Enhanced Killing of Candida albicans by Human Macrophages Adherent to Type 1 Collagen Matrices via Induction of Phagolysosomal Fusion

Candida albicans, a component of the normal flora of the alimentarytract and mucocutaneous membranes, is the leading cause of invasivefungal disease in premature infants, diabetics, and surgicalpatients and of oropharyngeal disease in AIDS patients. As littleis known about the regulation of monocyte/macrophage anti-Candidaactivity, we sought to determine if fungicidal activity mightbe regulated by extracellular matrix proteins to which monocytes/macrophagesare adherent in vivo. Compared to monocyte/macrophages thatadhered to plastic, human monocytes and monocyte-derived macrophagesthat adhered to type 1 collagen matrices, but not to fibronectin,vitronectin, or laminin, demonstrated a significant increasein candidacidal activity. The enhancement of monocyte fungicidalactivity was maintained over a 4-h period, whereas macrophagefungicidal activity was maximum at 1 h. Although adherence ofmonocytes and macrophages to collagen matrices concomitantlyenhanced the production of superoxide anion, only the fungicidalactivity of collagen-adherent monocytes was partially blockedby superoxide dismutase and catalase. Remarkably, we found thatonly 10% of the phagosomes in C. albicans-infected macrophagesthat adhered to plastic fused with lysosomes. In contrast, 80%of yeast-containing phagosomes of collagen-adherent macrophagesfused with lysosomes. These data suggest that nonoxidative mechanismsare critical for human macrophage anti-Candida activity andthat C. albicans pathogenicity is mediated, in part, by itsability to inhibit phagolysosomal fusion in macrophages.

INTRODUCTION

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Introduction

Candida albicans is part of the normal microbial flora thatcolonizes mucocutaneous surfaces of the oral cavity, gastrointestinaltract, and vagina of the healthy human host. Although Candidadoes not normally cause disease, when immune defenses are compromisedor the normal microflora balance is disrupted, C. albicans transformsitself into an opportunistic pathogenic killer. Indeed, Candidais the leading cause of invasive fungal disease in prematureinfants, diabetics, and surgical patients and of oropharyngealdisease in AIDS patients (1, 5, 7, 9, 13, 17, 23, 34, 45).

Host resistance against infections with C. albicans is mediatedpredominantly by neutrophils and monocytes/macrophages (M ${phi}$ ).In the early stages of Candida infection microabscesses containneutrophils surrounded by a small number of mononuclear cells.As the fungus is eliminated from the lesions, mononuclear cellspredominate (32). The importance of neutrophils in host defenseagainst Candida infections is underscored by the high incidenceof disseminated disease in individuals with neutropenia (1,40) and the fact that depletion of neutrophils in mice leadsto systemic disease (2, 12). Further, numerous in vitro studieshave documented the potent ability of neutrophils from mice,humans, and guinea pigs to kill C. albicans (3, 6, 37), andkilling is mediated by both oxidative and nonoxidative mechanisms(8, 21, 22, 38, 46).

While neutrophils clearly are important in host defense againstCandida invasion and exhibit potent killing activity againstthe fungus, the relatively poor candidacidal activity of M ${phi}$ isperplexing. Thus, in a comparison of human neutrophils, monocytes,and monocyte-derived M ${phi}$ , M ${phi}$ clearly were inferior to neutrophilsand monocytes in their candidacidal activity. However, unlikeneutrophils and monocytes, M ${phi}$ killed Candida equally well underaerobic and anaerobic conditions (42). Indeed the loss of candidacidalactivity that occurs as monocytes differentiate into M ${phi}$ in vitrohas been shown to correlate with the loss of the enzyme myeloperoxidaseand a decrease in the ability to produce hydroxyl radicals (35).As monocytes and M ${phi}$ produced equivalent amounts of superoxideanion, the data suggest that the candidacidal activity of monocytesis mediated by products distal to the superoxide anion. Further,relative to bacteria such as Escherichia coli, Listeria monocytogenes,Salmonella enterica serovar Typhimurium, and Staphylococcusaureus, C. albicans is resistant to toxic oxygen metabolites.Thus, the killing of Candida required 10 times more H₂O₂, NaI,and Fe₂SO₄ than the killing of these bacteria (51). Thus, optimumkilling by M ${phi}$ must rely more on nonoxidative killing mechanismsthan on oxidative mechanisms.

Numerous studies suggest that for optimal host protection againstC. albicans M ${phi}$ are essential, despite their tepid candidacidalactivity in vitro, and that, most likely, they require activationby cytokines (2, 4, 33). However, very little is known in thisregard. With respect to human cells, granulocyte-M ${phi}$ colony stimulatingfactor and interleukin 3 (IL-3), but not gamma interferon (IFN- ${gamma}$ )have been reported to enhance the growth inhibition and/or killingof C. albicans by monocytes (39, 47). In contrast, IFN- ${gamma}$ modestlyboosts the candidacidal activity of monocyte-derived M ${phi}$ (25,26) and alveolar M ${phi}$ (44). In addition, IL-1 ${alpha}$ has been shown toenhance the anti-Candida activity of monocytes and alveolarM ${phi}$ (44).

In vivo, monocytes emigrating from the peripheral circulationenter into an extravascular area rich in extracellular matrix(ECM) proteins. It is in this milieu that phagocytes functionin host defense against pathogenic microorganisms. In addition,tissue M ${phi}$ reside in areas that contain ECM proteins. Previously,we demonstrated that, compared to plastic-adherent monocytes,monocytes adherent to type 1 collagen matrices demonstratedsignificantly enhanced phagocytic capacity for serum-opsonizedE. coli, S. aureus, Streptococcus pyogenes, and Streptococcuspneumoniae and that phagocytic capacity was mediated by activationof complement receptor type 1 (CR1) and CR3 for phagocytosisand augmentation of Fc receptor-mediated phagocytosis (31).Although both collagen- and plastic-adherent monocytes werebactericidal for these microbial pathogens, more bacteria werekilled by collagen-adherent monocytes by virtue of their enhancedphagocytic capacity.

More recently, we demonstrated that collagen-adherent M ${phi}$ arefungicidal for the dimorphic fungal pathogen Histoplasma capsulatum,whereas plastic-adherent M ${phi}$ are permissive for intracellulargrowth. The mechanism of this activation is the capacity ofcollagen-adherent M ${phi}$ to induce massive phagolysosomal (PL) fusion,whereas minimal PL fusion occurs in plastic-adherent M ${phi}$ (29).These results suggest that monocytes/M ${phi}$ adherent to type 1 collagenmay express a previously unrecognized microbicidal activitythat proceeds in the absence of exogenous cytokines. This microbicidalactivity may be important with regard to the capacity of M ${phi}$ toparticipate in the inflammatory response and in the inductionof cell-mediated immunity in the nonimmune host.

The present study was designed to determine if adherence ofhuman monocytes/M ${phi}$ to type 1 collagen matrices or other ECM proteinsmight augment candidacidal activity and, if so, to determinewhether augmentation was caused by oxidative or nonoxidativemechanisms.

MATERIALS AND METHODS

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Materials and Methods

Reagents. Superoxide dismutase (SOD), catalase, and ferricytochrome c(type 3) were purchased from Sigma-Aldrich, St. Louis, Mo. Cytochromec (1 mM) was dissolved in Krebs-Ringer phosphate buffer containing0.2% dextrose and stored at –20°C. All other reagentswere prepared in RPMI 1640 and sterile filtered. Human serumprepared from six to eight individual donors was pooled andstored in 200-µl aliquots at –80°C until used.

Preparation of human monocytes and M ${phi}$ . Monocytes were isolated by sequential centrifugation on Ficoll-Hypaqueand Percoll gradients (Amersham Pharmacia LKB, Piscataway, N.J.)from buffy coats obtained from the Hoxworth Blood Center, Cincinnati,Ohio, or from blood drawn from healthy adult donors in our laboratory(28). The monocytes were washed, suspended in Hanks balancedsalt solution (HBSS) containing 20 mM HEPES and 0.1% autologousserum, and then allowed to adhere to various substrates for1 h at 37°C in 5% CO₂-95% air. The adherent monocytes werewashed and then were studied immediately or cultured in M199(Bio-Whittaker, Walkersville, Md.) containing 10% autologousserum and 10 µg of gentamicin (Sigma)/ml. Medium was replacedon day 3, and M ${phi}$ were studied after 7 days of culture.

Alternatively, M ${phi}$ were obtained by culture of monocytes at 10⁶/mlin Teflon beakers in RPMI 1640 (Bio-Whittaker) containing 15%human serum, 10 µg of gentamicin/ml, 100 U of penicillin/ml,and 100 µg of streptomycin/ml (Sigma) (28). M ${phi}$ were studiedafter 5 to 7 days in culture.

Yeasts. C. albicans yeasts (ATCC 18804) were maintained on Sabourauddextrose agar (Difco Laboratories, Detroit, Mich.). Yeasts weregrown to log phase in Sabouraud dextrose broth at 30°C withorbital shaking at 150 rpm. For superoxide anion productionassays, yeasts were harvested by centrifugation, washed threetimes in 0.01 M phosphate buffer, pH 7.2, containing 0.15 MNaCl (PBS), and then heat killed (HK) at 65°C for 1 h. Yeastswere stored at 4°C in PBS containing 0.05% sodium azide.

For studies with viable Candida cells, log-phase yeasts wereharvested by centrifugation, washed three times in HBSS containing0.25% bovine serum albumin (HBSA), and resuspended to 50 mlin HBSA. The yeasts were counted on a hemacytometer and standardizedto the appropriate concentration according to the assay protocol.

H. capsulatum strain G217B was maintained as described previously(28). Yeasts were grown in HMM medium (50) at 37°C withorbital shaking at 150 rpm. After 48 h, log-phase yeasts wereharvested by centrifugation, washed three times in HBSA, andresuspended to 50 ml in HBSA. Large aggregates were removedby centrifugation at 200 x g for 7 min at 4°C. The top 10ml was removed, and the single-cell suspension obtained wasstandardized to the appropriate concentration according to theassay protocol. HK yeasts were prepared as described above forCandida.

S. cerevisiae was inoculated into 50 ml of yeast extract-peptone-dextrosebroth and cultured for 24 h at 37°C with orbital shakingat 150 rpm. The yeasts were harvested, washed, and standardizedby following the same procedure as that for Candida yeasts.

Preparation of tissue culture plates coated with ECM proteins. (i) Collagen gels. Type I collagen from rat tails (Sigma) was dissolved in 0.1%acetic acid at 1 mg/ml and dialyzed overnight at 4°C indistilled water. Three hundred microliters of collagen was dispensedinto 24-well tissue culture plates and exposed to ammonia fumesfor 30 min at 25°C. The gels were washed four times withHBSS prior to adherence of monocytes or M ${phi}$ . Alternatively, collagen-coatedwells were prepared by dispensing collagen (50 µg/ml inRPMI) into the wells to adhere directly to the plastic for 2h at 25°C.

(ii) Fibronectin, vitronectin, and laminin. Fibronectin, vitronectin, and laminin (Sigma) were suspendedto 50 µg/ml in RPMI 1640, and 250 µl was aliquotedinto the wells of a 24-well tissue culture plate. After 2 hat 25°C, the wells were aspirated and monocytes/M ${phi}$ were allowedto adhere for 1 h at 37°C.

Quantitation of monocyte/M ${phi}$ fungicidal activity. Adherent monocytes and M ${phi}$ ( $~$ 2 x 10⁵) were incubated with C. albicansyeasts (2 x 10⁴) in the presence of 10% pooled human serum for1, 2, and 4 h at 37°C in 5% CO₂-95% air. At each time point,the supernatant was aspirated and the mixtures were resuspendedin 1 ml of sterile water to lyse the cells. The contents werevortexed vigorously and then were serially diluted and platedon Sabouraud dextrose agar plates. Inspection of the initiallysate revealed only single colonies, 98% of which were stillin the yeast phase. After incubation at 30°C for 48 h, CFUwere counted and the percentage of C. albicans cells that werekilled was calculated by comparison to the CFU obtained fromthe original inoculum, which also was quantified by serial dilutionand plating.

Quantitation of superoxide anion (O₂^–) production. O₂^– generation by monocytes/M ${phi}$ was quantified as the SOD-inhibitablereduction of ferricytochrome c (type 3; Sigma) as describedpreviously (36). Monocytes/M ${phi}$ (2 x 10⁵) were incubated for 1h at 37°C with serum-opsonized Candida yeasts (10⁷) in Krebs-Ringerphosphate buffer with 0.2% dextrose containing 80 µM cytochromec. Control wells contained cytochrome c without Candida (restingcells) or Candida plus 40 µg of SOD/ml. At the end ofthe incubation, the supernatants were collected by centrifugationat 4°C. The absorbance of the supernatants at 550 nm wasmeasured in a Spectronic Genesys 5 (Milton Roy, Rochester, N.Y.),and the background absorbance in control tubes containing onlybuffer and cytochrome c was subtracted. All experiments wereperformed in duplicate, and results were calculated as nanomolesof O₂^– from the equation E₅₅₀ = 2.1 x 10⁴ M^–1 cm^–1.Results are expressed as nanomoles of cytochrome c reduced per2 x 10⁵ cells per hour.

Quantitation of PL fusion. M ${phi}$ were allowed to adhere in 24-well tissue culture plates to12-mm-diameter round glass coverslips or to coverslips coatedwith collagen gels. Monolayers then were incubated with 200nM Lysotracker red (Molecular Probes, Eugene, Oreg.) in RPMI1640 containing 5% fetal calf serum for 2 h to label lysosomes.After two washes, the M ${phi}$ were infected with viable S. cerevisiae(2 x 10⁶ cells) or HK and viable C. albicans (1 x 10⁵ cells)or H. capsulatum (2 x 10⁶ cells) for 1 h at 37°C. HK C.albicans and H. capsulatum were labeled with fluorescein isothiocyanateas described previously (30). After an additional two washes,the M ${phi}$ were cultured in 200 nM Lysotracker red for an additional2 h. After being washed, the monolayers were fixed in 3.75%paraformaldehyde for 20 min at 25°C. The M ${phi}$ then were coveredin Dulbecco's PBS (DPBS) containing 5% glucose. M ${phi}$ that adheredto collagen matrices were incubated overnight at 4°C. Thebuffer was aspirated, and the gels were allowed to desiccateat 30°C for 24 h. The monolayers then were covered in DPBS-glucose.M ${phi}$ that adhered to the coverslips were counted immediately. Coverslipswere mounted cell side down in 90% glycerol in phosphate-bufferedsaline onto microscope slides. One hundred yeast-containingphagosomes were scored for lysosomal fusion or no fusion. Thedata are expressed as the means ± standard errors ofthe means (SEM) of the percentages of PL fusion in three ormore experiments performed in duplicate.

Alternatively, M ${phi}$ adhered to plastic or collagen gels in six-wellplates were incubated for 2 h at 37°C in M199 containing10% human serum, 10 µg of gentamicin/ml, and 18-nm colloidalgold stabilized with horseradish peroxidase (HRP-Au18) (29).The M ${phi}$ were washed three times with medium and then incubatedfor an additional 2 h at 37°C to insure that the HRP-Au18entered the lysosomal compartments. After the second incubation,10⁶ viable or HK Candida yeasts were added, and phagocytosiswas allowed to proceed for 1 h at 37°C. After 1 h the M ${phi}$ were washed three times with ice-cold 0.1 M sodium cacodylatebuffer, pH 7.4, and then processed for electron microscopy.M ${phi}$ PL fusion was quantified by counting the 18-nm gold particlesin phagosomes containing Candida yeasts (29). The data are expressedas the means ± SEM of the average numbers of gold particlesper yeast-containing phagosome.

Statistics. Statistical analysis of the data was performed using Sigma Stat(Jandel Scientific, San Rafael, Calif.). Student's t test orthe Mann-Whitney rank sum test was used to analyze the datafor statistical significance, and results were considered significantat P values <0.05.

RESULTS

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Results

Fungicidal activity of monocytes/M ${phi}$ adherent to collagen matrices, fibronectin, vitronectin, and laminin. In initial experiments we sought to determine if adherence offreshly isolated monocytes or monocyte-derived M ${phi}$ to ECM proteinsregulated the phagocytes' capacity to kill C. albicans yeasts.Therefore, monocytes and suspension-cultured M ${phi}$ were allowedto adhere to plastic or the various substrates for 1 h and werethen incubated with 2 x 10⁴ yeasts for an additional 1 h. Candidacidalactivity then was quantified by determining the remaining CFUas described in Materials and Methods. After 1 h, monocyteskilled an average of 48% of the initial inoculum and M ${phi}$ killed57% (Fig. 1A and B). In contrast, monocytes and M ${phi}$ that adheredto collagen matrices killed 70 and 79%, respectively, of theC. albicans yeasts. This significant enhancement of monocyte/M ${phi}$ candidacidal activity was not observed when the phagocytes wereallowed to adhere to fibronectin, vitronectin, or laminin (Fig.1A and B). In addition, adherence of monocytes/M ${phi}$ to collagen-coatedwells did not enhance fungicidal activity (data not shown),indicating that the enhanced killing required that the collagenbe in the form of a three-dimensional matrix, as is found invivo.

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FIG. 1. Collagen-adherent monocytes and M ${phi}$ have enhanced fungicidal activity against C. albicans. Freshly isolated monocytes and suspension-cultured M ${phi}$ were allowed to adhere to plastic (PL), type 1 collagen matrices (COL), fibronectin (FN), vitronectin (VIT), or laminin (LAM) for 1 h at 37°C. Alternatively, monocytes were cultured for 7 days on the various ECM components (adherent M ${phi}$ ). After the monolayers were washed, the cells were incubated with 2 x 10⁴ C. albicans yeasts in the presence of 10% pooled human serum for 1 h at 37°C. At the end of the incubation period, the remaining CFU were quantified as described in Materials and Methods. The data are the means ± SEM of the remaining CFU from five experiments with monocytes and suspension-cultured M ${phi}$ and seven experiments with adherently cultured M ${phi}$ . *, P < 0.05 compared to plastic (t test); **, P < 0.05 compared to plastic (Mann-Whitney rank sum test).

We also sought to determine if monocyte differentiation intoM ${phi}$ on the different ECM proteins would regulate phagocyte fungicidalactivity. Figure 1C shows that, when monocytes were culturedfor 7 days on ECM proteins, enhanced candidacidal activity wasobserved with vitronectin and laminin, as well as collagen,matrices. The enhanced fungicidal activity observed after 7days of culture on fibronectin was consistent but did not reachstatistical significance.

Enhanced fungicidal activity of monocytes/M ${phi}$ adherent to type 1 collagen matrices. We next sought to determine the kinetics of the enhanced fungicidalactivity exhibited by monocytes/M ${phi}$ adherent to collagen matrices.Therefore, monocytes/M ${phi}$ were allowed to adhere to plastic orcollagen gels for 1 h and candidacidal activity was quantifiedover a 4-h period. Figure 2A shows that collagen-adherent monocytescontinued to kill C. albicans yeasts over the 4-h incubationperiod, whereas there was an increase in Candida CFU at 2 and4 h with plastic-adherent monocytes. In contrast, with bothsuspension-cultured M ${phi}$ adherent to collagen gels for 1 h andM ${phi}$ cultured for 7 days on a collagen matrix, maximum fungal killingwas observed at 1 h. Thereafter, there was a slight increasein CFU, as was observed with M ${phi}$ adherent to plastic.

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FIG. 2. Time course of monocyte/M ${phi}$ fungicidal activity on plastic versus collagen matrices. Freshly isolated monocytes and suspension-cultured M ${phi}$ were allowed to adhere to plastic or type 1 collagen matrices for 1 h at 37°C, or monocytes were cultured for 7 days on plastic or collagen. After the monolayers were washed, the cells were incubated with 2 x 10⁴ C. albicans yeasts in the presence of 10% pooled human serum for 1, 2, and 4 h at 37°C. Remaining CFU then were quantified as described in Materials and Methods. The data are the means ± SEM of the remaining CFU from eight experiments with monocytes and adherently cultured M ${phi}$ and five experiments with suspension-cultured M ${phi}$ . * and **, P < 0.01 and < 0.05, respectively, compared to plastic (t test).

Mechanism of monocyte/M ${phi}$ fungicidal activity against C. albicans. Data from numerous laboratories suggest that neutrophils killC. albicans predominantly via the production of toxic oxygenmetabolites (8, 42, 46), whereas M ${phi}$ fungicidal activity is mediatedby both oxidative and nonoxidative mechanisms. Therefore, wenext sought to determine if collagen-adherent monocytes andM ${phi}$ stimulated the production of greater amounts of superoxideanion than plastic-adherent cells. Monocytes and M ${phi}$ were incubatedfor 1 h with opsonized C. albicans yeasts, and superoxide anionproduction was quantified by measuring the SOD-inhibitable reductionof cytochrome c. The data in Fig. 3A show that monocytes thatadhered to collagen matrices, but not nongelled collagen, producedsignificantly more SOD-inhibitable superoxide anion than plastic-adherentmonocytes. Similar results were obtained with M ${phi}$ adherent tocollagen matrices (Fig. 3B).

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FIG. 3. Adherence of monocytes/M ${phi}$ to collagen matrices enhances the production of superoxide anion. Monocytes (A) or M ${phi}$ (B) adherent to plastic, collagen, or collagen gels (Col Gel) were incubated in buffer alone (Co) or with opsonized C. albicans (Ca) (10⁷ yeasts) for 1 h at 37°C in the absence or presence of SOD (40 µg/ml), and the production of superoxide anion was quantified by measuring the reduction of cytochrome c. The data are the means ± SEM of three experiments with monocytes (A) and six experiments with M ${phi}$ (B). *, P < 0.05, compared to plastic (t test).

To determine if an enhanced respiratory burst was responsiblefor the increased candidacidal activity of collagen-adherentmonocytes/M ${phi}$ , the effect of respiratory burst inhibitors on monocyte/M ${phi}$ killing of C. albicans was quantified. Monocytes and M ${phi}$ adherentto plastic, collagen or collagen matrices were incubated withCandida yeasts in the presence or absence of SOD or catalase,and the remaining CFU were quantified after 1 h at 37°C.The fungicidal activity of plastic-adherent monocytes was partiallyreversed by catalase, but not SOD, but the effect of catalasewas not statistically significant (Fig. 4). Likewise, the fungicidalactivity of collagen-adherent monocytes was partially reversedby both SOD and catalase, but these results also were not statisticallysignificant (Fig. 4). In identical experiments performed withM ${phi}$ , neither SOD nor catalase had any effect on the fungicidalactivity of M ${phi}$ regardless of the substrate to which the cellsadhered (data not shown).

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FIG. 4. Reversal of monocyte fungicidal activity by SOD and catalase. Monocytes were allowed to adhere to plastic or type 1 collagen matrices for 1 h at 37°C. After being washed, the monocytes were incubated with 2 x 10⁴ C. albicans yeasts for 1 h at 37°C in the presence or absence of SOD or catalase. Remaining CFU then were quantified as described in the legend to Fig. 1. The data are the means ± SEM of five experiments. *, P < 0.05 compared to plastic control (Mann-Whitney rank sum test).

As the production of toxic oxygen radicals did not appear tobe involved in M ${phi}$ fungicidal activity, we sought to compare theamounts of PL fusion mediated by plastic- versus collagen-adherentM ${phi}$ upon phagocytosis of C. albicans. M ${phi}$ were allowed to adhereto plastic or collagen matrices, loaded with Lysotracker red,and then incubated with viable or HK Candida yeasts for 1 hat 37°C. For comparison, we quantified M ${phi}$ PL fusion afterphagocytosis of viable H. capsulatum and S. cerevisiae yeastsand HK H. capsulatum yeasts. In M ${phi}$ that ingested either HK Candidaor HK Histoplasma, over 80% of yeast-containing phagosomes demonstratedPL fusion (Fig. 5A). M ${phi}$ phagosomes that contained H. capsulatumshowed about 5% PL fusion, confirming our previous data (29).Remarkably, only 10% of phagosomes containing C. albicans demonstratedPL fusion. There was about 70% PL fusion in M ${phi}$ that had phagocytosedviable S. cerevisiae.

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FIG. 5. Adherence of M ${phi}$ to collagen matrices enhances PL fusion. Glass- or collagen-adherent M ${phi}$ were loaded with Lysotracker red and then incubated for 1 h with viable (V) or HK C. albicans (Ca) or H. capsulatum (Hc) or viable S. cerevisiae (V Sc). The percentage of lysosomal fusion was quantified as described in Materials and Methods. The data are the means ± SEM of four to nine experiments with C. albicans and H. capsulatum and seven experiments with S. cerevisiae. (A) Data comparing levels of PL fusion for viable and HK C. albicans and H. capsulatum and viable S. cerevisiae when the M ${phi}$ were allowed to adhere to glass coverslips. *, P < 0.001 compared to viable fungi (t test). (B) Data comparing levels of PL fusion with viable fungi for M ${phi}$ adherent to glass coverslips versus collagen gels. *, P < 0.001 compared to glass-adherent M ${phi}$ (t test). (C) Plastic- or collagen-adherent M ${phi}$ were labeled with HRP-Au18 and then incubated with C. albicans for 1 h at 37°C. After fixation and processing for electron microscopy, the number of gold particles in yeast-containing phagosomes was quantified. The data are the means ± SEM of the numbers of gold particles per phagosome. The number above each bar on the graph denotes the number of phagosomes counted for each fungus. *, P < 0.001 compared to plastic (Mann-Whitney rank sum test).

When M ${phi}$ were allowed to adhere to collagen matrices, phagosomescontaining either viable C. albicans or viable H. capsulatumdemonstrated about 80% PL fusion (Fig. 5B). These results wereconfirmed for C. albicans with HRP-Au18. Figure 5C shows that,after 1 h of phagocytosis, plastic-adherent M ${phi}$ containing C.albicans had an average of 0.58 gold particles per phagosome,whereas collagen-adherent M ${phi}$ had an average of 2.3 gold particlesper phagosome, a fourfold increase. In contrast, M ${phi}$ that hadingested HK yeasts had an average of about 12 gold particlesper phagosome, regardless of the substrate to which the cellswere adherent (data not shown). These results are illustratedin Fig. 6. The top panel of Fig. 6 shows that, despite numerousgold particles nearby in the cytoplasm, no gold particles arein the yeast-containing phagosome of a M ${phi}$ adherent to plastic.In contrast, in the bottom panel, numerous gold particles canbe seen adjacent to the yeast in a M ${phi}$ adherent to collagen.

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FIG. 6. Adherence of M ${phi}$ to collagen matrices enhances PL fusion. Plastic- or collagen-adherent M ${phi}$ were labeled with HRP-Au18 and then incubated with C. albicans for 1 h at 37°C and then fixed and processed for electron microscopy. (Top) Electron micrograph showing a C. albicans yeast within the phagosome of a M ${phi}$ adherent to plastic. Note that there are numerous gold particles in the surrounding cytoplasm but none in the phagosome. (Bottom) Collagen-adherent M ${phi}$ with numerous gold particles within the yeast-containing phagosome. Bars, 1 µm.

DISCUSSION

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Discussion

Studies of murine models of disseminated candidiasis demonstratethat M ${phi}$ play an important role in host resistance (2, 4, 33).However, in vitro, M ${phi}$ candidacidal activity is underwhelming,particularly compared to that of neutrophils (reviewed in reference43). Part of the explanation for the low killing capacity liesin the fact that, as monocytes differentiate into mature M ${phi}$ ,they lose the enzyme myeloperoxidase and, therefore, are notable to generate potent toxic oxygen radicals distal to H₂O₂(24, 35). Thus, for protection of the host, M ${phi}$ must either relyon PL fusion and lysosomal enzymes or be activated by T-cellcytokines, such as IFN- ${gamma}$ . However, IFN- ${gamma}$ alone does not turn M ${phi}$ into potent killers of C. albicans (25, 26, 47).

We hypothesized that part of the inability of M ${phi}$ to efficientlykill C. albicans might be caused by a deficit in PL fusion.Previously we had demonstrated that adherence of human M ${phi}$ totype 1 collagen gels stimulated the M ${phi}$ to kill H. capsulatumcells via the induction of PL fusion. Therefore, we sought todetermine if adherence to collagen or other ECM proteins mightenhance M ${phi}$ candidacidal activity by the same mechanism.

Indeed, we found that both monocytes and monocyte-derived M ${phi}$ demonstrated significantly increased candidacidal activity incells that adhered to type 1 collagen matrices compared to cellsthat adhered to plastic. Activation of M ${phi}$ occurred immediatelyupon adherence and did not require additional time in culture.Enhanced candidacidal activity was not observed when monocytesor M ${phi}$ adhered to fibronectin, vitronectin, laminin, or nongelledcollagen. However, when monocytes were allowed to differentiateinto M ${phi}$ while adherent to ECM proteins, culture on vitronectinand laminin, but not fibronectin, also induced a significantincrease in M ${phi}$ candidacidal activity. We have focused here oncollagen, as it was the most consistent ECM protein in enhancingM ${phi}$ fungicidal activity.

We hypothesize that optimum M ${phi}$ anti-Candida activity probablyrequires some combination of ECM proteins and cytokines andoccurs only upon the induction of CMI. However, it also is possiblethat monocytes emigrating into an inflammatory site where type1 collagen and other ECM proteins are present may exhibit sufficientfungicidal activity to help prevent or slow the disseminationof Candida, particularly when neutrophils are present (16).Thus, we suggest that, in the healthy human host, during theinflammatory response to Candida the influx of neutrophils andmonocytes, in conjunction with the ECM, might be sufficientto prevent Candida from causing disease. Clearly, when neutrophilsare removed from the equation, inflammatory monocytes aloneare insufficient to prevent dissemination and disease (1, 12,18, 20, 40).

It is generally accepted that the respiratory burst accountsfor the majority of the candidacidal activity of human neutrophils,and both oxygen-dependent and -independent mechanisms have beenpromoted for monocyte/M ${phi}$ candidacidal activity (reviewed in reference43). In a previous study with human M ${phi}$ and dendritic cells (DC),we were unable to obtain any evidence that either cell typekilled C. albicans through the generation of toxic oxygen metabolites(30). In fact, M ${phi}$ killing and DC killing of Candida were equivalentunder aerobic and anaerobic conditions, confirming earlier studieswith M ${phi}$ by Thompson and Wilton (42).

The data in the present study also do not support a significantrole for toxic oxygen radicals in the candidacidal activityof monocytes or M ${phi}$ . Remarkably, we found that Candida-infectedplastic-adherent M ${phi}$ demonstrated very little PL fusion comparedto the amount of PL fusion induced by phagocytosis of the nonpathogenicyeast S. cerevisiae or HK Candida or Histoplasma. In contrast,when M ${phi}$ were allowed to adhere to collagen matrices and theninfected with C. albicans, 80% of yeast-containing phagosomesdemonstrated PL fusion, similar to that seen when the M ${phi}$ wereinfected with H. capsulatum (29). Interestingly, and in contrastto our observations with human M ${phi}$ , PL fusion has been reportedto occur normally in mouse peritoneal M ${phi}$ (19, 27, 48).

The fact that PL fusion is inhibited upon ingestion of Candidacells by M ${phi}$ and the fact that M ${phi}$ do not generate toxic oxygenradicals distal to H₂O₂ (24, 35) may explain why human M ${phi}$ mediatesuch poor candidacidal activity. The data are surprising consideringthe facts that Candida is an opportunistic pathogen and thatthe capacity to inhibit PL fusion generally is considered tobe a property of intracellular pathogens.

The mechanism by which C. albicans inhibits PL fusion is unknown.However, it is not likely to be related to signal transductionthrough the mannose receptor, as PL fusion occurs normally afteringestion of S. cerevisiae and HK Candida. It also is not clearif filamentation is involved in inhibition of PL fusion. Mostlikely, the yeasts respond to phagocytosis by secreting an unknownagent that inhibits the fusion process.

It also is unknown how M ${phi}$ adherence to a collagen matrix stimulatesthe M ${phi}$ to undergo PL fusion, overriding the negative signal fromingested C. albicans cells. The "very late antigen" (VLA) receptorfamily are cell surface glycoproteins that promote cell-matrixadhesion and belong to the integrin family of adhesion molecules(14). Of the VLA molecules that have been described, VLA-2 hasbeen shown to be specific for collagen and VLA-3 has been shownto be specific for collagen, laminin, and fibronectin (41, 49).Of these, small amounts of only VLA-2 have been detected onhuman monocytes/M ${phi}$ (15). Thus, we hypothesize that adherenceto collagen provides an additional signal to the M ${phi}$ through VLA-2that promotes PL fusion that enhances M ${phi}$ candidacidal activity.

However, inhibition of PL fusion seems only to be part of thestrategy by which C. albicans survives in M ${phi}$ . Adherence of M ${phi}$ to collagen induced PL fusion in 80% of phagosomes containingCandida cells. Therefore, it is curious that M ${phi}$ candidacidalactivity was not more robust. Indeed, adherence of human M ${phi}$ tocollagen matrices leads to significant killing of H. capsulatumcells, which also survive intracellularly, in part, by inhibitingPL fusion (29). It is possible that the reason that M ${phi}$ Candidakilling on collagen is not more efficient is because the yeastsalso regulate intraphagosomal pH. Thus, C. albicans may modulatethe pH in the phagosome so that the pH is suboptimal for killingby lysosomal hydrolases, even in the presence of PL fusion.This is similar to the strategy utilized by H. capsulatum tosurvive in murine M ${phi}$ (10, 11).

This idea is supported by studies of murine resident peritonealM ${phi}$ (48). In these studies, PL fusion in unactivated M ${phi}$ was equivalentto that in IFN- ${gamma}$ -activated M ${phi}$ . However, there was a major differencein levels of phagosomal acidification. Only 3% of Candida-infectedresident peritoneal M ${phi}$ acidified phagolysosomes to a pH of <4.0,whereas in IFN- ${gamma}$ -activated M ${phi}$ , 42% of infected M ${phi}$ demonstratedacidified phagolysosomes. Further, the enhanced candidacidalactivity of IFN- ${gamma}$ -activated murine peritoneal M ${phi}$ directly correlatedwith phagosomal acidification, but not the production of toxicoxygen radicals. Thus, C. albicans clearly uses more than asingle strategy for intracellular survival in M ${phi}$ and appearsto use slightly different strategies to survive within humanversus murine M ${phi}$ . A better understanding of these survival strategiesshould help clarify the pathogenic properties of this dimorphicfungus and could possibly lead to the discovery of novel therapies.

ACKNOWLEDGMENTS

This work was supported by Public Health Service grants AI-37639from the National Institute of Allergy and Infectious Diseasesand HL-55948 from the National Heart, Lung, and Blood Institute.

We thank Georgianne Ciraolo for technical assistance with electronmicroscopy.

FOOTNOTES

* Corresponding author. Mailing address: Division of Infectious Diseases, University of Cincinnati Col. Med., P.O. Box 670560, Cincinnati, OH 45267-0560. Phone: (513) 558-4709. Fax: (513) 558-2089. E-mail: newmansl{at}uc.edu.

Editor: T. R. Kozel

REFERENCES

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