(Received for publication, August 17, 1994; and in revised form, November 14, 1994)
From the
-Glucan receptors are present on mammalian leukocytes and
initiate phagocytosis of particulate yeast
-glucans, such as
zymosan particles. Human monocytes and U937 cells express two membrane
proteins of 180 and 160 kDa, each of which binds particulate yeast
glucan through a 20-kDa polypeptide constituent. In this report, the
structural composition of the two
-glucan receptors and the
biochemical properties of their polypeptide constituents were examined.
The 180-kDa receptor was composed of three disulfide-linked
polypeptides of 95, 60, and 20 kDa, whereas the 160-kDa receptor was a
multimer of two polypeptides of 27 and 20 kDa. Unlike other receptor
constituents, the 20-kDa polypeptide was nonglycosylated and focused at
two distinct isoelectric points. Immunoblots of the focused
polypeptides showed the two 20-kDa variants and the 95-kDa subunit to
be constitutively tyrosine-phosphorylated, a feature not previously
reported for receptors on human mononuclear phagocytes.
Dephosphorylation of the receptor proteins resulted in the loss of
antigenic phosphotyrosine without affecting the antigenicity of either
20-kDa variant for the anti-idiotypic antibody to
-glucan
receptors. Separate analysis of the 160-kDa receptor showed it
contained both variants of the 20-kDa polypeptide. Thus, the 20-kDa
subunit constituent of the two
-glucan receptors is a functionally
and chemically unique polypeptide with apparent microheterogeneity in
its primary structure.
Yeast -glucan is a carbohydrate polymer derived from the
cell wall of Saccharomyces cerevisiae and composed of
-D-glucopyranosyl residues with consecutive 1,3 and
branched 1,6 linkages(1) .
-Glucan is a major constituent
of yeasts and fungi (2) and is the active pharmacological agent
of zymosan particles(3, 4) . The administration of
yeast
-glucans to laboratory animals rapidly gives rise to a state
of increased resistance to a variety of biologic insults through
mechanisms initiated by macrophages (5, 6, 7) . Recent studies with the soluble
yeast
-glucan, Betafectin, have shown it to protect against lethal
peritonitis in the rat model for intra-abdominal sepsis (8) and
have demonstrated its efficacy as an anti-infective agent against
postoperative infections in high risk surgical patients(9) .
Unlike nearly all ligands thus far reported for mammalian cells, the
yeast
-glucans are molecules which are totally foreign to animals
and, yet, are nonimmunogenic(10, 11) .
The
particulate yeast -glucans have been extensively used in isolated
cell systems because of their potent and pleiotropic immunomodulatory
activating capacities. Glucan and zymosan particles stimulate rapid
phagocytic responses in human monocytes, and these are inhibited
selectively by soluble yeast
-glucans(12, 13) .
Ligation of monocyte
-glucan receptors by particulate yeast
glucans induces production of a broad spectrum of cellular metabolites (14) and phosphorylation of a substantial number of cellular
proteins(15, 16) , some of which appear to be linked
to early secretory and synthetic responses(15) . During serum
opsonization, the dominant complement fragment deposited onto zymosan
particles is iC3b(17) , which binds to the I domain of the
-chain subunit of complement receptor type 3 (CR3;
CD11b)(
)(18) . The deposition of C3 fragments on
particles already displaying an independent phagocytic signal augments
phagocytosis by improving contact between particle and
cell(19, 20, 21, 22, 23) .
A role for a glucan-binding site on CR3 has been
suggested(24) . However, ligand binding studies with purified
CR3 show no binding by this complement receptor to unopsonized zymosan
particles or to soluble
-glucan(25) , and functional
studies with monocytes from patients genetically deficient in CR3 show
no impairment in the zymosan-induced production of platelet-activating
factor by a mechanism inhibitable by soluble
-glucans(26) .
-Glucan receptors have been best
described for human monocytes in terms of ligand specificity. Monocyte
-glucan receptors do not recognize homopolysaccharides of mannose
and galactose, or homoglucosyl polysaccharides with
-anomeric or
-1,4 linkages(12) . The smallest functional ligand has
been isolated and shown by mass spectrometry to be a yeast
heptaglucoside(27) . Structural conformations inherent to the
yeast glucan polymers are required for monocyte recognition, a feature
not exhibited by mammalian receptors for other carbohydrate molecules,
such as mannose (28) and galactose (29, 30) .
Steps to prepare an antibody to monocyte
-glucan receptors have
focused on the ligand specificity of the receptors so as to obtain an
antibody to the ligand-binding domain(31) . As schematically
shown in Fig. 1, an anti-idiotypic antibody was prepared to the
antigen-combining site or idiotype (Id) of a monoclonal antibody (mAb
OEA10) that recognizes the biologically active epitopes on particulate
yeast glucans and the purified yeast heptaglucoside. The idiotypic
specificity of the anti-Id is apparent by its capacity to compete with
-glucan ligand for mAb OEA10 and by its selective capacity to bind
and block monocyte ingestion of particulate yeast glucans. Two
-glucan receptors of 180 and 160 kDa have been isolated from human
myelomonocytic U937 cells and normal monocytes by immunoaffinity
purification with the anti-Id(32) . On both types of cells, the
two receptor proteins contain a 20-kDa polypeptide subunit which
expresses the anti-Id epitope and glucan-binding domain, and the
160-kDa protein presents as the immunodominant
-glucan receptor.
In this report, we present the structural composition of the 180- and
160-kDa
-glucan receptor proteins on U937 cells and characterize
the polypeptide subunit chains of the two multimeric proteins. Each
polypeptide subunit exists as a distinct structural domain maintained
by disulfide bonds, and the 20-kDa glucan-binding domain presents as
two allelic variants differing in isoelectric points.
Figure 1:
Schematic representation of a binding
site-specific antibody for -glucan receptors. Soluble and
particulate yeast
-glucans are recognized by plasma membrane
receptors (A) and by mouse mAb OEA10 (B). An
antibody, prepared to the antigen-combining region or Id of the mouse
monoclonal, binds to the ligand-binding region of
-glucan
receptors (C).
Figure 2:
Immunospecificity of mAb ACIA12 for the
160-kDa -glucan receptor. Detergent-soluble proteins from
surface-radioiodinated U937 cells were sequentially immunoprecipitated
for 1 h at 4 °C with mouse IgG1 (mAb BD4), mouse IgG1 mAb ACIA12,
and the rabbit IgG anti-Id (left panel), or were preadsorbed
with rabbit IgG and the anti-Id before immunoprecipitation with mAb
ACIA12 (right panel). The immunoadsorbed proteins were eluted,
resolved in nonreduced samples by SDS-PAGE in 5-15% acrylamide
gradient gels, dried, and detected by exposure to x-ray film. Variable
amounts of residual 180-kDa protein were present in cell samples
heavily surface-labeled and immunoprecipitated by mAb ACIA12,
suggesting a close association between the two
-glucan receptor
proteins in the cell membrane. Mobility and size of prestained protein
standards are indicated.
The surface-specific method described for
lactoperoxidase (Sigma) and HO
(36) was
used to radiolabel 2
10
U937 cells in 1 ml of PBS
with 1 mCi of Na
I at 4 °C for 15 min. The labeled
cells were washed, lysed at 4 °C for 1 h in PBS containing 1%
Nonidet P-40, 5 mM diisopropyl fluorophosphate, 2 mM phenylmethylsulfonyl fluoride, 1 µM pepstatin, and 1
µM leupeptin (lysis buffer), and centrifuged at 12,000
g for 30 min at 4 °C. The detergent-soluble
fractions were precleared with BSA-Sepharose beads for 18 h at 4 °C
and subjected to sequential immunoprecipitation(32) .
For nonreducing/reducing
two-dimensional SDS-PAGE, nonreduced samples of affinity-purified
proteins were resolved by electrophoresis and gel strips, 11 2
cm, containing the resolved proteins were excised from the gel. The gel
strips were incubated at 21 °C for 20 min in sample buffer
containing 2% SDS and 10 mM dithiothreitol and inserted into a
13-cm sample well of the second gel. Prestained standards were loaded
into a separate 7-mm well, and the running buffer for the second gel
contained 0.1 mM sodium thioglycollate. The separated proteins
were detected by silver staining as recommended by the manufacturer
(Bio-Rad).
For carbohydrate analysis by periodic acid-Schiff (PAS) reagent, reduced samples of purified receptor protein were separated by SDS-PAGE, electroblotted onto nitrocellulose, treated for 15 min with 1% periodic acid in 3% acetic acid, and washed with several changes of distilled water. The oxidized samples were stained for 15 min in the dark with fresh Schiff's reagent, treated for 5 min with 0.5% sodium m-bisulfite, washed, and stored in the dark. By this procedure, the carbohydrate in ovalbumin (4%) and rabbit IgG (3%) was detectable in blots of 0.1 µg of electrophoresed protein. To assess for transfer efficiency, concurrent samples of electrophoresed receptor protein were electroblotted onto nitrocellulose and stained for protein with 0.1% Ponceau S in 0.1% acetic acid.
Figure 3:
Subunit constituents of the 180- and
160-kDa -glucan receptor. Two-dimensional SDS-PAGE in 5-15%
acrylamide gradient gels was performed with 5 µg of
affinity-purified U937 cell receptor protein under nonreducing (NR) conditions in the first dimension and reducing (R) conditions in the second. The reference parent molecules
and their protein subunits were detected by staining with silver.
Analyses of four preparations of purified
-glucan receptors showed
variations in the proportions of the apparent aggregates of high
molecular size and the 88-kDa subunit. The mobility of a BSA
contaminant falls midpoint on the diagonal and was detectable in lanes
with and without loaded sample. Mobility and size of prestained protein
standards are indicated.
Figure 4:
Isoelectric points of the -glucan
receptor subunit constituents. Two-dimensional electrophoresis with
isoelectric focusing in the first dimension and SDS-PAGE in the second
was carried out under reducing conditions with 12 µg of
immunoaffinity purified U937 cell
-glucan receptors. The pH
gradient in the focusing gel was determined by measuring the pH of
ampholytes eluted into distilled water from 1-cm
segments
of the 5% slab gel, and the focused receptor polypeptides were
identified by staining the 5-15% acrylamide gradient sizing gel
with Coomassie Blue. Each of the subunit polypeptides exhibited the
same pI when focusing was increased from 8,000 to 12,000 V-h,
indicating that equilibrium had been
reached.
Charge heterogeneity of otherwise identical proteins is frequently
attributable to the content of sialic acid residues in oligosaccharide
side chains, many of which are covalently linked to N-glycosylation sites. The contribution of glycosylation as a
source of charge heterogeneity of the 20-kDa polypeptide was approached
in two ways: enzymatic removal of N-linked glycosylated units
and chemical oxidation of monosaccharides followed by staining with
Schiff's reagent. By the first method, 12 µg of purified
-glucan receptor protein or 10 µg of ovalbumin were incubated
for 24 h at 37 °C in the absence and presence of N-glycanase, and the resulting products were resolved by
SDS-PAGE. Under these enzymatic and electrophoretic conditions, the
ovalbumin control exhibited a downward shift in electrophoretic
mobility of about 1,000 daltons after treatment with N-glycanase (Fig. 5). The 95-kDa polypeptide contained
substantial amounts of N-linked carbohydrate, with the
predominant N-deglycosylated form of this molecule having a
molecular size of 76 kDa. Digestion with N-glycanase resulted
in less dramatic decreases in the apparent molecular weights of the 60-
and 27-kDa polypeptides and produced no detectable change in the 20-kDa
polypeptide. A likely dimer of incompletely reduced 20-kDa polypeptide (32) presented as a band of 40 kDa and, as with the fully
reduced 20-kDa subunit, showed no shift in electrophoretic mobility
after enzymatic digestion. Carbohydrate analysis by PAS staining can
potentially detect any oligosaccharide side chain of mammalian proteins
irrespective of linkage or sugar modification. For this analysis, 20
µg of purified
-glucan receptor protein were resolved by
SDS-PAGE under reducing conditions, transferred onto nitrocellulose,
and assessed for carbohydrate by the PAS assay. A concurrent sample of
12 µg of receptor protein was separated on the same gel,
transferred onto nitrocellulose, and stained for protein. The rank
order of glycosylation for the four receptor constituents was the same
by PAS staining as that detected by N-deglycosylation (Fig. 6). The 95-kDa polypeptide had the highest content of
oligosaccharide, whereas the 20-kDa polypeptide had no detectable
carbohydrate despite its being the most prominent transferred
polypeptide subunit.
Figure 5:
N-Glycosylation of the
-glucan receptor constituent polypeptides. Reaction mixtures (50
µl) of reduced samples containing 12 µg of purified receptor
protein were incubated without (Control) and with 0.8 unit of N-glycanase (N-g'ase) for 24 h at 37 °C.
The resulting products were resolved by SDS-PAGE and stained with
Coomassie Blue. Parallel samples containing 10 µg of ovalbumin (OA) were treated in a similar fashion. Under these conditions
of hydrolysis, the ovalbumin control exhibited a downward shift in
electrophoretic mobility of about 1,000 daltons after treatment with N-glycanase. Mobility and size of prestained protein standards
are indicated.
Figure 6:
Chemical analysis of the oligosaccharide
content of the -glucan receptor polypeptides. Samples of 20 µg
of purified receptor protein were resolved under reducing conditions in
5-15% acrylamide gradient gels by SDS-PAGE, transferred onto
nitrocellulose, and stained for carbohydrate (CHO) by
treatment with PAS reagent. Concurrent samples of 12 µg of purified
receptor proteins were stained for protein with Ponceau S. The lower
level of sensitivity of the PAS method was 5-10 ng of CHO for
glyco-protein standards electrophoresed and immobilized on
nitrocellulose.
Figure 7:
Constitutive tyrosine phosphorylation of
-glucan receptor polypeptides. Two-dimensional gel analysis by
isoelectric focusing followed by SDS-PAGE was carried out under
reducing conditions with 12 µg of purified
-glucan receptors.
The polypeptide subunits were transferred onto nitrocellulose, probed
with anti-phosphotyrosine, and detected by radioautography with
I-labeled goat anti-rabbit F(ab`)
. Control
blots on Immobilon treated with 1 M KOH before incubation with
the primary antibody revealed reactivity by each of the three
polypeptide subunits with anti-phosphotyrosine. The pH gradient of the
focusing gel was determined as described in Fig. 4.
Figure 8:
Localization of the two species of 20-kDa
polypeptides within the 160-kDa -glucan receptor. The 160-kDa
receptor was isolated by affinity purification with mAb ACIA12 and
reduced samples with 20 µg of purified protein were subjected to
two-dimensional gel electrophoresis by isoelectric focusing followed by
SDS-PAGE. The protein constituents in the sizing gel were detected by
staining with Coomassie Blue, and the pH gradient in the focusing gel
was determined as described in Fig. 4.
The present studies demonstrate the structural composition of
two -glucan receptors on human myelomonocytic U937 cells and
investigate the biochemical properties of their disulfide-linked
subunit constituents. Immunologic studies on human monocyte and U937
cell
-glucan receptors have shown both receptors to be multimeric
and have in common a 20-kDa polypeptide subunit which contains the
glucan binding domain(32) . The 20-kDa polypeptide is a key
subunit constituent for receptor function and contains epitopes for the
anti-idiotypic antibody previously shown to bind human monocytes and
selectively block their phagocytosis of particulate yeast
glucans(31) . As with anti-idiotypic antibodies to other
receptors(41) , ligand rather than membrane protein is used to
generate antibody, thereby limiting the antigenic specificity of the
final product to an antibody directed against ligand-binding sites in
the receptor (Fig. 1). The capacity of mAb OEA10
anti-
-glucan to recognize a haptenic ligand (31) , the
yeast heptaglucoside(27) , greatly increased the likelihood
that the anti-idiotypic antibody would be reactive and specific for
human
-glucan receptors. The availability of U937 cells made it
possible to prepare the large amounts of purified
-glucan receptor
protein needed for biochemical analyses. By two-dimensional analysis,
each of the two nonreduced receptors was reduced to its constituent
subunits, and each polypeptide constituent was detected by a sensitive
silver staining technique. The 180- and 160-kDa
-glucan receptors
both presented as complex dulfide-linked structures with the
composition of one, indicating it to be multivalent (Fig. 3).
The 180-kDa receptor was composed of three disulfide-linked
polypeptides of 95, 60, and 20 kDa and was estimated to contain these
subunits at equimolar ratios. The composition of the 160-kDa receptor
was limited to two polypeptides of 27 and 20 kDa, which were linked to
each other by disulfide bonds at molar ratios of about 2 and 5,
respectively. The presence of as many as five 20-kDa subunits in each
160-kDa receptor molecule may relate to the homopolymeric nature of the
-glucan ligands and effect high avidity binding between
-glucan receptors and ligands. No significant differences in the
number or sizes of the receptor subunits were apparent by the inclusion
of additional protease inhibitors at various points during
purification, indicating that both
-glucan receptors were cleaved
and bridged by disulfide bonds in their native state. The anti-Id
recognizes primary rather than conformational determinants in the
20-kDa polypeptide, making it possible to enrich for denatured or
native forms of the 20-kDa subunit during receptor purification.
Scale-up preparations of isolated receptor proteins, however, contained
no monomeric or partially assembled 20-kDa polypeptide subunits (Fig. 3), suggesting that each of the two
-glucan receptors
is derived from a proreceptor by proteolytic processing at regulated
cleavage sites rather than by post-translational assembly.
The
composite biochemical properties of the 20-kDa polypeptide subunit
showed it to be an unusual polypeptide and a unique constituent of
-glucan receptors. Compositional analysis of the four polypeptide
subunits from the two receptors revealed high similarities between the
amino acids of the 95-kDa subunit of the 180-kDa receptor and the
27-kDa subunit of the 160-kDa receptor protein, whereas relatively
little similarity in amino acid composition was apparent between the
20-kDa subunit and the three other subunit constituents (Table 1). Except for the 20-kDa polypeptide, each subunit
constituent of the 180- and 160-kDa
-glucan receptors exhibited a
single isoelectric point, with the 95- and 27-kDa polypeptides focusing
at nearly the same pI (Fig. 4). The 20-kDa polypeptide focused
as 2 molecules with pI more basic than those of the other subunits,
which may reflect its higher content of lysine residues. An average
charge differential of 0.3 pH unit was expressed by the two variants of
the 20-kDa subunit, the more minor of which had the lower pI and
accounted for about 15-20% of the two 20-kDa molecules. Since
charge heterogeneity often resides with the quantities of sialic acid
residues in oligosaccharide side chains or modifications by sulfation
or phosphorylation of sugar residues, glycosylation of the
-glucan
receptor constituents was the first parameter examined. The molecular
size of the 20-kDa polypeptide was unaffected by hydrolysis with N-glycanase, suggesting the absence of N-linked
oligosaccharides in this molecule (Fig. 5). A sensitive and more
general assay for carbohydrates was devised based on PAS staining. By
this method, monosaccharides containing vincinal hydroxyls are required
for positivity, a criterion met by nearly all oligosaccharide chains of
mammalian glycoproteins. Blots containing the 20-kDa polypeptide in
amounts 80-100-fold greater than the lower level of detection of
the typically glycosylated reference proteins showed no carbohydrate by
PAS staining (Fig. 6), indicating that the primary structure
and/or folding of the 20-kDa polypeptide precluded glycosylation.
Unlike the 20-kDa polypeptide, each of the other receptor constituents
was glycosylated as assessed by the enzymatic and chemical assays. In
both assays, the 95-kDa polypeptide presented as the most glycosylated
subunit, the 60-kDa as the least, and the 27-kDa as the most complex.
These data suggested that much of the carbohydrate detected by PAS
staining in these receptor constituents consisted of N-linked
oligosaccharides.
Studies on phosphorylation were initiated to
determine whether phosphorylation was a factor contributing to the
charge heterogeneity of the 20-kDa polypeptide. Even when consideration
was given to the fact that unopsonized zymosan particles induce protein
tyrosine phosphorylation in human monocytes(16) , the finding
that -glucan receptors from unstimulated cells were phosphorylated
on tyrosine residues of the 95- and 20-kDa constituent subunits was
unexpected (Fig. 7). As indicated in the text, dephosphorylation
with alkaline phosphatase rendered these molecules free of phosphates
but had little if any effect on their overall electrophoretic
differences. That both variants of the 20-kDa polypeptide retained
reactivity with the anti-Id suggested that phosphoamino acids were not
located within the glucan-binding domain. Although constitutive
phosphorylation has been reported for a number of receptors, the vast
majority of these protein phosphorylations occur through serine or
threonine residues. For receptors on human mononuclear phagocytes,
cross-linking of Fc
RI (CD64) and Fc
RII (CD32) on U937 (42) and THP-1 (43) cells by receptor antibodies
stimulates tyrosine phosphorylation, but neither phagocytic receptor
appears to be constitutively phosphorylated. Constitutive rather than
stimulus-inducible phosphorylation is a feature of the
-chains
(CD11a, b, and c) of the
2 integrin proteins (CD11/CD18), for
which the phosphorylated substrate is serine (40) . Conversely,
the common
-chain (CD18) is not phosphorylated in its basal state,
but treatment of human monocytes with soluble agents, such as phorbol
esters, rapidly and dramatically stimulates serine phosphorylation of
CD18. To our knowledge, no receptor on human mononuclear phagocytes has
been shown to be constitutively tyrosine phosphorylated prior to this
report.
The preparation of monoclonal antibodies to purified 180-
and 160-kDa -glucan receptors resulted in a mAb specific for the
160-kDa receptor and provided a means for separating the two receptors (Fig. 2). Analysis by isoelectric focusing clearly showed the
purified 160-kDa receptor to contain two variants of the 20-kDa
polypeptide (Fig. 8). Comparison of the 20-kDa variants before
and after purification of the 160-kDa protein from receptor
preparations revealed no significant differences in their isoelectric
points or relative proportions, thereby diminishing the possibility
that each of the two receptors contained a different type of 20-kDa
polypeptide with a distinguishing isoelectric point. Since isoelectric
focusing is sensitive to a difference of a single changed amino acid,
the charge heterogeneity observed for the 20-kDa polypeptide was a
likely reflection of microheterogeneity in its primary structure. That
the compositions and relative concentrations of each 20-kDa variant
were comparable regardless of whether samples were stained with protein
dyes or antibodies indicated them to be highly homologous constituents
and occurring at fixed frequencies in the
-glucan receptors. These
data were supported by those obtained with the purified 160-kDa
receptor protein, all of which are consistent with the 20-kDa
polypeptides being allelic variants.