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.     

Factor I-mediated processing of complement fragments on HIV immune complexes targets HIV to CR2-expressing B cells and facilitates B cell-mediated transmission of opsonized HIV to T cells

Our study demonstrates that binding of complement-opsonized HIV to complement receptor type 1 on human erythrocytes (E) via C3b fragments is followed by a rapid normal human serum-mediated detachment of HIV from E. The release was dependent on the presence of factor I indicating a conversion of C3b fragments to iC3b and C3d on the viral surface. This in turn resulted in an efficient binding of opsonized HIV to CR2-expressing B cells, thus facilitating B cell-mediated transmission of HIV to T cells. These data provide a new dynamic view of complement opsonization of HIV, suggesting that association of virus with E might be a transient phenomenon and the factor I-mediated processing of C3b to iC3b and C3d on HIV targets the virus to complement receptor type 2-expressing cells. Thus, factor I in concert with CR1 on E and factor H in serum due to their cofactor activity are likely to be important contributors for the generation of C3d-opsonized infectious HIV reservoirs on follicular dendritic cells and/or B cells in HIV-infected individuals.     

Regulatory proteins for the activated third and fourth components of complement (C3b and C4b) in mice. II. Identification and properties of complement receptor type 1 (CR1)

We identified on the membrane of mouse spleen cells a polypeptide of Mr 190,000 (S190), with binding affinity for the mouse third component of the complement system (C3). S190, purified by affinity chromatography on C3-Sepharose, has properties resembling those of the human C3 receptor type 1 (CR1). Thus, S190, like CR1, served as a cofactor for the C3b inactivator (I)-mediated cleavage of fluid-phase C3b into iC3b, and had cofactor activity comparable to that of serum factor H (H). S190 also acted as a cofactor for the cleavages of membrane-bound C3b or membrane-bound iC3b into C3c (Mr 140,000) and C3dg (Mr 40,000) by serum factor I. As is the case with CR1, the specific activity of S190 for the cleavages leading to C3c-C3dg formation was approximately 100-fold greater than that of H. We therefore conclude that S190 and CR1 are analogous proteins.     

Macrophage complement receptors and pathogen clearance

Phagocytosis, an important mechanism of the host-defence system and a primary function of macrophages, is facilitated by opsonization, a process by which serum components tag pathogens for recognition by neutrophils and macrophages. Complement component C3 is central to opsonization. Its first cleavage product, C3b, forms the multisubunit enzyme, C3bBb, which proteolytically cleaves additional C3 molecules on the pathogen surface. C3b is further degraded to iC3b, C3c and C3dg, products that serve as ligands for selective complement receptors on leukocytes. This receptor-ligand interaction subsequently modulates immune responses or directly targets the pathogen for clearance by phagocytosis. Although a central role for C3 in phagocytosis of certain pathogens is well accepted, the receptors orchestrating the phagocytic response have not been well characterized. The recent structures of C3 and its breakdown products have increased our insights into the molecular basis of complement activation and recognition by their receptors. Here we review the biology of macrophage receptors for C3 fragments and discuss their role in the host response to pathogens.     

Structure-guided identification of C3d residues essential for its binding to complement receptor 2 (CD21)

A vital role for complement in adaptive humoral immunity is now beyond dispute. The crucial interaction is that between B cell and follicular dendritic cell-resident complement receptor 2 (CR2, CD21) and its Ag-associated ligands iC3b and C3dg, where the latter have been deposited as a result of classical pathway activation. Despite the obvious importance of this interaction, the location of a CR2 binding site within C3d, a proteolytic limit fragment of C3dg retaining CR2 binding activity, has not been firmly established. The recently determined x-ray structure of human C3d suggested a candidate site that was remote from the site of covalent attachment to Ag and consisted of an acidic residue-lined depression, which accordingly displays a significant electronegative surface potential. These attributes were consistent with the known ionic strength dependence of the CR2-C3d interaction and with the fact that a significant electropositive surface was apparent in a modeled structure of the C3d-binding domains of CR2. Therefore, we have performed an alanine scan of all of the residues within and immediately adjacent to the acidic pocket in C3d. By testing the mutant iC3b molecules for their ability to bind CR2, we have identified two separate clusters of residues on opposite sides of the acidic pocket, specifically E37/E39 and E160/D163/I164/E166, as being important CR2-contacting residues in C3d. Within the second cluster even single mutations cause near total loss of CR2 binding activity. Consistent with the proposed oppositely charged nature of the interface, we have also found that removal of a positive charge immediately adjacent to the acidic pocket (mutant K162A) results in a 2-fold enhancement in CR2 binding activity.     

Neutrophils express a receptor for iC3b, C3dg, and C3d that is distinct from CR1, CR2, and CR3

In the present study we examined human neutrophils for the expression of a receptor capable of binding C3dg and defined the relationship of this receptor to those that have been previously described, namely CR1, CR2, and CR3. C3dg was isolated from serum depleted of plasminogen, supplemented with 20 mM Mg++, and incubated at 37 degrees C for 6 to 8 days. The purified protein was homogeneous when analyzed by polyacrylamide gel electrophoresis and exhibited an apparent m.w. of 41,000. C3dg was polymerized by treatment with dimethyl suberimidate, and the dimer was isolated by gel filtration. Binding of both monomeric and dimeric 125I-labeled C3dg to neutrophils was saturable, and the latter ligand bound to an average of 12,400 sites/cell among nine normal individuals. At 4 degrees C, bound monomeric C3dg dissociated from neutrophils with an average t1/2 of 30 min, whereas dimeric C3dg dissociated with a t1/2 in excess of 120 min. Specific binding of multimeric C3dg was cation independent and was competitively inhibited by molar concentrations of iC3b and C3d that were equivalent to the inhibitory concentrations of unlabeled C3dg; C3b was less able to compete with C3dg for binding to these sites. The capacity of this neutrophil receptor to bind iC3b, C3dg, and C3d suggested its possible identity as CR2 or CR3. However, no specific binding to neutrophils of 125I-labeled HB-5 monoclonal anti-CR2 was detected. Furthermore, uptake of 125I-labeled C3dg was not inhibited by saturating concentrations of rabbit anti-CR1, anti-Mac-1, or OKM10. Thus, a receptor resides on neutrophils that binds the C3d region of iC3b and C3dg and is distinct from CR1, CR2, and CR3.     

Delineation of the complement receptor type 2-C3d complex by site-directed mutagenesis and molecular docking

The interactions between the complement receptor type 2 (CR2) and the C3 complement fragments C3d, C3dg, and iC3b are essential for the initiation of a normal immune response. A crystal-derived structure of the two N-terminal short consensus repeat (SCR1-2) domains of CR2 in complex with C3d has previously been elucidated. However, a number of biochemical and biophysical studies targeting both CR2 and C3d appear to be in conflict with these structural data. Previous mutagenesis and heteronuclear NMR spectroscopy studies directed toward the C3d-binding site on CR2 have indicated that the CR2-C3d cocrystal structure may represent an encounter/intermediate or nonphysiological complex. With regard to the CR2-binding site on C3d, mutagenesis studies by Isenman and coworkers [Isenman, D. E., Leung, E., Mackay, J. D., Bagby, S. & van den Elsen, J. M. H. (2010). Mutational analyses reveal that the staphylococcal immune evasion molecule Sbi and complement receptor 2 (CR2) share overlapping contact residues on C3d: Implications for the controversy regarding the CR2/C3d cocrystal structure. J. Immunol. 184, 1946-1955] have implicated an electronegative “concave” surface on C3d in the binding process. This surface is discrete from the CR2-C3d interface identified in the crystal structure.We generated a total of 18 mutations targeting the two (X-ray crystallographic- and mutagenesis-based) proposed CR2 SCR1-2 binding sites on C3d. Using ELISA analyses, we were able to assess binding of mutant forms of C3d to CR2. Mutations directed toward the concave surface of C3d result in substantially compromised CR2 binding. By contrast, targeting the CR2-C3d interface identified in the cocrystal structure and the surrounding area results in significantly lower levels of disruption in binding. Molecular modeling approaches used to investigate disparities between the biochemical data and the X-ray structure of the CR2-C3d cocrystal result in highest-scoring solutions in which CR2 SCR1-2 is docked within the concave surface of C3d.     

Molecular modelling of human complement component C3 and its fragments by solution scattering

Solution scattering experiments using both X-rays and neutrons are reported for human complement component C3 and up to six other glycoprotein fragments that are derived from C3. The X-ray and neutron molecular masses and neutron matchpoints are in agreement with the known primary sequence of C3. The X-ray radius of gyration RG of C3 is 5.2 nm and is similar for the related forms C3u, C3(a + b) and C3b. The X-ray cross-sectional radius of gyration RXS of C3b is however less than that of C3, C3u and C3(a + b). The major fragments of C3b, namely C3c and C3dg, were studied. The RG of C3c is 4.7 nm and for C3dg is 2.9 nm. C3c and C3dg do not interact when they coexist in solution in equimolar amounts. When C3u is cleaved into iC3u, the RG of iC3u increases to 5.9 nm and its RXS decreases, showing that C3c and C3dg behave as independent entities within the parent glycoprotein. Analyses of the neutron RG and RXS values by contrast variation techniques confirm the X-ray analyses, and show no evidence for significant hydrophobic or hydrophilic domains within C3 or any of its fragments. Shape analyses show that C3, C3c and C3dg are elongated particles. Debye models were developed using the scattering curve out to Q = 1.6 nm-1. These show that C3 and C3c resemble oblate ellipsoids while C3dg resembles a prolate ellipsoid. C3dg lies on the long edge of C3c within C3. The dimensions of the models are 18 nm X 2 nm X 10 nm for C3, 18 nm X 2 nm X 7 nm for C3c and 10 nm X 2 nm X 3 nm for C3dg. These models are compatible with analyses of the scattering curve RG and RXS values, data from sedimentation coefficients, and images of C3 and C3c seen by electron microscopy.     

The clearance of tetanus toxoid/anti-tetanus toxoid immune complexes from the circulation of humans. Complement- and erythrocyte complement receptor 1-dependent mechanisms

The role of complement and its receptor on erythrocytes (CR1) in the physiologic elimination of large immune complexes from the circulation of humans was assessed. Large radiolabeled soluble tetanus toxoid- anti-tetanus toxoid complexes were injected i.v. into three normal individuals and three patients with SLE. These complexes were prepared in antibody excess and were 45S in size, fixed C and bound to E CR1 in vitro. The percentage of complexes bound in vitro was directly proportional to CR1 number/E in four normal subjects and three SLE patients. After i.v. injection into normal subjects, complexes were cleared rapidly, with a monoexponential rate constant (10.3 to 11% complexes cleared/min). In the SLE patients, clearance was best explained by two phases: the first occurred within the first minute indicating immediate trapping of a fraction of the complexes (19.5 to 25.3% of injected complexes trapped), the second was monoexponential and was similar to the normal range. A large fraction of complexes bound within the first minute to E in vivo; the percentage of binding was variable, ranging from 16.3% to 71.5% and was related to E CR1 number. In a second study complexes were injected that had been attached to autologous E by opsonization with C in vitro. Their elimination was similarly monoexponential, except in one SLE patient in whom there was significant initial trapping (30.9%). A fraction of these complexes were released from E within the first minute, the percentage release being greatest in the patient with the lowest CR1 number (81.4%). E bearing immune complexes remained in the circulation and were not transiently sequestered in the liver or spleen. This is the first study of the clearance of soluble immune complexes in vivo in humans and shows that C and CR1 on E participate in immune complex clearance reactions, and that abnormal clearance can be detected in the form of rapid removal of immune complexes from the circulation.     

Elevated NK-mediated lysis of Raji and Daudi cells carrying fixed iC3b fragments

Raji and Daudi cells were opsonized with C3b, iC3b, and C3d fragments by using purified complement components. The sensitivity of C3-opsonized cells to lysis mediated by low density blood lymphocytes was studied. Raji and Daudi cells carrying C3b or C3d fragments were lysed with similar efficiencies as the nonopsonized cells. The presence of iC3b on the target surface imposed elevated NK sensitivity. The iC3b-mediated enhancement of NK lysis was inhibited when iC3b fragments or rabbit anti-human C3 antibodies were included into the lytic assays. These results indicate that the iC3b fragments fixed on the targets bind to the CR3 on the lymphocytes. Results obtained in immobilized conjugate-lytic assays showed that iC3b-opsonized targets interact more readily with the lymphocytes. This was reflected by the elevated proportion of lymphocytes that were bound to the iC3b-carrying targets. The proportions of conjugates in which target damage occurred were similar with the control and with the iC3b-carrying cells. It seems therefore that opsonization of targets with iC3b leads to recruitment of effector lymphocytes due to contact with their CR3. However, once the effector-target contact is established, the triggering of lytic function does not seem to be influenced by the iC3b/CR3 bridge.     

Contribution of complement component C3 and complement receptor type 3 to carbohydrate-dependent uptake of oligomannose-coated liposomes by peritoneal macrophages

Peritoneal macrophages (PEMs) preferentially and rapidly take up oligomannose-coated liposomes (OMLs) and subsequently mature to induce a Th-1 immune response following administration of OMLs into the peritoneal cavity. Here, we examine the contributions of complement component C3 and complement receptor type 3 (CR3) to carbohydrate-dependent uptake of OMLs by PEMs. Effective uptake of OMLs into PEMs in vitro was observed only in the presence of peritoneal fluid (PF), and OMLs incubated with PF were incorporated by PEMs in vitro in the absence of PF. These phenomena were inhibited by methyl-alpha-mannoside, N-acetylglucosamine or EDTA, but not by galactose. Pull-down analysis followed by peptide mass fingerprinting of PF-treated OMLs indicated that the OMLs were opsonized with complement fragment iC3b. In vivo uptake of OMLs by PEMs was inhibited by intraperitoneal injection of an antibody against CR3, a receptor for iC3b, and OML uptake by PEMs in the peritoneal cavity was not observed in C3-deficient mice. Thus, our results indicate that OMLs are opsonized with iC3b in a mannose-dependent manner in the peritoneal cavity and then incorporated into PEMs via CR3.     

Kinetic analysis of the interactions of complement receptor 2 (CR2, CD21) with its ligands C3d, iC3b, and the EBV glycoprotein gp350/220

The molecular mechanisms involved in the interaction of complement receptor 2 (CR2) with its natural ligands iC3b and C3d are still not well understood. In addition, studies regarding the binding site(s) of the receptor on C3 as well as the affinities of the C3 fragments for CR2 have produced contradictory results. In the present study, we have used surface plasmon resonance technology to study the interaction of CR2 with its ligands C3d, iC3b, and the EBV surface glycoprotein gp350/220. We measured the kinetics of binding of the receptor to its ligands, examined the influence of ionic contacts on these interactions, and assessed whether immobilized and soluble iC3b bound with similar kinetics to CR2. Our results indicate that 1) gp350 binding to CR2 follows a simple 1:1 interaction, whereas that of the C3 fragments is more complex and involves more than one intramolecular component; 2) kinetic differences exist between the binding of C3d and iC3b to CR2, which may be due to an additional binding site found on the C3c region of iC3b; and 3) iC3b binds to CR2 with different kinetics, depending on whether the iC3b is in solution or immobilized on the surface. These findings suggest that binding of CR2 to iC3b and C3d is more complex than previously thought.     

Normal function of CR1 on affected erythrocytes of patients with paroxysmal nocturnal hemoglobinuria

Paroxysmal nocturnal hemoglobinuria (PNH) is an acquired hemolytic anemia in which affected erythrocytes (E) are abnormally sensitive to lysis by autologous complement. Affected E from patients with PNH (PNH-E) are deficient in an E membrane regulatory protein of complement, decay-accelerating factor (DAF). Because a functional defect in a second membrane regulatory protein of complement, CR1 (C3b receptor), has also been hypothesized, severely affected PNH-E (type III PNH-E) were tested for abnormalities in CR1 by four methods. E from two patients with 100% type III PNH-E had 3201 and 6783 sites per cell for binding of 125I-labeled rabbit polyclonal F(ab')2 anti-CR1. These values fall within the normal range of CR1 antigenic sites per cell (1267 to 7915, mean = 5,014 +/- 155 SEM) established by assaying the E from 113 healthy donors. The Ka of CR1 on type III PNH-E for 125I-labeled C3b dimer was 2.06 X 10(7) M-1, and the Ka values for the binding of the same ligand to the E from two healthy individuals were 2.45 X 10(7) M-1 and 1.58 X 10(7) M-1. In an assay designed to measure the capacity of human E (Eh) to accelerate the decay of the classical C3 convertase deposited on 1 X 10(7) bystander sheep E (EAC1gp,4bh,2agp), the half-life (t 1/2) of this convertase was diminished from 18.1 min (range 15.2 to 22.9) to 8.1 min (range 7.4 to 8.5) by the addition of 1 X 10(7) normal Eh, to 6.2 min by 100% type III PNH-E, and to 7.5 min by Eh pretreated with an IgG fraction of human antiserum directed against the D antigen of the Rh system. In contrast, Eh (t 1/2 = 7.4) pretreated with a saturating dose of F(ab')2 anti-CR1, and CR1-deficient Eh (less than 10 CR1 molecules/E) from a patient with systemic lupus erythematosus, showed a loss of convertase decay-accelerating capacity to t 1/2 = 11.6 and t 1/2 = 12.4, respectively. Type III PNH-E pretreated with anti-CR1 demonstrated a total loss of their decay-accelerating capacity (t 1/2 = 19.9). In an assay of I cofactor activity, soluble C3b was rapidly converted to iC3b by purified I plus Eh or type III PNH-E, whereas CR1-deficient Eh exhibited less than 5% the I cofactor activity of normal Eh.(ABSTRACT TRUNCATED AT 400 WORDS)     

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.     

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.     

Capping of complement receptors on human neutrophils induced by group A streptococcal cell walls

Peptidoglycan-polysaccharide polymers derived from group A streptococcal cell walls (PG-PS) were opsonized with either purified C3 or normal human serum and were used as a probe to investigate the mobility of CR1 and CR3, the C3b and iC3b receptors, respectively, on human neutrophils. Incubation of monolayers or cell suspensions of neutrophils with PG-PS opsonized with C3b or serum resulted in capping of PG-PS, as detected by fluorescein-labeled antibody to PS. No binding of PG-PS to neutrophils was observed with heat-inactivated serum. By 30 min the cell walls were internalized and observed in one to three vacuoles. Capping was totally inhibited when PG-PS opsonized with C3b or serum was preincubated with Fab'-anti-C3b. Similar inhibition was observed when C3b-opsonized PG-PS was incubated with neutrophils that were preincubated with anti-CR1 or fluid-phase C3b; only partial inhibition of neutrophil capping was observed by using serum-opsonized PG-PS. Because anti-CR1 blocks only the C3b receptor, the cap formation observed with serum-opsonized PG-PS is probably due to CR3. These results suggest that both CR1 and CR3 on neutrophils cap after stimulation by group A streptococcal cell wall fragments.     

Expression of specific binding sites on Candida with functional and antigenic characteristics of human complement receptors

Receptors for C3 degradation fragments (CR1, CR2, and CR3) are present on many human cells including phagocytes and lymphoid cells and may be critical in the attachment of invading microorganisms. In these studies Candida were found to mimic the human CR by binding erythrocytes coated with specific human C3 fragments. Yeast forms of Candida species were adhered to glass slides and were allowed to germinate. Sheep erythrocytes (E) were coated with IgM (EA) and human complement components to prepare EA, EAC14, EAC3b, EAC3bi, and EAC3d. These test cells were then examined for adherence to the organism. Antibodies to human CR1, CR2, and CR3 were used to evaluate their potential for blocking adherence of the test erythrocytes to Candida. Fluorescein-labeled antibodies to human complement receptors were also used to characterize the binding sites. EAC3bi and EAC3d, but not E, EA, or EAC14, bound extensively to the germ tubes and pseudohyphae of Candida albicans and C. stellatoidea. EAC3b bound infrequently. Other Candida species, generally considered less pathogenic, bound significantly fewer specific test erythrocytes than C. albicans. Monoclonal antibodies to human CR1 and CR3 (3D9, 1B4, C511, 2B6, anti-B2, Mo1, and anti-Mac-1), in general, did not block adherence of test erythrocytes. Blocking of adherence of EAC3bi and EAC3d test erythrocytes coated with small quantities of C3 fragments occurred with high concentrations of monoclonal (anti-CR2) HB-5 and polyclonal (anti-CR2) anti-GP 140. Immunofluorescence studies demonstrated binding of Mo-1 to the germinated forms of the organism, whereas binding of the other antibodies was not seen. These studies suggest a surface constituent on the organism similar to CR on human cells. Additional studies are necessary to further define the molecular nature of the binding site. The ability of organisms to mimic human CR may be more generalized than previously known and may serve as a mechanism for modification of the inflammatory and immune response.     

Innate immunity and brain inflammation: the key role of complement

The complement inflammatory cascade is an essential component of the phylogenetically ancient innate immune response and is crucial to our natural ability to ward off infection. Complement is involved in host defence by triggering the generation of a membranolytic complex (the C5b-9 complex) at the surface of the pathogen. Complement fragments (opsonins; C1q, C3b and iC3b) interact with complement cell-surface receptors (C1qRp, CR1, CR3 and CR4) to promote phagocytosis and a local pro-inflammatory response that, ultimately, contributes to the protection and healing of the host. Complement is of special importance in the brain, where entrance of elements of the adaptive immune system is restricted by a blood-brain barrier. There is now compelling evidence that complement is produced locally in response to an infectious challenge. Moreover, complement biosynthesis and activation also occurs in neurodegenerative disorders such as Alzheimer's, Huntington's and Pick's diseases, and the cytolytic/cytotoxic activities of complement are thought to contribute to neuronal loss and brain tissue damage. However, recent data suggest that at least some of the complement components have the ability to contribute to neuroprotective pathways. The emerging paradigm is that complement is involved in the clearance of toxic cell debris (e.g. amyloid fibrils) and apoptotic cells, as well as in promoting tissue repair through the anti-inflammatory activities of C3a. Knowledge of the unique molecular and cellular innate immunological interactions that occur in the development and resolution of pathology in the brain should facilitate the design of effective therapeutic strategies.     

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.     

Resistance to phagocytosis by group A streptococci: failure of deposited complement opsonins to interact with cellular receptors

The previous finding that phagocytosis-resistant M+ group A streptococci bear quantities of C3 which are sufficient for phagocytosis of their M- derivatives was investigated at two levels. It was first established that the C3 associated with M+ streptococci was not able to promote adherence to cells bearing the complement receptors CR1 and CR3 under conditions in which M- streptococci readily attached. The molecular form of C3 bound to M+ and M- streptococci was then defined by adding 125I-C3 to serum used for opsonization. C3 eluted from the bacteria by chaotropic and hydrolytic agents was analyzed by SDS-PAGE, and revealed that both cell types bound the opsonic forms of C3, C3b, and iC3b. Furthermore, approximately 80% of the C3b and iC3b associated with both cell types was covalently bound to a surface component, although most of the C3 bound to M+ streptococci was detergent-extractable, whereas greater than 50% of that bound to M- streptococci was not. These findings demonstrate that the M+ surface is interfering with the receptor binding of deposited C3b and iC3b, and that this contributes to resistance to phagocytosis by these organisms.