Induction of Capsule Growth in Cryptococcus neoformans by Mammalian Serum and CO2

The pathogenic fungus Cryptococcus neoformans has a polysaccharidecapsule that is essential for virulence in vivo. Capsule sizeis known to increase during animal infection, and this phenomenonwas recently associated with virulence. Although various conditionshave been implicated in promoting capsule growth, includingCO₂ concentration, osmolarity, and phenotypic switching, itis difficult to reproduce the capsule enlargement effect inthe laboratory. In this study, we report that serum can inducecapsule growth, and we describe the conditions that induce thiseffect, not only by serum but also by CO₂. Capsule enlargementwas dependent on the medium used, and this determined whetherthe strain responded to serum or CO₂ efficiently. Serum wasmost effective in inducing capsule growth under nutrient-limitedconditions. There was considerable variability between strainsin their response to either serum or CO₂, with some strainsrequiring both stimuli. Sera from several animal sources wereeach highly efficient in inducing capsule growth. The cyclicAMP (cAMP) pathway and Ras1 were both necessary for serum-inducedcapsule growth. The lack of induction in the ras1 mutant wasnot complemented by exogenous cAMP, indicating that these pathwaysact in parallel. However, both cAMP and Ras1 were dispensablefor inducing a partial capsule growth by CO₂, suggesting thatmultiple pathways participate in this process. The ability ofserum to induce capsule growth suggests a mechanism for thecapsular enlargement observed during animal infection.

INTRODUCTION

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Introduction

The yeast Cryptococcus neoformans is a human pathogen that isubiquitous in certain environments, such as soil contaminatedwith pigeon excreta. Human infection is believed to result frominhalation of infectious particles and, in some areas, 50 to70% of individuals have antibodies against C. neoformans. However,cryptococcal disease in normal hosts is rare (22). Althoughmost cases of human infection with C. neoformans are not recognizedclinically, the infection can become latent and/or disseminatein the setting of immune impairment. The most common clinicalmanifestation of cryptococcosis is meningitis, a condition thatis lethal unless treated.

C. neoformans has several virulence factors (for review, seereference 12), including a capsule, which is mainly composedof the polysaccharide glucuronoxylomannan (GXM). The size ofthe capsule of C. neoformans is variable, ranging from 5 to30 µm (19, 43) and varying between strains (38). In soilsand under laboratory conditions, the capsule size of most C.neoformans strains is relatively small but can increase duringmammalian infection (5, 14, 33). Littman showed that the sizeof the capsule was highly variable and dependent on the environmentalconditions (32). During in vivo infection, the size of the capsulevaries depending on the organ studied. For instance, the lungenvironment is a powerful inducer of capsule growth (43). Anothercompartment that induces capsule growth, although not as efficientlyas the lung, is the brain (18, 43). There are several reportsindicating that the induction observed in vivo contributes tothe virulence of the pathogen. Strains unable to induce capsulegrowth showed reduced virulence (3, 16, 23). In this regard,increase in capsule size has been associated with resistanceto phagocytosis (8, 30, 37). But paradoxically, there is nocorrelation between capsule size at the moment of infectionand virulence (3, 16, 24, 28). Several conditions induce capsulegrowth in vitro (for review, see reference 36). The most commonlyused are high CO₂ concentration (23) and iron deprivation (25,46). Other factors have also been described, such as availabilityof vitamins, the amino acids present, the type of carbon source(32) and osmolarity (17, 27). Unfortunately, it is difficultto achieve capsule growth under laboratory conditions, and notall the strains respond to these stimuli. Consequently, thisphenomenon has not been extensively studied despite its relevanceto cryptococcal infection.

The phenomenon of capsular growth is believed to be relevantbecause it increases the size of the cell and thus poses a problemfor phagocytosis (29, 51). Furthermore, the capsule and thecapsular polysaccharide interfere with a large number of processesinvolved in the immune response (15, 29, 34, 42, 47). The capsuleis required for virulence, since acapsular mutants are avirulent(13, 21), and it is also necessary for survival inside phagocyticcells (45). However, several reports suggest that it is notnecessary for protection in killing assays (9, 31).

Prior studies have shown that serum can have an inhibitory effecton yeast growth (41). However, studies about the effect of serumon capsule size are scarce (4), and it is not clear whetherit can be used as a modulator of capsule growth. Here we demonstratethat sera from multiple sources can be potent inducers of capsulegrowth. We have also analyzed the requirement of CO₂ and gainedinsight into the putative pathways involved in this process.We conclude that both serum and CO₂ induce capsule growth andthat this induction is also controlled by additional environmentalfactors.

MATERIALS AND METHODS

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Materials and Methods

Strains and growth conditions. C. neoformans strains are listed in Table 1. Additionally, tostudy the role of cyclic AMP (cAMP) and Ras1 pathways, the followingstrains, kindly provided by J. Heitman, were used: RPC3 (cac1::URA5[3]), RPC7 (cac1::URA5 CAC1 [3]), CDC1 (pka1::URA5 [16]), CDC16(pka1::URA5 PKA1 [16]), LCC1 (ras1::ADE2 [1]), and LCC2 (ras1::ADE2RAS1 [1]). For each strain, the cells were grown overnight inSabouraud dextrose broth medium (Difco, Sparks, Md.) at 30°Cin a rotating shaker with moderate agitation (150 to 180 rpm).The cells were collected, washed three times with phosphate-bufferedsaline solution (PBS), and counted with a hemocytometer.

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TABLE 1. Induction of capsule growth by serum and CO₂

Capsule growth induction. To study capsule growth, the yeast cells were incubated at 37°Cfor the time interval indicated in one of the following media:PBS, Sabouraud dextrose broth, or Dulbecco's modified Eaglemedium (DME; Life Technologies, Rockville, Md.). As serum source,10% heat-inactivated fetal calf serum (FCS) was used in allexperiments unless otherwise indicated. In some experiments,10% human, rat, mouse, or guinea pig serum was used. Inactivationof sera was performed by incubation at 56°C for 30 min.The yeast cells (around 2 x 10⁶ to 4 x 10⁶) were placed in six-wellplates containing 2 ml of medium and incubated at 37°C inthe absence or presence of 10% CO₂. To supplement the mediawith iron, EDTA-ferric sodium salt (Sigma, St. Louis, Mo.) wasadded at the concentration indicated in each case. For someexperiments, the pH of the medium was adjusted with HCl or NaOH.Since incubation of the yeast did not significantly change thepH of the medium (most probably due to the low density of thecells used), no additional buffer was required. In some experiments,cAMP (Sigma Aldrich) was added at a final concentration of 10mM.

India ink staining and microscopy. To visualize the size of the capsule, a drop of India ink wasadded to the cell suspension on the slide. The samples wereobserved in an Olympus AX70 microscope. Pictures were takenwith a QImaging Retiga 1300 digital camera using the QCaptureSuite V2.46 software (QImaging, Burnaby, British Columbia, Canada)and processed with Adobe Photoshop 7.0 for Windows (San Jose,Calif.).

Measurement of capsule volume. To calculate the capsule volume, the diameters of the wholecell (D_wc) and the cell body (D_cb) were each measured with AdobePhotoshop 7.0, and capsule volume was defined as the differencebetween the volume of the whole cell (yeast cell plus capsule)and the volume of the cell body (no capsule). Volumes were determinedusing the equation for volume of a sphere as 4/3 x ${pi}$ x (D/2)³.In parallel, a relative measurement was calculated by representingthe percentage of capsule in the whole cell as follows: [(D_wc- D_cb) x 100]/D_wc. Between 15 and 40 cells were measured foreach determination.

Immunofluorescence. To detect the capsule of C. neoformans, a monoclonal antibodyto GXM 18B7 (11) and a goat anti-mouse (GAM) immunoglobulinG conjugated to tetramethylrhodamine isothiocyanate (TRITC)were used. Briefly, cells were incubated in 1% bovine serumalbumin-0.5% horse serum for 1 h at 37°C, washed, incubatedwith primary antibody 18B7 (10 µg/ml [11]) for 30 minat 37°C, washed, and incubated with GAM-immunoglobulin G-TRITC(5 µg/ml; Southern Biotechnology Associates, Inc., Birmingham,Ala.). After incubation at 37°C for 1 h and a final wash,the cells were suspended in mounting medium (50 mM n-propylgallate,50% glycerol in PBS) and observed with an Olympus AX70 microscope.To detect complement bound to the C. neoformans capsule, theyeast cells were grown in Sabouraud and washed with PBS, and2 x 10⁶ cells were suspended in 80 µl of mouse serum.After 1 h of incubation at 37°C, the cells were washed andincubated for 24 h in PBS plus 10% FCS at 37°C. To detectcomplement fluorescein-conjugated antibody (C), the yeast wasincubated in 1% bovine serum albumin-0.5% horse serum for 1h at 37°C, washed, incubated with conjugated GAM-complement(5 µg/ml; Cappel, ICN, Aurora, Ohio) for 30 min at 37°C,and visualized under the microscope after suspension in themounting medium described above.

Statistics. The data were assessed for normal distribution by using theShapiro-Wilk test. For measurements where the data were normallydistributed, statistical analysis was done with an analysisof variance and t test. For measurements where the data werenot normally distributed, statistical analysis was done by usingthe Kruskal-Wallis statistic. P values of <0.05 were consideredsignificant. All the statistics were performed with the Unistat5.5 (Unistat Ltd., London, England) and Analyze-it (Analyze-itLtd., Leeds, England) software for Excel.

RESULTS

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Results

Effect of serum, CO₂, and growth medium on capsule growth induction. Although serum is known to induce morphological changes in otherfungi, such as the phenomenon of germ tube formation in Candidaalbicans, exposure to serum is not generally believed to affectC. neoformans. While carrying out other studies in our laboratory,we noted that under certain conditions media containing 10%heat-inactivated FCS induced a significant increase in capsulesize. To characterize this phenomenon systematically, we studiedthe effect of both serum and CO₂ in the induction of capsulegrowth. We examined capsule growth of strain H99, because thisstrain was used in prior capsule studies (19, 23, 40) and mostof the auxotrophic mutants are derived from this strain (39,48). Under laboratory growth conditions, the capsule of H99has a relatively small size, which is in marked contrast tothe large capsule variants observed during murine infection(19). We first studied the capsule induction in the presenceand/or absence of CO₂ and/or 10% heat-inactivated FCS. Capsuleinduction was studied in three different media: PBS, Sabouraud,and DME. As shown in Fig. 1A, in the absence of CO₂ serum induceda prominent capsule in strain H99 when the cells were incubatedin PBS, indicating that serum alone is a potent inducing factorfor capsule growth. However, when H99 was cultured in Sabouraudor DME, serum did not induce capsule growth. We repeated thisexperiment, but in an atmosphere containing 10% CO₂. In DME,capsule growth occurred in response to CO₂, even in the absenceof serum. This result indicated that the growth medium affectedthe ability to induce capsule growth and suggested the needfor additional stimuli. Most of the experiments described inthis paper were carried out in PBS because its composition isdefined, and in this solution the effect of serum on capsulegrowth was prominent. Serum induced capsule growth at concentrationsof 5% or higher, whereas below 5% the proportion of cells exhibitingincreased capsule size was very small. Hence, we selected aserum concentration of 10% as our standard, because at thisconcentration strain H99 consistently demonstrated induced capsulegrowth. The induction of capsule growth was noticeable afteronly 6 h of incubation in inducing medium. Full induction ofcapsule growth, however, required 24 h (results not shown).The kinetics of capsule growth were not affected by incubationin CO₂.

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FIG. 1. Effect of the medium in the induction of the C. neoformans capsule by serum and/or CO₂. Strain H99 was grown in Sabouraud overnight, washed with PBS, and suspended in different media (PBS, Sabouraud, or DME) containing 10% heat-inactivated FCS as indicated in Materials and Methods. Two equivalent sets of media were prepared: one was placed at 37°C (A), and the other one was placed at 37°C in an atmosphere containing 10% CO₂ (B). The panels show C. neoformans cells in a suspension of India ink particles after 24 h of incubation. In both panels A and B, the bar in the first panel denotes 10 µm and is applicable to the other panels.

Sera from fetal calf, mouse, human, rat, and guinea pig inducedcapsule growth (Fig. 2). There were no significant differencesin the capsule volume of cells incubated in sera from differentanimals; however, there were small differences between mammaliansera, with rat and human sera being the most and less effective,respectively. Heat inactivation of serum had no effect on capsuleinduction (results not shown), suggesting no role of complementin the induction process.

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FIG. 2. Efficiency of different sources of serum in the induction of capsule growth. H99 was placed in PBS (A) or PBS containing 10% of the following sources of serum: FCS (B), mouse (C), human (D), rat (E), and guinea pig (F). Pictures of the cells suspended in India ink particles were taken after overnight incubation at 37°C.

Effect of pH and temperature on the serum-induced capsule growth. Several reports have indicated that capsule induction is a pH-dependentphenomenon (18, 23, 44). We observed that in the media in whichthe size of capsule increased, the pH was higher than 7. Thissuggested that a pH higher than 7 was necessary to induce capsulegrowth. However, pH was not a sufficient stimulus to inducecapsule growth, since in a medium such as DME (pH around 7.5),serum did not induce capsule growth in the absence of CO₂. Toinvestigate the effect of pH, we adjusted the pH to 5.6, fromthe slightly alkaline value of 7.3 found under our inductionconditions (PBS plus serum). However, at a pH of 5.6, the serumdid not efficiently increase capsule size, with only 15% ofthe cells having a large capsule, which was defined as a diameterof more than 45% of the total volume of the cell, capsule included(Fig. 3A).

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FIG. 3. Effect of pH on capsule growth. (A) Strain H99 was grown in Sabouraud and in the logarithmic phase cells were transferred to PBS, PBS plus 10% heat-inactivated FCS (pH 7.4), or the previous medium with the pH adjusted to 5.6 with HCl. After incubating overnight, the proportion of the size occupied by the capsule in the whole cell was calculated as described in Materials and Methods, measuring at least 100 cells in each case; the average and standard deviation are plotted in the left panel. Asterisks denote statistical differences between the size of the capsule after growth in Sabouraud medium and after incubation under the rest of the conditions, using the t test or Kruskall-Wallis test, dependent on the normality of the distribution of the samples. (B) H99 was grown as described for panel A but transferred to Sabouraud, Sabouraud plus 10% heat-inactivated FCS, or Sabouraud plus 10% FCS with pH adjusted to 7.5 with NaOH. The size of the capsule was calculated and is represented as described for panel A. Statistical differences are noted with an asterisk and were calculated as described for panel A.

Given the inefficiency of capsule induction by serum at pH 5.6,we investigated whether the lack of capsule growth in serum-supplementedSabouraud medium was due to the acidic pH of this medium (range,5.5 to 6). Consequently, we adjusted the pH of Sabouraud mediumto 7.5 and studied serum induction. After incubation with theyeast, the pH of the suspension dropped to 7, but only a smallproportion of cells (around 15%) demonstrated an increase incapsule size. However, statistical analysis indicated that theproportion of capsule in the cells after overnight incubationin Sabouraud without agitation in the presence or absence ofserum decreased slightly (Fig. 3B). This indicates that in Sabouraudmedium the lack of capsule induction was not due to the lowpH of the medium.

The effect of temperature on capsule growth was studied. Asshown in Fig. 4A, serum induced capsule growth at 24, 30, and37°C, but the volume of the capsule was significantly largerat 37°C. However, the differences between the absolute volumesdid not correlate with differences in the relative amount ofcapsule compared to the size of the cell. As shown in Fig. 4B,the percentage of the capsule after induction was very similarat all temperatures. To investigate the discrepancy betweenthe data referred in volume or in percentage, we correlatedthe volume and the diameter with the size of the cell and foundpositive correlations between both parameters (Fig. 4D). Theapparent discrepancy arises because the size of the cell bodyis smaller at lower temperatures (Fig. 4C). So, we concludethat temperature does not have any effect on the proportionof capsule produced by the cell, but it does affect the sizeof the cell body.

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FIG. 4. Effect of temperature on capsule induction. Strain H99 was grown in Sabouraud (open bars), and capsule was induced by transferring the cells to PBS containing 10% heat-inactivated FCS and incubating at 24, 30, or 37°C for 24 h (black bars) or 48 h (grey bars). After induction, capsule volume (A), relative size of the capsule (B), and cell volume (C) were calculated as described in Materials and Methods. The mean and standard deviation in each case of at least 25 cells are indicated in panels A to C. (D) Correlation between cell body and total cell diameter (cell body plus capsule). The equation and the R² and P values for each regression are also indicated.

Capsule growth in the presence of serum and CO₂ is highly strain dependent. Prior studies have noted differences in capsule growth amongstrains (19, 23, 32). To investigate this possibility, we comparedcapsule induction among various strains, including 24067 (serotypeD) and H99 (serotype A). Strain 24067 exhibited two major differencescompared to H99. First, it manifested capsule growth in PBSin the presence of CO₂, without serum and additional nutrients(Table 1). Second, induction of capsule growth in strain 24067was accompanied by a great heterogeneity in cell size and shape,such that cells with big capsules were mixed with other cellswith a very small size of both cell body and capsule. In contrast,capsule induction in H99 produced a more homogenous population,with more than 95% of the cells demonstrating large capsules.We found that the cells that were placed in the induction mediumhad increased capsule size, and the small cells with small capsuleswere buds originated during the overnight incubation. We confirmedthis finding by labeling the cells at the beginning of the incubationwith C, which binds covalently to the capsule and can be easilyvisualized by immunofluorescence using an anti-C fluoresceinisothiocyanate-conjugated antibody and does not segregate tothe daughter cells. After overnight incubation in serum, noneof the cells with a small capsule had C labeling, whereas morethan 90% of the cells with a large capsule had C bound to thecapsule (results not shown).

Capsule induction by serum and CO₂ was studied in other serotypeA, B, C, and D C. neoformans strains. We found great variabilityin the response of different strains to the stimuli for capsuleinduction (Table 1). Serum strongly induced capsule growth inmost serotype A strains, whereas for strains of this serotypeCO₂ had little or no effect. In contrast, most of the serotypeB strains responded very efficiently to either CO₂ or serum,and the combination of both stimuli induced a strong increasein capsule size for five of six strains. However, the serotypeC strains studied did not respond to serum but did manifestincreased capsule growth when exposed to CO₂. Serotype D strainsdemonstrated considerable variability in response to both serumand CO₂. For two strains (24067 and 13), both serum and CO₂efficiently induced the capsule, whereas this induction wasabsent in other serotype D strains. We considered the possibilitythat the inability of serum to induce capsule growth for somestrains was due to a limiting concentration of serum. Hence,we repeated the experiments using 100% FCS with seven differentstrains that did not respond to serum, but we did not observeinduction of capsule growth (results not shown). This resultsuggested that the inability of some strains to respond to serumwas due to the genetic background of the strains and not tothe experimental conditions used.

Serum-induced capsule growth is not due to iron limitation. Iron limitation can stimulate capsule growth (46). Since serumcontains iron-binding proteins that sequester iron, we exploredwhether the phenomenon of serum-induced capsule growth was dueto iron limitation. Supplementation of serum-containing mediumwith different concentrations of iron did not inhibit the inductionof capsule growth regardless of the presence or absence of CO₂(Fig. 5).

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FIG. 5. Effect of iron on the induction of capsule by serum. Cells from strain H99 were placed on 10% heat-inactivated FCS containing different amounts of ferric-EDTA in the absence or presence of 10% CO₂. Controls without iron and without serum were also studied. The average and standard deviation of capsule volume (A) and relative size of the capsule (B) under various conditions where FCS was supplemented with Fe are represented. Open bars denote the data of cells incubated in the absence of CO₂, and closed bars denote that in cells incubated in 10% CO₂.

The cAMP pathway and RAS1 are involved differently in the serum- and CO₂-induced capsule growth. cAMP is necessary to increase capsule size under conditionsof iron limitation (3, 16). Hence, we investigated whether thispathway was involved in induction of capsule growth by studyingthe responsiveness of mutant strains lacking the adenylate cyclase(CAC1) and the cAMP-dependent protein kinase (PKA1) to serumand CO_2. When cells from these mutant strains were incubatedin 10% FCS, no capsule growth was observed (Fig. 6). Since inductionof capsule growth by serum was not observed in these mutantstrains, we investigated whether capsular polysaccharide waspresent by indirect immunofluorescence using a monoclonal antibodyto GXM. All the mutants were positive for the staining, indicatingthe presence of a capsule. Hence, absence of capsule inductionwas not a consequence of a lack of an encapsulated phenotype.Measurement of capsule volume and relative size of mutant strainsunder conditions of capsule growth induction revealed no significantdifferences relative to cells in the control media (Fig. 7A and B).In contrast, when CO₂ was used as a stimulus for capsulegrowth, both cac1 and pka1 cAMP mutants manifested capsule growthcompared to control condition, although the induction was significantlylower than that observed in the reconstituted or wild-type strains(Fig. 6 and 7C and D).

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FIG. 6. Role of the cAMP pathway and Ras1 on serum- and CO₂-induced capsule growth. (A) The strains H99, RPC3 (cac1), RPC7 (cac1 CAC1), CDC1 (pka1), CDC16 (pka1 PKA1), LCC1 (ras1), and LCC2 (ras1 RAS1) were incubated in the presence of 10% CO₂ in DME medium or in PBS containing 10% heat-inactivated FCS in the absence of CO₂. The pictures show cells in a suspension of India ink after incubation for 24 h, and the scale bar in the first picture (10 µm) applies for the rest of the pictures in the rest of the column.

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FIG. 7. Capsule size after serum- and CO₂-induced capsule growth in mutant strains of the cAMP and Ras1 pathways. Histograms in panels show capsule sizes of the mutant cells described in the legend for Fig. 6. The bars denote the mean and standard deviation of at least 20 cells after growth in Sabouraud (open bars), after 24 h of incubation (closed bars) in PBS plus 10% heat-inactivated FCS (A and B), or in DME and 10% CO₂ (C and D). Determined as described in Materials and Methods, results in panels A and C represent the absolute capsule volume and results in panels B and D represent the relative size of the capsule. Asterisks denote statistical differences (P < 0.05) in capsule size between time zero and 24 h of induction.

We also studied the role of Ras1 in the serum- and CO₂-inducedcapsule growth. RAS1 encodes a G-protein which has been mainlyinvolved in C. neoformans in the control of the mitogen-activatedprotein kinase pathway (49). In the presence of serum, ras1mutant cells failed to induce capsule growth (Fig. 6 and 7A and B).These experiments were performed at 37°C, a temperaturewhere ras1 mutants show impaired growth (1). So, we repeatedthis experiment at room temperature and 30°C, but ras1 mutantcells did not manifest capsule growth at the lower temperatures.When CO₂ was used as inducing factor, ras1 mutant cells inducedsignificant capsule growth (Fig. 6), although the size was smallerthan the size of the complemented strain (Fig. 7C and D).

We considered that the lack of serum-induced capsule growthfor the ras1 mutants could reflect a defective cAMP pathway,which would involve an activation of the adenylate cyclase byRas1. Hence, we studied the capsule induction by serum of ras1mutant cells in the presence of exogenous cAMP. Addition ofcAMP increased capsule size in the wild-type strain comparedto the control without cAMP, but it did not have any effecton the behavior of the ras1 mutant (results not shown), suggestingthat a defective cAMP pathway was not the cause of the lackof capsule induction by serum in the ras1 mutant.

DISCUSSION

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Discussion

Capsule growth is a morphological response of C. neoformansto a variety of stimuli, including infection of mammalian hosts.Here we report that incubation of C. neoformans in serum inducesan increase in the capsule volume. Furthermore, we have studiedthe relationship between this phenomenon and other stimuli thatare known to induce capsule growth, such as iron and CO₂ levels.To our knowledge, the serum induction phenomenon was unknownin the cryptococcal field. Previous studies have used a serum-containingmedium to induce the capsule size (6, 7), but neither demonstratedthat the effect was due to serum. In fact, both studies employedconditions that included other factors that can increase capsulesize, such as a 5% CO₂ atmosphere. Other studies (4, 32) reportedno induction of capsule growth when using human pooled serum,although one of these reports (4) described capsule inductionby lyophilized rabbit coagulase plasma.

One striking finding of the serum inducing effect was its dependenceon the composition of the medium. When cells were incubatedin PBS with serum, capsule growth was induced, whereas in Sabouraudmedium no increase in capsule size was observed. Dykstra etal. (17) reported that a high concentration of glucose (16%)repressed capsule induction, and they correlated this phenomenonto changes in osmolarity. However, Littman observed that thecapsule induction by thiamine was not prevented by the additionof 10% glucose (32). We do not think that this explanation isrelevant to our observations, since the glucose concentrationunder our conditions was lower (2%). With regards to inductionby CO₂, Granger et al. (23) demonstrated that capsule inductionby CO₂ only occurred in DME with 22 mM NaHCO₃. Although we didnot find that the addition of NaHCO₃ to the DME was requiredfor capsule growth, this discrepancy could be due to the differentCO₂ concentrations used in each study. Furthermore, it is conceivablethat the requirement for NaHCO₃ is not applicable to all C.neoformans strains. The dependence of the phenomenon on thecomposition of inducing medium may explain why the serum-inducedcapsule growth has not been reported before, despite the factthat C. neoformans is commonly incubated in solutions containingserum during immunological studies.

Another factor that influences capsule growth is the pH of themedium. Solutions with a pH lower than 7 inhibited the inductionof capsule growth. This is consistent with the fact that allthe media reportedly used to induce capsule growth (such aslow-iron medium) have a pH around 7.3. The importance of thepH has been previously noted (18, 23, 44), and it is known thata basic pH can enhance capsule growth (17) and affect the morphologyof the colonies on plates. Although a pH higher than 7 is requiredto induce capsule growth by serum, it is not a sufficient condition,since increasing the pH in media that do not allow capsule growthin the presence of serum, such as Sabouraud, did not resultin larger capsules. The mechanism by which pH regulates capsulegrowth is not known, but in other organisms, such as C. albicans,morphological transitions are pH dependent (10). Sera from eachof the four different mammalian species tested induced capsulegrowth. This result suggests the existence of a common inducingfactor in mammalian sera. We noted some differences in the efficiencyof the capsule growth induction, which could be related to differencesin the concentration of the inducing compound. Littman studiedthe assimilation of most of the cerebrospinal fluid componentsby C. neoformans and their effect on capsule size (32). He reportedthat the most common lipids found in nervous tissue did notaffect capsule size in vitro, whereas glutamic acid did inducecapsule size. One of the most abundant proteins in serum isalbumin, and we studied its role on capsule growth but did notfind any effect of this protein (results not shown). Iron deprivationis one of the main factors that induces capsule growth (46).In our study, iron deprivation did not explain the capsule induction,since addition of saturating concentrations of iron did notprevent the induction. The identification of the inducing compoundpresent in the serum is an important future goal that is outsidethe scope of this study.

While evaluating the role of temperature in the capsule growthprocess, we noticed a strong correlation between capsule sizeand cell size. Although at 37°C there was a larger capsulevolume, the percentage of volume corresponding to the capsulewas the same in all the cases. This result is in agreement withprevious work that indicated that a shift from 24 to 37°Cdid not affect the proportion of capsule present in the cells(25). This suggests that in some strains the cell regulatesthe size of the capsule after induction. This is potentiallya very interesting finding, because it implies the existenceof mechanisms to control capsule size and thus avoid unlimitedgrowth of the capsule. With regards to cell size, a potentialcontrol mechanism is cell cycle. In other yeast (50), the sizeof the cell determines the moment of cell division, and it isconceivable that in C. neoformans the process of capsule growthinduction by serum is regulated not only by the cell size butalso by the capsule size.

We observed considerable interstrain variability with regardsto the response to serum. In general, serotype A and B strainsmanifested fewer interstrain differences. However, serotypeD strains were highly variable in their response to serum. Forsome serotype D strains, such as 24067, we observed the simultaneouspresence of macro- and microforms in the inducing medium. Similarmicroforms and heterogeneity have been described in vivo (19).Under our conditions, this heterogeneity was probably causedby the absence of capsule induction by the daughter cells arisingduring the incubation in serum. We do not have an explanationfor this phenomenon, but it could represent phenotypic switchingor changes in the medium during the incubation of the yeast,which would make this medium no longer efficient in inducingcapsule size for the new cells produced. For other strains,such as H99, the presence of serum induced a homogenous response,although it has been reported that H99 can undergo a great variabilityafter long incubations under conditions of capsule growth (23).The interstrain differences indicate the importance of the genotypefor the capsule growth response. Our results establish greatinterstrain variation in capsule growth in response to serum,CO₂, and the inducing medium components. Consequently, the optimalconditions for each strain must be determined empirically.

cAMP is involved in C. neoformans capsule growth under low-ironconditions (2, 3, 16). Hence, we studied whether this pathwaywas required for induction of capsule growth by serum or CO₂.The cAMP pathway and Ras1 were each essential for inductionof capsule growth by serum. Since Ras1 seems to act mainly througha cAMP-independent pathway (mitogen-activated protein kinasepathway [1]), we interpret this result as implying that seruminduction is required for the interplay of several independentpathways. However, although reduced, some degree of capsulegrowth was found in the presence of CO₂ in the cAMP and ras1mutants. Hence, RAS1 seemed to play a role under these conditions,even though ras1 mutants have impaired growth at 37°C (1).It is possible that the putative role of Ras1 is performed underthese conditions by the homolog Ras2 (48). On the basis of theobservations with the various mutants, we conclude that CO₂-inducedcapsule growth can occur through different pathways. At thispoint, we cannot distinguish whether both cAMP and Ras1 pathwayscooperate as different but overlapping pathways or if thereis another different pathway involved in the induction. Interestingly,induction of capsule growth by a low iron concentration seemsto involve only the activation of the cAMP pathway, withoutany involvement of Ras1 (3, 16). This indicates that the growthof the capsule responds to different stimuli that are integratedby different pathways of the cell which, according to the conditions,will act in an overlapping manner or, in some other way, cooperateto increase capsule size efficiently.

Our results establish that capsule growth is induced in C. neoformansstrains by mammalian sera. This effect may contribute to virulenceby promoting the induction of large capsule variants after animalinfection. Depending on the C. neoformans strain, this effectis independent of, or can be enhanced by, CO₂. Serum-mediatedgrowth of the C. neoformans capsule provides a potential explanationfor the observation that cells in tissue often manifest largecapsules that are not evident when grown in fungal media invitro.

ACKNOWLEDGMENTS

We thank J. Heitman (Duke University, Durham, N.C.) for thegift of strains and A. Telzak for careful reading of the manuscript.

This work was supported by the following National Institutesof Health grants: HL59842, AI33142, and AI33774.

FOOTNOTES

* Corresponding author. Mailing address: Departments of Medicine and Microbiology and Immunology, Albert Einstein College of Medicine, 1300 Morris Park Ave., Bronx, NY 10461. Phone: (718) 430-3665. Fax: (718) 430-8701. E-mail: casadeva{at}aecom.yu.edu.

Editor: T. R. Kozel

REFERENCES

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