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Infection and Immunity, December 1998, p. 5812-5818, Vol. 66, No. 12
Laboratory of Medical Mycology, Research
Institute for Disease Mechanism and Control, Nagoya University
School of Medicine, Showa-ku, Nagoya 466-8550, Japan,1 and
Department of
Microbiology, Montana State University, Bozeman, Montana
59717-35202
Received 27 April 1998/Returned for modification 30 June
1998/Accepted 15 September 1998
This study was conducted to define adhesive characteristics of the
acid-stable moiety of the Candida albicans
phosphomannoprotein complex (PMPC) on adherence of this fungus to
marginal zone macrophages of the mouse spleen. Complete digestion of
the acid-stable moiety (Fr.IIS) of the C. albicans PMPC
with an Candida albicans
adherence to host receptors is important for establishment of
colonization and for initiation of invasion into host tissue (6,
8, 9, 15, 20). Many candidate adhesin molecules on yeast cells
have been reported (3, 5, 12, 16, 21, 26), and the cell wall
phosphomannoprotein complex (PMPC) has received the most attention
(4, 28, 29, 31, 35).
We have focused our studies on interactions between C. albicans and macrophages found in the marginal zone of mouse
splenic tissue and certain macrophages in peripheral lymph nodes
(9, 13, 15, 17-19, 27). This site for interaction studies
was chosen because of its clear importance in trapping of yeast cells during candidemia. Use of an ex vivo assay (30) has led to
preliminary data indicating that a mannose receptor as characterized by
Stahl (34) is significantly different from the receptor for
C. albicans (reference 16 and our
unpublished data). Candida adhesins involved in the
attachment to the macrophages appear to be entirely associated with the
phosphomannan complex on the fungal cell surface.
The phosphomannan part of the C. albicans PMPC can be
divided into acid-stable and acid-labile moieties (24, 32,
33). Both parts are involved in adherence of this fungus to host
tissues such as spleen and lymph node (19, 27). Chaffin et
al. (7) isolated a C. albicans cell surface
mutant lacking the acid-labile moieties. In wild-type cells, these
moieties consist of In this study, we isolated PMPCs from S. cerevisiae
wild-type and three mnn mutant strains and compared their
adhesin activities with that of the C. albicans
acid-stable PMPC mannan fraction, Fr.IIS, which was previously isolated
(19). We show that the adhesin activity of the acid-stable
moiety depends on both number and length of mannosyl side chains bound
to the outer core mannan, and not on the kind of side-chain linkages.
For our work, Fr.IIS was obtained from a serotype B strain of
C. albicans, because the PMPC structure from this
strain contains Organisms and culture conditions.
C. albicans A9
(serotype B), Saccharomyces cerevisiae wild-type parent
strain X2180, and three derived mnn mutant strains, S. cerevisiae mnn1, mnn2 and
mnn4, were used. The C. albicans strain was
described previously (13, 17-19, 30). S. cerevisiae mnn1 mannan lacks Acid-stable part of the C. albicans
PMPC.
The acid-stable part of the C. albicans
PMPC was obtained by acid treatment of the complex followed by size
exclusion column chromatography as described previously
(19). In brief, hydrophilic yeast cells of C. albicans were treated with 300 mM Acetolysis products of Fr.IIS.
Alpha-linked
oligomannosyls were isolated from Fr.IIS of C. albicans NIH B-792 by acetolysis and size exclusion column
chromatography (32). The resulting
oligomannosyls, Man, Man PMPCs of S. cerevisiae.
PMPCs were obtained from
S. cerevisiae strains by methods similar to those used for
C. albicans (18). In brief, stationary-phase yeast cells of the various strains were grown in GYEP broth for 48 h at 30°C and treated with 300 mM 2-ME. The resulting 2-ME extracts
were applied to a ConA-agarose column, and 0.5 M
0019-9567/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Minimum Chemical Requirements for Adhesin Activity of the
Acid-Stable Part of Candida albicans Cell Wall
Phosphomannoprotein Complex
ABSTRACT
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
-mannosidase or hydrolysis with 0.6 N sulfuric acid
destroyed adhesin activity, as determined by the inability of the
soluble digests to inhibit yeast cell adherence to the splenic marginal
zone. Fr.IIS adhesin activity was decreased following digestion
with an -1,2-specific mannosidase. Oligomannosyls consisting of one
to six mannose units, which were isolated from the acid-stable
part of the PMPC, did not inhibit yeast cell binding and thus do not
function alone as adhesin sites in the PMPC. To gain more insight into
the minimum requirements for adhesin activity, PMPCs were
isolated from a Saccharomyces cerevisiae wild-type strain
and from mutant strains mnn1, mnn2, and
mnn4; the PMPCs were designated scwt/Fr.II, scmn1/Fr.II,
scmn2/Fr.II, and scmn4/Fr.II, respectively. S. cerevisiae scmn2/Fr.II lacks oligomannosyl side chain branches
from the outer core mannan, and scmn2/Fr.II was the only PMPC
without adhesin activity. S. cerevisiae scwt/Fr.II,
scmn1/Fr.II, and scmn4/Fr.II showed adhesin activities less than that
of C. albicans Fr.II. These three S. cerevisiae PMPCs are generally similar to Fr.IIS, except that the
S. cerevisiae structure has fewer and shorter side
chains. Immunofluorescence microscopy show that the acid-stable part of the PMPC is displayed homogeneously on the C. albicans
yeast cell surface, which would be expected for a surface adhesin. Our
results indicate that both the mannan core and the oligomannosyl side chains are responsible for the adhesin activity of the acid-stable part
of the PMPC.
INTRODUCTION
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
-1,2-linked oligomannosyl residues
phosphodiester linked to the acid-stable part. The mutant strain was
reported to be reduced in adherence ability compared to the wild type.
Li and Cutler (27) defined an adhesin site on the
acid-labile part of C. albicans PMPC as a
-1,2-linked mannotetraose; Fradin et al. showed that this
oligomannoside functions as an adhesin in attachment of yeast cells to
a macrophage cell line (11). Furthermore, antigenic factor
6, which consists of a -1,2-linked mannoside located on the
acid-stable part of the mannoprotein of serotype A C. albicans (23), acts as an adhesin in the binding of
C. albicans to epithelial cells (29). These
various data strongly support an adhesin function for
-1,2-linked oligomannosyls in the PMPC of C. albicans. In other studies, we showed strong mannan adhesin
activity that was not associated with -1,2-linked oligomannosyls
(19). A serotype B strain, which lacks
-1,2-glycosides bonds in the acid-stable part, had strong
adhesin activity associated with the acid-stable part (19, 24). The PMPC acid-stable parts from Saccharomyces
cerevisiae and C. albicans are similar
(2), but the S. cerevisiae acid-stable part
of the PMPC and the phospholinked glycosides do not have -1,2-linked oligomannosyl residues. These features and the
availability of well-defined cell wall mannan mutants (2)
make S. cerevisiae a useful tool for understanding the
nature of the adhesin site(s) in the acid-stable part of the
C. albicans PMPC.
-1,2-oligomannosyl residues only in
the acid-labile part of the structure, whereas serotype A strains have
these -1,2-glycosidic linkages in the acid-labile and
acid-stable parts (23). The use of serotype B strains in
these studies does not bias the results because both strains appear to
bind to splenic marginal zone macrophages by the same mechanism(s)
(18).
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
-1,3-linked mannoses at the ends
of the side chains, S. cerevisiae mnn2 mannan lacks all side
chains, and mannan of S. cerevisiae mnn4 lacks
phosphate-bound mannose chains (2). The mnn
mutants were kindly provided by Clinton Ballou, University of
California, Berkeley. Stock cultures of the strains maintained in 50%
glycerol at 
80°C were spread onto a GYEP (2% glucose, 0.3% yeast
extract, 1% peptone) agar plate and cultured for 48 h at 30°C,
and a single colony of each strain was inoculated into GYEP broth. For
ex vivo adherence assays, hydrophilic C. albicans yeast
cells were obtained by culturing for 24 h at 37°C in GYEP broth
under aeration by reciprocal shaking at 100 strokes per min. The
stationary-phase hydrophilic Candida cells were washed in
cold distilled water; their hydrophobicity was determined by attachment
of latex microspheres to the cell wall surface as described previously
(15), and the cell number was adjusted to 1.5 × 108 per ml in Dulbecco's modified Eagle's medium (DMEM;
Sigma Chemical Co., St. Louis, Mo.), (pH 7.4) (18, 19, 30).
For isolation of PMPC, C. albicans was cultured in GYEP
broth for 24 h at 37°C, and S. cerevisiae was
cultured in GYEP broth for 36 h at 30°C as described above.
-mercaptoethanol (2-ME) in
0.1 M EDTA (pH 9.0) for 30 min at 20 to 25°C; the resultant supernatant was dialyzed against distilled water and lyophilized, and
the material was called 2-ME extract. 2-ME extract was dissolved in 25 mM phosphate buffer (PB; pH 7.2) containing 0.15 N NaCl (PBS), applied
to a concanavalin A (ConA)-agarose (Honen Co., Tokyo, Japan) column,
and washed with PBS, and materials were eluted with 0.5 M
-methyl-D-mannopyranoside. The eluted fractions were
pooled, forming the PMPC, and designated Fr.II (18). Fr.II was dissolved in 10 mM HCl, hydrolyzed for 60 min at 100°C, and applied to a size exclusion column (Toyopearl HW 40S; Toyo Soda Manufacturing Company Ltd., Tokyo, Japan), and fraction eluting in the
void volume was lyophilized. This fraction, the acid-stable part of the
PMPC, was designated Fr.IIS (19). Mannose,
-1,2-linked mannobiose, and -1,2-linked mannotriose,
which were kindly supplied by Nobuyuki Shibata, Tohoku College of
Pharmacy, Sendai, Japan, were used to determine the peaks corresponding
to mono-, di-, and trisaccharides eluted from the size exclusion columns.
1-2Man, Man 1-2Man 1-2Man, Man 1-2Man 1-2Man 1-2Man, Man 1-3Man 1-2Man
1-2Man 1-2Man, and Man 1-2Man 1-3Man 1-2Man 1-2Man
1-2Man, were kindly supplied by Nobuyuki Shibata; these residues
were designated M1 to M6, respectively.
-methyl-D-mannopyranoside-eluted fractions were pooled.
These pools, the PMPCs, were designated scwt/Fr.II for the
S. cerevisiae parent strain X2180, scmn1/Fr.II for
mutant mnn1, scmn2/Fr.II for mutant mnn2, and
scmn4/Fr.II for mutant mnn4.
TABLE 1.
PMPCs used in this study
Enzymatic digestion and chemical treatment.
Fr.IIS was
dissolved in 50 mM citrate buffer (pH 5.0) at 200 µg/ml, with each
milliliter containing 0 to 20 µU of -1,2-mannosidase (Glyko
Inc., Novato, Calif.). This enzyme was isolated from Aspergillus saitoi and is highly specific for -1,2-linked mannose at
the nonreducing end. Alternatively, 0 to 1.13 U of -mannosidase
(Glyko) was used. This enzyme was isolated from Canavalia
ensiformis and breaks -1,2-, -1,3-, and -1,6-linked
mannose bonds. Samples were incubated for 18 h at 37°C and then
treated at 100°C for 3 min to inactivate enzymatic activity. For
proteinase K treatment, Fr.IIS was dissolved in 25 mM Tris-HCl buffer
(pH 7) containing proteinase K (100 µg/ml; Wako Pure Chemicals,
Osaka, Japan), incubated for 60 min at 37°C, and then incubated for 3 min at 100°C to inactivate the proteinase K. All samples were diluted
1:10 in DMEM and tested for the ability to inhibit yeast adherence to
mouse splenic tissue in the ex vivo assay as described below.
Lectin and antibodies.
Horseradish peroxidase
(HRP)-conjugated ConA (Honen Co.) was used to detect mannans in the
fractions isolated from C. albicans and S. cerevisiae. Antisera specific for antigenic factors 5 and 9 of
C. albicans were obtained from a commercial source
(Candida Check, Iatron Laboratories Inc., Tokyo, Japan). Factor 5 corresponds to -1,2-linked oligomannosyl residues of
C. albicans mannan (32, 33), and factor 9 corresponds to the -1,6-mannan core without mannose side chains
(1). Mouse immunoglobulin M (IgM) monoclonal antibody (MAb)
B6.1, specific for a -1,2-linked mannotriose (14), was also used to monitor for -linked mannose chains.
-1,2-mannosides. Both antisera were treated twice
with S. cerevisiae mnn2 yeast cells for 2 h at 4 to 6°C to adsorb antibodies against proteins or other mannan
epitopes. The adsorbed antisera were used for detection of various
moieties within the acid-stable part of the PMPC on the surface of
C. albicans. The slide agglutination titer against
C. albicans yeast cells was 40 for both antisera.
Dot blots. Antibodies reacting with PMPCs from C. albicans and S. cerevisiae were tested in a dot blot format. One microliter of each PMPC extract (10 mg/ml) from C. albicans and S. cerevisiae was placed on nitrocellulose sheets (Cellulosenitrat, EBA 85; Schleicher & Schuell, Dassel, Germany) and air dried for 30 min. The sheets were soaked in 25 mM Tris-HCl buffer (pH 7.5) containing 0.5 N NaCl (Tris-buffered saline [TBS]) and 3% skim milk for 30 min at 20 to 25°C. Each sheet was reacted overnight at 4 to 6°C with one of the following antisera: anti-factor 5 (1:100) rabbit serum, anti-factor 9 (1:100) rabbit serum, anti-Fr.II/scmn1 (1:200) rabbit serum, anti-Fr.II/scmn4 (1:200) rabbit serum, and mouse MAb B6.1 (4 µg/ml). All antibody preparations were diluted in TBS containing 1% skim milk. After being washed in TBS-1% skim milk, the sheets were incubated with HRP-conjugated anti-rabbit IgG goat serum (1:2,000; Cappel Research Products, Durham, N.C.) or HRP-conjugated anti-mouse IgM goat serum (1:1,000; Jackson ImmunoResearch Laboratories, Inc.) for 3 h at 20 to 25°C. For HRP-ConA, the sheet blotted with the mannoprotein fractions was soaked in TBS containing 3% bovine serum albumin (BSA) and reacted with HRP-conjugated ConA (2 µg/ml) for 60 min at 20 to 25°C. Finally, all sheets were incubated in a mixture of 4-chloro-1-naphthol and H2O2 in TBS (18).
IFM and flow cytometry. Hydrophilic yeast cells of C. albicans grown in GYEP for 24 h at 37°C were fixed with 3% formalin in 25 mM PB (pH 7.4) for 2 h at 20 to 25°C. After several washes with PB, the fixed samples were treated with PBS-3% BSA for 30 min at 20 to 25°C and then incubated with rabbit anti-scmn1/Fr.II (1:100 in PBS containing 1% BSA) rabbit serum or rabbit anti-scmn4/Fr.II (1:100 in 1% BSA-PBS) for 2 h at 37°C. After washing with 1% BSA-PBS, the samples were reacted with fluorescein isothiocyanate-conjugated anti-rabbit IgG goat serum (diluted 1:50 in PBS containing 1% BSA) (Cappel Research Products) for 2 h at 20 to 25°C. For indirect immunofluorescence microscopy (IFM) of yeast cells adhered to the splenic tissue, cryosections of the tissue with adherent yeast cells were fixed with 3% formalin for 2 h at 20 to 25°C. The sections were further processed by the same procedures as described for yeast cells. As controls, yeast cells were incubated with the antisera in the presence of Fr.IIS at 250 µg/ml, or antibodies against PMPC were omitted in the first incubation. Samples were observed with a BH2-RFK epifluorescence microscope (Olympus Optical Co., Ltd., Tokyo, Japan) and photographed on Kodak Tmax 400 film. This method was used to determine the distribution patterns of the adhesin complexes on the yeast cell surface.
For flow cytometry, hydrophilic C. albicans yeast cells were prepared as for IFM and analyzed in a flow cytometer (EPICS XL; Coulter Corporation, Miami, Fla.) equipped with an argon laser (488 nm) (14). This method was used to define the proportion of C. albicans cells that expressed mannan adhesins on the cell wall surface.Determination of adhesion activity. To test adhesin activity of the yeast PMPC, both an ex vivo adherence inhibition assay and an ex vivo binding assay were used as described previously (18, 19). In brief, for the inhibition assay, each PMPC sample at a concentration of 10, 20, 50, or 100 µg/ml (diluted in DMEM) was added to splenic cryosections mounted on glass slides and incubated for 15 min at 4 to 6°C. After being washed in DMEM, C. albicans yeast cells were added to the sections, and subsequent yeast binding to the splenic tissue was determined under a light microscope. For ex vivo binding assays, latex beads were coated with each PMPC of C. albicans or S. cerevisiae as before (19, 27). Latex beads (PolybeadR Microparticles; Polysciences Inc., Warrington, Pa.) were incubated with one of the PMPC fractions (1 mg/ml) in 0.067 M carbonate buffer (pH 9.6) for 2 h at 21 to 25°C. After several washes, the beads were blocked with 1% BSA (Sigma) for 2 to 3 h at 21 to 25°C. BSA-coated latex beads were used as a negative control. The beads were washed in DMEM three times and stored at 4°C. PMPC-coated latex beads (1.5 × 108 beads/ml) were added to the cryosections mounted on glass slides and incubated for 20 min at 4 to 6°C. After being fixed with 2.5% glutaraldehyde and washed in DMEM, the coated beads that attached to the splenic marginal zone were viewed in an Olympus BH-2 microscope equipped with phase-contrast optics. In both adherence experiments, the mean number of yeast cells or the adhesin-coated latex beads was calculated from 20 different fields of the splenic marginal zone (five fields per section; we examined four sections). This experiments was repeated twice. To evaluate the results of adhesin activity among the PMPCs, Student's t test was performed.
Nuclear magnetic resonance (NMR) analysis.
The presence of
-1,2-, -1,3-, and -1,2-linked mannose chains in each
PMPC of C. albicans and S. cerevisiae
was analyzed in a JEOL-GSX 400 spectrometer as described previously
(32).
Measurement of carbohydrate. Total amount of carbohydrates in each PMPC was determined by the phenol-sulfuric acid method (10) with D-mannose as a standard. The contents of carbohydrate in Fr.IIS, Fr.II/scwt, Fr.II/scmn1, Fr.II/scmn2, and Fr.II/scmn4 used were 95.6, 93.5, 91.4, 93.8, and 92.8%, respectively.
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RESULTS |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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Characterization of various PMPCs.
In dot blots, ConA
reacted with all PMPC samples isolated from C. albicans and S. cerevisiae wild-type and
mnn mutant strains. Anti-factor 5 and MAb B6.1, which react
with -1,2-linked mannosyls of C. albicans, did
not react with Fr.IIS or with any PMPC derived from S. cerevisiae. Anti-factor 9 rabbit serum, which detects core
-mannan, reacted strongly with scmn2/Fr.II (data not shown). Both anti-scmn1/Fr.II and anti-scmn4/Fr.II reacted with PMPCs from C. albicans and S. cerevisiae
wild-type and mutant strains but not with scmn2/Fr.II). NMR
analysis of Fr.IIS from C. albicans and PMPCs
from S. cerevisiae showed no evidence of
-1,2-linked oligomannosyl residues,
scmn1/Fr.II did not contain -1,3-linked mannosyl residues, and
scmn2/Fr.II did not contain -1,2-or -1,3-linked mannose chains (data not shown). These were the results expected, based on previous reports (2, 32).
Effects of enzymatic digestion on the adhesin activity of
Fr.IIS.
The acid-stable part (Fr.IIS) of the C. albicans PMPC has adhesin activity, as determined by its ability
to inhibit binding of C. albicans yeast cells to the
splenic marginal zone (19). The ability of Fr.IIS to inhibit
the binding was strongly reduced after treatment with an
-mannosidase that generally degrades -mannan (18).
Also, -1,2-specific mannosidase reduced the adhesin activity of
Fr.IIS, but to a lesser extent than -mannosidase treatment (Table
2). In contrast, proteinase K treatment
had no effect on the adhesin activity of Fr.IIS (Table 2).
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Adhesin activity of acid-stable oligomannosyls obtained from acetolysis of the C. albicans PMPC. We tested the oligomannosyls (M1 to M6) isolated as acetolysis products from the acid-stable part of C. albicans PMPC for the ability to inhibit yeast cell adherence by adding each to the splenic cryosections prior to addition of yeast cells. The binding of C. albicans to the marginal zone was not inhibited by any of the oligomannosyls tested at 20 µg/ml (inhibition of 2 to 3%), and only slight (3 to 10%) inhibition occurred when each was tested at 100 µg/ml.
Sulfuric acid hydrolysis inactivates adhesin activity of Fr.IIS. To release mannose units from the nonreducing ends of the oligomannosyl side chains, Fr.IIS was treated with 0.6 N sulfuric acid for 0 to 6 h at 100°C. Samples from each time period were separated on a size exclusion column (Fig. 1). A peak corresponding to a single released mannose (M1) increased during the treatment, and peaks of di- and trisaccharides (M2 and M3) also slightly increased during the treatment; in contrast, the amount of void-volume material decreased by 6 h of chemical treatment (Fig. 1). During the acid hydrolysis, oligosaccharides greater than trisaccharides were not detected. The fractions corresponding to M1, M2 plus M3, and the void-volume material were pooled and lyophilized. All samples were added to the splenic cryosections at 20 µg/ml to test for adhesin activity by the ability to inhibit adherence of yeast cells to the splenic marginal zone in the ex vivo assay. In all cases, M1 and a mixture of M2 and M3 did not show adhesin activity (Table 3). The adhesin activity of the void-volume material decreased as a function of time upon treatment with sulfuric acid (Table 3). By 6 h of treatment, essentially all Fr.IIS adhesin activity was destroyed and none of the released degradation products had activity. These data suggested that oligomannosyl side chains and side chain length are important in the adhesin activity of the acid-stable part of the PMPC.
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Adhesin activity of PMPC from S. cerevisiae wild-type and mnn mutants. PMPC samples of S. cerevisiae strains were tested for adhesin activity at 10 µg/ml in the ex vivo assay as described above for PMPC from C. albicans. The greatest adhesin activity was associated with PMPC from S. cerevisiae mutant mnn1 (Fig. 2). scmn1/Fr.II caused a 60% inhibition of C. albicans yeast cell adherence to the splenic marginal zone. This inhibition was slightly stronger than that of scwt/Fr.II (P < 0.1) but weaker than that of C. albicans Fr.IIS (P < 0.05), which gave about 90% inhibition when tested at 10 µg/ml. scmn4/Fr.II inhibited yeast binding to a lesser extent than scmn1/Fr.II (P < 0.05), but scmn2/Fr.II showed essentially no inhibitory activity at 10 µg/ml (Fig. 2). When tested at 50 µg/ml, adhesin activity was also negligible (inhibition of C. albicans yeast cells binding was only 7.2% ± 6.3%).
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Expression of the C. albicans acid-stable moiety of the PMPC on the yeast cell surface. If the acid-stable moiety is an adhesin, it should be expressed on the cell wall surface. We used rabbit polyclonal antibodies, anti-scmn1/Fr.II and anti-scmn4/Fr.II rabbit polyclonal antibodies, and IFM to analyze expression. Stationary-phase hydrophilic C. albicans yeast cells incubated with anti-scmn1/Fr.II showed bright fluorescence over the entire surface of all yeast cells (Fig. 4A). This was confirmed by flow cytometric analysis, which showed that 99.8% of the stationary-phase C. albicans yeast cells expressed the PMPC acid-stable moiety on the cell wall surface (data not shown); Fig. 4B shows the same expression pattern for yeast cells that adhered to the splenic marginal zone. Results were similar when anti-scmn4/Fr.II was used (data not shown). Negative controls, which consisted of yeast cells reacted with normal rabbit serum, showed no detectable fluorescence (data not shown). In addition, reaction of C. albicans cell walls with the two antibodies was inhibited by adding of C. albicans Fr.IIS at 250 µg/ml at the time of addition of the antibodies (data not shown).
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DISCUSSION |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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The C. albicans PMPC is composed of acid-stable
mannan and phosphate-bound acid-labile mannan parts, the entire
complex of which is N linked to protein (24, 32). We
have studied adhesin activity of the C. albicans PMPC
in relation to adherence of yeast cells to macrophages of the mouse
splenic marginal zone (13, 17, 18) and found that the
adhesin activity of the complex is due to acid-labile and acid-stable
parts (19, 27). The adhesin associated with the acid-labile
part of the PMPC is a -1,2-mannotetraose (27). Since
adhesin activity associated with the acid-stable part of the molecule
appears to be stronger than that of the mannotetraose (19),
in this study we sought to define the minimum chemical requirement for
adhesin activity of this adhesin moiety.
The acid-stable part consists of an -1,6-linked mannan outer
core unit and -1,2-and -1,3-linked oligomannosyl
chains side chains bound to the core (23). More recently, an
-1,6-linked mannose side chain was found in the acid-stable part of
the C. albicans PMPC (33). The findings
reported here demonstrate that digestion of Fr.IIS with a general
-mannosidase completely destroyed the adhesin activity of Fr.IIS, as
evidenced by loss of the ability of the digest to inhibit binding of
C. albicans yeast cells to the splenic marginal zone in
an ex vivo assay. This result is similar to our earlier findings
(18) and indicates that mannose chains are essential for
adhesin activity of the acid-stable part of the PMPC. Our finding
that -1,2-mannosidase treatment incompletely decreased the
adhesin activity of Fr.IIS suggests that -1,2-linked oligomannosyl side chains are partially responsible for the
adhesin activity. These side chains are not sufficient, however, for
adhesin activity because yeast binding was not inhibited by any
acetolysis-released oligomannosyl side chains (M1 to M6) at
20 µg/ml and only slightly affected at 100 µg/ml; the latter value
is more than 10 times the concentration required for inhibition of
adherence due to Fr.IIS.
One interpretation of the results from the -1,2-mannosidase
digestion and subsequent lack of adhesin activity associated with
the isolated oligomannosyl side chains is that the
-1,6-mannan core is responsible for the acid-stable adhesin
activity. However, the results from experiments using scmn2/Fr.II,
which contains the -1,6-mannan core but lacks all -1,2-and
-1,3-linked oligomannosyl side chains (2),
showed that the core alone is not sufficient for adhesin activity.
These results imply that both the mannan outer core and the
oligomannosyl side chains are essential for adhesin
activity of the acid-stable part of the PMPC.
To investigate the relationship between side chain length and adhesin
activity, we used partial sulfuric acid hydrolysis. Others have shown
that sulfuric acid cleaves glycosidic linkages at the terminal mannoses
of the oligomannosyl side chains (22). When
Fr.IIS was treated with sulfuric acid for various lengths of time and
elution profiles of the hydrolysates were monitored on a size exclusion
column, the relative amount of monomeric mannose (M1) increased during
the treatment, and peaks corresponding to M2 and M3 also increased
slightly with time. These results are consistent with hydrolysis
preference for terminal mannose units rather than random breakage of
glycoside bonds. Fractions eluted in the void volume, therefore, would
be composed of the -mannan core with truncated versions of the
oligomannosyl side chains, the lengths of which were
proportional to the time of hydrolysis. The adhesin activity of the
fraction eluted in the void volume was clearly reduced as a
function of time of hydrolysis (Table 3). The above results
strongly suggest that adhesin activity is directly related to
the mannosyl chain length. This suggestion is supported by the
experiments using the S. cerevisiae PMPCs. Wild-type
S. cerevisiae PMPCs have shorter
oligomannosyl side chains than C. albicans (2). Accordingly, the PMPC from the wild-type
strain, S. cerevisiae X2180, had less adhesin activity than the C. albicans Fr.IIS. We used the simpler
PMPC structure from S. cerevisiae wild-type and
mnn mutant strains to explore the minimum chemical
requirements for adhesin activity of the acid-stable part of the
PMPC. All PMPC extracts except that from S. cerevisiae
mnn2 showed adhesin activity, but lower than that of PMPC from
C. albicans. These results confirm that mannosyl side
chains are essential for adhesin activity and indicate that chain
length is also important. The nature the side chain linkages appears to
be of less significance; in fact, our results for the mnn1
mutant suggests that terminal -1,3-linked mannose units may even
interfere with adhesin activity. Our conclusion that side chain length
is important was also supported by preliminary experiments in which the
more elaborate PMPC from a serotype A strain of C. albicans had more adhesin activity than PMPC from a serotype B
strain which has shorter side chains (32).
Molecules involved in adherence of yeast cells to host cells or tissues should be expressed on the surface of the fungal cell wall. In accordance with this supposition, several morphological observations by electron microscopy have shown that C. albicans mannans are located on the surface of cell wall and along the plasmalemma (27, 36). In this study, polyclonal antibodies against S. cerevisiae mannan used to detect the acid-stable part of the C. albicans PMPC reacted with the entire surface of yeast cells, as observed by IFM. Flow cytometric analysis revealed that about 99.8% yeast cells expressed this moiety on the cell wall surface. These findings were consistent with the acid-stable adhesin activity of the cell wall PMPC of C. albicans. In addition, the acid-labile adhesin moiety of the PMPC was expressed over the entire surface of yeast cells (14).
Antibodies against the Candida phosphomannan complex might be expected to block adherence, but they do not. Possible explanations are that although the antibodies react with the phosphomannan complex on the cell wall surface, their specificity is for nonadhesin sites within this large complex. Thus, the adhesin sites may still be free to attach to Candida receptors in the splenic marginal zone. This is a logical explanation because the antibody was generated against S. cerevisiae mannan, which would preclude having antibodies with specificities against certain adhesin sites in the acid-stable and acid-labile parts of the phosphomannan complex of C. albicans. Adherence of the Candida yeast cells may occur in vivo even in the presence of antibodies specific for adhesin sites in the phosphomannan complex, provided that the antibodies on the yeast surface results in rapid complement activation and adherence via C3 receptors on marginal zone macrophages. In the presence of Candida-specific antibodies, complement activation on the yeast cell surface has been shown to occur within 1 to 2 min (25), which would be rapid enough to promote adherence to the splenic marginal zone macrophages.
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ACKNOWLEDGMENTS |
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We thank Leo Dewald for excellent assistance and N. Shibata, Tohoku College of Pharmacy, for his special assistance with NMR analysis and for providing oligomannosyls of C. albicans.
This work was supported by grants for Scientific Researcher from the Ministry of Education, Science and Culture (grant 09670278) and from the Ministry of Health and Welfare (to T.K.) and grant 5RO1 AI 24912 to J.E.C. from the National Institute of Allergy and Infectious Diseases.
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FOOTNOTES |
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* Corresponding author. Mailing address: Laboratory of Medical Mycology, Research Institute for Disease Mechanism and Control, Nagoya University School of Medicine, 65 Tsurumai, Showa-ku, Nagoya 466-8550, Japan. Phone: 8152-744-2460. Fax: 8152-744-2459. E-mail: tkanbe{at}tsuru.med.nagoya-u.ac.jp.
Editor: T. R. Kozel
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REFERENCES |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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Infection and Immunity, December 1998, p. 5812-5818, Vol. 66, No. 12
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