Monoclonal anti-mouse macrophage antibodies recognize the globular portions of C1q, a subcomponent of the first component of complement

One of seven monoclonal antibodies generated against mouse macrophages (M phi) was found to recognize isolated heterologous C1q. This antibody was shown to be cytotoxic and to react in a strain-independent way with mouse M phi derived from bone marrow cells as well as with M phi from the peritoneal cavity; it did not react, however, with mouse granulocytes, thymocytes, or T and B lymphocytes. The hemolytic activity of fluid phase C1q was inhibited to 50% at a 2 X 10(-4) dilution of hybridoma supernatant, whereas a 100-fold higher concentration was required to inhibit C1q bound to immune complexes ( EAC1q ) to the same extent. It was demonstrated that this antibody recognizes the isolated globular, Fc-binding portions of the C1q molecule and reacts with the A and B chains. Because M phi have been shown to synthesize C1q, the Fc-recognizing subcomponent of the first component of complement, evidence was provided that endogeneous C1q can serve as an Fc receptor on M phi during secretion. This fact was demonstrated by a dose-dependent inhibition of Fc-receptor activity for EIgG by the F(ab')2 fragment of this monoclonal antibody. These experiments further support the concept that C1q produced by M phi functions on the surface as an Fc-recognizing molecule before it is released and incorporated into the macromolecular complex of serum C1.     

NH2-terminal calcium-binding domain of human complement C1s- mediates the interaction of C1r- with C1q

The assembly of C1, the first component of human complement, involves interactions between various domains of each of its three subcomponents, C1q, C1r, and C1s. The isolation, assignment of function, and structural characterization of the individual domains of C1r and C1s are critical for a thorough understanding of this complex assembly. The present study describes a 27-kDa plasmin-generated fragment derived from the NH2-terminal half of the heavy A chain of C1s-, the activated form of C1s. This fragment, C1s-alpha, was shown in the presence of Ca2+ to mimic the ability of whole C1s- to self-associate, bind to C1r-, and facilitate the binding of C1r to C1q. These results directly prove that the Ca2(+)-binding sites of C1s as well as all of the determinants necessary for binding of C1s- to C1r- and C1q are located in the NH2-terminal 27-kDa alpha region of the A chain.     

Activation of the first component of human complement (C1) by antibody-antigen aggregates.

The activation of subcomponents C1r and C1s in the first component of complement, C1, when bound to antibody-antigen complexes was investigated. Activation was followed both by the splitting of the peptide chains of subcomponents C1r and C1s and by the development of proteolytic activity. For the maximum rate of activation to occur, all components must be present in approximate molar proportions of antibody: C1q:C1r:C1s of 13:1:5:5. For activation of subcomponent C1s, subcomponents C1r or C1r, but not C1r inactivated with iPr2P-F (di-isopropyl phosphorofluorideate), are effective. For activation of subcomponent C1r, subcomponents C1s, C1s or C1s inactivated with iPr2P-F are effective. Subcomponent C1s is activated by C1r, and C1r is activated autocatalytically, probably through the formation of an intermediary C1r. in which the peptide chain is unsplit but a conformational change caused by interaction with the other components has led to the formation of a catalytic site able to split subcomponent C1r to C1r.     

Molecular modelling of human complement subcomponent C1q and its complex with C1r2C1s2 derived from neutron-scattering curves and hydrodynamic properties.

Models for the structures of subcomponent C1q of first component C1 of human complement and its complex with subunit C1r2C1s2 are compared with experimental neutron-scattering curves. The length of the C1q collagenous arm is closer to 14.5 nm than to 11.5 nm proposed from electron microscopy, and this is consistent with the primary sequence of C1q. The mean C1q base-arm angle is 40-45 degrees and C1q is found to be flexible: the base-arm angle can vary up to 30 degrees from equilibrium at any moment. The complex of C1r2C1s2 and C1q requires a large shape change in C1r2C1s2. Ring-like models for C1r2C1s2 are not as successful at rationalizing the scattering data as are models that involve C1r2C1s2 binding to one side of C1q. Hydrodynamic calculations of the sedimentation coefficients for C1q and C1 are generally consistent with these neutron models.     

Production and characterization of a murine monoclonal IgM antibody to human C1q receptor (C1qR)

A hybridoma cell line that produces a monoclonal antibody (MAb) to cell surface C1q receptor (C1qR) has been produced by fusion of the P3 X 63-Ag8.653 mouse myeloma cell line with the spleen cells of a CD-1 mouse that had been hyperimmunized with viable Raji cell suspensions (5 X 10(7) cells/inoculum). This MAb, designated II1/D1, is an IgM antibody with lambda-light chain specificity. Radiolabeled or unlabeled, highly purified II1/D1 was used to determine that: this antibody competes for C1q binding sites on C1qR-bearing cells; the molecule recognized by this MAb is the C1qR; and cells that are known to bind C1q also bind II1/D1 in a specific manner. Western blot analysis of solubilized Raji, or U937 cell membranes, showed that the 125I-MAb detected a major protein band of approximately 85,000 m.w. in its unreduced state, indicating that the C1qR is similar, if not identical, in both types of cells. Analyses of 125I-II1/D1 binding experiments revealed that the antibody bound to Raji cells or U937 cells in a specific manner. Uptake of the antibody was saturable, with equilibrium virtually attained within 35 min. Scatchard analysis of the binding data using the intact MAb suggests that the affinity constant KD is 2.9 X 10(-10) M, and at apparent saturation, 24.6 ng of the antibody were bound per 2 X 10(6) cells, giving an estimated 7.8 X 10(3) antibody molecules bound per cell. That the II1/D1 antibody is specifically directed to the C1q was further evidenced by an ELISA in which the ability of C1qR-bearing cells to bind the MAb was abrogated by c-C1q in a specific and dose-dependent manner. These results indicate that the II1/D1 is a specific antibody directed against the C1q and can be a useful tool in studying the biologic interaction of human C1q with its receptors on a variety of cells.     

The Croonian Lecture, 1980. The complex proteases of the complement system

The assembly and activation of the early components of complement, after their interaction with antibody-antigen complexes, are described in terms of the structures of the different proteins taking part. C1q, a molecule of unique half collagen--half globular structure, binds to the second constant domain of the antibody molecules through its six globular heads. A tetrameric complex of C1r2-C1s2 binds to the collagenous tails and leads to formation of the serine-type proteases C1r and C1s. C1s activates C4, which forms a covalent bond between its alpha' chain and the Fab section of the antibody. C2 is also activated by C1s and associates with the bound C4 molecule to form C42, a labile protease that activates C3, but which loses activity as the C2 peptide chains dissociate from C4. C2, by analogy with factor B, the equivalent component of the alternative pathway of activation, appears to be a novel type of serine protease with a similar catalytic site but different activation mechanism to the serine proteases that have been described previously.     

Measurement of macromolecular interactions between complement subcomponents C1q, C1r, C1s, and immunoglobulin IgM by sedimentation analysis using the analytical ultracentrifuge

The interactions between the complement components and with immunoglobulins are greatly enhanced by lowering the ionic strength and become readily measurable by physical techniques. Thus, the binding between C1q and IgM was previously shown to be appreciable (k = 1 x 10(6) M-1) at 0.084 M ionic strength (Poon, P.H., Phillips, M.L., and Schumaker, V.N. (1985) J. Biol. Chem. 260, 9357-9365). We have now found that, at 0.128 M ionic strength, the binding between human C1- (the activated first component of complement) and IgM was strong at physiological concentrations (k = 1 x 10(7) M-1), while under the same conditions binding between C1q and IgM was not observed. To explore the nature of the interactions responsible for this enhanced binding by C1- over C1q, mixtures of the various subcomponents of C1- were studied alone and with IgM. C1r2 did not bind to C1q, even when the ionic strength was reduced to 0.098 M, nor did the presence of C1r2 enhance the binding of C1q to IgM. In contrast, two C1s2 independently bound to C1q (k = 1 x 10(6) M-1), and caused a marked increase in its association with IgM (k = 5 x 10(6) M-1) at 0.098 M ionic strength. No detectable interaction was found between C1s2 and/or C1r2 and IgM in the absence of C1q. Moreover, there was no detectable interaction between the C1(-)-like complex formed between C1r2C1s2 and the collagenous C1q stalks (pepsin-digested C1q) and IgM. These data suggest that the binding of C1s2 to C1q, either alone or together with C1r2, induces a conformational change in C1q which results in additional C1q heads binding to complementary sites on IgM.     

The role of the C9b domain in the binding of C9 molecules to EAC1-8 defined by monoclonal antibodies to C9

Three mAb to human C9, X195, X197, and P40 were used to analyze the roles of the C9a and C9b domains in the reaction of the C9 molecule with sensitized sheep E bearing C1 to C8 (EAC1-8). X195 bound to NH2-terminal (C9a) fragments, and X197 bound to COOH-terminal (C9b) fragments obtained by cleavage of C9 with alpha-thrombin or trypsin. P40 recognized the epitope on the C9b fragment obtained by alpha-thrombin cleavage but did not react with the NH2-terminal or COOH-terminal fragment obtained by trypsin cleavage. In this respect, P40 differed from mAb to C9 reported previously. P40 almost completely inhibited the hemolytic activity of C9. X195 and X197 also inhibited C9 activity, but less effectively than P40. C9 molecules bound to P40 could not bind to EAC1-8 cells. C9 bound to X197 could not bind rapidly to EAC1-8, but prolonged incubation of the C9-X197 complex with EAC1-8 caused considerable lysis of the cells. C9 molecules bound to X195 could bind rapidly to EAC1-8, but their lytic activity was partially inhibited by the bound antibody. From these results, it is concluded that the C9b but not C9a domain contributes to the binding of C9 to EAC1-8 and that the epitope recognized by P40 or a closely adjacent site may be the binding site of C9 molecule to EAC1-8.     

Structural model of the collagen-like region of C1q comprising the kink region and the fibre-like packing of the six triple helices

A detailed three-dimensional model of the collagenous part of C1q was derived by model building and computer-aided energy refinement calculations. The proposed structure is based on the collagen-like (-Gly-Xaa-Yaa-) repeating sequence of 78 to 81 residues in the N-terminal regions of the constituent A, B and C chains, on the mode of disulphide linkage between the 18 chains of C1q, and on its electron microscopically derived gross structure. It is demonstrated that the interruptions of the repeating sequence about half-way along the length of the collagenous regions (Gly36-Ile37-Arg38-Thr39 in the A chain and Ala36-Ile37-Hy138 in the C chain) do not lead to a disruption of the triple helical conformation but rather to a bend of about 60 degrees in an otherwise continuous triple helix. These features are consistent with a flexibility comparable with that of regular triple helices and with the observed low proteolytic susceptibility of the kink region. The azimuthal orientation of the kink is defined approximately by ArgA38 being located in the cap of the knee. Because of this extra residue between two glycine residues, a bad contact that would arise between the methyl group of AlaC36 and the peptide carbonyl of IleA37 in a straight triple helix is relaxed. The model features also a cluster of hydrophobic contacts between large hydrophobic side-chains in the interaction edges between the six collagen triple helices aligned with their about 10 nm long N-terminal regions in the fibril-like endpiece of C1q. The azimuthal orientations of the triple helices were derived by energy calculations of side-chain interactions previously applied to fibre-forming collagens. Independently, the same orientations and interaction edges were derived from the azimuthal orientation of the kink and the electron microscopically observed orientations of the triple helical arms that emerge from the endpiece, and which carry the C-terminal globular binding domains. The structural model has a number of implications for the assembly of the first component of complement from C1q and the zymogen complex C1r2C1s2 and possible mechanisms of its activation.     

Enhanced Ig production by human peripheral lymphocytes induced by aggregated C1q

Because B cells express receptors for C1q, we have investigated the role of C1q in the stimulation of B cells. When B cells were cultured in the presence of C1q that had been frozen, T cells, and suboptimal concentrations of PWM, there was a dose-dependent enhancement of IgM, IgG, and IgA by the B cells. No significant enhancement of Ig production by B cells was seen in the absence of T cells or PWM. The contribution of T cells or PWM could be replaced by supernatants of PMA and Con A-activated PBMC (T cell growth factor). C1q that had been frozen, in contrast with freshly isolated C1q, was at least 3 times more active in enhancement of the production of Ig by B cells in culture in the presence of suboptimal concentrations of T cell growth factor. The capability of C1q to stimulate B cells could be ascribed to aggregates of C1q. Monomeric C1q was only marginally active to stimulate B cell Ig production, whereas dimeric and tetrameric C1q were able to enhance Ig production by B cells in relation to their size. Furthermore, aggregation of C1q on soluble aggregates of rabbit IgM also increased its potential to enhance B cell Ig production. The interaction of C1q with the B cells occurs via the collagenous tail of C1q, as suggested by inhibition experiments with purified collagenous tails and globular heads of C1q. These results indicate that triggering of C1qR on B cells positively regulates Ig production in vitro.     

Receptor-mediated binding of C1q on pulmonary endothelial cells

Normal undamaged pulmonary endothelial cells appear to be immunologically privileged in that they do not express receptors for the Fc portion of IgG nor for C3b. However, these receptors become unmasked on endothelial cells injured by viral infection or exposure to white cell lysates. We now present evidence to indicate that C1q binds to specific receptors on the surface of normal healthy endothelial cells. The binding is dose-dependent, reversible and saturable. Furthermore our data show that binding of C1q to endothelial cells is via the collagenous portion of the molecule not via the globular head regions. Thus binding of C1q to endothelium would have the effect of exposing Fc receptors that could then bind to IgG of circulating immune complexes. That Fc receptors are in fact exposed is shown by rosette formation with antibody sensitized erythrocytes. With 2C1r-2C1s-associated C1q, no binding occurred using C1 fixation and transfer assays. Our results indicate that C1q binding to endothelium provides a means for localizing immune complexes on pulmonary vessels and may be important in the initiation and progression of the inflammatory response.     

Inhibition of metastasis of syngeneic murine melanoma in vivo and vasculogenesis in vitro by monoclonal antibody C11C1 targeted to domain 5 of high molecular weight kininogen

Metastasis of malignant tumors is a major cause of morbidity and mortality. Inhibition of tumor growth in distant organs is of clinical importance. We have demonstrated that C11C1, a murine monoclonal antibody to the light chain region of high molecular weight kininogen (HK), reduces growth of murine multiple myeloma in normal mice and human colon cancer in nude mice. C11C1 inhibits angiogenesis by reducing tumor microvascular density by blocking binding of HK to endothelial cells. We now evaluate the anti-metastatic effect of C11C1 on C57BL/6 mouse lung metastatic model using B16F10 melanoma cells. The tail veins of mice were injected with 0.5 × 10⁶ cells of melanoma B16F10. One group received C11C1 and the other received saline (control) intraperitoneally. When mice were killed at 28 days, 6 of 10 control mice had detectable metastatic pulmonary nodules which stained positive with an antibody against S-100 protein, a tumor antigen present in malignant melanoma cells. In the C11C1 groups, none of the mice showed metastatic foci in their lungs. We showed that C11C1 inhibits endothelial cell tube formation in a 3-D collagen fibrinogen gel model by inhibiting the rate of cleavage of HK by plasma kallikrein without changing the binding affinity for HK. These studies demonstrate that a monoclonal antibody to HK has the potential to prevent metastasis with minimal side effects.     

Factor J: isolation and characterization of a new polypeptide inhibitor of complement C1

An Mr 20,000 protein inhibitor of C1, the first component of complement, has been purified from human urine and characterized. This inhibitor, tentatively designated factor J, is apparently distinct from known complement inhibitors. During purification on QAE-Sephadex, Mono Q, and heparin-Sepharose, factor J was detected by its ability to inhibit the complement-mediated lysis of sheep erythrocytes bearing antibody, C1, and activated C4 (EAC14). The purity of factor J was documented by the concordant elution from a hydroxylapatite column of functional activity and the UV absorbance as measured at three different wavelengths (220, 254, and 280 nm). The relative Mr of 20,000 was determined by sodium dodecyl sulfate-slab gel electrophoresis of radioiodinated protein. Amino acid analysis indicated a high cysteine content and allowed calculations of a specific activity of 7 functional units/pmol. The target of factor J inhibitory activity on the lysis of EAC14 was localized to C1 by the following criteria: factor J inhibited C1 in a C1 transfer assay, but had no effect on C42 activity or decay, and had no effect on the efficiency of isolated C2 or C3-C9 as provided in serum-EDTA. Factor J inhibition was rapid and not significantly influenced by temperature. In a second functional assay, factor J inhibited the association of the tetrameric complex C1r2s2 with 125I-C1q, and the results, when analyzed graphically by a reciprocal plot, were consistent with noncompetitive inhibition (Ki = 529-760 pM range). Functional and/or antigenic data indicated that factor J is distinct from the other known inhibitors of C1, namely the C1 inhibitor and the C1q inhibitor. Antihuman serum precipitated radioiodinated factor J, indicating that an antigen identical or cross-reacting with factor J exists in serum. In summary, factor J is a newly described potent inhibitor of C1 function.     

Activation of the first component of human complement, C1, by monoclonal antibodies directed against different domains of subcomponent C1q

Two monoclonal antibodies directed against C1q, and their (Fab)2 and Fab fragments, were used to study the mechanism of C1 activation. Monoclonal antibody 2A10, an IgG2a, was digested by pepsin to yield fully immunoreactive (Fab')2. Monoclonal antibody 1H11, an IgG1, was digested by papain to yield fully immunoreactive, bivalent (Fab)2. Previously 1H11 had been shown to bind to the C1q "heads," whereas 2A10 bound to stalks. Activation of C1 was followed by the cleavage of 125I-C1s in the presence of C1 inhibitor (C1-Inh) at 37 degrees C. Spontaneous activation was minimal at inhibitor concentrations above 0.4 micron (1.3 X physiologic inhibitor concentration); all results were corrected for the spontaneous activation background. Heat-aggregated IgG activated completely in this system and was taken as 100% activation. Monoclonal antibody 2A10 caused precipitation of C1 and slow activation; neither the (Fab')2 nor the Fab' derived from 2A10-caused activation. Probably, aggregates of intact 2A10 and C1 were serving as immune complexes to activate other molecules of C1. In contrast, both 1H11 and its (Fab)2 activated completely and stoichiometrically; that is, maximal activation was achieved at a ratio of one C1q head to one antibody combining site. The monovalent Fab derived from 1H11 bound well to C1q, but no activation of C1 was observed. Thus, bivalent binding of this head-binding monoclonal is required for C1 activation, but not the presence of the antibody Fc portion. Neither 1H11 nor its (Fab)2 fragments caused C1 precipitation; however, the 1H11 did form complexes composed of two C1q cross-linked by multiple 1H11, which were visualized by electron microscopy. The presence of these dimeric complexes correlated well with activation. A model for C1 activation is proposed in which two C1q subcomponents are held together by multiple (Fab)2 bridging C1q heads. The model is roughly analogous to touching opposing pairs of fingers and thumb tips, the two hands representing the two C1q, forming a cage. C1-Inh, which probably binds to C1r through the open end of the C1 cone, is too long asymmetric to be included within the cage. Thus, according to this model, the dimers of C1 are released from the inhibitory action of C1-Inh, and activation proceeds spontaneously and rapidly at 37 degrees C.     

Trimeric reassembly of the globular domain of human C1q

C1q is a versatile recognition protein which binds to a variety of targets and consequently triggers the classical pathway of complement. C1q is a hetero-trimer composed of three chains (A, B and C) arranged in three domains, a short N-terminal region, followed by a collagenous repeat domain that gives rise to the formation of (ABC) triple helices, each ending in a C-terminal hetero-trimeric globular domain, called gC1q, which is responsible for the recognition properties of C1q. The mechanism of the trimeric assembly of C1q and in particular the role of each domain in the process is unknown. Here, we have investigated if the gC1q domain was able to assemble into functional trimers, in vitro, in the absence of the collagenous domain, a motif known to promote obligatory trimers in other proteins. Acid-mediated gC1q protomers reassembled into functional trimers, once neutralized, indicating that it is the gC1q domain which possesses the information for trimerization. However, reassembly occurred after neutralization, only if the gC1q protomers had preserved a residual tertiary structure at the end of the acidic treatment. Thus, the collagenous domain of C1q might initialize the folding of the gC1q domain so that subsequent assembly of the entire molecule can occur.     

C1q Protein Binds to the Apoptotic Nucleolus and Causes C1 Protease Degradation of Nucleolar Proteins

In infection, complement C1q recognizes pathogen-congregated antibodies and elicits complement activation. Among endogenous ligands, C1q binds to DNA and apoptotic cells, but whether C1q binds to nuclear DNA in apoptotic cells remains to be investigated. With UV irradiation-induced apoptosis, C1q initially bound to peripheral cellular regions in early apoptotic cells. By 6 h, binding concentrated in the nuclei to the nucleolus but not the chromatins. When nucleoli were isolated from non-apoptotic cells, C1q also bound to these structures. In vivo, C1q exists as the C1 complex (C1qC1r₂C1s₂), and C1q binding to ligands activates the C1r/C1s proteases. Incubation of nucleoli with C1 caused degradation of the nucleolar proteins nucleolin and nucleophosmin 1. This was inhibited by the C1 inhibitor. The nucleoli are abundant with autoantigens. C1q binding and C1r/C1s degradation of nucleolar antigens during cell apoptosis potentially reduces autoimmunity. These findings help us to understand why genetic C1q and C1r/C1s deficiencies cause systemic lupus erythematosus.     

Recombinant human complement subcomponent C1s lacking beta-hydroxyasparagine, sialic acid, and one of its two carbohydrate chains still reassembles with C1q and C1r to form a functional C1 complex.

In contrast to the human serum protein which is approximately one-half erythro-beta-hydroxyasparagine at asparagine 134 [Theilens et al. (1990) Biochemistry 29, 3570-3578], recombinant C1s expressed by insect cells after infection with recombinant baculovirus entirely lacks posttranslational modification at asparagine 134. It is also incompletely glycosylated, lacking, at least, sialic acid. Site-directed mutagenesis of one of the two sites of carbohydrate attachment (Asn 159 to Gln 159) yields a faster migrating recombinant C1s still abundantly secreted. Furthermore, the mutated protein displays good hemolytic activity when reassembled with C1q and either human serum or recombinant C1r, demonstrating that these posttranslational modifications are not critical for any of the multiple interactions between C1s and C1q, C1r, C2, and C4 required for reassembly of the C1 complex, activation, and initiation of the classical complement pathway. The 4.0S recombinant C1s dimerizes to yield 5.6S C1s2 in the presence of Ca2+ and forms the 9.1S C1s-C1r-C1r-C1s tetramer upon the addition of human serum C1r and the 15.6S C1 complex upon the addition of C1q to the tetramer. The recombinant C1s and human serum C1s have identical N-terminal amino acid sequences, indicating proper recognition by the insect signal peptidase. The recombinant C1s is secreted and isolated as the unactivated zymogen, and it may be activated by human serum C1r which cleaves at Arg422-Ile423 to yield the characteristic heavy and light chains. A very tight complex is formed between C1-inhibitor and the light chain of recombinant C1s.(ABSTRACT TRUNCATED AT 250 WORDS)     

The unactivated form of the first component of human complement, C1.

The first component of complement, C1, was isolated unactivated from human serum by repeated additions of di-isopropyl phosphorofluoridate during isolation. The unactivated subcomponents were also isolated, and evidence is given that the three subcomponents C1q, C1r and C1s account wholly for the activity of component C1 in serum. No evidence could be found for a fourth subcomponent, C1t. The approximate molar proportions of the subcomponents in serum are C1q/C1r/C1s = 1:2:2. Optimum activity by haemolytic assay was found at approximate molar proportions C1q/C1r/C1s of 1:4:4. No activity was found when subcomponents were assayed singly or in pairs, except for subcomponents C1q and C1s, which in molar ratio 1:4 gave 15-20% of the activity of the mixture C1q + C1r + C1s. The proteolytic activity of the isolated subcomponent C1s varied according to the method of activation used. Subcomponents C1q + C1r + C1s and C1q + C1s in the presence of antibody-antigen aggregates were activated and inactivated simultaneously, showing a peak of activity and subsequent loss of activity. Both reactions are probably due to proteolysis, and analysis of the peptide bonds split will be necessary to distinguish these two phenomena.     

Existence of different but overlapping IgG- and IgM-binding sites on the globular domain of human C1q

C1q is the first subcomponent of the classical complement pathway that binds antigen-bound IgG or IgM and initiates complement activation via association of serine proteases C1r and C1s. The globular domain of C1q (gC1q), which is the ligand-recognition domain, is a heterotrimeric structure composed of the C-terminal regions of A (ghA), B (ghB), and C (ghC) chains. The expression and functional characterization of ghA, ghB, and ghC modules have revealed that each chain has some structural and functional autonomy. Although a number of studies have tried to identify IgG-binding sites on the gC1q domain, no such attempt has been made to localize IgM-binding site. On the basis of the information available via the gC1q crystal structure, molecular modeling, mutational studies, and bioinformatics, we have generated a series of substitution mutants of ghA, ghB, and ghC and examined their interactions with IgM. The comparative analysis of IgM- and IgG-binding abilities of the mutants suggests that the IgG- and IgM-binding sites within the gC1q domain are different but may overlap. Whereas Arg(B108), Arg (B109), and Tyr(B175) mainly constitute the IgM-binding site, the residues Arg(B114), Arg(B129), Arg(B163), and His(B117) that have been shown to be central to IgG binding are not important for the C1q-IgM interaction. Given the location of Arg(B108), Arg (B109), and Tyr(B175) in the gC1q crystal structure, it is likely that C1q interacts with IgM via the top of the gC1q domain.     

Human pulmonary surfactant protein (SP-A), a protein structurally homologous to C1q, can enhance FcR- and CR1-mediated phagocytosis

C1q, a subunit of the first component (C1) of the classical complement pathway, and the pulmonary surfactant protein SP-A are structurally homologous molecules, each having an extended collagen-like domain contiguous with a non-collagenous domain. It is the collagen-like region of C1q that binds to mononuclear phagocytes and mediates the enhancement of phagocytosis of opsonized particles by these cells. Because SP-A enhances the endocytosis of phospholipids by alveolar type II cells and alveolar macrophages, we examined whether these two molecules were functionally interchangeable. The phagocytosis of sheep erythrocytes opsonized with IgG or with IgM and complement was enhanced by the adherence of monocytes or macrophages, respectively, to SP-A. The enhanced response was dependent on the concentration of SP-A used for coating the surfaces, similar to that seen when monocytes were adhered to C1q-coated surfaces. Both the percentage of cells ingesting the opsonized targets and the number of targets ingested per cell increased with increasing concentrations of SP-A. No such enhancement was seen with cells adhered to albumin, iron-saturated transferrin, or uncoated surfaces. However, SP-A did not substitute for C1q in the formation of hemolytically active C1. C1q did not stimulate lipid uptake by alveolar type II cells or alveolar macrophages and had only a slight inhibitory effect on the binding of SP-A to alveolar type II cells. Thus, these results suggested that a function which requires interactions of both the collagenous and the non-collagenous regions (i.e. initiation of the classic complement cascade) could not be mimicked by a protein sharing structural macromolecular similarity but lacking sequence homology in the non-collagen-like region. However, SP-A could substitute for C1q in stimulating a function previously shown to be mediated by the collagen-like domains of the C1q molecule.