Characterization of the human glomerular C3 receptor as the C3b/C4b complement type one (CR1) receptor

The functional and immunochemical characteristics of the human glomerular C3 receptor were investigated by adherence of sheep erythrocytes (Es) coated with defined C3 fragments and by using polyclonal and/or monoclonal antibodies directed against epitopes expressed on complement receptors CR1, CR2, and CR3. C3b-bearing Es (EsC3b) strongly adhered to glomeruli in frozen kidney sections in a reaction that was selectively inhibited by F(ab')2 anti-CR1 antibodies. There was no adherence of EsC3dg, EsC3d, and EsC3bi in the presence or absence of Ca++ and Mg++ under physiologic buffer conditions. The weak glomerular binding of EsC3bi, which was observed in half-isotonic buffer was selectively suppressed by anti-CR1 antibodies. By indirect immunofluorescence, anti-CR1 antibodies stained all podocytes in glomeruli, whereas no staining of kidney sections was seen with OKM1 and anti-Mol antibodies directed against the alpha-chain of CR3 and with anti-CR2 antibodies anti-B2 and BL13. Solubilization of membrane glycoproteins from freshly isolated glomeruli from three human kidneys, in the presence of 0.1% Nonidet P-40, yielded a material that bound to lentil lectin Sepharose and could accelerate the decay of preformed cell-bound amplification C3 convertase sites in a reaction that was inhibited by anti-CR1 antibodies. The material containing CR1 activity was labeled with 125I, immunoprecipitated with anti-CR1, and analyzed by SDS-PAGE and autoradiography. Anti-CR1 immunoprecipitated a form of CR1 of Mr 205,000 in solubilized glomeruli from three donors, and an additional form of Mr 160,000 in glomeruli from two of the donors. Immunoprecipitation of CR1 from surface-labeled erythrocytes from these individuals demonstrated them to be homozygous for the 205,000 Mr form of the receptor. Whether the 160,000 band represents in vitro or in vivo proteolytic cleavage of CR1, or cell specific-modulation of gene expression of glomerular CR1, remains unclear. Thus, CR1 is the only type of C3 receptor expressed in the human kidney. Glomerular CR1 shares the functional antigenic and biochemical properties of the C3b/C4b CR1 receptor of peripheral blood cells.     

Polymorphism of the C3b/C4b receptor (CR1): characterization of a fourth allele

The receptor for C3b/C4b (C3bR or CR1) has an unusual polymorphism in which three codominant alleles determine variants with a large difference in Mr (160,000, 190,000, or 220,000). We found an individual who has, in addition to the common 190,000 Mr molecule, a C3bR whose Mr is 250,000. In this proband and in some members of his family, this novel heterozygous phenotype can be isolated from 125I surface-labeled cells by iC3 or iC4 affinity chromatography or by immunoprecipitation with the use of polyclonal or monoclonal anti-C3bR. Relative to the 190,000 Mr C3bR, E from individuals in this family have 20 to 30% of the total receptor counts in the 250,000 Mr C3bR. However, on C3bR-bearing leukocytes there is a much larger amount of the 250,000 Mr C3bR (approximately 60%) relative to the 190,000 Mr C3bR. Similar to the other three C3bR variants, the Mr is 5,000 greater on polymorphonuclear cells than on E, and treatment of this new C3bR with endoglycosidase F decreases its Mr by approximately 10,000. Therefore, because this variant is inherited and has structural and functional similarities to the other three C3bR, we conclude that this 250,000 Mr CR1 probably represents a fourth allele.     

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.     

Sodium fluoride reveals multiple pathways for regulation of surface expression of the C3b/C4b receptor (CR1) on human polymorphonuclear leukocytes

We have examined the effects of NaF on C3b receptor (CR1) expression and function in human polymorphonuclear leukocytes (PMN). Plasma membrane expression of CR1 was determined with a monoclonal antibody (3D9); CR1 function was assessed with erythrocytes bearing C3b (EC3b) or C3b oligomers prepared with avidin and biotin. NaF inhibited in a dose-dependent manner CR1-mediated phagocytosis and NaF inhibited f-met-leu-phe or phorbol dibutyrate-induced increases in CR1 expression, with 50% inhibition at 5 mM NaF. Increased plasma membrane expression of CR3 induced by f-met-leu-phe also was inhibited by NaF. However, increased CR1 and CR3 expression due to incubation at 37 degrees C were unaffected by 10 mM NaF. Incubation of PMN with 10 mM NaF depleted 80% of intracellular adenosine triphosphate (ATP) after 10 min. However, inhibition of CR1 function was unrelated to ATP level, inasmuch as normal increases in CR1 expression and in phagocytosis occurred 20 min after removal of NaF, whereas ATP levels remained below 25% of normal. Strikingly, internalization of soluble oligomeric C3b ligands was unaffected by 10 mM NaF, which completely inhibited phorbol dibutyrate-induced CR1 internalization and EC3b phagocytosis. We conclude that there are two different mechanisms for increasing plasma membrane expression of CR1, one of which is inhibitable by NaF. Moreover, there are two distinct pathways of CR1 internalization which can also be distinguished by their sensitivity to NaF.     

Fibronectin-enhanced phagocytosis of an alternative pathway activator by human culture-derived macrophages is mediated by the C4b/C3b complement receptor (CR1)

We examined the ability of human monocytes and culture-derived macrophages under serum-free conditions to phagocytose desialated sheep erythrocytes (E), an activator of the alternative pathway of human complement. Freshly derived monocytes ingested desialated erythrocytes, but the degree of phagocytosis varied among individual donors. However, exposing the phagocyte to intact plasma fibronectin (Fn) had no effect on monocyte phagocytosis. Macrophages derived from monocytes in culture were far more efficient at ingesting desialated E, and the extent of phagocytosis was proportional to the degree of desialation. Although exposure of macrophages to substrate-bound Fn or fluid-phase Fn enhanced the phagocytosis of desialated E, pretreatment of desialated E with Fn did not enhance phagocytosis, demonstrating that Fn acted through an interaction with the macrophages. Fn-enhanced phagocytosis of desialated E was inhibited by treating macrophages with a monoclonal antibody to the C4b/C3b receptor (CR1), but not with a monoclonal antibody to the receptor for C3bi (CR3). Addition of cobra venom factor (CVF) to the macrophages also inhibited Fn-enhanced phagocytosis of desialated E. Phagocytosis of IgG-sensitized E, either in the absence or in the presence of Fn, was not significantly affected by anti-CR1 or CVF, demonstrating that these reagents did not lead to a general inhibition of phagocytosis. These experiments suggest that macrophages may deposit enough C3b onto desialated E to cause CR1-mediated phagocytosis in the presence of Fn. The ability of macrophages to opsonize and ingest foreign particles that activate complement may be critically important in areas of inflammation where concentrations of serum-derived specific opsonins may be inadequate.     

Cell surface expression of the C3b/C4b receptor (CR1) protects Chinese hamster ovary cells from lysis by human complement.

The C3b/C4b receptor, also known as complement receptor type 1 (CR1, CD35), is a single chain glycoprotein consisting of 30 repeating homologous protein domains known as short consensus repeats (SCR) followed by transmembrane and cytoplasmic domains. A series of recombinant proteins derived from CR1 has been prepared and assessed for the capacity to inhibit complement lysis of the host Chinese hamster ovary (CHO) cells. The full-length recombinant CR1 inhibited human complement-mediated CHO cell lysis, and the efficiency of inhibition was directly proportional to the number of receptors/cell. The SCR 15-18 of CR1, but not SCR 15-16, inhibited complement lysis of the host CHO cell, bound monomeric C3b (Kd,app = 6.5 x 10(-7) M), and dimeric C3b (Kd = 1.8 x 10(-8) M), and served as a cofactor in the proteolysis of C3b by factor I, confirming and extending the observations of Fearon and colleagues (Kalli, K. R., Hsu, P., Bartow, T. J., Ahearn, J. M., Matsumoto, A. K., Klickstein, L. B., and Fearon, D. T. (1991) J. Exp. Med. 174, 1451-1460). The SCR 1-4 of CR1, but not SCR 1-2, also inhibited complement lysis of the host CHO cell, indicating that more than two SCR are necessary and that four SCR are sufficient for optimal C4b binding to CR1. Thus, the structural requirements for C4b binding are analogous to those for C3b binding, namely, four SCR of CR1 form the binding sites for each of these proteins. CR1 has long been recognized to regulate extrinsic complement activation, that is, to bind to and promote the degradation of fluid phase C3b and of C3b attached to immune complex. These results demonstrate that CR1 is also an intrinsic regulator of complement activation in that, under appropriate conditions, CR1 inhibits complement-mediated lysis of the cell on which it is expressed.     

Factor I-dependent inactivation of human complement C4b of the classical pathway by C3b/C4b receptor (CR1, CD35) and membrane cofactor protein (MCP, CD46).

Proteolytic inactivation of C4b is a crucial step for regulation of the classical complement pathway. A plasma protease factor I and membrane cofactors, C3b/C4b receptor (CR1) and membrane cofactor protein (MCP), participate in the regulation of cell-bound C4b although the physiological potency of these cofactors remains unknown. We have examined the optimal conditions of the factor I-mediated C4b regulatory system using purified cofactors. CR1 being a cofactor at a cofactor/C4b ratio less than 0.1 (w/w), fluid phase C4b, and methylamine-treated C4 (C4ma) were degraded by factor I into C4bi: minimal Cd4 was generated in the fluid phase. Liposome-bound C4b (LAC4b), on the other hand, was degraded into C4c and C4d. CR1 showed two optimal pHs (6.0 and 7.5) for fluid phase C4b, but one (6.0) for LAC4b, and in both cases low conductivity conditions enhanced the C4bi generation. CR1 cofactor activity was barely influenced by the NP-40 concentration. On the other hand, MCP degraded C4b and C4ma, as a factor I-cofactor, more efficiently into C4c and C4d. Though MCP cofactor activity, like that of CR1, was enhanced under low conductivity conditions, it has only one optimal pH, 6.0, in both fluid and solid phases. Furthermore, as in the case of C3b cleavage, a sufficient NP-40 concentration to solubilize membrane was needed for MCP to express full cofactor activity for C4b, in contrast to CR1. MCP was less potent for C4b inactivation than for C3b inactivation, while CR1 acted as a slightly more effective cofactor for C4b cleavage than for C3b cleavage.(ABSTRACT TRUNCATED AT 250 WORDS)     

Deficiency of erythrocyte C3b receptor (CR1) in AIDS and AIDS-related syndromes

The expression of C3b receptors (CR1) on erythrocytes of gay men at various levels of risk for AIDS was studied. Fourty-nine heterosexual male controls had a mean (X)±standard deviation of 516±136 CR1 per erythrocyte (CR1-3); 17 asymptomatic gay men had X=423±156, 16 gay men with one AIDS-related complex (ARC) symptom or sign had X=342±154, 9 patients with ARC had X=252±76, and 14 gay men with AIDS had X=173±76 CR1-E. The patients with ARC and AIDS had a highly significant decrease in CR1-E when compared with normal individuals (p=<0.001) and studies of families of 4 AIDS patients suggest that this defect is acquired.     

Deficiency of the C3b/C4b receptor (CR1) of erythrocytes in systemic lupus erythematosus: analysis of the stability of the defect and of a restriction fragment length polymorphism of the CR1 gene

The role of genetic factors in controlling CR1 quantitative expression on erythrocytes (E) of patients with systemic lupus erythematosus (SLE) was reexamined by determining the temporal stability of CR1 numbers and the frequency of a CR1 genomic restriction fragment length polymorphism (RFLP). The mean number of binding sites/(E) for Yz-1 monoclonal anti-CR1 correlated with the number of sites for polyclonal anti-CR1 that had been determined 2 to 4 yr previously in 18 normal persons (p less than 0.001), 18 patients (p less than 0.001), and 28 relatives (p less than 0.001), indicating that CR1 sites/E was a stable characteristic in all three groups. The mean number of Yz-1 sites/E was 281 +/- 34 (+/- SEM) in 28 probands with SLE and 457 +/- 21 in 93 relatives, both determinations being less than that for 100 normal persons, 553 +/- 21 (p less than 0.002). Thirty-six patients and 51 normal individuals were also assessed for the presence of the 7.4 kb and 6.9 kb HindIII CR1 allelic restriction fragments that correlate with high and low expression, respectively, of CR1 on E. The distribution of patients differed from normal (p less than 0.05), with a smaller proportion being homozygous for the 7.4 kb allele. In addition, the mean numbers of Yz-1 sites/E for patients and relatives who were homozygous (p less than 0.02) and heterozygous (p less than 0.05) for the 7.4 kb allele were significantly lower than those for normal persons matched for the HindIII RFLP, suggesting the existence of additional heritable factors that decrease CR1 expression. The stability over time of the CR1 deficiency among patients, the finding of decreased CR1 number among an expanded group of relatives, the altered frequency among patients of CR1 alleles defined by the HindIII RFLP, and the decreased expression of CR1 on E among patients and relatives compared with normal individuals having the same HindIII RFLP indicate a role for genetic factors in CR1 deficiency in SLE.     

The C4A and C4B isotypic forms of human complement fragment C4b have the same intrinsic affinity for complement receptor 1 (CR1/CD35)

Several previous reports concluded that the C4b fragment of human C4A (C4Ab) binds with higher affinity to CR1 than does C4Bb. Because the isotypic residues, (1101)PCPVLD and (1101)LSPVIH in C4A and C4B, respectively, are located within the C4d region, one may have expected a direct binding contribution of C4d to the interaction with CR1. However, using surface plasmon resonance as our analytical tool, with soluble rCR1 immobilized on the biosensor chip, we failed to detect significant binding of C4d of either isotype. By contrast, binding of C4c was readily detectable. C4A and C4B, purified from plasma lacking one of the isotypes, were Cs converted to C4Ab and C4Bb. Spontaneously formed disulfide-linked dimers were separated from monomers and higher oligomers by sequential chromatographic steps. The binding sensorgrams of C4Ab and C4Bb monomers as analytes reached steady state plateaus, and these equilibrium data yielded essentially superimposable saturation curves that were well fit by a one-site binding model. Although a two-site model was required to fit the equilibrium-binding data for the dimeric forms of C4b, once again there was little difference in the K(D) values obtained for each isotype. Independent verification of our surface plasmon resonance studies came from ELISA-based inhibition experiments in which monomers of C4Ab and C4Bb were equipotent in inhibiting the binding of soluble CR1 to plate-bound C4b. Although divergent from previous reports, our results are consistent with recent C4Ad structural data that raised serious doubts about there being a conformational basis for the previously reported isotypic differences in the C4b-CR1 interaction.     

Purification and functional analysis of the polymorphic variants of the C3b/C4b receptor (CR1) and comparison with H, C4b-binding protein (C4bp), and decay accelerating factor (DAF)

Four CR1 variants have been found in the normal population and are designated CR1-A (190,000 daltons), CR1-B (220,000 daltons), CR1-C (160,000 daltons), and CR1-D (250,000 daltons). In the present study, we first developed an improved chromatographic purification scheme for CR1 that does not employ a C3b affinity step. CR1 variants (A, B, and C) were then isolated, and their individual functional activity was assessed. Each possessed similar co-factor activity for I-mediated cleavage of C3(H2O), as well as for the inhibitory activity for fluid phase C3 convertases. These results indicate that, despite relatively large Mr differences, in the purified state these three CR1 variants have similar functional activities. The functional activity of CR1 was also compared with C4bp, H, and decay accelerating factor (DAF) in fluid phase assays designed to assess the inhibition of the C3 convertases and co-factor activity. On a molar basis, CR1 had approximately the same inhibitory activity as C4bp for the classical pathway convertase, and had the same as H for the alternative pathway convertase. These results indicate that CR1 encompasses the functional capabilities of both proteins. They also raise a number of interesting genetic and structural questions in regard to these complement regulatory proteins, because C4bp is thought to have multiple C4b binding domains, whereas H is reported to bind one C3b. DAF was an approximately fourfold better inhibitor of the alternative pathway convertase than CR1 or H, but was a fourfold less efficient inhibitor of the classical pathway convertase than CR1 or C4bp. The effective inhibitory capacity of DAF in these fluid phase assay systems suggests that the DAF substrate specificity is for the convertases. Fluid phase CR1 was twofold less efficient than H in serving as a co-factor for the first cleavage of fluid phase C3b, and hardly mediated the second cleavage. These data are in contrast to the co-factor activity of CR1 on a cell membrane, and provide additional evidence for the local environment being a critical modulator of the function of proteins that regulate the activation of C3.     

Native C3 does not bind to the C3b receptor (CR1) of human blood B lymphocytes or alter immunoglobulin synthesis

Complement receptors on lymphocytes were first described more than 12 yr ago (1-3) and have come to be used as a common marker for the identification of B cells (4). The function of these receptors on the lymphocyte and their possible role in induction and/or regulation of the immune response remain unclear. In particular, there continues to be controversy as to whether native C3 can bind to the C3b receptor of these cells without cleavage to C3b (5-10). The resolution of this question is critical in order to clarify the expected state of availability of the receptor in vivo, because in plasma, the C3 concentration is relatively high (1.1 to 1.5 mg/ml), whereas there is little or no circulating C3b due to efficient degradation by factor H and the C3-inactivator (11). With the recent development of an improved method for the isolation of C3 from human plasma, it has been possible to obtain biochemically and functionally pure C3 that has not undergone structural or conformational alteration during processing and fully retains the specific hemolytic activity of C3 in fresh serum (12). Berger et al. (13) were able to demonstrate that C3 prepared in this way failed to bind to the C3b receptor of human polymorphonuclear leukocytes or erythrocytes. Similar observations were made by Schreiber et al. (14), also with phagocytic cells and erythrocytes, and by Dixit et al. (15) with an isolated membrane receptor preparation from rabbit macrophages. In the present communication, we extend these observations to human peripheral blood B lymphocytes. Purified C3 in its native state fails to block B lymphocyte-EA (IgM) C4b3b rosettes, whereas C3b causes 50% inhibition at 5 to 6 micrograms/ml. Furthermore, C3 failed to alter polyclonal immunoglobulin (Ig) production by human B cells, whereas C3b inhibited this B cell function. These data suggest that native C3 does not bind to the C3b receptors of B lymphocytes, and thus they are not occupied under normal conditions in vivo.     

The partly folded back solution structure arrangement of the 30 SCR domains in human complement receptor type 1 (CR1) permits access to its C3b and C4b ligands

Human complement receptor type 1 (CR1, CD35) is a type I membrane-bound glycoprotein that belongs to the regulators of complement activity (RCA) family. The extra-cellular component of CR1 is comprised of 30 short complement regulator (SCR) domains, whereas complement receptor type 2 (CR2) has 15 SCR domains and factor H (FH) has 20 SCR domains. The domain arrangement of a soluble form of CR1 (sCR1) was studied by X-ray scattering and analytical ultracentrifugation. The radius of gyration R_G of sCR1 of 13.4(±1.1) nm is not much greater than those for CR2 and FH, and its R_G/R₀ anisotropy ratio is 3.76, compared to ratios of 3.67 for FH and 4.1 for CR2. Unlike CR2, but similar to FH, two cross-sectional R_G ranges were identified that gave R_XS values of 4.7(±0.2) nm and 1.2(±0.7) nm, respectively, showing that the SCR domains adopt a range of conformations including folded-back ones. The distance distribution function P(r) showed that the most commonly occurring distance in sCR1 is at 11.5 nm. Its maximum length of 55 nm is less than double those for CR2 or FH, even though sCR1 has twice the number of SCR domains compared to CR2 Sedimentation equilibrium experiments gave a mean molecular weight of 235 kDa for sCR1. This is consistent with the value of 245 kDa calculated from its composition including 14 N-linked oligosaccharide sites, and confirmed that sCR1 is a monomer in solution. Sedimentation velocity experiments gave a sedimentation coefficient of 5.8 S. From this, the frictional ratio (f/f₀) of sCR1 was calculated to be 2.29, which is greater than those of 1.96 for CR2 and 1.77 for FH. The constrained scattering modelling of the sCR1 solution structure starting from homologous SCR domain structures generated 5000 trial conformationally randomised models, 43 of which gave good scattering fits to show that sCR1 has a partly folded-back structure. We conclude that the inter-SCR linkers show structural features in common with those in FH, but differ from those in CR2, and the SCR arrangement in CR1 will permit C3b or C4b to access all three ligand sites.     

Interferon-gamma-dependent modulation of C3b receptors (CR1) on human peripheral blood monocytes

Cell surface expression of the C3b receptor (CR1) was transiently down regulated on purified human monocytes exposed to purified recombinant human interferon-gamma(rIFN-gamma). Receptors were quantitated by using CR1-specific monoclonal antibody by radioimmunoassay or flow cytometry and by rosette analysis with the use of C3b-coated bovine erythrocytes. The reduction of CR1 was dependent on the dose of IFN-gamma used and the time of cellular exposure. Down-regulation was transient, with maximum loss occurring after 2 to 3 days of stimulation with IFN-gamma. However, after 6 days CR1 was re-expressed at the plasma membrane. This effect was observed with monocytes isolated by either centrifugal elutriation or adherence on fibronectin-coated dishes. IFN-gamma-dependent diminution of CR1 occurred concomitant with increased expression of Fc receptors and HLA-DQ antigen and unaltered expression of the C3bi receptor (CR3). The mechanism of CR1 loss from the monocyte cell surface was not due to internalization, because total cellular levels of CR1 (plasma membrane and intracellular pool) also decreased in response to IFN-gamma. These results indicate that IFN-gamma may be involved in regulating CR1 on mononuclear phagocyte surfaces.     

Human T lymphocytes expressing the C3b/C4b complement receptor type one (CR1, CD35) belong to Fc gamma receptor-positive CD4-positive T cells

The phenotypic characteristics of human T lymphocytes expressing the C3b/C4b complement receptor type one (CR1, CD35) were investigated using dual-color surface immunofluorescence and cytofluorometric analysis of stained peripheral blood mononuclear cells (PBMC) from normal individuals. Two to ten percent of PBMC coexpressed CR1 and the CD5, CD2, or CD3 antigen. CR1 was detected on a subset of CD4+ T lymphocytes but not on CD8+ or on Leu-7+ lymphocytes. Costaining for CR1 and for the CD4 subpopulation markers anti-Leu-8, TQ1, OKT17, 2H4, and 4B4 indicated that CR1 on lymphocytes may be coexpressed with any of these phenotypic determinants. All CR1+ lymphocytes expressed Fc gamma receptors (Fc gamma Rs) as assessed by their ability to bind biotinylated dimeric human IgG. The expression of CR1 was increased in mixed lymphocyte reaction with kinetics similar to those of HLA-DR antigen expression. Coexpression of CR1 and Fc gamma R+ may provide a subset of CD4+ lymphocytes with an enhanced ability to bind and respond to C3-bearing complexes of IgG and antigen.     

Interaction of human monomeric C3b with its receptor (complement receptor type 1, CR1) on neutrophils. Evidence for negative cooperativity

The binding of highly purified monomeric 125I-C3b to its receptor (CR1) on resting human polymorphonuclear neutrophils (PMN) was analyzed under equilibrium conditions, at 4 degrees C and low ionic strength. Scatchard analysis of specific binding data yielded curvilinear concave upward plots, which resulted from the presence of site-site interactions of the negative type among PMN C3b-receptors (negative cooperativity), as shown by dissociation kinetic experiments. Indeed, the dissociation rate of 125I-C3b from PMN was markedly increased in the presence of an excess of unlabeled C3b in the dilution medium and was directly dependent on the degree of initial receptor occupancy with the radioligand. These interactions occurred when 2% of the receptors were occupied with 125I-C3b and resulted in a 4-fold decrease in CR1 affinity when the receptor went from its "empty" to its "filled" conformation. In a disease associated with a continuous production of C3b (factor I deficiency), CR1 on in vivo circulating PMN was found to be in a "low affinity" and "high dissociating" state similar to that of normal CR1 at high occupancy. Finally, negative cooperativity among CR1 sites disappeared after PMN activation with chemotactic peptides.     

Translation of the human C3b/C4b receptor mRNA in a cell-free system and by Xenopus oocytes

The C3b/C4b complement receptor (CR1) is a large, single-chain integral membrane glycoprotein present on erythrocytes, leukocytes, glomerular podocytes, and splenic dendritic-reticular cells that mediates the binding of complement-coated particles and immune complexes. CR1 is unusual in that it is polymorphic in size with the four allelic variants having molecular weights of 190,000, 220,000, 250,000, and 280,000 (SDS-PAGE, reducing conditions). The in vitro translation of the common (Mr 220,000) allelic variant CR1 has been achieved by using mRNA in lysates of rabbit reticulocytes and in Xenopus oocytes. HL-60, a promyelocytic human leukemic cell line, was treated with DMSO to induce differentiation and synthesis of CR1. Poly(A+) RNA was purified from these cells by column chromatography on oligo(dT)-cellulose. In the rabbit reticulocyte system, no CR1 was detected unless the translation mixture was denatured. In the presence of methylmercuric hydroxide, the CR1 translation product, unlike most translation products, had the same molecular weight in gel electrophoresis as the high-mannose-containing pro-CR1 and was 15-20K larger than nonglycosylated CR1. This suggests that a cotranslational modification of CR1 structure occurs, probably involving a proteolytic cleavage event. When poly(A+) RNA was translated in Xenopus oocytes, CR1 could be detected by treatment of oocytes with anti-CR1 monoclonal antibody followed by fluorescein-conjugated goat anti-mouse IgG. CR1 was diffusely distributed but preferentially localized to the vegetal surface. The molecular weight of this product, identified in immunoprecipitates of lysates of [35S]methionine-labeled oocytes, was identical with that of CR1 of HL-60.     

Regulation of proteolytic activity of complement factor I by pH: C3b/C4b receptor (CR1) and membrane cofactor protein (MCP) have different pH optima for factor I-mediated cleavage of C3b

C3b/C4b receptor (CR1) and membrane cofactor protein (MCP) are integral membrane glycoproteins with factor I-dependent cofactor activity. They bind to C3b, allowing factor I to cleave C3b at two sites (first and second cleavage), which results in the generation of C3bi, a hemolytically inactive form which is a ligand for complement receptor type three (CR3). C3bi is further degraded by factor I and CR1 (third cleavage) to C3dg (a ligand for complement receptor type two, CR2) and C3c. Using two different substrates, fluid-phase C3b and cell-bound C3b, the cleavage of C3b by MCP and factor I was compared to that by CR1 and factor I under various conditions. The optimal pH for the first and second cleavage of either substrate was 6.0 for MCP and 7.5 for CR1. The third cleavage was mediated only by CR1 and factor I, the optimal pH being 8.0. Low ionic conditions enhanced the C3b binding and cofactor activity of both CR1 and MCP. The efficiency of binding C3b to CR1 or MCP was maximal at pH 6.2. The isoelectric point (pI) of MCP was acidic (approximately 4.0), while that of CR1 was 6.8. Therefore, compared to CR1, MCP possesses distinct functional profiles relative to C3b-binding and factor I-cofactor activity.