Expression of complement receptor type 1 (CR1) on erythrocytes of paracoccidiodomycosis patients

Complement receptor type 1 (CR1) is a membrane glycoprotein that acts as a receptor for the C3b, iC3b and C4b fragments of complement. In primates, one function of erythrocytes is to promote safe clearance of immunocomplexes (IC) from the circulation through CR1. Theoretically, in diseases characterized by high levels of circulating IC, an erythrocyte CR1 (CR1/E) deficiency may favor IC deposition in tissues or facilitate inappropriate activation of leukocytes in the circulation. Depression of the cell immune response occurs in paracoccidioidomycosis (PCM), especially in the more severe cases, and is frequently associated with high serum IC levels. In the present study we quantified the number of CR1/E in patients with the acute and chronic forms of PCM before and after treatment and correlated it with serum IC levels and CD4+ and CD8+ T cell concentration in the peripheral blood of these patients. Patients with PCM, particularly those with active disease and who had received treatment for shorter periods of time, had low numbers of CR1/E. In addition, an increase in serum IC concentration and a reduction in the CD4+/CD8+ T cell ratio were observed. After treatment there was a significant increase in mean CR1/E number and a reduction in serum IC levels. In patients with the chronic form of the disease the CD4+/CD8+ T cell ratio tended to increase after treatment and was associated with increased CR1/E levels. These results suggest that the reduction in CR1/E observed in patients is a phenomenon acquired with the disease and that CR1 could play a role in the pathogenesis of PCM.This revised version was published online in October 2005 with corrections to the Cover Date.     

Distribution in clusters of complement receptor type one (CR1) on human erythrocytes

The distribution of CR1 on human E was studied using label-fracture and thin section electron microscopy. CR1 was found to be organized in clusters on unfixed cells and on cells that had been prefixed with paraformaldehyde or glutaraldehyde before labeling. The number of clusters/E ranged from 8 to 20 as estimated from the examination of freeze-fracture replicas of labeled cells. Clusters contained an average of 30 to 75 gold particles on cells from two donors which expressed 462 and 586 CR1 Ag sites/cell, as determined by flow cytometry. In thin section electron micrographs, gold complexes were seen surrounding an electron-dense material protruding from the membrane which represents compact aggregates of CR1. The maximal distance between gold particles and the membrane was 100 nm, which corresponds to the estimated length of the major allotypic form of CR1, as calculated from the primary DNA sequence of the molecule. The distribution in clusters of CR1 on the E membrane may provide the basis for an enhanced affinity of C3b-CR1 interactions on the plasma membrane of the cells and may explain the preferential binding of C3b-bearing immune complexes to E in vivo.     

Cellular distribution of complement receptor type 4 (CR4): expression on human platelets

Neutrophils have been shown to express a receptor for C3dg that is distinct from CR2 and is termed complement receptor type 4 (CR4). In the present study, other peripheral blood cell types were examined by indirect immunofluorescence and flow cytometry for the presence of C3dg binding activity. Specific uptake of C3dg occurred with neutrophils, platelets, and B lymphocytes, but not with eosinophils or T lymphocytes. Monocytes, contained within a mixed cell population of peripheral blood mononuclear cells and platelets, also bound C3dg, whereas purified monocytes did not. Binding of 125I-labeled glutaraldehyde-cross-linked C3dg to platelets was saturable, with an average of 1940 C3dg molecules bound per platelet at saturation (n = 8), ranging in number from 660 to 3930 molecules bound. Activation of platelets with thrombin did not consistently cause an increase in the expression of CR4 sites. 125I-C3dg binding to platelets was competitively inhibited equally well by unlabeled C3dg and iC3b, and approximately fourfold less well by C3b. The addition of platelets to elutriated monocytes generated C3dg binding activity on these cells by the formation of platelet-monocyte complexes. Thus, the CR4 on platelets accounted for the C3dg binding activity initially observed with partially purified monocytes. The adherent property of platelets may enable them to confer on certain other cell types the ability to localize C3dg-coated immune complexes or particles.     

Human complement receptor type 1 (CR1) binds to a major malarial adhesin

Plasmodium falciparum erythrocyte membrane protein 1 (PfEMP1), a major adhesin molecule expressed on Plasmodium-falciparum-infected erythrocytes, interacts with several receptors on endothelial cells and uninfected erythrocytes. This 'stickiness', known as rosetting, is a strategy used by the parasite to remain sequestered in the microvasculature to avoid destruction in the spleen and liver. Erythrocyte rosetting causes obstruction of the blood flow in microcapillaries. Recent data suggest a direct interaction between PfEMP1 and a functional site of complement receptor type 1 (CR1; CD35) on uninfected erythrocytes. Consistent with the hypothesis that CR1 is important in malaria pathogenesis is a 40-70-fold increase in the frequency of two CR1 blood-group antigens (at least one of which might rosette less efficiently) in malaria-exposed African populations. Furthermore, structural differences in erythrocyte CR1 between human and non-human primates are probably explained by the selective pressure of malaria.     

Large-scale isolation of complement receptor type 1 (CR1) from human erythrocytes. Proteolytic fragmentation studies.

A large-scale procedure for the isolation of complement receptor type 1 (CR1, the C3b receptor) from human erythrocytes is described. Two of the four known phenotypes of CR1 are detectable in the isolated material. Amino acid and hexosamine analysis of the A phenotype (Mr 240 000) indicates a polypeptide chain length of about 2030 amino acids and a carbohydrate content of 8%. Both N- and O-linked sugars appear to be present. Trypsin digestion of isolated CR1 shows that it is degraded rapidly and extensively, and no stable products of Mr greater than 25000 are found. The ability of the receptor to bind to solid-phase ligand is destroyed after a single cleavage by trypsin. The capacity of the receptor to act as a cofactor for Factor I-mediated cleavage of soluble C3b is, however, only gradually decreased by proteolysis, and 30% of this activity remains after extensive degradation. The same pattern of loss of binding to solid-phase ligand, with partial retention of interaction with soluble ligand, is also characteristic of the complement proteins Factor H and C4bp, which are functionally related to CR1.     

Overexpression of complement receptor type I (CR1, CD35) on erythrocytes in patients with hemoplasma infection

In the present study, 12 patients with fever of undetermined origin, anemia and icterus were diagnosed with hemoplasma infection by light microscopy, transmission electron microscopy examination and PCR assay after being excluded from other usual febrile diseases. Complement receptor type I (CR1, CD35) expression on the surface of erythrocytes was assessed by flow cytometry using mouse anti‐human CD35 antibody. Compared with healthy volunteers, the level of CD35 was significantly elevated in patients with severe hemoplasma infection at diagnosis, and decreased sharply after treatment. However, in latent infection cases without clinical manifestations, CD35 expression showed an ascending trend but had no statistical difference compared to the healthy controls. The present study demonstrated that hemoplasma infection can induce high levels of expression of CR1 on the membrane of red blood cells, which may be a reaction to the immunity challenge.     

Loss of complement receptor type 1 (CR1) on ageing of erythrocytes. Studies of proteolytic release of the receptor.

Complement receptor type 1 (CR1) is a glycoprotein of Mr about 250 000 present on erythrocytes and other cell types. CR1 acts as a cofactor in the factor I-mediated breakdown of complement fragment C3b to form iC3b. Using an assay of cofactor activity, a wide variation in mean CR1 levels between erythrocytes from individual donors is observed. CR1 levels also decrease on ageing of erythrocytes in vivo, and again the rate of loss is widely variable between individuals. However, variable loss of CR1 during ageing of erythrocytes is likely to make only a minor contribution to the observed variation in mean CR1 levels. CR1 is very sensitive to proteolysis, and random proteolytic removal of CR1 from erythrocytes is likely to be an important factor in loss of CR1 on ageing of red cells in vivo. In vitro, mild trypsin treatment, plasmin or thrombin digestion of erythrocytes results in the loss of the factor I cofactor activity from the cell surface, and appearance of this activity in the supernatant. We conclude that an active fragment of CR1 is released from the cell surface on proteolysis. Subsequent prolonged trypsin treatment destroys most of the activity of this fragment. Proteolytic removal of CR1 from red cells may account not only for loss on ageing of cells, but also for the acquired CR1 deficiencies observed by others in systemic lupus erythematosus.     

Roles of the complement receptor type 1 (CR1) and type 3 (CR3) on phagocytosis and subsequent phagosome-lysosome fusion in Salmonella-infected murine macrophages

Abstract The receptors involved in the recognition of Salmonella typhimurium and S. typhi by murine macrophages were identified, and their relevance to phagosome-lysosome fusion was also investigated. Phagocytosis of S. typhimurium by murine macrophages was dependent on the opsonization with normal fresh serum, although the opsonin had no triggering activity in phagosome-lysosome fusion. In contrast, the opsonization of S. typhi with normal fresh serum efficiently triggered both phagocytosis and following phagosome-lysosome fusion. Anti-murine CR1 antibody suppressed phagocytosis of S. typhimurium by 36%, whereas anti-CR3 antibody, mannan, and advanced glycosylation endproducts (AGE)-BSA all failed to prevent phagocytosis of S. typhimurium , suggesting that CR1 may only contribute to the recognition of S. typhimurium and may possibly play a minor role. Other receptors involved may also influence the outcome phagocytosis in terms of phagosome-lysosome fusion. In the case of S. typhi , only anti-CR3 antibody significantly inhibited not only phagocytosis of S. typhi but also following phagosome-lysosome fusion. Treatment with K76COONa, an inhibitor of C3bINA (I factor), resulted in a marked inhibition of phagosomelysosome fusion in S. typhi -infected macrophages, although no significant inhibition was observed on phagocytosis of S. typhi . These results suggest that S. typhimurium and S. typhi may be recognized at least in part by CR1 and CR3, respectively, and that the recognition by CR3 but not CR1 is functionally associated with subsequent phagosomelysosome fusion in murine macrophages.     

Hypoxia-induced expression of complement receptor type 1(CR1, CD35) in human vascular endothelial cells

Reoxygenation of hypoxic human umbilical vein endothelial cells(HUVECs) increases protein expression of the complement regulators CD46and CD55. As the receptor for C3b is known to be present on injuredbovine endothelial cells, we investigated whether hypoxia or inflammatory mediators induce complement receptor type 1 (CR1; CD35) expression on HUVECs. CR1 protein expressionincreased 3.7 ± 0.6-fold as measured by ELISA on HUVECsfollowing hypoxia (48 h, 1%O₂). Colocalization of CD35 andvon Willebrand factor by confocal microscopy confirmed that CD35 waspredominantly intracellular. Lipopolysaccharide or tumor necrosisfactor- also significantly increased HUVEC CR1 proteinexpression. Western blot analysis of neutrophil or hypoxicHUVEC lysates revealed a 221-kDa CR1 band under nonreducingconditions. RT-PCR of hypoxic HUVEC mRNA revealed a singleband that, after sequencing, was identified as CD35. In situhybridization of hypoxic HUVECs, but not normoxic HUVECs or fibroblasts, demonstrated increased CD35 mRNA.Hypoxic HUVECs bound immune complexes and acted as a cofactorfor factor I-mediated cleavage of C3b. Thus hypoxia induces functionalHUVEC CR1 expression.     

Analysis of C3-receptor activity on human B-lymphocytes and isolation of the complement receptor type 2 (CR2).

The rosetting of defined C3-fragment-coated sheep erythrocytes to B-cell-enriched tonsil lymphocytes was measured. The rosetting lymphocytes were homogeneous with respect to expression of C3b, iC3b and C3d receptors. Isolation of receptors for C3 fragments from surface-radioiodinated lymphocytes by affinity chromatography on immobilized C3u, iC3b and C3d,g produced two proteins with partially overlapping specificities. A protein of 240 000 Mr, recognized by the monoclonal antibody To5 and identified as CR1 (complement receptor type 1), had affinity for C3u and iC3b. A protein of 145 000 Mr, recognized by the monoclonal antibody B2, had affinity for all three C3 fragments. Inhibition of rosetting by antibodies to these proteins indicates that CR1 is responsible for C3b-mediated rosetting and that the 145000-Mr receptor (CR2) is responsible for C3d-mediated rosetting. Partial inhibition by both anti-CR1 and anti-CR2 antibodies of iC3b-mediated rosetting indicates that both receptors are involved in iC3b-mediated rosetting. No other protein appears to be involved in tonsil B-cell rosetting to C3-fragment-coated cells. A method for preparing CR2 from tonsil lymphocytes based on affinity chromatography on C3d,g-Sepharose has been developed. Forty tonsil pairs (2 X 10(10) B-cells) yield about 40 micrograms of pure protein equivalent to a purification of 6500-fold from a detergent extract.     

Solubilization of active complement receptor type 1 (CR1) from human erythrocyte stroma with trypsin and its purification

Mild trypsinization of human erythrocyte stroma solubilized CR1 (complement receptor type 1, C3b/C4b receptor) without significant loss of decay-accelerating activity to C5 convertases on hemolytic intermediate cells (EAC 1-3b, P). The solubilized CR1 was purified using DEAE-Sephacel, C3-Sepharose, and anti-CR1-Sepharose column chromatographies. The purified material showed a single band on sodium dodecyl sulfate-polyacrylamide gel electrophoresis under non-reducing conditions, and its molecular weight was determined to be 175K, about 20K smaller than native CR1. Because the purified sample was separated into the several segments by sodium dodecyl sulfate-polyacrylamide gel electrophoresis under reducing conditions, the molecule is considered to be nicked and those segments are associated by disulfide bonds. These results mean that a large portion of the CR1 molecule is present outside of the plasma membrane of erythrocytes, and the intramembranous and cytoplasmic domains are not necessary for decay-accelerating activity.     

Membrane complement receptor type three (CR3) has lectin-like properties analogous to bovine conglutinin as functions as a receptor for zymosan and rabbit erythrocytes as well as a receptor for iC3b

Human leukocyte complement receptor type three (CR3) was shown to be lectin-like and to resemble bovine serum conglutinin (K) in that it bound to both iC3b and unopsonized yeast (Saccharomyces cerevisiae), and was inhibited by EDTA or N-acetyl-D-glucosamine (NADG). CR3 and K also bound to zymosan (Z), a yeast cell wall extract that contains primarily polysaccharide and no detectable protein. However, structural differences and the absence of K on bovine phagocytes indicated that CR3 was not the human homologue of bovine K. Phagocytic and respiratory responses to unopsonized Z were CR3 dependent because they were inhibited by monoclonal antibodies specific for the alpha-chain of CR3 and did not occur with phagocytes from patients with a genetic deficiency of CR3. The binding of CR3 to Z did not require opsonization of the Z with neutrophil-secreted C3, as Z binding and responses were not inhibited by Fab anti-C3. In addition, CR3-dependent binding of yeast occurred with neutrophils from which protein secretion was blocked by fixation with paraformaldehyde. Rabbit erythrocytes (RaE) also bound weakly to neutrophil CR3 and triggered ingestion. Anti-CR3 not only blocked the binding and ingestion of RaE but also blocked selectively the ingestion of RaEC3b without affecting the strong binding mediated by CR1. Even though sheep E and sheep EC3b were not ingested by neutrophils, a weak binding of CR3 to sheep E was suggested by the finding of 20 to 40% inhibition of sheep EAIgG ingestion by anti-CR3. Such inhibition was only observed in buffers that allowed activity of the CR3 binding site and not in buffers containing either EDTA or NADG. An apparently contradictory finding was that the weak CR3-dependent binding of Z triggered neutrophil ingestion and a superoxide burst, whereas the avid CR3-dependent binding of sheep EC3bi did not induce significant ingestion or a respiratory burst. Blocking studies with monoclonal antibodies specific for different epitopes of the alpha-chain of CR3 suggested that this might result from the presence of two distinct binding sites in CR3: one site for fixed iC3b that did not trigger functions, and a second function-triggering site for Z that did not bind to fixed iC3b.     

Monoclonal antibodies to the human C3b/C4b receptor (CR1) enhance specific B cell differentiation

The addition of monoclonal antibodies against the human C3b/C4b receptor (CR1) to cultures of peripheral blood lymphocytes in the presence of suboptimal amounts of TNP bound to polyacrylamide beads enhanced by 150 to 400% the specific anti-TNP response, as measured by a plaque-forming cell assay on day 7. Anti-CR1 antibodies similarly enhanced the anti-fluorescein antibody response. Enhancement only occurred in cultures performed in the presence of the relevant antigen. No enhancing effect on the anti-TNP response was observed on addition to cultures of monoclonal antibodies directed against other surface antigens of B cells or an anti-T cell antibody of the same subclass as that of anti-CR1 antibodies. Anti-CR1 antibodies alone did not induce nonspecific B cell proliferation and did not provide B cells with a first signal for proliferation in the presence of a source of B cell growth factors. Anti-CR1 antibodies did not enhance the nonspecific proliferative response of B cells to growth factors derived from PHA-stimulated T cells, semi-purified BCGF 20 KD, BCGF 50 KD, or recombinant IL 2 in the presence of anti-mu. In this respect, the effect of anti-CR1 antibodies differs from that of anti-CR2 antibodies which interact with early stages of B cell activation. In contrast, anti-CR1 antibodies enhanced specific differentiation of antigen-activated B cells in the absence of T cells when soluble T cell factors were provided. Similar results were obtained by using either of two sources of differentiation factors, the MLA-144 supernatant or a 30 to 15 KD fraction from PHA-stimulated T cells. These results indicate that triggering of CR1 on B cells positively regulates the specific antibody response to low doses of antigen by enhancing B cell differentiation whether T cell help is provided by intact T cells or by T cell-derived differentiation factors.     

Distribution and quantitative expression of the complement receptor type 1 (CR1) on human peripheral blood T lymphocytes.

The complement receptor, type 1 (CR1) is expressed on a variety of cell types including primate erythrocytes, phagocytic cells, and B lymphocytes. On these cells, CR1 plays a role in a diverse spectrum of biological activities including the clearance of immune complexes from the circulation, down-regulation of the complement system, recognition of complement-coated microorganisms, and cellular activation. CR1 is also expressed by some, but not all, T lymphocytes. The present study was undertaken in order to examine the distribution of CR1 on normal human T cell subsets by flow cytometry and to quantify the expression of T cell CR1 by radioimmunoassay. Data presented here indicate that, in a panel of 19 normal individuals, a mean of 9.7% of the overall peripheral blood lymphocyte population expressed CR1 and that, as assessed by two-color flow cytometry, 12.0% of CD3+, 13.0% of CD4+, and 20.0% of CD8+ cells expressed CR1. While single peaks of CR1 staining were observed within the CD3 and CD4 subsets, a biphasic pattern of staining was evident within the CD8 subset in which relatively high-intensity CR1 staining was detected within the subpopulation of "dull" CD8+ cells, whereas a lower intensity of CR1 staining was observed within the subpopulation of "bright" CD8+ cells. Duplicate analyses performed over a relatively short time frame suggested that, while the overall percentage of cells that expressed CR1 varied considerably among normal individuals, in at least some individuals the percentage of cells expressing CR1 was relatively stable, especially within the CD4 subset. In cell suspensions enriched for T lymphocytes by rosetting with sheep erythrocytes, 10.0% of the cells were CR1+ and a mean of approximately 3700 CR1 were expressed per CR1+ cell. There was no apparent correlation between the number of CR1 per T cell and the number of CR1 expressed per erythrocyte in the same blood sample. The expression of CR1 on subpopulations within the CD3+, CD4+, and CD8+ lymphocyte subsets may play a role in both normal cell function and in the pathophysiology of disease states including the acquired immune deficiency syndrome (AIDS).     

Expansion of the complement receptor gene family. Identification in the mouse of two new genes related to the CR1 and CR2 gene family

Human cDNA probes encoding the C3b/C4b complement receptor, CR1, have been used to identify, in the mouse, two new genes which are related to CR1 but which appear to encode a different protein product. These new mouse genes, arbitrarily designated mouse genes X and Y, hybridize specifically to three different cDNA probes derived from human CR1. The degree of hybridization homology between the mouse X and Y genes suggests they are very closely related to one another; however, the chromosomal localization of the mouse X gene to chromosome 8 and the mouse Y gene to chromosome 1 indicates they are distinct gene sequences. The mRNA species detected with the X and/or Y (X/Y) sequences are approximately 2000 bases in length, but vary in both quantity and size depending upon the tissue analyzed. DNA sequence analysis of a cDNA specific for the X and Y sequences indicates the mature protein(s) will contain the 60 amino acid consensus repeat characteristic of a group of other proteins including CR1, the C3d receptor (CR2), H, C4 binding protein (C4bp), the interleukin 2 (Il 2) receptor and others. The identity of the mouse X and Y genes, and the function of the proteins which they encode, is not known; however, the small size of the mRNA and the tissue specific expression suggests they do not encode mouse CR1 or CR2 but instead encode a related protein (or proteins) which is expressed in a wide variety of mouse tissues.     

Platelet-activating factor enhances complement-dependent phagocytosis of diamide-treated erythrocytes by human monocytes through activation of protein kinase C and phosphorylation of complement receptor type one (CR1)

Oligomerization of band 3 protein has been recently indicated as an early event in senescent or damaged red cell membrane followed by specific deposition of anti-band 3 antibodies and binding of complement C3 fragments. The band 3-anti-band 3-C3b complex is recognized by homologous monocytes, and phagocytosis ensues. This study shows that recognition of the anti-band 3-C3b complex by the monocyte C3b receptor type one (CR1) plays a crucial role in the process of removal of damaged red cells. Indeed, blocking of monocyte CR1 with an anti-CR1 monoclonal antibody abrogated phagocytosis of diamide-treated red cells. Platelet-activating factor (PAF) is a phospholipid mediator involved in inflammatory processes. Nanomolar (R)-PAF enhanced the CR1-dependent phagocytosis of diamide-treated human red cell and of sheep red cells coated with C3b, induced the fast translocation of protein kinase C to monocyte membrane compartment, and stimulated the phosphorylation of monocyte CR1. The biologically inert lyso-PAF and the enantiomer (S)-PAF were inactive. PAF receptor antagonists and inhibitors of protein kinase C blocked the enhancement of phagocytosis induced by PAF. Protein kinase C translocation, phosphorylation of CR1, and stimulation of this receptor to an active state capable of mediating phagocytosis represent a novel pathway by which PAF interferes with red cell homeostasis and possibly modulates inflammatory reactions and host mechanisms against infections.     

Flow cytometric assay for phagocytosis of human monocytes mediated via Fc gamma-receptors and complement receptor CR1 (CD35).

We developed a simple flow cytometric assay for phagocytosis by human monocytes that is mediated via Fc gamma receptors and the complement receptor CR1 (CD35), using fluorescent latex beads carrying IgG and complement components C4b and C3b. To prepare fluorescent latex beads carrying IgG(BA), BSA-coated latex beads (B) were incubated with diluted rabbit anti-BSA IgG. To bind complement components, BA-particles were incubated with whole human serum pretreated with K-76 monocarboxylic acid (K-76COOH). K-76COOH inhibits the activities of C5 and factor I (12,13), resulting in the deposition of C1,4b,2a,3b on BA-particles (BAC1,4b,2a,3b). Further incubation of BAC1,4b,2a,3b with EDTA-GVB at 37 degrees C gave particles carrying IgG and C4b,C3b (BAC4b,3b). The C3 fragment, C3b, was confirmed to present on BAC1,4a,2a,3b particles by SDS-PAGE and immunoblot, and these particles were calculated to have approximately 25,000-30,000 C3b molecules per particle. To evaluate the particle attachment, the phagocytic assay was performed with 3 microM cytochalasin D treated cells. The percent cells with ingested particles and the number of ingested particles/100 cells for 60 min were estimated, being 5.1% and 5.4 for B, 12.3% and 26.7 for BA, 42.5% and 108.7 for BAC4b,3b, and 42.6% and 112.5 for BAC1,4b,2a,3b, respectively.     

Decay accelerating activity of complement receptor type 1 (CD35). Two active sites are required for dissociating C5 convertases.

The goal of this study was to identify the site(s) in CR1 that mediate the dissociation of the C3 and C5 convertases. To that end, truncated derivatives of CR1 whose extracellular part is composed of 30 tandem repeating modules, termed complement control protein repeats (CCPs), were generated. Site 1 (CCPs 1-3) alone mediated the decay acceleration of the classical and alternative pathway C3 convertases. Site 2 (CCPs 8-10 or the nearly identical CCPs 15-17) had one-fifth the activity of site 1. In contrast, for the C5 convertase, site 1 had only 0.5% of the decay accelerating activity, while site 2 had no detectable activity. Efficient C5 decay accelerating activity was detected in recombinants that carried both site 1 and site 2. The activity was reduced if the intervening repeats between site 1 and site 2 were deleted. The results indicate that, for the C5 convertases, decay accelerating activity is mediated primarily by site 1. A properly spaced site 2 has an important auxiliary role, which may involve its C3b binding capacity. Moreover, using homologous substitution mutagenesis, residues important in site 1 for dissociating activity were identified. Based on these results, we generated proteins one-fourth the size of CR1 but with enhanced decay accelerating activity for the C3 convertases.     

Beta-glucan, a "specific" biologic response modifier that uses antibodies to target tumors for cytotoxic recognition by leukocyte complement receptor type 3 (CD11b/CD18).

beta-Glucans were identified 36 years ago as a biologic response modifier that stimulated tumor rejection. In vitro studies have shown that beta-glucans bind to a lectin domain within complement receptor type 3 (CR3; known also as Mac-1, CD11b/CD18, or alphaMbeta2-integrin, that functions as an adhesion molecule and a receptor for factor I-cleaved C3b, i.e., iC3b) resulting in the priming of this iC3b receptor for cytotoxicity of iC3b-opsonized target cells. This investigation explored mechanisms of tumor therapy with soluble beta-glucan in mice. Normal mouse sera were shown to contain low levels of Abs reactive with syngeneic or allogeneic tumor lines that activated complement, depositing C3 onto tumors. Implanted tumors became coated with IgM, IgG, and C3, and the absent C3 deposition on tumors in SCID mice was reconstituted with IgM or IgG isolated from normal sera. Therapy of mice with glucan- or mannan-rich soluble polysaccharides exhibiting high affinity for CR3 caused a 57-90% reduction in tumor weight. In young mice with lower levels of tumor-reactive Abs, the effectiveness of beta-glucan was enhanced by administration of a tumor-specific mAb, and in SCID mice, an absent response to beta-glucan was reconstituted with normal IgM or IgG. The requirement for C3 on tumors and CR3 on leukocytes was highlighted by therapy failures in C3- or CR3-deficient mice. Thus, the tumoricidal function of CR3-binding polysaccharides such as beta-glucan in vivo is defined by natural and elicited Abs that direct iC3b deposition onto neoplastic cells, making them targets for circulating leukocytes bearing polysaccharide-primed CR3. Therapy fails when tumors lack iC3b, but can be restored by tumor-specific Abs that deposit iC3b onto the tumors.