig. 2). In the strains containing a single functional copyof ECM33, this band of Als1p extended slightly further alongthe length of the hyphae. Importantly, in the homozygous ecm33 ${Delta}$ /ecm33 ${Delta}$ mutant, Als1p was expressed diffusely over the majority of thehyphal surface, except at the very tip. Therefore, ECM33 isnecessary for the normal localization of Als1p.

Although Als1p is known to be expressed on the cell surfaceof C. albicans (10), it is possible that some fraction of thetotal pool of Als1p is buried within the cell wall and is thereforenot accessible to the monoclonal antibody that was used to detectthis protein. If this possibility were true, then the aberrantlocalization of Als1p in the ecm33 ${Delta}$ mutants could have been dueto the exposure of some Als1p that is normally inaccessibleto the anti-Als1p antibody. To test this possibility, we incubatedgerm tubes of the wild-type, homozygous ecm33 ${Delta}$ /ecm33 ${Delta}$ mutant,and ecm33 ${Delta}$ ::ECM33/ecm33 ${Delta}$ ::ECM33 double-complemented strain forvarious times in zymolyase to remove the cell wall. After a5-min exposure to this enzyme, there was a slight reductionin the intensity of Als1p staining in all strains. However thedistribution of Als1p along the hyphae of the different strainsremained similar to that of control hyphae that were not exposedto the enzyme (data not shown). Longer exposure to the enzymeresulted in the progressive loss of Als1p staining on all hyphae,but it did not change the distribution of the remaining Als1p.Therefore, the aberrant localization of Als1p in the ecm33 ${Delta}$ strainswas not due to the cell surface expression of protein that wasnormally buried within the cell wall of the wild-type strain.

DISCUSSION

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Discussion

Ecm33p is important for several factors that contribute to thevirulence of C. albicans. One of these factors is growth rate.The growth rate of C. albicans strains is known to have a significanteffect on their virulence in the mouse model of hematogenouslydisseminated infection (24). Although the relationship betweenC. albicans growth rate and virulence during oropharyngeal infectionhas not been reported, it is highly probable that strains thatgrow slowly have attenuated virulence during this infection,as well.

It is unlikely that the slow growth rate of blastospores ofthe ecm33 ${Delta}$ mutants played a significant role in their interactionswith endothelial cells and oral epithelial cells in vitro. Theseorganisms germinated normally on both types of host cells andthe resultant hyphae were of normal length. Previously, it wasreported that ecm33 ${Delta}$ mutants had filamentation defects in bothliquid and solid media (16). However, these prior experimentswere performed under different conditions from the ones usedin the current studies. Also, the previous ecm33 ${Delta}$ mutants hadURA3 integrated at a different chromosomal locus. Thus, ourcurrent results are not directly comparable to the previousdata.

We observed that hyphae of the ecm33 ${Delta}$ mutants adhered to andwere endocytosed poorly by both endothelial cells and oral epithelialcells. The adherence defect of these mutants was not as greatas their endocytosis defect, indicating that their reduced endocytosiswas not solely the result of decreased adherence.

Ecm33p is located in the C. albicans cell wall, and it is knownto be important for cell wall integrity (5, 16). We found thatthe ecm33 ${Delta}$ strains had markedly aberrant cell wall architecturewith an abnormally electron dense outer mannoprotein layer.We speculate that the enhanced mannoprotein synthesis in thesemutants may represent a compensatory response to a weakenedcell wall. This abnormal mannoprotein layer likely contributedto the reduced adherence and endocytosis of the ecm33 ${Delta}$ strainsby interfering with the normal expression and/or function ofC. albicans adhesin and invasin proteins. Consistent with thistheory, we found that the Als1p adhesin was abnormally distributedon the surface of the ecm33 ${Delta}$ strains, probably as a result ofeither abnormal trafficking of Als1p or prolonged ALS1 geneexpression. Furthermore, we found no evidence that Ecm33p byitself was able to mediate adherence or invasion of oral epithelialcells.

The ecm33 ${Delta}$ mutants also had diminished capacity to damage oralepithelial cells. Because endocytosis is required for C. albicansto damage endothelial cells and FaDu oral epithelial cells (8,20), the decreased host cell damage caused by the ecm33 ${Delta}$ mutantsis likely due in part to the reduced endocytosis of these strains.It is also possible that the ecm33 ${Delta}$ mutants have reduced secretionof lytic enzymes, such as secreted aspartyl proteases and phospholipases(12, 13, 26), which contributed to the host cell damage defectof these mutants.

A notable finding was that the phenotype of strains that stillpossessed one functional copy of ECM33 was much closer to thephenotype of the strain that had no functional ECM33 than tophenotype of the strains containing two copies of ECM33. PreviousNorthern blot analysis of ECM33 transcript levels in the variousstrains confirmed that strains containing one intact copy ofECM33 expressed approximately 50% less ECM33 mRNA than did strainscontaining two intact copies of ECM33 (16). Although the exactamount of Ecm33p expressed by these stains is currently unknown,it is likely that at least some of this protein is expressedby strains containing a single functional copy of ECM33. Therefore,there appears to be a critical threshold of cellular Ecm33pcontent. When the amount of Ecm33p drops below this threshold,there is a significant alteration in cell wall architectureand growth rate. These changes result in a reduction in virulence-relatedtraits, including the capacity of C. albicans to adhere to,invade, and damage host cells. Why Ecm33p is so vital for C.albicans pathogenicity is currently under investigation.

ACKNOWLEDGMENTS

We thank Norma Solis and Quynh Trang Phan for help with tissueculture studies, Donald Sheppard for invaluable discussion,and the perinatal nurses at the Harbor-UCLA Medical Center PediatricClinical Research Center for collection of umbilical cords.

This work was supported in part by grants R01DE013974, DE017088,R01AI054928, R01AI19990, and MO1RR00425 from the U.S. NationalInstitutes of Health and by BIO 2003-00030 from the ComisionInterministerial de Ciencia y Tecnolog $y$ a (CYCIT, Spain), andCPGE 1010/2000 for Strategic Groups from Comunidad Autonomade Madrid. Raquel Martinez-Lopez is the recipient of a fellowshipfrom the Ministerio de Educacion y Ciencia de España.

FOOTNOTES

* Corresponding author. Mailing address: Division of Infectious Diseases, Los Angeles Biomedical Research Institute at Harbor-UCLA Medical Center, 1124 W. Carson St., Torrance, CA 90502. Phone: (310) 222-3813. Fax: (310) 782-2016. E-mail: sfiller{at}ucla.edu.

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