Deficiency of complement component C3 is associated with accelerated removal of soluble 123I-labelled aggregates of IgG from the circulation.

Complement and erythrocyte complement receptors CR1 (CD35) play an important role in the clearance of immune complexes. We studied the elimination of soluble 123I-labelled aggregates of human immunoglobulin G (123I-AIgG), used as a model for immune complexes, in two patients with a congenital and two patients with an acquired deficiency of complement component C3, and compared these with 10 healthy controls. The first disappearance halflife of 123I-AIgG was shorter (3.3 +/- 0.4 versus 7.0 +/- 0.4 min in the controls, P = 0.005) and maximal hepatic uptake of aggregates was increased in the C3 deficient patients (maximal liver/background ratio 3.6 +/- 0.4 versus 2.7 +/- 0.2 in controls, P = 0.04). Apparently, in the absence of C3, removal of circulating immune complexes by the liver is accelerated, probably through Fc receptor-dependent mechanisms.     

CR1 on erythrocytes of Brazilian systemic lupus erythematosus patients: the influence of disease activity on expression and ability of this receptor to bind immune complexes opsonized with complement from normal human serum

Hypocomplementaemia and low expression of CR1 on erythrocytes (E) of patients with systemic lupus erythematosus (SLE) are associated with defective clearance of circulating immune complexes (IC) and so they may have pathogenic significance. Here, we investigated whether the reduced CR1/E in SLE patients per se might affect the binding of IC to CR1/E. First, we analysed the expression of CR1 on E of active (n=30) and inactive (n=34) SLE patients using a FITC-conjugated mouse anti-CR1 monoclonal antibody E11 and flow cytometry. Both groups of patients had a significantly reduced CR1/E expression compared with healthy controls (n=40). It was also observed that the number of E bearing CR1 was reduced in both groups of SLE patients studied. Second, we determined the functional activity of CR1/E by measuring the binding to E of FITC-bovine serum albumin (BSA)/rabbit anti-BSA complexes, formed at equivalence, which were opsonized with complement from normal human serum (NHS). On the other hand, we did not find differences between the patient and control groups in the ability of E to bind IC/NHS. There was also a positive correlation between the CR1/E expression and the number of E bearing CR1 in control and inactive SLE groups, which was not observed in the group of active SLE patients. Considering the involvement of low levels of complement and CR1/E expression on complex processing, in this in vitro model the results show that an effective coating of the complexes with complement is sufficient to bind them preferentially to CR1 over normal levels of receptor expression.     

Immune complex clearance by complement receptor type 1 in SLE

Patients with systemic lupus erythematosus (SLE) have relative deficiencies of the C3b/C4b receptor (CR1, CD35) on erythrocytes (E). This receptor takes part in the binding, transport and endocytosis of circulating immune complex bound complement components (ICC). Besides the autoantibodies the abnormalities in IC elimination are fundamental to the pathogenesis of SLE. During the last 15 years more than 100 patients with SLE have been treated in our Department and their data on ICC clearance by ECR1 analyzed. After plasmapheresis the ECR1 expression and also the binding sites for ICC were increased, while the level of IC and autoantibodies were reduced. Stimulating erythropoiesis in patients with anaemia and lupus nephritis caused the decreased expression and functional activity of ECR1 to be improved. In patients with SLE the level of soluble CR1 was also decreased, but a significant portion of soluble CR1 bound ICC in vivo, especially in those with severe renal lesion.     

The role of hypocomplementaemia and low erythrocyte complement receptor type 1 numbers in determining abnormal immune complex clearance in humans.

Defective clearance of immune complexes (IC) may contribute to the pathogenesis of diseases such as SLE. We studied the effect of hypocomplementaemia and the influence of erythrocyte complement receptor type 1 (CR1, CD35) number on the clearance of radiolabelled tetanus toxoid (TT)-anti-TT IC from the circulation. These were injected intravenously into 9 normal subjects and 15 patients with diseases characterized by IC formation and/or hypocomplementemia, including 2 with hereditary complement deficiency. IC were found to bind to erythrocyte CR1 in a complement-dependent manner and their degree of uptake was directly correlated with CR1 numbers. Two phases of IC clearance were identified. The first was rapid, occurring within 1 min. Since this phase might represent inappropriate deposition of IC in target organs we called it trapping. It was seen predominantly in subjects with low CR1, low complement, and low binding of complexes to red cells. The second phase was monoexponential with a mean elimination rate of 14.1%/min; it was inversely correlated with CR1 numbers and binding of complexes to red cells. In a second study each individual was injected with IC bound to autologous erythrocytes in vitro using normal serum so that the effects of complement deficiency were eliminated. Up to 81.4% of these bound IC were released in vivo from erythrocytes in 1 min, and the proportion was inversely correlated with CR1 numbers. Only five patients showed trapping, and these had low CR1 numbers and high percentage release of IC. The second phase of elimination was inversely correlated with CR1 numbers and the proportion of IC remaining bound to red cells at 1 min. The two complement-deficient patients had normal CR1: when IC were injected, trapping and very fast clearance rates were observed; however complexes that had been opsonized and bound to erythrocytes were cleared at a slower rate without evidence for trapping. These studies show that complement and erythrocyte CR1 may determine the physiological clearance of certain types of IC and suggest that this system may function abnormally when CR1 number or complement function are reduced.     

CR1 deficiency in SLE: acquired or genetic?

Erythrocytes from 30 patients suffering from systemic lupus erythematosus (SLE) were tested for CR1 activity by an immune adherence haemagglutination technique. Defective CR1 activity (CR1D) was found in 11 (37%) of the patients on initial testing. On repeat testings, however, CR1 activity often varied from time to time and was shown to be inversely related to serum anti-DNA binding and apparent complement activation in vivo. Two of the 19 patients with normal CR1 activity acquired CR1D during the study. One patient with previously defective CR1 attained normal activity in the course of the study. The increased occurrence of CR1D in patients with SLE is largely or wholly acquired rather than genetically determined.     

A CR1 polymorphism associated with constitutive erythrocyte CR1 levels affects binding to C4b but not C3b

The erythrocyte type one complement receptor (E-CR1) mediates erythrocyte binding of complement-opsonized immune complexes (IC), and helps protect against random deposition of circulating IC. Two linked CR1 polymorphisms occur in binding domains, at I643T and Q981H. In Caucasians, the variant alleles (643T, 981H) are associated with low constitutive E-CR1 expression levels. This study was conducted to determine if these polymorphisms affect ligand binding, and if so, represent risk factors for the autoimmune IC disease, systemic lupus erythematosus (SLE). In an ELISA comparing relative ligand binding differences, E-CR1 from individuals homozygous for the variant residues (643TT/981HH) exhibited greater binding to C4b, but not C3b, than homozygous wild-type E-CR1. Analysis of single-binding domain CR1 constructs demonstrated that the 981H residue imparted this enhanced C4b binding. No differences were observed in the 981H allele frequency between Caucasian controls (0.170, n = 100) and SLE patients (0.130, n = 150, P = 0.133), or between African American controls (0.169, n = 71) and SLE patients (0.157, n = 67). In a subset of individuals assessed for CR1 size, excluding from this analysis those expressing at least one B allele revealed a trend for over-representation of the 981H allele in Caucasian controls (0.231 frequency, n = 26) versus SLE patients (0.139, n = 83, P = 0.089), but again no difference between African American controls (0.188, n = 24) and SLE patients (0.191, n = 34). These data suggest that the 981H residue compensates for low constitutive expression of E-CR1 in Caucasians by enhancing C4b binding. This may contribute protection against SLE.     

Influence of TPA (12-O-tetradodecanoyl-phorbol-13-acetate) on human B lymphocyte function

A deficiency of C3b receptors (CR1) on erythrocytes from patients with systemic lupus erythematosus (SLE) has already been reported and assumed to be one of the causes of the impaired immune complex clearing function found in these patients. In the present study, we developed a functional assay to quantify the amount of CR1 on human erythrocytes. Sample erythrocytes were reacted with tetanus toxoid-anti-tetanus toxoid immune complexes (IC) in the presence of complement. The amount of CR1 was expressed as the amount of IC bound to sample erythrocytes. Determination of CR1 showed a decrease in erythrocytes from patients with SLE, rheumatoid arthritis and other connective tissue diseases. The activity of CR1 in erythrocytes from patients with SLE changed in parallel with complement activity and also reflected the clinical status of two of three patients. These results imply that the reduction of CR1 found in SLE patients might be cause not only by hereditary factors but by unknown factors that influence the amount or function of CR1.     

Physiological up-regulation of inhibitory receptors Fc gamma RII and CR1 on memory B cells is lacking in SLE patients

Under physiological conditions immune complexes (IC) are efficiently cleared from the circulation and meanwhile provide important feedback signals for the immune system via Fc gamma Rs and complement receptors. Dysregulation of these mechanisms have been implicated in conditions where IC concentrations reach pathological levels and inflict diseases, like systemic lupus erythematosus (SLE). Our aim was to compare distinct sub-populations of CD19(+) B cells of healthy individuals and SLE patients with regard to their expression of Fc gamma R type II (Fc gamma RII, CD32), complement receptor type 1 (CR1, CD35) and complement receptor type 2 (CR2, CD21) and sIgG/IgM. The following four groups of peripheral CD19(+) B cells were investigated: IgM(+)/CD27(-) naive, IgM(+)/CD27(+) and IgM(-)/CD27(+) memory cells and CD27(high) plasmablasts. We demonstrate that the expression of the inhibitory receptors Fc gamma RII and CR1 is up-regulated on peripheral memory B cells of healthy controls, whereas this up-regulation is considerably impaired on the memory B cells of SLE patients. This reduction affects both the IgM(+) and switched memory B cells. We found a striking difference between the expression of complement receptors CD21 and CD35; namely, no up-regulation of CD21 occurred on the memory B cells of healthy donors, and its decreased expression in SLE patients was characteristic for both the CD27(-) naive and the CD27(+) memory B-cell populations. Our results clearly demonstrate that the previously reported reduced expression of IC-binding receptors is mainly due to the disturbed memory compartment; however, the higher frequency of CD19(+)/CD27(high)/sIg(low) plasmablasts expressing minimal levels of these receptors also contributes to this diminution.     

Effects of immune complex formation and complement activation on circulating platelets in the primate

Primate platelets are different from rodent and rabbit platelets in that they do not express receptors for C3a or C5a or immune adherence receptors. This study assessed the effects of immune complex (IC)-induced complement activation on primate platelets in the circulation. Cynomolgus monkeys (CYN, N = 4) immunized to bovine gamma globulin (BGG) were infused with BGG over 5 min to induce acute intravascular IC formation and complement activation. The studies were carried out under normal complement conditions (N = 12), partial complement inhibition (CAB-2 treated, N = 3), or total complement inhibition (CVF treated, N = 1). Under normal complement conditions, BGG infusion increased C3a levels from undetectable to an average of 11.9 +/- 2.6 micrograms/ml. At this time, decreases occurring in both circulating neutrophils (85 +/- 6%) and monocytes (78 +/- 6%) were significantly greater than decreases in circulating platelets (13 +/- 3%, p < 0.001). Partial complement inhibition had an equivocal effect on the BGG-induced changes in circulating leukocytes, while total complement inhibition abrogated these changes. In contrast, platelet changes were unaffected by complement inhibition. We conclude that, compared to circulating leukocytes, circulating platelets are insensitive to intravascular complement activation induced by IC in the nonhuman primate. These results contrast with previous studies in rodents which demonstrate strong effects of IC-induced intravascular complement activation on both circulating neutrophils and platelets.     

CR1 and CR1-like: the primate immune adherence receptors

Immune adherence describes the phenomenon in which complement‐opsonized substrates, such as immune complexes (IC), viruses, or bacteria, are bound by primate erythrocytes via erythrocyte complement receptors. In vivo studies have shown that this binding allows the erythrocyte to act as an inert shuttle, targeting IC to the monocyte phagocytic system and away from vulnerable tissue. Thus, immune adherence appears to play an integral role in the primate in promoting the safe clearance of circulating IC and preventing IC‐mediated pathologies. The complement receptors that mediate immune adherence comprise two unique but closely related gene products, either the type one complement receptor (CR1) in humans or CR1‐like in non‐human primates. This review focuses on the structure, function, and physiological role of the primate immune adherence receptors.     

Immune complex binding to erythrocyte-CR1 (CD 35), CR1 expression and levels of erythrocyte-fixed C3 fragments in SLE outpatients

Erythrocytes (E) from a cross-sectional group of 22 outpatients with systemic lupus erythematosus (SLE) and/or mixed connective tissue disease (MCTD), the majority without active disease (n = 14), were analyzed for CR1 antigen expression and capacity to bind complement opsonized, radiolabelled immune complexes (IC). Furthermore, E-bound C3 fragments and the plasma C3d concentration were determined. E-bound C3b/iC3b fragments were not elevated in patients with SLE, whereas E from 11 out of 22 SLE patients had increased C3d levels which correlated with the plasma C3d concentration (Rs 0.73, p less than 0.001). E-fixed C3d fragments did not affect the binding of Mab or preopsonized IC to E-CR1 and were not correlated with disease activity or medical treatment. Antigen expression of E-CR1 measured by ELISA or agglutination showed positive correlation with the IC binding capacity of E-CR1 (Rs 0.92 and 0.72 respectively, p less than 001). The IC binding capacity of E-CR1 from SLE patients was significantly reduced (p less than 0.005), whereas the antigen expression of CR1 (ELISA) on E from the patients did not differ from that of E from healthy donors (p greater than 0.1). E-CR1 antigen was measured by Mab reacting with an epitope outside the IC-binding site of E-CR1. E-CR1 antigen expression or IC binding showed no correlation either with disease activity or prednisolone treatment. However, 4 og 5 patients with MCTD and 4 of 5 patients receiving Imurel were found to have low E-CR1 expression and capacity to bind IC. Thus, measurement of antigenic E-CR1 in a cross-sectional group of SLE outpatients by use of Mab reacting with an epitope outside the ligand-binding region of CR1 did not reveal a significantly reduced CR1 expression. However, an assay for CR1-mediated IC binding showed a clearly reduced E-CR1 function.     

Consumption of erythrocyte CR1 (CD35) is associated with protection against systemic lupus erythematosus renal flare

Erythrocyte complement receptor type one (E-CR1) is thought to protect against immune complex (IC) disease through interactions that lead to E-CR1 consumption, and low E-CR1 levels are characteristic of systemic lupus erythematosus (SLE). The purpose of this study was to test the hypothesis that E-CR1 consumption can predict or mark SLE flare. Recurrently active SLE patients [n = 43; 28 with past or present major renal manifestations (SLER) and 15 without (SLENR)], were evaluated every 2 months by detailed protocol testing (mean follow-up 22 months), including direct measurements of E-CR1 levels using a radioimmunoassay. In all patients, detectable E-CR1 levels fluctuated widely through acute periods of consumption and regeneration, preventing the use of any single value as a baseline. However, when individual chronic baseline values were used, determined as the mean of all E-CR1 values 4 months or more from a flare, a clear trend was observed. In 16 of 16 instances of non-renal flare in SLER patients, E-CR1 levels decreased at flare (mean decrease 34%, P < 0.0001). In contrast, no consistent difference was observed for flare in SLENR patients or for renal flare in SLER patients. Changes in E-CR1 levels did not correlate with plasma CR1 levels. In conclusion, single occurrences of E-CR1 consumption did not generally predict or mark SLE flare. However, compared to the average E-CR1 levels measured during no-flare intervals, E-CR1 consumption in SLER patients at flare was strongly associated with freedom from signs of renal involvement. We postulate that E-CR1 consumption reflects E-CR1 function that includes protecting against SLE nephritis.     

Association of T cell and macrophage dysfunction with surface gp 120-immunoglobulin-complement complexes in HIV-infected patients.

The mechanism of CD4+ cell depletion and functional T helper cell inhibition in HIV-infected individuals is poorly understood. The present study demonstrates that immune complex-covered CD4+ cells are associated with T cell inhibition and macrophage stimulation. We studied 30 patients with ARC/AIDS and 35 asymptomatic HIV+ haemophilia patients. Overall, 20 +/- 3% of peripheral CD4+ lymphocytes were covered with gp120 (range 0-94%). gp120+ cells also exhibited surface-bound IgG (P = 0.0001), IgM (P = 0.0001), and complement (P = 0.0001). Decreased in vitro lymphocyte proliferation was associated with the immune complex load of CD4+ cells. The higher the percentage of CD4+ gp 120+ cells in the blood, the lower the T cell response in vitro (P = 0.001). Moreover, an association was found between immune complex-positive cells and plasma neopterin (P = 0.01). Patients with increased plasma neopterin levels had decreased in vitro responses to pokeweed mitogen (PWM) (P = 0.006), phytohaemagglutinin (PHA) (P = 0.004), concanavalin A (Con A) (P = 0.09), and anti-CD3 MoAb (P = 0.03), and decreased CD4+ cell counts in the blood (P = 0.006). Since maximally 1% of CD4+ lymphocytes are infected with HIV, T cell dysfunction and T cell depletion in HIV-infected patients may also be caused by the release of free gp120 that binds to uninfected CD4+ cells. Our data suggest that the functional inhibition and subsequent elimination of uninfected CD4+ lymphocytes with surface gp120-immunoglobulin-complement complexes may be a pathomechanism in the manifestation of AIDS.     

A lysine-binding protein in SLE sera inhibits the binding of immune complexes to normal erythrocyte CR1 (complement receptor type 1).

The binding of 125I-labelled immune complexes (IC) to normal human erythrocyte CR1 (complement receptor type 1) by sera from patients with SLE was found to be significantly decreased compared to normal sera. In 13/29 patients, there was an inhibitor which decreased the binding of opsonized IC in normal sera to normal erythrocytes. It was found in each of the nine patients who had clinically active disease. The inhibitor was shown to be a globulin that was labile at 56 degrees C and bound to lysine; low concentrations of tranexamic acid and of lysine abolished the effects of the inhibitor which suggests that it possesses lysine-binding sites: these may block the CR1-binding site on IC opsonized with complement. This inhibitor may decrease the efficiency of IC carriage by erythrocyte CR1.     

Concerted clearance of immune complexes bound to the human erythrocyte complement receptor: development of a heterologous mouse model

Experiments in primates have demonstrated that immune complexes (IC) bound to erythrocytes (E) via complement receptor 1 (CR1) are cleared to the liver in a process which removes CR1, but otherwise spares the E. Human E are stabilized for >1 h in the circulation of the mouse if the terminal complement pathway is blocked, and we used this paradigm to examine clearance in a mouse model. Human E were opsonized with an anti-CR1 mAb cross-linked to dsDNA (antigen-based heteropolymer, AHP), and then incubated with systemic lupus erythematosus (SLE) plasmas containing IgG anti-dsDNA to form IC in situ. These IC stably bind to E CR1 in the complete absence of complement, thus allowing analysis in a model which does not require human C3b to facilitate E binding. Dual label experiments, based on RIA, flow cytometry and fluorescence microscopy, were employed to monitor separately E and IC. When opsonized E-IC were injected into A/J mice, >90% of the IC were rapidly removed from the E coincident with loss of CR1. The E remained in the circulation while IC were localized to the liver, mainly to Kupffer cells. Preliminary experiments in NZB/W mice, which spontaneously develop IgG anti-dsDNA, indicated that infusion of E-AHP led to rapid binding of murine IgG to the E-AHP, followed by removal of the nascent IC from E, and loss of CR1 in a concerted reaction. These studies provide additional evidence that E CR1 functions as a privileged site for IC clearance, and that the key step in clearance requires removal of CR1 from E to release bound IC for uptake by acceptor macrophages. This model can be extended to genetically altered mice to investigate the role of specific Fcγ receptors as well as complement receptors in IC clearance.     

Conformational changes induced by hapten in murine monoclonal antibodies to dinitrophenyl groups--the analysis by temperature-perturbation spectroscopy

Complement receptor for C3b (CR1) on erythrocytes was investigated in various diseases by immune adherence hemagglutination (IAHA) using aggregated human IgG. In normal controls, 21 out of 312 (6%) revealed defective CR1 reactivity, and there was no difference in the prevalence of defective CR1 reactivity between female (11/157, 7%) and male (10/155, 6%). Among diseases examined significantly high prevalence of defective reactivity of CR1 on erythrocytes was seen in systemic lupus erythematosus (SLE) (22/30, 73%) and malignancy of hematopoietic system, especially in acute myelogenous leukemia (AML)(6/11, 55%).     

Immune adherence of nascent hepatitis B surface antigen-antibody complexes in vivo in humans

Upon i.v. injection into humans, pre-formed immune complexes bind complement and adhere to complement receptor type I (CR1, CD35) on erythrocytes (immune adherence). However, in most circumstances antigen and antibody react in the presence of complement; such nascent immune complexes may have properties different from pre-formed immune complexes. To define whether nascent immune complexes would also adhere to erythrocytes in vivo in humans, we studied immune complexes that formed upon i.v. injection of radiolabelled hepatitis B surface antigen (HBsAg) into immunized volunteers (eight subjects with anti-HBsAb levels ranging from undetectable to 50 U/ml.; and three control non-immune individuals). Immune complexes formed immediately in the subjects with detectable levels of specific antibody, and the clearance rate of these immune complexes correlated with the anti-HBsAb level (r = 0.78, P < 0.01). A fraction of the circulating immune complexes bound to erythrocytes in the three individuals with the highest antibody level (8-15% at 10 min). The effect of CR1 number per erythrocytes was analysed in two subjects with similar antibody levels and immune complexes clearance rates: immune adherence was higher in the subject with more CR1 per erythrocytes. The same immune complexes model studied in vitro provided similar results: a fraction of nascent immune complexes bound to human erythrocytes; this immune adherence was observed only when immune complexes formed in the presence of antibody excess, and correlated with CR1 number per erythrocytes (r = 0.99, P < 0.01). Finally, adherence of nascent HBsAg-antibody immune complexes to platelets was demonstrated in rabbits. Although immune adherence involves only a small fraction of nascent immune complexes at any given time, it may be essential for the safe disposal of large nascent immune complexes.     

Cytokine induction by circulating immune complexes and signs of in-vivo complement activation in systemic lupus erythematosus are associated with the occurrence of anti-Sjögren's syndrome A antibodies

Circulating immune complexes (IC) and levels of IC‐induced cytokines have been correlated with complement activation and autoantibody profiles in systemic lupus erythematosus (SLE). SLE sera were analysed concerning levels of immune complexes (IC), classical complement function and different antinuclear and anti‐C‐reactive protein (CRP) autoantibodies. Blood mononuclear cells from healthy donors were stimulated with isolated IC and production of interleukin (IL)‐10, IL‐6 and IL‐12p40 was measured. Functional experiments revealed that increased levels of IC‐induced cytokines were associated with both increased classical complement activation and the occurrence of anti‐Sjögren's syndrome A (SSA) and anti‐SSB but not other autoantibodies. Biochemical measurement of circulating IC showed that the degree of complement activation and the occurrence of anti‐SSA were synergistically associated with levels of circulating IC in SLE sera, as complement activation was a prerequisite for the enhancing effect of anti‐SSA. Anti‐CRP was associated with complement activation, but not with other autoantibodies. Our results indicate that anti‐SSA and possibly anti‐SSB antibodies influence IC formation and subsequent IC‐induced cytokine induction, and that they thereby participate in the inflammatory process in active SLE.     

Immune complex binding efficiency of erythrocyte complement receptor 1 (CR1).

C3b-coated immune complexes adhere to the complement receptor 1 (CR1, CD35) on human erythrocytes. This multi-valent binding might be favoured by the known clustering of CR1 and by the multiple C3b-binding sites on each CR1. The size of the CR1 clusters correlates directly with the number of CR1/erythrocytes, and the different structural CR1 alleles bear between two and five C3b-binding sites. Using radiolabelled hepatitis B surface antigen-antibody complexes, we investigated whether CR1 numbers and structural alleles modulate the ability of erythrocytes to bind immune complexes, and assessed if any reorganization of immune complexes takes place at the erythrocyte surface after the initial binding reaction. The binding efficiency (immune complexes/CR1) correlated with CR1 number as determined by the maximal binding at 4 degrees C, the kinetics of binding at 37 degrees C, and the binding in the presence of excess immune complexes and of immune complexes of small size. Binding efficiencies were similar for erythrocytes with low CR1 from normal subjects and patients with AIDS or SLE. A monoclonal antibody blocking the C3b-binding sites (3D9) of CR1 interfered with binding efficiency at a lower concentration on cells bearing low CR1 numbers, suggesting that CR1 clustering is essential. The larger alleles of CR1 (DD and BB) were more efficient than AA alleles. The distribution of immune complexes, visualized by immunofluorescence, was heterogeneous on erythrocytes: about two out of three cells bore between one and 12 immune complexes. No visible immune complex reorganization took place after initial binding, as prefixed erythrocytes displayed the same immune complex distribution and number/erythrocytes as unfixed erythrocytes. The contribution of CR1 alleles in immune complex binding efficiency was confirmed by morphological analysis. These results demonstrate that immune adherence efficiency is the resultant of the CR1 clustering, as well as the particular alleles carried by erythrocytes. Moreover, there is little or no immune complexes surface reorganization after the initial binding reaction.